paging method and apparatus and communication timing method and apparatus

专利摘要:
This application discloses a method and apparatus for paging. The method includes: receiving, by a network device, a random access preamble from a terminal device, where the random access preamble is used to request a paging message; obtain, by the network device, a paging identifier associated with the preamble of random access; and sending, through the network device, a paging message to the terminal device based on the paging identifier. This application can reduce signaling overhead in a paging process.
公开号:BR112020005990A2
申请号:R112020005990-0
申请日:2018-09-26
公开日:2020-09-29
发明作者:Huang Huang；Mao Yan；Kuandong Gao
申请人:Huawei Technologies Co., Ltd.；
IPC主号:

专利说明:

[0001] [0001] The present invention relates to the communications field and, in particular, to a paging method and apparatus and to a communication timing method and apparatus. FUNDAMENTALS
[0002] [0002] To improve data rates and the effectiveness of wireless communication, a beamforming technology is provided in a next generation wireless communications system (eg new radio). Beam-forming technology can limit the energy of a transmission signal to a beam direction, to improve the effectiveness of signal reception. Beaming technology can effectively increase the transmission range of a radio signal and reduce signal interference to achieve greater communication efficiency and greater network capacity. Beam forming technology poses challenges for beam management, while improving the effectiveness of a communications network.
[0003] [0003] In a next generation communications system, due to the existence of a plurality of beams and beam directivity, a paging message needs to be sent through the beam scan. If all paging messages are sent on each beam, excessive overhead is caused by sending paging messages. SUMMARY
[0004] [0004] This application provides a paging method and apparatus and a communication timing method and apparatus, so that a terminal device is triggered by the use of a random access preamble, sending a paging message, to reduce overloads signaling.
[0005] [0005] According to a first aspect, this request provides a pagination method, including: receiving, by a network device, a random access preamble from a terminal device, where the random access preamble is used to request a paging message; obtain, by the network device, a paging identifier associated with the preamble of random access; and sending, via the network device to the terminal device based on the paging identifier, a paging message corresponding to a group of paging users.
[0006] [0006] The random access preamble is used to trigger a paging procedure. The network device can recognize a type of the received random access preamble, and if the type of the random access preamble is a pre-established type, determine whether the random access preamble is used to request the paging message. The paging identifier is used to encrypt a physical downlink control channel, PDCCH, and the physical downlink control channel indicates a shared downlink channel (psysical downlink shared channel, PDSCH) used to send the paging message. The paging user group is also referred to as a paging group, a paging set, or a paging cluster. A group of paging users includes a plurality of terminal devices. A plurality of terminal devices on the same paging occasion (PO) is grouped into a plurality of groups of paging users, and each group of paging users includes at least one terminal device. A grouping rule is not limited in this order, for example, grouping is performed based on a UE ID (user equipment identifier, user equipment identifier) of the terminal device. The paging identifier can include a radio network temporary identifier (RNTI).
[0007] [0007] In a possible project, the network device receives the preamble of random access from the terminal device, the network device obtains the group of paging users associated with the preamble of random access, and the network device sends, to the terminal device based on the paging identifier corresponding to the paging user group, the paging message corresponding to the paging user group.
[0008] [0008] In a possible project, the network device receives the random access preamble from the terminal device, the network device obtains the paging user group associated with the random access preamble and obtains the paging identifier associated with the group of paging users, and the network device sends the paging message corresponding to the paging user group to the terminal device based on the paging identifier.
[0009] [0009] In this request, the network device sends the paging message to the terminal device in response to the trigger by the random access preamble, and can use an existing random access procedure, to reduce signaling overloads.
[0010] [0010] In a possible project, the sending, by the network device to the terminal device based on the paging identifier, of a paging message corresponding to a group of paging users includes: encrypting, by the network device, a channel physical downlink control based on the paging identifier; and sending, through the network device, the paging message corresponding to the group of paging users to the terminal device on a shared physical downlink channel indicated by the physical downlink control channel.
[0011] [0011] In a possible project, before receiving, by a network device, a preamble of random access from a terminal device, the method additionally includes: sending, through the network device, a paging indication message to the terminal device, where the paging indication message carries a paging indication bit from a group of paging users of the terminal device, and the paging indication bit is a preset value; and / or send, through the network device, random access configuration information to the terminal device, where the random access configuration information is used to configure a random access preamble corresponding to each group of paging users.
[0012] [0012] In a possible project, the random access preamble corresponding to the paging user group is a pre-stored or predefined random access preamble.
[0013] [0013] The network device can group a plurality of terminal devices on the same pagination occasion in a plurality of paging user groups, each paging user group corresponds to a paging indication bit, a preamble of random access and a paging identifier, different groups of paging users correspond to different random access preambles, different groups of paging users have different paging identifiers, and the paging indication bit indicates whether a terminal device is paged in the user group pagination. When the paging indication bit is the preset value, a terminal device in the paging user group associated with the paging indication bit must send a random access preamble to the network device.
[0014] [0014] In a possible project, obtaining, by the network device, a paging identifier associated with the preamble of random access includes:
[0015] [0015] The total number of paging occasions, the total number of paging messages, the total number of random access occasions and the total number of random access preambles, are quantities in the batch receiving cycle, and the receiving cycle Discontinuous includes, but is not limited to, a subframe, a slot or an SS block. The paging occasion is a time interval, and indicates a possible location where the network device sends the paging indication message, and a possible location where the terminal device receives the paging indication message.
[0016] [0016] In a possible project, the network device sends the paging identifier corresponding to the preamble of random access to the terminal device.
[0017] [0017] The network device sends the paging identifier to the terminal device by using system information (system information, SI), a message 2 in a random access process, an RRC message (radio resource control, RRC ), a media access control element (MAC-CE) message, downlink control information, DCI, or a downlink control channel order physical (downlink control channel order, PDCCH order).
[0018] [0018] In a possible design, the network device determines the configuration information for a paging message window of the paging message based on at least one of the following information: a total number of paging occasions, a total amount of paging messages, a total number of random access occasions, a subcarrier spacing, a type of service, a carrier frequency, a total number of random access preambles, an Index of a random access occasion corresponding to the preamble of random access, a random access preamble start time, the random access preamble duration, a random access preamble end time, time domain location information from a random access response window corresponding to the preamble of random access, and frequency domain location information from the corresponding random access response window and a random access response.
[0019] [0019] The total number of paging occasions, the total number of paging messages, the total number of random access occasions and the total number of random access preambles, are quantities in the batch receiving cycle, and the receiving cycle Discontinuous includes, but is not limited to, a subframe, a slot or an SS block. The paging message window is a time interval, the network device sends the paging message in the paging message window, the terminal device receives the paging message in the paging message window and the domain location information of Paging message window times include at least one of a window size and a start time.
[0020] [0020] In a possible project, the network device sends the configuration information from the paging message window to the terminal device, so that the terminal device determines a time domain location and / or a frequency domain location of the paging message window based on the configuration information of the paging message window.
[0021] [0021] In a possible design, the paging identifier can be referred to as an RNTI or a temporary paging radio network identifier (P-RNTI), and the paging identifier is used to encrypt a downlink control channel or downlink control information, DCI corresponding to the paging message.
[0022] [0022] According to a second aspect, this request provides a pagination method, including: sending, by a terminal device, a random access preamble to a network device, where the random access preamble is used to request a message paging system corresponding to a group of paging users of the terminal device; obtain, by the terminal device, a paging identifier associated with the preamble of random access; and receiving, by the terminal device, a paging message from the network device based on the paging identifier.
[0023] [0023] In a possible project, the obtaining, by the terminal device, of a paging identifier associated with the preamble of random access includes: receiving, by the terminal device, the paging identifier that is of the network device and that is associated with the preamble random access; or obtain, by the terminal device, a pre-configured or pre-stored paging identifier associated with the preamble of random access; or determine, by the terminal device based on at least one of the following information, the paging identifier associated with the preamble of random access: a total number of paging occasions, a total number of paging messages, a total number of paging occasions random access, a subcarrier spacing, a type of service, a carrier frequency, a total amount of random access preambles, an index of a random access occasion corresponding to the random access preamble, an index of the random access preamble, an index of the paging message, an index of the paging user group of the terminal device, an index of a time-frequency resource corresponding to the preamble of random access, an index of a block of synchronization signals corresponding to the preamble of random access , an index of a CSI-RS port corresponding to the preamble of random access and a corresponding RA-RNTI the preamble of random access.
[0024] [0024] The total number of paging occasions, the total number of paging messages, the total number of random access occasions and the total number of random access preambles, are quantities in a batch receiving cycle, and the batch cycle. Discontinuous receipt includes, but is not limited to, a subframe, slot, or SS block.
[0025] [0025] In a possible project, the receipt, by the terminal device, of the paging message from the network device in a paging message window based on the paging identifier includes: monitoring, by the terminal device, a control channel corresponding physical downlink in the paging message window based on the paging identifier; and receiving, by the terminal device, the paging message on a shared downlink channel indicated by the downlink control channel.
[0026] [0026] In a possible project, the receipt, by the terminal device, of the paging message from the network device based on the paging identifier includes: obtaining, by the terminal device, configuration information from the message paging message window paging, where the paging message window configuration information includes a start location and / or a paging message window window size; and receiving, by the terminal device, the paging message from the network device in the paging message window based on the paging identifier.
[0027] [0027] In a possible project, obtaining, by the terminal device, configuration information from the paging message window of the paging message includes: receiving, by the terminal device, configuration information from the paging message window of the paging message paging from the network device; or obtain, by the terminal device, pre-stored or pre-configured configuration information from the paging message window of the paging message; or determine, by the terminal device, the configuration information of the paging message window of the paging message based on at least one of the following information: a total number of paging occasions, a total number of paging messages, a quantity total random access occasions, a subcarrier spacing, a type of service, a carrier frequency, a total number of random access preambles, an index of a random access occasion corresponding to the random access preamble, a start time of the random access preamble, duration of the random access preamble, a random access preamble end time, time domain location information from a random access response window corresponding to the random access preamble, domain location information frequency of a random access response and a total number of user groups from pagination.
[0028] [0028] The total number of paging occasions, the total number of paging messages, the total number of random access occasions and the total number of random access preambles, are quantities in the batch receiving cycle, and the receiving cycle discontinuous includes, but is not limited to, a subframe, a slot or an SS block.
[0029] [0029] In a possible project, before sending, by a terminal device, a preamble of random access to a network device, the method additionally includes: receiving, by the terminal device, a paging indication message from the device network, where a paging indication bit that is in the paging indication message and that is from a group of paging users of the terminal device is a pre-established value; and / or receive, by the terminal device, random access configuration information from the network device, where the random access configuration information is used to configure the random access preamble corresponding to each group of paging users, and / or configure the paging user group of the terminal device; and / or receive, by the terminal device, the paging identifier that is from the network device and that is associated with the preamble of random access.
[0030] [0030] In a possible project, the random access preamble corresponding to the group of paging users is a pre-stored or predefined random access preamble.
[0031] [0031] According to a third aspect, this application provides a method of pagination, including:
[0032] [0032] In a possible project, before sending, through the network device, a random access response to the terminal device, the method additionally includes: sending, through the network device, a paging indication message to the terminal device, where a paging indication bit that is in the paging indication message and that is from a group of paging users of the terminal device is a pre-established value; and / or send, through the network device, random access configuration information to the terminal device, where the random access configuration information is used to configure a random access preamble corresponding to each group of paging users.
[0033] [0033] According to a fourth aspect, this request provides a pagination method, including: sending, by a terminal device, a random access preamble to a network device, where the random access preamble is associated with a group of terminal device paging users; receive, by the terminal device, a random access response from the network device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, and the programming information of pagination includes at least one of the frequency information, an encoding and modulation scheme, a reference signal, subcarrier spacing information and DCI; and receiving, by the terminal device, a paging message from the network device based on the paging programming information.
[0034] [0034] In a possible project, before sending, by a terminal device, a preamble of random access to a network device, the method additionally includes: receiving, by the terminal device, a message indicating the paging from the device of network, where a paging indication bit that is carried in the paging indication message and that belongs to the terminal device's paging user group is a pre-established value; and / or receive, by the terminal device, random access configuration information from the network device, where the random access configuration information is used to configure a random access preamble corresponding to each group of paging users.
[0035] [0035] In a possible project, the method additionally includes: when the random access preamble needs to be retransmitted, if a retransmission amount reaches a maximum retransmission amount (maximum preamble transmission number) associated with the random access preamble or an amount maximum retransmission associated with the paging message, interrupting the retransmission; or if the terminal device reaches a next DRX cycle, interrupting retransmission; or if the paging message received by the terminal device does not carry the identifier of the terminal device, interrupt the retransmission.
[0036] [0036] In accordance with a fifth aspect, this request provides a method of communication timing, including: receiving, by a network device, a preamble of random access from a terminal device; determine, by the network device, a format of a time advance command (TAC) and / or a scale factor of a time advance TA based on a random access preamble format; and sending, through the network device to the terminal device, a random access response carrying the TAC and / or the scale factor.
[0037] [0037] The scale factor can also be referred to as a step size (step size or scale factor). The scaling factor can alternatively be sent by the network device using radio resource control signaling (RRC), media access control element signaling (Media access control element) , MAC CE), system information (system information, SI), downlink control information, DCI) or similar, or is determined based on indication information carried in any of the above.
[0038] [0038] In a possible project, in an initial uplink synchronization process, the scale factor and length of the TAC are related to one or more parts of the following information: a subcarrier spacing, SCS), a carrier frequency (carrier frequency / frequency band), a random access preamble format (preamble format), a frame structure, a bandwidth, a service type ),
[0039] [0039] In an uplink synchronization update process, the scale factor and length of the TAC are related to one or more parts of the following information: a subcarrier spacing, a carrier frequency, an access preamble format random, a frame structure, a bandwidth, a type of service and a total amount of random access preambles.
[0040] [0040] In a possible design, the length of the TAC increases along with a length of the preamble of random access. For example, when a sequence length of the random access preamble is 839, the length of the TAC is 11 bits; when the sequence length of the random access preamble is 31, 63, 71, 127 or 139, the length of the TAC is less than 11 bits, and the length of the TAC can be any length between 1 bit and 11 bits.
[0041] [0041] In a possible design, the scale factor increases along with the length of the random access preamble. For example, when the sequence length of the random access preamble is 839, a scale factor value is 16; when the sequence length of the random access preamble is 31, 63, 71, 127 or 139, the scale factor value is less than 16, and the scale factor can be 0.25, 0.5, 1, 2 , 4 or 8.
[0042] [0042] In accordance with a sixth aspect, this request provides a method of communication timing, including: receiving, by a terminal device, a TAC from a network device, and obtaining, by the terminal device, a scale factor ; determine, by the terminal device, a timing advance and / or determine a timing advance offset based on at least one of the TAC from the network device, the scale factor obtained, a random access preamble format currently used, a frame structure, a total amount of random access preambles, a currently used basic time unit, a number of currently used sampling points, a currently used carrier frequency, a current service type, a spacing of currently used subcarrier, currently used subcarrier index, maximum subcarrier spacing, maximum number of sampling points, and currently used displacement factor; and sending, via the terminal device, uplink data based on the timing advance and the timing advance offset.
[0043] [0043] During the implementation of this embodiment of the present invention, the length of the TAC is adjusted based on the sequence length of the random access preamble, to reduce the overhead of transmitting a random access response, and a way of representing the advance timing is changed in different scenarios, to improve the accuracy of the transmission timing advance of the UE.
[0044] [0044] In a possible project, the receipt, by a terminal device, of a TAC from a network device includes: sending, by the terminal device, a preamble of random access to the network device, and receiving, by the device terminal, a random access response that is sent by the network device and which carries the TAC.
[0045] [0045] In a possible project, the terminal device receives the TAC sent by the network device by using signaling, for example, the network device sends the TAC by using signaling, such as RRC signaling, MAC-CE signaling, SI signaling or DCI.
[0046] [0046] In a possible project, obtaining, by the terminal device, a scale factor includes: receiving, by the terminal device, the scaling factor from the network device; or obtain, by the terminal device, a pre-stored or pre-configured scale factor; or determine, by the terminal device, the scale factor based on a length of the preamble of random access. A scale factor value increases with the random access preamble. For example, when the sequence length of the random access preamble is 839, the scale factor value is 16; when the sequence length of the random access preamble is 31, 63, 71, 127 or 139, the scale factor value is less than 16, and the scale factor can be 0.25, 0.5, 1.2 , 4 or 8.
[0047] [0047] According to a seventh aspect, this application provides a paging apparatus. The device has a function of implementing the behavior of the network device in the previous method. The function can be implemented by hardware, or it can be implemented by hardware running the corresponding software. The hardware or software includes one or more modules corresponding to the previous function.
[0048] [0048] In a possible implementation, the device includes: a receiving unit, a processing unit and a sending unit. The receiving unit is configured to receive a random access preamble from a terminal device, where the random access preamble is used to request a paging message. The processing unit is configured to obtain a paging identifier associated with the random access preamble. The sending unit is configured to send a paging message to the terminal device based on the paging identifier.
[0049] [0049] In another possible implementation, the device includes: a receiver, a transmitter, a memory and a processor. The memory is configured to store a segment of program code.
[0050] [0050] The receiver is configured to receive a random access preamble from a terminal device, where the random access preamble is used to request a paging message. The processor is configured to invoke the program code stored by the memory to perform the following operation: obtaining a paging identifier associated with the preamble of random access. The transmitter is configured to send a paging message to the terminal device based on the paging identifier.
[0051] [0051] In a possible implementation, the device can be a chip, and the chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0052] [0052] Based on the same inventive concept, for a principle of solving problems and beneficial effects of the device, consult the implementations of the previous possible method of the network device and its beneficial effects. Therefore, for the implementation of the device, consult the implementation of the method, and the repetitions are not described again.
[0053] [0053] According to an eighth aspect, this application provides a paging apparatus. The device has a function of implementing the behavior of the terminal device in the previous method. The function can be implemented by hardware, or it can be implemented by hardware running the corresponding software. The hardware or software includes one or more modules corresponding to the previous function.
[0054] [0054] In a possible implementation, the device includes: a sending unit, a processing unit and a receiving unit.
[0055] [0055] The sending unit is configured to send a random access preamble to a network device, where the random access preamble is used to request a paging message corresponding to a group of paging users on the device. The processing unit is configured to obtain a paging identifier associated with the random access preamble. The receiving unit is configured to receive a paging message from the network device based on the paging identifier.
[0056] [0056] In another possible implementation, the device includes: a receiver, a transmitter, a memory and a processor. The memory stores a set of program codes.
[0057] [0057] The transmitter is configured to send a random access preamble to a network device, where the random access preamble is used to request a paging message corresponding to a group of paging users on the device.
[0058] [0058] The processor is configured to invoke the program code stored by the memory to perform the following operation: obtaining a paging identifier associated with the preamble of random access.
[0059] [0059] The receiver is configured to receive a paging message from the network device based on the paging identifier.
[0060] [0060] Based on the same inventive concept, for a principle of solving problems and beneficial effects of the device, consult the implementations of the previous possible method of the terminal device and its beneficial effects. Therefore, for the implementation of the device, consult the implementation of the method, and the repetitions are not described again.
[0061] [0061] According to a ninth aspect, this application provides a paging apparatus. The device has a function of implementing the behavior of the network device in the previous method. The function can be implemented by hardware, or it can be implemented by hardware running the corresponding software. The hardware or software includes one or more modules corresponding to the previous function.
[0062] [0062] In a possible implementation, the device includes: a receiving unit and a sending unit. The receiving unit is configured to receive a random access preamble from a terminal device, where the random access preamble is associated with a group of paging users on the terminal device, and the random access preamble is used to request a paging message. The sending unit is configured to send a random access response to the terminal device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, and the scheduling information pagination includes at least one of the frequency information, the time information, an encoding and modulation scheme, a reference signal, a subcarrier spacing, and downlink control information. The sending unit is additionally configured to send a paging message to the terminal device based on the paging programming information.
[0063] [0063] In another possible implementation, the device includes: a receiver, a transmitter, a memory and a processor. The memory is configured to store a segment of program code.
[0064] [0064] The receiver is configured to receive a random access preamble from a terminal device, where the random access preamble is associated with a group of paging users of the terminal device, and the random access preamble is used to request a paging message. The transmitter is configured to send a random access response to the terminal device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, and paging programming information includes at least one of the frequency information, the time information, a coding and modulation scheme,
[0065] [0065] Based on the same inventive concept, for a principle of solving problems and beneficial effects of the device, consult the implementations of the previous possible method of the network device and its beneficial effects. Therefore, for the device implementation, consult the method implementation, and the repetitions are not described again.
[0066] [0066] According to a tenth aspect, this application provides a paging apparatus. The device has a function of implementing the behavior of the terminal device in the previous method. The function can be implemented by hardware, or it can be implemented by hardware running the corresponding software. The hardware or software includes one or more modules corresponding to the previous function.
[0067] [0067] In a possible implementation, the device includes: a sending unit and a receiving unit.
[0068] [0068] The sending unit is configured to send a random access preamble to a network device, where the random access preamble is associated with a group of paging users on the device. The receiving unit is configured to receive a random access response from the network device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, programming information Paging features include at least one of the frequency information, an encoding and modulation scheme, a reference signal, subcarrier spacing information and DCI. The receiving unit is additionally configured to receive a paging message from the network device based on the paging schedule information.
[0069] [0069] In another possible implementation, the device includes: a receiver, a transmitter, a memory and a processor. The memory stores a set of program codes.
[0070] [0070] The transmitter is configured to send a preamble of random access to a network device, where the preamble of random access is associated with a group of paging users of the device. The receiver is configured to receive a random access response from the network device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, paging programming information include at least one of the frequency information, a coding and modulation scheme, a reference signal, subcarrier spacing information and DCI. The receiver is additionally configured to receive a paging message from the network device based on the paging programming information.
[0071] [0071] Based on the same inventive concept, for a principle of solving problems and beneficial effects of the device, consult the implementations of the previous possible method of the terminal device and its beneficial effects. Therefore, for the implementation of the device, consult the implementation of the method, and the repetitions are not described again.
[0072] [0072] According to an eleventh aspect, this request provides a communication timing device. The device has a function of implementing the behavior of the network device in the previous method. The function can be implemented by hardware, or it can be implemented by hardware running the corresponding software. The hardware or software includes one or more modules corresponding to the previous function.
[0073] [0073] In a possible implementation, the device includes: a receiving unit, a processing unit and a sending unit. The receiving unit is configured to receive a random access preamble from a terminal device. The processing unit is configured to determine a format of a TAC and / or a scale factor of a timing advance based on a format of the random access preamble. The sending unit is configured to send a random access response to the terminal device carrying the TAC and / or the scale factor.
[0074] [0074] In another possible implementation, the device includes: a receiver, a transmitter, a memory and a processor. The memory is configured to store a segment of program code.
[0075] [0075] The receiver is configured to receive a random access preamble from a terminal device. The processor is configured to invoke the program code stored by the memory to perform the following operation: determine a format of a TAC and / or a scale factor of a time advance based on a format of the preamble of random access. The transmitter is configured to send a random access response to the terminal device carrying the TAC and / or the scale factor.
[0076] [0076] In another possible implementation, the device can be a chip, and the chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0077] [0077] Based on the same inventive concept, for a principle of solving problems and beneficial effects of the device, consult the implementations of the previous possible method of the network device and its beneficial effects. Therefore, for the device implementation, consult the method implementation, and the repetitions are not described again.
[0078] [0078] According to a twelfth aspect, this request provides a communication timing device. The device has a function of implementing the behavior of the terminal device in the previous method. The function can be implemented by hardware, or it can be implemented by hardware running the corresponding software. The hardware or software includes one or more modules corresponding to the previous function.
[0079] [0079] In a possible implementation, the device includes: a receiving unit, a processing unit and a sending unit.
[0080] [0080] The receiving unit is configured to receive an advance TAC timing command from a network device. The processing unit is configured to obtain a scale factor and determine a timing advance and / or to determine a timing advance offset based on at least one of the TAC from the network device, the scale factor obtained, a basic unit of time currently used, a number of sampling points currently used, a carrier frequency currently used, a current service type, a subcarrier spacing currently used, a subcarrier index currently used, a maximum subcarrier spacing, a maximum number of sampling points and a displacement factor currently used. The sending unit is configured to send uplink data based on the timing advance and timing advance offset.
[0081] [0081] In another possible implementation, the device includes: a receiver, a transmitter, a memory and a processor. The memory stores a set of program codes.
[0082] [0082] The receiver is configured to receive a TAC advance timing command from a network device. The processor is configured to invoke the program code stored in memory to perform the following operations: obtain a scale factor and determine a timing advance and / or determining a timing advance offset based on at least one of the TAC to from the network device, the scale factor obtained, a basic unit of time currently used, a number of sampling points currently used, a carrier frequency currently used, a current service type, a currently used subcarrier spacing, a currently used subcarrier index, maximum subcarrier spacing, maximum number of sampling points and displacement factor currently used. The transmitter is configured to send uplink data based on the time advance and time advance offset.
[0083] [0083] Based on the same inventive concept, for a principle of solving problems and beneficial effects of the device, consult the implementations of the previous possible method of the terminal device and its beneficial effects. Therefore, for the implementation of the device, consult the implementation of the method, and the repetitions are not described again.
[0084] [0084] In accordance with a thirteenth aspect, this request provides a method of timing communication, including: receiving, by a terminal device, a signaling message from a network device, where the signaling message includes information of indication and a TAC timing advance command, the indication information is N1 bits, the TAC is N2 bits, different values of the indication information correspond to different scale factors and Nt and N2 are integers greater than or equal to 1; and determining, by the terminal device, a transmission timing adjustment based on a TAC value and a scaling factor corresponding to a value of the indication information.
[0085] [0085] In a possible project, N1 = 1.20u3eN2 = 3,4,5,6,7 or
[0086] [0086] In a possible project, N1 = 1.20uU3, eN1 + N2 = 6,
[0087] [0087] In a possible project, Ni = 1; and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a feed advance group. TAG timing associated with the terminal device; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0088] [0088] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0089] [0089] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0090] [0090] In a possible project, Nt = 1, and when the value of the indication information is equal to O, the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 1, the indication information value is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0091] [0091] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 1, the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0092] [0092] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the value of the indication information is a first pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the value of the indication information is a second pre-configured or pre-stored fixed value.
[0093] [0093] In a possible design, the signaling message includes a MAC CE and the signaling message additionally includes a TAG index of the timing advance group index.
[0094] [0094] In accordance with a fourteenth aspect, this request provides a method of sending data, including:
[0095] [0095] In a possible project, N1 = 1.20u3eN2 = 3,4,5,6,7 or
[0096] [0096] In a possible project, Ni = 1; and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a feed advance group. TAG timing associated with the terminal device; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0097] [0097] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0098] [0098] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to O, the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0099] [0099] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the value of the indication information is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0100] [0100] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 1, the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0101] [0101] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the value of the indication information is a first pre-configured or pre-stored fixed value; or when the indication information value is 1, the indication information value is a second pre-configured or pre-stored fixed value.
[0102] [0102] In a possible design, the signaling message includes a MAC CE and the signaling message additionally includes a TAG index of the timing advance group index.
[0103] [0103] In accordance with a fifteenth aspect, this request provides a device for receiving data.
[0104] [0104] In a possible project, N1 = 1.20u3eN2 = 3,4,5,6,7 or
[0105] [0105] In a possible design, Ni = 1; and when an indication information value is equal to O, a scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a forward feed group. TAG timing associated with a terminal device; or when an indication information value is equal to 1, a scale factor corresponding to the indication information value is related to a minimum subcarrier spacing in a TAG associated with a terminal device.
[0106] [0106] In a possible project, Ni = 1, and when an indication information value is equal to 1, a scale factor corresponding to the indication information value is a pre-configured or pre-stored fixed value; or when an indication information value is equal to O, a scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a TAG associated with a terminal device.
[0107] [0107] In a possible project, Ni = 1, and when an indication information value is equal to 1, a scale factor corresponding to the indication information value is a pre-configured or pre-stored fixed value; or when an indication information value is equal to O, a scale factor corresponding to the indication information value is related to a minimum subcarrier spacing in a TAG associated with a terminal device.
[0108] [0108] In a possible project, Nt = 1, and when an indication information value is equal to O, a scale factor corresponding to the indication information value is a pre-configured or pre-stored fixed value; or when an indication information value is equal to 1, a scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a TAG associated with a terminal device.
[0109] [0109] In a possible project, Ni = 1, and when an indication information value is equal to O, a scale factor corresponding to the indication information value is a pre-configured or pre-stored fixed value; or when an indication information value is equal to 1, a scale factor corresponding to the indication information value is related to a minimum subcarrier spacing in a TAG associated with a terminal device.
[0110] [0110] In a possible project, Ni = 1, and when an indication information value is equal to O, a scale factor corresponding to the indication information value is a first pre-configured or pre-stored fixed value; or when an indication information value is equal to 1, a scale factor corresponding to the indication information value is a second pre-configured or pre-stored fixed value.
[0111] [0111] In a possible design, a signaling message includes a MAC CE or DCI and the signaling message additionally includes a TAG index of the timing advance group index.
[0112] [0112] In accordance with a sixteenth aspect, this application provides a data sending device, including: a determination unit, configured to determine a referral information value and a TAC value, where the referral information is N1 bits, TAC is N2 bits, different values of the indication information correspond to different scale factors and N1 and N2 are integers greater than or equal to 1; and a sending unit, configured to send, to a terminal device, a signaling message carrying the eoTAC indication information.
[0113] [0113] In a possible project, N1 = 1.20u3eN2 = 3,4,5,6,7 or
[0114] [0114] In a possible project, Ni = 1; and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a feed advance group TAG timing associated with the terminal device; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0115] [0115] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0116] [0116] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the scale factor corresponding to the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0117] [0117] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0118] [0118] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0119] [0119] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a first pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a second pre-configured or pre-stored fixed value.
[0120] [0120] In a possible design, the signaling message includes a MAC CE or DCI and the signaling message additionally includes a TAG index of the timing advance group index.
[0121] [0121] According to another aspect, this application provides a device. The device includes: a receiver, a transmitter, a memory and a processor, where the memory stores a set of program codes, and the processor invokes the program code to perform the methods, according to the thirteenth and fourteenth aspect aspect.
[0122] [0122] According to another aspect, this order provides a computer-readable storage medium. The computer-readable storage media stores an instruction. When the instruction is executed on a computer, the computer is enabled to perform the methods, according to the previous aspects.
[0123] [0123] In another aspect, this application provides a computer program product including an instruction. When the computer program product is run on a computer, the computer is enabled to perform the methods, according to the previous aspects. BRIEF DESCRIPTION OF THE DRAWINGS
[0124] [0124] In order to describe the technical solutions in the modalities of the present invention or in the fundamentals more clearly, in the following, the attached drawings necessary to describe the modalities of the present invention or the fundamentals are described.
[0125] [0125] FIG. 1a is a network architecture diagram, according to an embodiment of the present invention;
[0126] [0126] FIG. 1b is a schematic flow chart of an LTE random access process;
[0127] [0127] FIG. 1c is a schematic diagram of an LTE random access response message structure;
[0128] [0128] FIG. 1d is a schematic flowchart of an LTE paging process;
[0129] [0129] FIG. 2a is a schematic flowchart of a pagination method, according to an embodiment of the present invention;
[0130] [0130] FIG. 2b is a schematic diagram of a mapping relationship between a group of paging users, a preamble of random access and a paging message, according to an embodiment of the present invention;
[0131] [0131] FIG. 3a is another schematic flowchart of a pagination method, according to an embodiment of the present invention;
[0132] [0132] FIG. 3b is a schematic diagram of a message structure of a random access response, according to an embodiment of the present invention;
[0133] [0133] FIG. 3c is yet another schematic flowchart of a pagination method, according to an embodiment of the present invention;
[0134] [0134] FIG. 4 is a schematic flow chart of a communication timing method, according to an embodiment of the present invention;
[0135] [0135] FIG. 5 is a schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0136] [0136] FIG. 6 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0137] [0137] FIG. 7 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0138] [0138] FIG. 8 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0139] [0139] FIG. 9 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0140] [0140] FIG. 10 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0141] [0141] FIG. 11 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0142] [0142] FIG. 12 is another schematic structural diagram of a paging apparatus, according to an embodiment of the present invention;
[0143] [0143] FIG. 13 is another schematic structural diagram of a communication timing apparatus, according to an embodiment of the present invention;
[0144] [0144] FIG. 14 is another schematic structural diagram of a communication timing apparatus, according to an embodiment of the present invention;
[0145] [0145] FIG. 15 is another schematic structural diagram of a communication timing apparatus, according to an embodiment of the present invention;
[0146] [0146] FIG. 16 is another schematic structural diagram of a communication timing apparatus, according to an embodiment of the present invention;
[0147] [0147] FIG. 17 is a schematic flow diagram of a communication timing method, according to an embodiment of the present invention;
[0148] [0148] FIG. 18 is a schematic diagram of a signaling message format, according to an embodiment of the present invention;
[0149] [0149] FIG. 19 is another schematic structural diagram of a communication timing apparatus, according to an embodiment of the present invention; and
[0150] [0150] FIG. 20 is another schematic structural diagram of a communication timing apparatus, according to an embodiment of the present invention. DESCRIPTION OF THE MODALITIES
[0151] [0151] In the following, the modalities of the present invention are described with reference to the accompanying drawings in the modalities of the present invention.
[0152] [0152] FIG. 1a is a schematic architectural diagram of a communications system, in accordance with an embodiment of the present invention. The communications system includes a plurality of base stations and a plurality of terminal devices. FIG. 1a shows that a network device communicates with two terminal devices. The communications system can be a global system for mobile communications (global system for mobile communications, GSM), a code division multiple access system (CDMA), and a code division multiple access system broadband (wideband code division multiple access, WCDMA), a worldwide interoperability system for microwave access (worldwide interoperability for microwave access, WiMAX), a long term evolution system (long term evolution, LTE), a 5G communications system (for example, a new radio system (new radio, NR)), a communications system that integrates a plurality of communications technologies (for example, a communications system integrating an LTE technology and an NR technology) or a subsequent evolved communications system. It should be noted that in FIG. 1a, the quantities and forms of network devices and base station devices are only an example for the description, and are not a limitation on the embodiments of the present invention.
[0153] [0153] FIG. 1b is a schematic flow chart of an LTE random access process. The random access process includes the following steps:
[0154] [0154] S101: A network device sends system information to a terminal device, and the terminal device receives system information sent by the network device, where the system message can carry a parameter, such as a maximum amount of retransmission . S102: The terminal device sends a random access preamble (msg1, a message 1) to the network device, and the network device receives the random access preamble sent by the terminal device. S103: The network device sends a random access response (msg2) to the terminal device, and the terminal device receives the random access response sent by the network device, where the random access response includes a random preamble index and a uplink programming concession (UL concession). S104: The terminal device sends a message 3 (msg3) for a first programming transmission to the network device, and the network device receives message 3 for the first programming transmission that is sent by the terminal device, where the terminal device sends message 3 (msg3) for programming transmission based on a time domain location and a frequency domain location indicated by the uplink programming grant; and if the network device correctly receives message 3, the network device sends a message 4 (msg4) to the terminal device to resolve a conflict, where the conflict means that a plurality of users initiate a random access process by using the same uplink resource, but the network device considers that only one user initiates random access. S105: The network device sends a program retransmission to the terminal device, where the program retransmission is sent using DCI (downlink control information, DCI). S106: The terminal device sends a schedule transmission relay to the network device. S107: The network device sends a contention resolution (msg4, message 4) to the terminal device.
[0155] [0155] In an LTE random access process, user equipment sends a random access preamble (message 1) to a base station, and the base station estimates a timing advance (TA ) based on the preamble of random access. After sending the random access preamble, the UE monitors a PDCCH over a period of time by using an RA-RNTI and receives a random access response (message 2) sent by the base station. The time interval is a random access response window. A random access response window start time is a time of three milliseconds after a time T in which the random access preamble is sent, that is, the start time is T + 3 milliseconds. A window size of the random access response window can be configured by using SI and notified by the base station to the UE.
[0156] [0156] A structure of a MAC PDU (protocol data unit, protocol data unit) of the random access response is shown in FIG. 1c. The MAC PDU includes two parts: a MAC header and a MAC payload. The MAC header includes a plurality of subheadings, one length of each header is one byte, one of the plurality of common information subheadings, and another subheader is a RAR subheader, and the RAR subheader carries configuration information for a MAC RAR (response response). random access response, RAR). The MAC payload includes a plurality of MAC RARs (MAC RAR1 for MAC RARn). The RAR subheader in the MAC header and the MAC RAR in the MAC payload are in individual correspondence. The RAR subheader includes three fields. The first two fields are used to indicate a type of the RAR subheader and a reserved field, and a length of the last field is six bits, used to indicate a random access preamble index, RAPID. MAC RAR includes four fields: a reserved bit (R), a timing advance command (Timing Advance Command, TAC), a uplink grant, UL grant and a temporary radio network identifier temporary cell radio network temporary identifier, TO-RNTI.
[0157] [0157] The random access response is sent on a physical downlink shared channel, PDSCH, and PDSCH-related DCI is sent on a physical downlink control channel, PDCCH ). A PDCCH corresponding to the random access response is encrypted using an RA-RNTI.
[0158] [0158] It should be noted that for ease of description, the preamble of random access, and the preamble indicate the same concept in this application.
[0159] [0159] FIG. 1d shows a paging process in an LTE system. A base station (eNodeB) sends a paging message in a broadcast manner. A paging message is used to paging a group of user equipment (user equipment, UE), and the paging message includes information about one or more paged UEs, for example, UE IDs. The base station determines a time to send the paging message based on information, such as a UE ID and a number of POs. The UE determines a paging message PO. The paging message is sent on a PDSCH, and DCI related to the PDSCH are sent on a PDCCH. A PDCCH corresponding to the paging message is identified by a paging radio network temporary identifier (P-RNTI). In an LTE system, the P-RNTI is a fixed value FFFE (hexadecimal) and has a length of 16 bits.
[0160] [0160] In an NR system, due to the existence of a plurality of beams and beam directivity, a paging message needs to be sent by using a beam. If all paging messages are sent on each beam, excessive overload is caused. For the fact that to page in NR is a focus of current research.
[0161] [0161] In this application, the terminal device is a device with a wireless communication function, and can be a portable device, a vehicle-mounted device, a wearable device or a computing device that has a wireless communication function, or other processing device connected to a wireless modem or the like. The terminal device may have different names on different networks, for example, user equipment, an access terminal, a subscriber unit, a subscriber station, a mobile station, a mobile console, a remote station, a remote terminal, a mobile device, a user terminal, a terminal, a wireless communications device, a user agent or a user device, a cell phone, a cordless phone, a Session Initiation Protocol phone, SIP), a wireless local loop station (Wireless Local Loop, WLL), a personal digital assistant (Personal Digital Assistant, PDA) or a terminal device on a 5G network or a future evolved network.
[0162] [0162] In this application, the base station can also be referred to as a base station device, it is a device implanted in a radio access network to provide a wireless communication function, and includes, but is not limited to : a base station (for example, a BTS (transceiver base station, BTS), a B node (NodeB, NB), an evolved B node (Evolved NodeB, eNB, or eNodeB)), a transmission node or a transmission reception point (transmission reception point, TRP, or TP) or a next generation B node (generation NodeB, gNB) in an NR system, a base station or a network device in a future communications network), a relay node, an access point, a vehicle-mounted device, a wearable device, a wireless fidelity station (Wireless-Fidelity, Wi-Fi), a wireless backhaul node, a small cell, a micro station or similar.
[0163] [0163] FIG. 2a is a schematic flowchart of a pagination method, according to an embodiment of the present invention. The method includes, but is not limited to, the following steps.
[0164] [0164] S201: A terminal device sends a random access preamble to a network device, and the network device receives the random access preamble from the terminal device.
[0165] [0165] Specifically, as shown in FIG. 2b, the terminal devices in the same PO are grouped into n groups of paging users in advance, where n is an integer greater than O, each group of paging users includes at least one terminal device, and a grouping rule is not limited in this modality. For example, terminal devices in the same PO are grouped based on UE IDs. Both the terminal device and the network device can store group information from N paging user groups. Each of the N paging user groups corresponds to a paging indication bit, a random access preamble (random access preamble index) and a paging message. Different values of the paging indication bit indicate whether a terminal device in the paging user group is paged. For example, when the paging indication bit is 1, this indicates that at least one terminal device in the paging user group needs to be paged. When the paging indication bit is O, this indicates that no terminal device in the paging user group needs to be paged. Different paging user groups correspond to different random access preambles, and the random access preamble corresponding to the paging user group is used to trigger a paging procedure.
[0166] [0166] The terminal device determines the group of paging users and the preamble of random access corresponding to the group of paging users. The terminal device sends the random access preamble to the network device, and the network device receives the random access preamble from the terminal device.
[0167] [0167] In a possible project, before the network device receives the preamble of random access from the terminal device, the method additionally includes the following:
[0168] [0168] The network device sends a paging indication message to the terminal device, where a paging indication bit that is carried by the paging indication message and that is from the terminal device's paging user group is a value pre-established.
[0169] [0169] Specifically, when the network device needs to page the terminal device, the network device determines the group of paging users of the terminal device, and sends the paging indication message to the terminal device, where the pagination that is carried by the paging indication message and that belongs to the terminal device group of paging users is the pre-established value. The terminal device receives the paging indication message from the network device, and upon determining that the paging indication bit of the paging user group is the default value, the terminal device sends the random access preamble corresponding to the group paging users for the network device.
[0170] [0170] When the paging indication bit is the preset value, the terminal device or a terminal device in the associated paging user group sends the random access preamble to the network device. The paging indication message can be carried in information, such as DCI, RMSI, an NR-SIB1, an NR-SIB2, a system message, or a PDSCH of the paging indication message. When DCIs are used to carry the paging indication message or the DCIs indicate the PDSCH of the paging indication message, the DCI of the paging indication message must be encrypted using a temporary radio network identifier (RNTI) . The RNTI can be a temporary radio network identifier used especially to encrypt DCI, to be distinguished from a temporary radio network identifier corresponding to another message. In an implementation, an RNTI corresponding to the paging indication message is different from that corresponding to the paging message. In another implementation, the RNTI corresponding to the paging indication message is the same as that corresponding to the paging message. For example, the paging indication message and the paging message are sent at different points in time and / or frequencies. For another example, 1 bit indication information in DCI is used to indicate that DCI is one of the two previous types. For another example, the information or a reference signal in the PDCCH corresponding to the DCI is used to indicate that DCI is one of the two previous types.
[0171] [0171] For example, three groups of paging users are obtained through advance grouping: a group of paging users
[0172] [0172] In a possible project, before the network device receives the preamble of random access from the terminal device, the method additionally includes the following: The network device sends configuration information from the paging message to the terminal device.
[0173] [0173] Specifically, the configuration information may include information, such as a length of the paging occasion, a number of paging occasions, a length of a discontinuous reception cycle (DRX), and a location of the POWDER. When paging messages at one or more POs or a paging message control feature or a paging indication control feature is multiplexed time splitting or multiplexed frequency splitting with a block of synchronization signals block, SS block), and one or more values can be configured in the configuration information, where the value is used to indicate an index of the paging occasion, or an index or number of POs where DCI and PDSCH are not transmitted together (for example, a DCI part of the paging indication message is the frequency division multiplexed with a block of synchronization signals, a PDSCH of the paging indication message is sent at another time frequency location that is predefined or that is configured by a base station, and another part of the DCI of the paging indication message and the block of synchronization signals are sent separately at different points time and frequencies). A specific configuration method is mod (index, K) = m, where K indicates a number of POs in a set burst of synchronization signals (SS burst set), and the index indicates an index of the PO.
[0174] [0174] When T = 5 ms or 10 ms, N can be defined as 1 and k = O, and this indicates that each frame has an SS block or a PBCH.
[0175] [0175] When T = 20 ms, N = 2, Mod (SFN, N) = O indicates that during the burst burst SS frame period, a first frame has an SS block or PBCH, and Mod (SFN, N ) = 1 indicates that in the SS burst frame period, a second frame has an SS block or a PBCH.
[0176] [0176] When T = 40 ms, N = 4, MOd (SFN, N) = O indicates that in the period of the SS burst frame, the first frame has an SS block or a PBCH; Mod (SFN, N) = 1 indicates that in the burst burst SS frame period, the second frame has an SS block or a PBCH; Mod (SFN, N) = 2 indicates that in the SS burst frame period, a third frame has an SS block or a PBCH; and Mod (SFN, N) = 3 indicates that in the burst burst SS frame period, a fourth frame has an SS block or a PBCH.
[0177] [0177] When T = 80 ms, N = 8, Mod (SFN, N) = O indicates that in the period of the SS burst frame, the first frame has an SS block or a PBCH; Mod (SFN, N) = 1 indicates that in the SS burst frame period, the second frame has an SS block or a PBCH; Mod (SFN, N) = 2 indicates that in the burst burst SS frame period, the third frame has an SS block or a PBCH; Mod (SFN, N) = 3 indicates that in the burst burst SS frame period, the fourth frame has an SS block or a PBCH; Mod (SFN, N) = 4 indicates that in the SS burst frame period, a fifth frame has an SS block or a PBCH; Mod (SFN, N) = 5 indicates that in the SS burst frame period, a sixth frame has an SS block or a PBCH; Mod (SFN, N) = 6 indicates that in the burst burst SS frame period, a seventh frame has an SS block or a PBCH; and MOd (SFN, N) = 7 indicates that in the SS burst frame period, an eighth frame has an SS block or a PBCH.
[0178] [0178] When T = 160 ms, N = 16, Mod (SFN, N) = O indicates that in the period of the SS burst frame, the first frame has an SS block or a PBCH; Mod (SFN, N) = 1 indicates that in the SS burst frame period, the second frame has an SS block or a PBCH; Mod (SFN, N) = 2 indicates that in the burst burst SS frame period, the third frame has an SS block or a PBCH; Mod (SFN, N) = 3 indicates that in the burst burst SS frame period, the fourth frame has an SS block or a PBCH; Mod (SFN, N) = 4 indicates that in the burst burst SS frame period, the fifth frame has an SS block or a PBCH; Mod (SFN, N) = 5 indicates that in the burst burst SS frame period, the sixth frame has an SS block or a PBCH; Mod (SFN, N) = 6 indicates that in the burst burst SS frame period, the seventh frame has an SS block or a PBCH; Mod (SFN, N) = 7 indicates that in the burst burst SS frame period, the eighth frame has an SS block or a PBCH; Mod (SFN, N) = 8 indicates that in the burst burst SS frame period, a ninth frame has an SS block or a PBCH; Mod (SFN, N) = 9 indicates that in the burst burst SS frame period, a tenth frame has an SS block or a PBCH; Mod (SFN, N) = 10 indicates that in the burst burst SS frame period, an eleventh frame has an SS block or a PBCH; Mod (SFN, N) = 11 indicates that in the burst burst SS frame period, a twelfth frame has an SS block or a PBCH; Mod (SFN, N) = 12 indicates that in the SS burst frame period, a thirteenth has either an SS block or a PBCH; Mod (SFN, N) = 13 indicates that in the SS burst frame period, a fourteenth has either an SS block or a PBCH; Mod (SFN, N) = 14 indicates that in the SS burst frame period, the fifteenth frame has an SS block or a PBCH; and Mod (SFN, N) = 15 indicates that in the SS burst frame period, the sixteenth frame has an SS block or a PBCH.
[0179] [0179] The location of the PBCH frame or the SS block or SS burst set can alternatively be determined by the network device.
[0180] [0180] In a possible project, before receiving the preamble of random access from the terminal device, the network device can additionally send the paging message and the paging indication message. Paging messages at different POs or different paging messages associated with the SS block or QCL paging messages can be sent through frequency division multiplexing. The network device can configure, using at least one among ISMS, a MIB, RRC, a MAC-CE, DCI, SI, an NR-SIB1 and an NR-SIB2, a number of POs or paging messages that are the multiplexed frequency division. For example, the network device that sets up a number of POs that is the multiplexed frequency division is 2, and this indicates that two POs are the multiplexed frequency division. When calculating a PO time location, the terminal device can assume that two POs that are the multiplexed frequency division have the same time location. In a possible implementation, the network device configures the DCI of the paging message in the PO or frequency information of a PDCCH with reference to the frequency information of the RMSI or NR-SIB1 or NR-SIB2 using the configuration information. For example, the DCI of the paging message in the PO or a frequency offset from the PDCCH is configured, where the frequency offset can be an offset from a frequency start location or a frequency end location or a central location of the PDCCH or PDSCH of the RMS! or NR-SIB1 or NR-SIB2. For example, when the POI of the paging message in the PO or the bandwidth of the PDCCH is configured, the DCI of the paging message or the bandwidth of the PDCCH can be the same as the PDCCH bandwidth of the RMSI or the NR-SIB1 or NR-SIB2 or it can be a multiple of the RMS bandwidth! or NR-SIB1 or NR-SIB2, where the multiple can be a multiple integer or a multiple fraction or predefined as one. The configuration information is at least one among RMSI, a MIB, RRC, a MAC-CE, DCI, SI, an NR-SIB1 and an NR-SIB2. QCL is almost colocalized (quasi-colocated), and indicates that the beam information or Doppler information, and the delay extension information of two signals or two reference signals are the same.
[0181] [0181] S202: The terminal device obtains a paging identifier associated with the random access preamble and the configuration information of a paging message window.
[0182] [0182] The network device obtains the paging identifier associated with the random access preamble, or the network device obtains a paging user group associated with the random access preamble and obtains a paging identifier associated with the paging user group . The network device encrypts the PDCCH based on the paging identifier, and the paging identifier is used by the terminal device to monitor the PDCCH, to receive the paging message from the POSCH based on an indication of the PDCCH DCI. The paging message window indicates a time interval in which the paging message is sent or received.
[0183] [0183] In a possible project, the terminal device obtains the paging identifier associated with the random access preamble, includes the following: the terminal device receives the paging identifier that is from the network device and that is associated with the access preamble random; or the terminal device obtains a pre-configured or pre-stored paging identifier associated with the random access preamble; or the terminal device determines, based on at least one of the following information, the paging identifier associated with the preamble of random access: a total number of paging occasions, a total number of paging messages, a total number of paging occasions random access, a subcarrier spacing, a type of service, a carrier frequency, a total amount of random access preambles, an index of a random access occasion corresponding to the random access preamble, an index of the random access preamble, an index of the paging message, an index of the paging user group corresponding to the preamble of random access, an index of a time-frequency resource corresponding to the preamble of random access, an index of a block of synchronization signals corresponding to the preamble random access, an index of a channel state information reference signal port (CSI-R S) corresponding to the random access preamble and a temporary random access radio network identifier (RA-RNTI) corresponding to the random access preamble.
[0184] [0184] The total number of paging occasions, the total number of paging messages, the total number of random access occasions and the total number of random access preambles are quantities in a current DRX cycle, and a length of the DRX cycle includes, but is not limited to, a subframe, a slot and an SS block. The random access preamble index is a sequence number of the random access preamble sent by the terminal device, and the terminal device can number the random access preamble sent using a step 1 size. The index of the paging message is a paging message sequence number sent by the network device, and the terminal device can number the paging message sent using the size of step 1. The paging user group index indicates a user group sequence number pagination, and different groups of paging users have different indexes. The index of the time-frequency resource corresponding to the random access preamble indicates a sequence number of the time-frequency resource occupied by the random access preamble. The index of the sync signal block corresponding to the random access preamble indicates a sequence number of the sync signal block (SS block) of the random access preamble. The CSI-RS port index corresponding to the random access preamble indicates a port sequence number of a CSI-RS in a block of synchronization signals from the random access preamble. The terminal device can determine the paging identifier based on the index of the random access preamble, the index of the paging message, the index of the paging user group of the terminal device, the index of the time-frequency resource corresponding to the preamble of the random access, the sync signal block index corresponding to the random access preamble, the CSI-RS port index corresponding to the random access preamble, and the RA-RNTI corresponding to the random access preamble, or you can consult a table of pre-configured or pre-stored mapping to obtain the paging identifier associated with the random access preamble.
[0185] [0185] It should be noted that in this modality, a block of synchronization signals (synchronization signal block, SS block) can correspond to one or more OFDM symbols. The SS block includes at least one of the following: a primary synchronization signal (primary synchronization signal, PSS), a secondary synchronization signal (secondary synchronization signal,
[0186] [0186] For example, the terminal device determines the paging identifier based on any of the following formulas: (VRNTI (i) = IxRA-RNTI + i; (2) RNTI (i) = Kxi + RA-RNTI; (3) RNTI (i) = - RNTIo + mod (i, 1); (4) RNTI (i) = RNTIo + mod (i, 1) + Ixmod (bstia, N); (5) RNTI (i) = RNTIo + mod (i, 1) + Ixmod (bstia, N) H + IxNxmod (aunt, T); (6) RNTI (i) = RNTIo + mod (i, I) + Ixmod (bstia, N) + IxNxmodí ( tia, T) H + IxNxTxmod (fia, F); (7) RNTI (i) = RNTIo-mod (i, |); (8) RNTI (i) = RNTlo-mod (i, 1) -lxmod (bstia , N); (9) RNTI (i) = RNTlo-mod (i, 1) -lxmod (bstia, N) -IxNxmodí (tia, T); and (10) RNTI (i) = RNTlo-mod (i, 1) -lIxmod (bsta, N) -IxNxmod (thia, T) - IxNxTxmod (yarn, F).
[0187] [0187] For another example, the terminal device determines the paging identifier based on any one of the following formulas: (11) RNTI (i) = RNTo + floor (i / 10); (12) RNTI (i) = RNTlo + floor (i / I0) + Ixfloor (bstia / NO); (13) RNTI (i) = RNTlo + floor (i / I0) + Ixfloor (bstia / NO) - + IxNxfloor (tia / TO); (14) RNTI (i) = RNTlo + floor (i / 10) + I | xfloor (bstia / NO) + IxNxfloor (tia / TO) - + IxNxTxfloor (fia / FO); (15) RNTI (i) = RNTIo-floor (i / 10); (16) RNTI (i) = RNTlo-floor (i / 10) -Ixfloor (bstia / NO);
[0188] [0188] Specifically, bsta can be a random access resource index, NO indicates a number of random access resources, that is, a random access resource group, associated with a downlink signal, NO can be configured by base station or can be a default value, TO indicates a time length of the random access feature, and a time unit can be an interval, a mini-interval of a mini-interval, an OFDM symbol and a length of time of the random access preamble format.
[0189] [0189] In another modality, in the calculation of the RNTI in all the previous modalities, the locations of any two of i, bstia, tia and fa can be exchanged. Correspondingly, the locations of | N Te F need to be changed and, correspondingly, the locations of 10, NO, TO and FO need to be changed.
[0190] [0190] floor (x / y) means to divide x by y and then round to the nearest whole number. In another mode, the floor can be replaced with a ceil function or another function, for example, rounding that corresponds to rounding.
[0191] [0191] In the previous modality, RNTI (i) indicates a paging identifier corresponding to a random access preamble, and i indicates any of the index of the random access preamble, the index of the paging message, the index of the user group of paging of the terminal device, the index of the time-frequency resource corresponding to the preamble of random access, the index of the block of synchronization signals corresponding to the preamble of random access or the index of the CSI-RS port corresponding to the preamble of random access. K indicates a constant greater than O, for example, K = 60. RA-RNTI indicates a temporary random access radio network identifier corresponding to a random access preamble |. RNTI, indicates an initial paging identifier, and RNTI, is a constant greater than O. For example, RNTI, = 60. For another example, RNTI, =
[0192] [0192] bsta is at least one of a downlink signal index, a downlink group index, a downlink signal index in a downlink group, an access occasion index random (RACH occasion), a random access transmission occasion index (RACH transmission occasion), a random access preamble format index (RACH preamble format), a random access resource index, a group index of random access preamble and a group index of random access occasion. The downlink signal may be a block of synchronization signals SS block or a physical broadcast channel block (PBCH block). The SS block / PBCH block is a signal block including a plurality of OFDM symbols, and includes at least one of a primary synchronization signal (PSS), a secondary synchronization signal (secondary synchronization signal, SSS), a physical broadcast channel (PBCH), a demodulation reference signal (DMRS) and a CSI-RS. In an implementation, bsta is an index of a signal or a resource at a time "at or current frequency Sa.
[0193] [0193] fa is at least one of a downlink signal time index and a time index of a random access preamble resource. The time index can be one or a combination of more than one subframe number, an interval number, a mini interval (mini
[0194] [0194] fa is at least one of a downlink signal frequency index, a downlink signal carrier index, a downlink signal frequency index and a frequency index of the random access preamble feature .
[0195] [0195] | is a specified first constant, N is a specified second constant, T is a specified third constant, F is a specified fourth constant and K is an octave constant.
[0196] [0196] For example, | is any integer from 1 to 64, N is any integer from 1 to 128, T is any integer from 1 to 80, Faith is any integer from 1 to 50 and K is any constant from 1 to 65535. In another embodiment , K indicates a number of all RA-RNTIs; | is a number of paging user groups, and / or paging messages, and / or paging occasions, and N is a number of downlink signals or random access occasions in a random access period.
[0197] [0197] mod (x, y) in the formula indicates a module operation, or it can be written as x% y, or it can be written as x mod y. If y is 1, no calculation is performed on a corresponding item (that is, it can be omitted).
[0198] [0198] For another example, the terminal device searches for a pre-configured or pre-stored mapping table to determine the paging identifier associated with the random access preamble. In a mapping table shown in Table 1, a random access preamble (a random access preamble index) and a paging identifier (RNTI) are in an individual match, and different random access preambles are associated with different identifiers for pagination.
[0199] [0199] For another example, in a mapping table shown in table 2, a plurality of preambles of random access can correspond to the same paging identifier (RNTI). Table 2 Preamble access index | Temporary network identifier and dj
[0200] [0200] For another example, in a mapping table shown in Table 3, a group of paging users and a paging identifier (RNTI) are in an individual correspondence, and different groups of paging users correspond to different paging identifiers . Table 3 User group index for | Temporary network identifier and
[0201] [0201] For another example, in a mapping table shown in Table 4, a plurality of groups of paging users correspond to the same paging identifier (RNTI). Table 4 User group index for | Temporary network identifier
[0202] [0202] It should be noted that Table 1 to Table 4 are only examples for the description, and are not a limitation in this embodiment of the present invention. In one implementation, RNTI1 to RNTIN are any integers between 0 and 65535. In another embodiment, RNTI1 to RNTIN increase sequentially or decrease sequentially, and / or are N consecutive integers, for example, N = 10, RNTI1 = 1 and RNTI10 = 10, For another example, N is related to at least one of the following parameters: a number of POs (paging occasion) in a DRX cycle, a maximum number of UEs paged in a TA (tracking area) , a maximum number of UEs paged in a PO, a band, a period of a set of sync signal blocks, a frame structure, a paging message or an RMSI subcarrier spacing and an amount of sync signal blocks actually transmitted.
[0203] [0203] In a possible design, the terminal device and / or the network device can simultaneously configure a plurality of types of mapping tables. A corresponding mapping table is selected based on a value in a state identifier field, and is searched to determine the paging identifier. For example, based on the previous example, the terminal device will simultaneously configure four mapping tables from Table 1 to Table 4, and a state identifier field for the table selection is Flag. When Flag = O, the mapping table in Table 1 is used, when Flag = 1, the mapping table in Table 2 is used, when Flag = 2, the mapping table in Table 3 is used, and when Flag = 3 , the mapping table in Table 4 is used. In another possible design, the terminal device and / or the network device can select a table and / or a parameter value (including N) from a table based on a carrier frequency range. For example, when a carrier frequency is less than 3 GHz, Table 1 is selected; when the carrier frequency is greater than 3 GHz and less than 6 GHz, Table 2 is selected; when the carrier frequency is greater than 6 GHz and less than 40 GHz, Table 3 is selected; and when the carrier frequency is greater than 40 GHz, Table 4 is selected.
[0204] [0204] In another modality, the RA-RNTI is related to at least one of the following parameters: the index of the preamble of random access, the index of the resource of time-frequency corresponding to the preamble of random access, the index of time of the random access preamble resource, the frequency index of the random access preamble resource, a downlink signal index corresponding to the random access preamble, a downlink signal group index corresponding to the random access preamble, a random access resource group, a random access preamble group, a random access preamble format, a random access preamble sequence length, a band, a bandwidth, a frame structure, a number of resources of random access in an interval (or associated with a number of downlink signals from a random access resource in an interval, or an amount of random access response messages corresponding to an interval), a number of random access preambles in a random access resource, a number of random access resources associated with a downlink signal, a total number of associated random access preambles with a downlink signal, a time length of a random access resource, a subcarrier spacing and a type of service. Sub carrier spacing can be a sub carrier spacing of at least one of the following signals or channels: a PBCH (physical broadcast channel, physical broadcast channel), RMSI (remaining minimum system information, remaining minimum system information), other information OSI (Other system information), a random access preamble, a random access response, a paging message and a message
[0205] [0205] For example, the terminal device and the network device determine the RA-RNTI based on any one of the following ways: () RA-RNTI = RNT lo + modí (bstia, N); (2) JRA-RNTI = RNT lo + mod (bstia, N) -Nxmod (aunt, T); (S) RA-RNTI = RNTlo + mod (bstia, N) H Nxmod (aunt, T) HFNxTxmod (fia, F); (4) RA-RNTI = RNT lo-modí (bstia, N); (5S) RA-RNTI = RNTlo-modí (bstia, N) -Nxmod (ta, T); and (6) RA-RNTI = RNTlo-modí (bstia, N) -Nxmod (tia, T) -NxTxmodí (fia, F).
[0206] [0206] Another example is as follows: () RA-RNTI = RNT lo + floor (bstia / NO); (2) RA-RNTI = RNT lo + floor (bstia / NO) + Nxfloor (tia / TO); (3) RA-RNTI = RNTlo + floor (bstia / NO) + Nxfloor (tia / TO) H + HNxTxfloor (fia / FO); (4) RA-RNTI = RNTo-floor (bstia NO); (5) RA-RNTI = RNT10-floor (bstid / NO) -Nxfloor (tid / TO); and (6) RA-RNTI = RNTo-floor (bstia / NO) -Nxfloor (tia / TO) -NxTxfloor (fia / FO).
[0207] [0207] Specifically, bsta can be a random access resource index, and NO indicates a number of random access resources, that is, a random access resource group, associated with a downlink signal. NO can be configured by the base station or it can be a default value; and TO indicates a time length of a random access resource, where a time unit can be an interval, a mini-interval of the mini-interval, an OFDM symbol or a time length of the random access preamble format. floor (x / y) means to divide x by y and then round to the nearest whole number. In another modality, the floor can be replaced with ceil or another function, for example, rounding corresponding to rounding.
[0208] [0208] In another modality, the RA-RNTI can be calculated by performing mod and / or floor in different parameters, and this is not limited in this report.
[0209] [0209] In another embodiment, the network device notifies the terminal of a way to determine the RA-RNTI. For example, when the network device has Flag = O information, a first way is indicated; and when Flag = 1, a second way is indicated.
[0210] [0210] N is a second specified constant, T is a third specified constant, F is a fourth specified constant, NO is a fifth constant, TO is a sixth constant and FO is a seventh constant. For example, N is any integer from 1 to 128, T is any integer from 1 to 80 and F is any integer from 1 to 50. For another example, NO and FO are configured by the base station. For another example, TO is determined based on a random access preamble format and a random access preamble subcarrier.
[0211] [0211] In another modality, a way of calculating the paging identifier RNTI (i) and / or RA-RNTI is related to at least one of the following parameters: the index of the preamble of random access, the index of the paging message , the index of the paging user group of the terminal device, the index of the time-frequency resource corresponding to the random access preamble, the time index of the resource of the random access preamble, the frequency index of the access preamble resource random, the downlink signal index corresponding to the random access preamble, the downlink signal group index corresponding to the random access preamble, a random access resource group, a random access preamble group, a format random access preamble, a random access preamble sequence length, a bandwidth, a bandwidth, a frame structure, an amount of ace resources sso random in an interval (or an amount of downlink signals associated with a random access resource in an interval, or an amount of random access response messages corresponding to an interval), an amount of random access preambles in an interval random access resource, a number of random access resources associated with a downlink signal, a total amount of random access preambles associated with a downlink signal, a length of time for a random access resource, a spacing of subcarrier and a type of service. For example, the calculation method is related to a carrier frequency: When a frequency of a random access resource is less than 3 GHz, RNTI (i) and / or RA-RNTI is obtained in the first calculation method; when the frequency of the random access resource is greater than 3 GHz and is less than 6 GHz, RNTI (i) and / or RA-RNTI is obtained in the second method of calculation; and when the frequency of the random access resource is greater than 6 GHz, RNTI (i) and / or RA-RNTI is obtained in the third calculation method. In other words, the way of calculating RNTI (i) and / or RA-RNTI is different in different application scenarios with different parameters, and a specific way can be predefined, pre-stored or indicated by the configuration information of the base.
[0212] [0212] In another modality, in the calculation of the RA-RNTI in all the previous modalities, the locations of any two of bstia, tia and fa can be exchanged, correspondingly, the locations of N, T and F need to be exchanged and, correspondingly , the locations of NO, TO and FO need to be changed. In an implementation, b5ta is an index of a signal or a resource in a current team «« and / or frequency Sa.
[0213] [0213] In a possible project, the terminal device can receive, via signaling, the paging identifier that is from the network device and that is associated with the preamble of random access, where the signaling can be at least one among an RRC message , a MAC-CE, SI or DCI message.
[0214] [0214] In a possible design, the terminal device obtains the paging message window configuration information from the paging message includes the following: the terminal device receives the paging message window configuration information from the paging device network; or the terminal device obtains pre-stored or pre-configured configuration information from the paging message window; or the terminal device obtains the configuration information from the paging message window based on at least one of the following information: a random access preamble start time, random access preamble duration, a preamble end time random access, time domain location information / frequency domain location information from a random access response window corresponding to the random access preamble and a total number of paging user groups.
[0215] [0215] The paging message window indicates a possible time interval for sending / receiving the paging message or paging scheduling information corresponding to the paging message (the paging message scheduling information includes, but is not limited to , a time / frequency location corresponding to the DCI of the paging message, a PDCCH of the paging message or a set of control resources (CORESET) of the paging message). The network device sends the paging message in the paging message window, according to a pre-stored or preconfigured rule, and the terminal device receives the paging message in the same paging message window, according to the pre-configured or pre-stored rule.
[0216] [0216] The following describes in detail the specific modalities of a process for determining the configuration information of the paging message window in the modalities of the present invention.
[0217] [0217] In another possible implementation, the network device sends configuration information from the paging message window to the terminal device via signaling, such as SI, RRC or DCl, and the terminal device receives signaling, such as SI , RRC, a MAC CE or DCI from the network device, and obtain the configuration information from the paging message window that is included in the signaling. Of course, the configuration information for the paging message window may alternatively be predefined or pre-stored by the terminal device, and the configuration information for the paging message window may also have another name. This is not limited in this mode.
[0218] [0218] For example, the network device sends the configuration information of the paging message window through RRC signaling using the following format: SupervisionInfoSEQUENCE (PagingMessageWindowStartENUMERATED (ts2, ts3, ts4, ts5, ts6, ts7, ts8, ts10 , ...),
[0219] [0219] In RRC signaling, the paging message window configuration information includes at least one of the following: an initial paging message window start time (PagingMessageWindowStart), an initial paging message window size ( PagingMessageWindowsSize) and an initial scrolling time of the paging message window (PagingMessageWindowoOffset). When the network device sends configuration information from the paging message window by using a system message (system information, SI), the configuration information from the paging message window can be obtained from at at least one of the remaining minimum system information (RMSI), RRC, a MAC-CE, a MIB (main information block), DCI and SI (system information, system information). The initial scrolling time of the paging message window (PagingMessageWindowoOffset) is used to determine a travel time between the paging message windows corresponding to two different downlink signals, or an offset between the paging window and a time of sending the preamble of random access.
[0220] [0220] In another possible implementation, the configuration information of the paging message window is completely the same as that of a random access response window. In this case, the network device only needs to send the configuration information from the random access response window, and the terminal device determines the configuration information from the paging message window based on the configuration information from the random access response window. .
[0221] [0221] In an LTE system, a window size of the random access response window is configured by the network device and is relatively large, and is usually at a millisecond level, and an access response window start time random is usually fixed and cannot adapt to different service requirements and a multi-port application scenario in a future NR 5G system. Therefore, a flexible paging message window size and a flexible paging message window start time need to be designed.
[0222] [0222] One embodiment of the present invention further discloses a method for determining a paging message window. The network device and the terminal device separately determine a window size and / or a paging message window start time based on a subcarrier spacing. The paging message is sent or received based on the size of the window and / or the start time of the paging message window. In addition, the size of the paging message window may be related to the initial size of the reference paging message window.
[0223] [0223] In another possible implementation, the start time of the initial paging message window, the initial size of the paging message window and the initial travel time of the paging message window, are respectively a real start time of the paging message window, a real size of the paging message window and an actual offset time of the paging message window.
[0224] [0224] In another possible implementation, the actual start time of the paging message window, the actual size of the paging message window and the actual travel time of the paging message window, are determined separately based on the start of the initial paging message window, the initial size of the paging message window, the initial travel time of the paging message window, and other parameters. The other parameters include, but are not limited to, at least one of the following: a random access preamble format, a random access preamble length, a random access preamble carrier frequency, an access preamble band random, a number of random access occasions (RACH, RO occasion) in an interval, a number of downlink signals in a random access resource in an interval, a number of random access response messages corresponding to an interval, a number of paging occasions in a DRX cycle, a number of random access preambles in an RO, a number of ROs associated with a downlink signal, a total amount of random access preambles or resources associated with a link signal downlink, a number of downlink signals actually sent, an RO time length, a subcarrier spacing, a width bandwidth, a frame structure, a type of service, the start time of the random access preamble, the duration of the random access preamble, the end time of the random access preamble, the time domain location information random access response window corresponding to the random access preamble, the frequency domain location information of the random access response window corresponding to the random access preamble, the index of the random access preamble, the index of the paging message, o Index of the paging user group corresponding to the preamble of random access, the index of the time-frequency resource corresponding to the preamble of random access, the index of the block of synchronization signals corresponding to the preamble of random access, the total number of messages of paging, the total number of random access occasions, the number of groups of paging users, the number of of paging messages, the number of random access preambles associated with the paging message, the number of POs and a DRX cycle length. The paging message window start time, the paging message size and the scrolling time of the paging message window can be fixed values, for example, the scrolling time of the paging message window is fixed as 0 .
[0225] [0225] The subcarrier spacing can be a subcarrier spacing of at least one of a PBCH, ISMS, a random access response, a paging message, other system information (other system information), a random access preamble, an NR-SIB1 (system information block 1, system information block 1) and a message 3.
[0226] [0226] Subcarrier spacing can be specified in the random access configuration information or in the configuration information of the paging message window. In this way, a uniform way to determine the paging message window can be provided for different subcarrier spacing, to reduce signaling overheads.
[0227] [0227] In another possible implementation, similar to an LTE random access response, the window size of the paging message window does not change.
[0228] [0228] In a possible implementation, the window size of the paging message window is variable, for example, the window size is determined based on a subcarrier spacing.
[0229] [0229] In another possible implementation, the paging message window window size is not only related to subcarrier spacing, but also needs to be determined with reference to the initial paging message window size pre-configured by the paging device. network. The network device can notify the terminal device of the initial size of the paging message window by using a system message.
[0230] [0230] In another possible implementation, both the network device and the terminal device can determine the size of the paging message window based on the initial size of the paging message window and on a subcarrier spacing.
[0231] [0231] For example, the paging message window window size is PagingMessageWindowSize * Scale, where PagingMessageWindowSize is the initial paging message window size, and Scale is related to a paging message subcarrier spacing or an index u of subcarrier spacing. For example, Scale = 2nd. In another implementation, a Scale value is shown in Table 5. Table 5 shows a correspondence between a subcarrier spacing of a random access preamble and a Scale.
[0232] [0232] For another example, the Scale value is shown in Table 6. Table 6 shows a correspondence between a subcarrier spacing of a random access preamble and a Scale.
[0233] [0233] It should be noted that in Table 5 and Table 6, SO to S6 can be any non-negative integers between 0 and 128. Optionally, for any two subcarrier spacing iej, if the subcarrier spacing i <j, Si < Si. Optionally, for any two subcarrier spacing iej, if the subcarrier spacing i <j, Si> S ,.
[0234] [0234] In another possible implementation, PagingMessageWindowStart can be indicated by an offset between a last random access preamble send time location and a paging message window start time. The last send time of the random access preamble and the start time of the paging message window can be indicated by a subframe, an interval, a mini interval of the mini interval or an OFDM symbol.
[0235] [0235] For example, when the random access preamble length L = 839, the paging message window start time is fixed as 3 ms; and when L = 127 or 139, the paging message window start time is fixed as O ms. The length of the preamble of random access is indicated by the signaling (for example, indication information indicating that the length of the preamble of random access occupies 1 bit). For another example, when a carrier frequency is less than 6 GHz, the paging message window start time is fixed at 3 ms; when the carrier frequency is not less than 6 GHz, the start time of the paging message window is fixed as 1 ms (or an interval, a mini-interval or an OFDM symbol). For another example, when the number of paging messages or groups of paging users is N, the size of the paging message window is N * PagingMessageWindowSize, where PagingMessageWindowSize indicates the size of the paging message window.
[0236] [0236] In the previous solution, the start time of the paging message window (PagingMessageWindowsStart) can alternatively be determined based on a subcarrier spacing, for example, PagingMessageWindowStart = W * 2 "“ intervals, where W can be any pre-stored or pre-configured non-negative integer. For another example, when the carrier frequency is less than 3 GHz, PagingMessageWindowStart = 3 * 2 "intervals; when the carrier frequency is greater than 3 GHz and less than 6 GHz, PagingMessageWindowStart = 2 * 2nd intervals; and when the carrier frequency is greater than 6 GHz, PagingMessageWindowStart = 2 "intervals. u is an index of the subcarrier spacing.
[0237] [0237] In another possible implementation, the start time of the paging message window starts PagingMessageWindowsStart in the configuration information of the paging message window is an optional parameter. In another embodiment, the start time paging message window is a fixed value and does not need to be sent by the network device. In another embodiment, the start time of the paging message window can be obtained by searching the table based on parameters, such as a carrier frequency, a bandwidth, a frame structure, a subcarrier spacing and a type of service used in a random access process. For example, the paging message window start time = W * 2 "intervals, where W can be any pre-stored or preconfigured non-negative integer. For another example, when the carrier frequency is less than 3 GHz, paging window start time = 3 * 2nd intervals; when carrier frequency is greater than 3 GHz and less than 6 GHz, paging window start time = 2 * 2nd intervals ; and when the carrier frequency is greater than 6 GHz, the paging message window start time = 2 "intervals. u is an index of the subcarrier spacing.
[0238] [0238] In another possible implementation, a random access feature (associated with a downlink signal) and a paging message window have a match, and a travel time is calculated from a start location of the paging message. The terminal device obtains a random access resource index (and / or group) and / or a downlink signal index (and / or group). The terminal device determines the start time of the paging message window based on the initial offset of the time information to receive the paging message, the random access resource index (and / or group) and / or the signal signal index. downlink (and / or group). For example, a RACH subframe / interval is considered to include four random access resources (a random access resource group can be a random access resource in a time-frequency resource, or it can correspond to a set of access resources random from a plurality of different frequency domain resources in the same time domain resource, a random access resource can include one or more random access preambles, and the random access preamble used to request the paging message is within random access resource) numbered as 0, 1, 2 and 3 (respectively associated with downlink signals 0, 1, 2 and 3). The start time of the paging message window corresponding to a first random access resource / random access resource group (numbered 0) in the subframe / random access resource interval is a start time of an access resource random after the last subframe / interval to send the random access preamble.
[0239] [0239] In an LTE system, the terminal device needs to receive a random access response (RAR) in a random access response window, but really, the network device can send a RAR only at a particular time in the response window random access. Therefore, the waste of electricity from the terminal device is caused by the fact that the terminal device needs to monitor the entire random access response window.
[0240] [0240] One embodiment of the present invention provides a method for triggering the transmission of a paging message through random access. The terminal device receives the paging message at intervals in the paging message window, and does not need to monitor the entire paging message window. Similarly, the network device sends the paging message at intervals only in the paging message window, that is, in the paging message window, the paging message appears once at intervals, where the interval can be fixed or not be fixed. In another possible implementation, each paging message window and an offset time appear in the same StepSize interval in time, for example, a time segment (T + 2, T + 4, ..., and T + 2n) when the paging message may appear in the paging message window indicates a time when the network device can send the paging message, and / or a time when the terminal device may need to monitor the paging message. A paging message window | corresponding to an i th random access resource (or a downlink signal associated with the random access resource, numbered as i-1) in a subframe / RACH interval is a window of time obtained after the conversion of the window corresponding to the first resource of random access towards the time axis by (i-1) * StepSize * PagingMessageWindowoOffset subframes / intervals / mini-intervals. The terminal device receives a RAR only at the following window time: (i-1) * StepSize * PagingMessageWindowOffset + (k-1) * StepSize, where k = 1,2, ..., and PagingMessageWindowsSize, eiek are numbered starting from 1.
[0241] [0241] It can be understood that the paging message | appears at equal intervals of a StepSize.
[0242] [0242] The range of the paging message window can be determined and delivered to the terminal device by the network device.
[0243] [0243] For example, StepSize = 2, i = 1, PagingMessageWindowSize = n and PagingMessageWindowStart = 1.
[0244] [0244] For another example, StepSize is configured using signaling, and signaling can be at least one of the radio resource control signaling, a MAC CE, system information, downlink control information and the like, and is sent by the network device to the terminal device. Optionally, StepSize can alternatively be determined based on subcarrier spacing information or a subcarrier spacing index u. For example, an implementation similar to that of the Scale can be used, and the details are not described in this report again.
[0245] [0245] In a possible implementation, the paging message can be sent at a time in a period: a length of time for the period, a location of appearance time in the period, and / or a number of periods. Any one or more of the previous three parameters can appear based on a predefined or pre-stored format or specified by the base station. For example, a time length of the period is four intervals, the appearance time location in the period is 0110 (indicating the display for the second and fourth time), and the number of periods is 2, that is, a total size of the window is eight intervals. In this configuration, a possible send / receive time location of the paging message is only four intervals. It should be noted that a similar method can also be used for the random access response window.
[0246] [0246] Optionally, PagingMessageWindowSize and / or PagingMessageWindowoOffset are additionally related to parameters, such as a carrier frequency range, bandwidth, frame structure and type of service.
[0247] [0247] In the previous method, the terminal device does not need to continuously monitor the paging message at all points in time for the entire paging message window and instead monitors the paging message in the time segments that are spaced in the paging message window, thereby reducing the electricity consumption of the terminal device.
[0248] [0248] In another possible implementation, a unit of time for the random access preamble is an interval, and a unit of time for the paging message is a mini-slot. Different random access features trigger paging messages sent on different beams. In the paging message window, an interval has four mini intervals. The paging message triggered by an ith random access preamble (located in an i * random resource, and correspondingly associated with a downlink signal i) is sent in an i »» mini interval (i = O, 1, 2 or 3). A total of four paging messages can be sent at one interval. A paging message window start time corresponding to each of the four paging messages is a corresponding mini-interval in a T + 3 interval, that is, a paging message window start time of a tenth message frame. random access in a T interval is an ith mini-interval in the T + 3 interval. That is, a travel time between the paging message windows of a plurality of paging messages is O gap (but there is a mini-gap offset). A start time of the random access window (PagingMessageWindowStart) is at least three intervals, for example, a start time of the random access preamble / resource group 3 is actually three intervals + three mini intervals.
[0249] [0249] In another possible implementation, a paging message window start time (PagingMessageWindowStart), a paging message window scroll time (PagingMessageWindowoOffset), a paging message window size or an initial paging window size Paging message (PagingMessageWindowSize) includes two parts, where each part corresponds to a different unit of time. For example, a first part time unit is an interval, and a second part time unit is a mini interval of the mini interval. A first part time can be specified by signaling (for example, specified by system information, a PBCH, ISDN, RRC signaling, DCI or a MAC CE), and a second part time can be specified by signaling, or can be determined implicitly. For example, a time location of a specific mini-interval of the paging message can be specified by signaling, or it is obtained implicitly based on the index of the random access preamble / resource, the index of the paging message and the paging user group index. For a specific implementation, consult a way of indicating a paging message length, and the details are not described in this report again.
[0250] [0250] In addition, the network device can send the configuration information to the terminal device to indicate the start time and the length of the paging message window; and the terminal device determines a time unit of the start time and the length of the paging message window based on the configuration information of the network device. For example, the configuration information sent by the network device is FlagWin. When FlagWin = O, the time unit of the start time and the length of the paging message window is an interval; when FlagWin = 1, the start time and length of the paging message window includes both the time units of an interval and a mini-interval; when FlagWin = 3, the time unit of the start time and the length of the paging message window are a mini interval; and when FlagWin = 4, the time unit of the paging message window size is an interval, and appears in intervals of a pre-established or configured StepSize by the network device. Certainly, another form of indication can be used alternatively, and this is not limited in this modality.
[0251] [0251] In a possible design, the network device can configure a PDCCH monitoring interval or a number of continuous PDSCH symbols in the paging message based on at least one of the main information block (Main Information Block, MIB ), RMSI, RRC, a MAC-CE, system information, an NR-SIB1 and DCI. The number of continuous PDSCH symbols in the paging message can be indicated by using indication information, and the number of continuous symbols can alternatively be a type of interval, or it can be an amount of continuous symbols in a programming message , or it can be a number of continuous symbols, that is, a number of symbols programmed by a PDSCH. For example, 2 bits are used to indicate that the number of continuous symbols in the paging message is one of 2.4,
[0252] [0252] A PDCCH monitoring interval of the paging message can be additionally configured by using at least one of a main information block (Main Information Block, MIB), RMSI, RRC, a MAC-CE, system information, an NR-SIB1 and DCI, and the range is at least one of the 2, 4, 7 and 14 OFDM symbols. For example, 2 bits can be used to indicate that the paging message's PDCCH interval type is one of 2, 4, 7, and 14 OFDM symbols, or 1 bit is used to indicate whether the message's PDCCH monitoring interval paging interval is the same as an RMSI PDCCH monitoring interval type, or the 1-bit information indicates that the paging message PDCCH interval type is 14 OFDM symbols or an RMSI type, or the information of 1 bit indicates that the PDCCH range type of the paging message is 14 OFDM symbols or 7 OFDM symbols, or the 1 bit information indicates that the PDCCH range type of the paging message is 14 OFDM symbols or 4 OFDM symbols, or the 1-bit information indicates that the type of PDCCH range of the paging message is 14 OFDM symbols or of 2 OFDM symbols, or the 1-bit information indicates that the type of PDCCH range of the paging message is 7 OFDM symbols or 4 OFDM symbols, or the 1-bit information indicates that the PDCCH interval type of the paging message is 7 OFDM symbols or 2 OFDM symbols, or the 1-bit information indicates that the PDCCH interval type of the paging message is 4 symbols OFDM or 2 OFDM symbols, or 1 bit is used to indicate interval based programming or non-interval based programming. The monitoring period or monitoring interval is not limited to 2, 4, 7 and 14 symbols, or it can be any one of 1 to 14 symbols, or it can be a combination of several quantities.
[0253] [0253] In a possible project, the network device configures RMSI programming information by using a PBCH, it can configure a type of RMSI interval or a number of continuous symbols by using a PBCH or a MIB message, or it can configure a type of interval or a number of continuous symbols for RMSI transmission by using DCI. For example, 2-bit information is used to indicate that an amount of PDSCH continuous symbols for RMSI transmission can be one of 2, 4, 7, and 14 OFDM symbols, or 2 bits can be used to indicate that the number of symbols PDSCH streams for RMSI transmission can be one of 2, 4 and 7 OFDM symbols, or 2 bits can be used to indicate that the amount of PDSCH streams for RMSI transmission can be one of 4, 7 and 14 OFDM symbols, or 2 bits can be used to indicate that the number of PDSCH continuous symbols for the RMSI transmission can be one of 2, 7 and 14 OFDM symbols, or 2 bits can be used to indicate that the number of PDSCH continuous symbols for the RMSI transmission can be be one of the 2, 4 and 14 OFDM symbols, or the 1 bit information can be used to indicate that the number of PDSCH continuous symbols for the RMSI transmission is both 14 OFDM symbols and 7 OFDM symbols; or 1 bit information can be used to indicate that a type of PDSCH interval for RMS transmission! it is both 14 OFDM symbols and 4 OFDM symbols; or 1-bit information can be used to indicate that the amount of continuous PDSCH symbols for the RMSI transmission is either 14 OFDM symbols or 2 OFDM symbols; or 1-bit information can be used to indicate that the number of continuous PDSCH symbols for the RMSI transmission is either 7 OFDM symbols or 4 OFDM symbols; or 1-bit information can be used to indicate that the amount of continuous PDSCH symbols for the RMSI transmission is either 7 OFDM symbols or 2 OFDM symbols; or 1 bit information can be used to indicate that the amount of PDSCH continuous symbols for RMSI transmission is either 4 OFDM symbols or 2 OFDM symbols, or 1 bit is used to indicate interval based programming or non-based programming interval.
[0254] [0254] In another possible implementation, the same terminal device can simultaneously send a plurality of preambles of random access to request one or more paging messages / messages from the system. After sending the plurality of random access preambles, the terminal device receives one or more corresponding paging messages and / or system messages. A paging message / system message length of the terminal device may be a joint set of one or more paging message / system message windows corresponding to the random access features of the plurality of random access preambles. To be specific, the terminal device sends the plurality of random access preambles to the network device in a plurality of random access resources / preamble groups, and the terminal device receives separately, in the joint set of the paging message windows / system messages corresponding to the plurality of random access preambles, one or more paging messages / system messages corresponding to the plurality of random access preambles. To be specific, the plurality of paging message windows / system messages corresponding to the plurality of random access preambles is superimposed over time, and the union set of the plurality of paging message windows / system messages corresponding to the plurality of random access preambles is used as an entire paging message / system message window of the terminal device.
[0255] [0255] According to this embodiment of the present invention, a plurality of paging messages requested by the preamble of random access sent in the same interval is answered, a travel time between receiving points in the time of the paging messages of the terminal device is configured, and a plurality of paging message windows can be configured together, so that signaling overheads are reduced, and the windows may or may not cross, and the complexity of receiving the terminal device is reduced.
[0256] [0256] In another possible implementation, the paging message window is determined based on a random access response window. For example, the paging message window and the random access response window are completely the same. For another example, based on any of the previous methods for determining the start time and length of the paging message window, an initial value or an actual value of a configured / preset / pre-stored parameter used in the message window paging value is directly replaced with an initial value or an actual value of a configured / pre-established / pre-stored parameter in the random access response window. For example, an initial paging window start time is replaced with an initial random access response window start time, and / or an initial paging message length is replaced with an initial response window size. random access time, and / or an initial scroll time of the paging message window is replaced with an initial travel time of the random access response window. For another example, a plurality of paging message windows corresponding to the same downlink signal are completely the same, and the paging message window is determined based on the random access response window and / or an N1 number of groups of paging users or an N2 amount of paging messages. For example, the size of the paging message window = N1 x the size of the random access response window, or the size of the paging message window = N2 x the size of the random access response window, and the start time of the paging message window is the same as the start time of the random access response window.
[0257] [0257] In a possible project, the terminal device does not need to generate the configuration information from the paging message window of the random access preamble and instead receives the configuration information from the paging message window of the access preamble. random sent by the network device. The network device generates the configuration information for the paging message window based on at least one of the following information: a random access preamble start time, random access preamble duration, a preamble end time. random access, time domain location information from a random access response window corresponding to the random access preamble, frequency domain location information from the random access response window corresponding to the random access preamble, and a total amount groups of paging users.
[0258] [0258] The network device sends the configuration information from the paging message window to the terminal device.
[0259] [0259] For the generation of the paging message window configuration information by the network device, consult the process in which the terminal device generates the paging message window configuration information, and the details are not described in this report again .
[0260] [0260] S203: The network device obtains a paging identifier and / or a group of paging users associated with the preamble of random access.
[0261] [0261] Specifically, the network device determines that a type of the random access preamble must trigger a paging procedure, and the network device obtains the paging identifier and / or the paging user group associated with the random access preamble. . The paging identifier is used to encrypt a physical downlink control channel, and the physical downlink control channel is used to indicate a shared physical downlink channel to send the paging message.
[0262] [0262] In a possible design, the network device obtains the paging identifier associated with the random access preamble includes the following: the network device obtains a pre-configured or pre-stored paging identifier associated with the random access preamble ; or the network device determines, based on one or more parts of the following information, the paging identifier associated with the random access preamble: an index of the random access preamble, an index of the paging message, an index of the user group terminal device paging index, an index of a time-frequency resource corresponding to the random access preamble, an index of a block of synchronization signals corresponding to the random access preamble, an index of a reference information signal port channel status (CSI-RS) corresponding to the random access preamble and a temporary random access radio network identifier (RA-RNTI) corresponding to the random access preamble.
[0263] [0263] For a way in which the network device obtains, based on a pre-stored or pre-configured way, the paging identifier associated with the random access preamble, consult the process in which the terminal device obtains the pagination based on a pre-stored or pre-configured way in S202, and the details are not described in this report again.
[0264] [0264] For a process in which the network device determines the paging identifier associated with the random access preamble, consult the process in which the terminal device generates the paging identifier in S202, and the details are not described in this report again.
[0266] [0266] S203: The network device sends a paging message to the terminal device, and the terminal device receives the paging message from the network device.
[0267] [0267] The network device sends the paging message to the terminal device in the paging message window, and sends the random access response to the terminal device. In the random access response, a RAR subheader corresponding to the random access preamble does not have the corresponding MAC RAR, that is, the terminal device does not perform random access and uplink synchronization based on the random access response. The network device encrypts the physical downlink control channel in the paging message window based on the paging identifier. The physical downlink control channel corresponds to the shared physical downlink channel for transmitting the paging message, and the physical downlink control channel is used to transmit the DCI of the paging message.
[0268] [0268] In a possible design, the network device sends the paging message in the paging message window. For a method used by the network device to obtain the paging message window configuration information, refer to the process in which the terminal device obtains the paging message window at S202, and the details are not described in this report again. The network device can send the configuration information from the paging message window to the terminal device.
[0269] [0269] In a possible design, the method additionally includes the following: the network device sends the paging message to the terminal device, where the paging message can include at least one of a list of user equipment identifiers (list UE ID or list of UE ID records), system change information, natural disaster warning information, such as an earthquake and tsunami, a uplink programming grant (UL grant) of a message 3, a C -RNTI (or TC-RNTI, temporary temporary cell radio network identifier), a non-contention based random access preamble (for example, a random access preamble index and / or a random access resource index) and a timing advance (TA).
[0270] [0270] For example, when the paging message includes both a UE | D and a non-contention-based preamble, each UE | D in the paging message can be associated with a non-contention-based preamble; or some UE IDs in the paging message may be associated with a non-contention-based preamble and other UE IDs are not associated with a non-contention-based preamble. In another embodiment, different UE IDs correspond to a completely different contention-based preamble or non-contention based random access preambles, or some UE IDs are associated with the same non-contention based random access preamble. For another example, the base station device may indicate that one of the previous three ways is currently used.
[0271] [0271] For another example, when the paging message includes both a UE ID and a uplink scheduling grant (UL grant) of a message 3, each UE ID in the paging message can be associated with a scheduling grant. uplink (UL grant) of message 3; or each of some UE IDs in the paging message may be associated with an uplink scheduling grant (UL grant) of message 3 and other UE IDs are not associated with an uplink scheduling grant. In another embodiment, the uplink programming grants (UL grant) of message 3 associated with different UE IDs are completely the same or completely different, or some UE IDs are associated with the same uplink programming grant. For another example, the base station device may indicate that one of the previous three ways is currently used.
[0272] [0272] For another example, when the paging message includes both a UE ID, a uplink programming grant (UL grant) of a message 3 and a TA, the TA can be a common TA for all terminals in the message paging or a plurality of TAs for a plurality of terminals, each UE ID in the paging message is associated with an uplink programming grant (UL grant) of message 3 and a TA; or each of some UE IDs in the paging message is associated with a uplink scheduling grant (UL grant) of message 3 and a TA and other UE IDs are not associated with an uplink scheduling grant and a TA. In another embodiment, the uplink programming grants (UL grant) of message 3 and / or TAs associated with different UE IDs are completely the same or completely different, or some UE IDs are associated with the same uplink programming grant. and / or the same TA. For another example, the base station device may indicate that one of the previous three ways is currently used.
[0273] [0273] For another example, when the paging message includes both a UE ID and a C-RNTI (or a TC-RNTI), each UE ID in the paging message can be associated with a C-RNTI (or TOC-RNTI ); or each of some UE IDs in the paging message can be associated with a C-RNTI (or TC-RNTI) and other UE IDs are not associated with C-RNTI (or TOC-RNTI). In another modality, C-RNTIs (or TO-RNTIs) associated with different UE IDs are completely the same or completely different, or some UE IDs are associated with the same C-RNTI (or TC-RNTI). For another example, the base station device may indicate that one of the previous three ways is currently used.
[0274] [0274] For another example, the paging message may, alternatively, not include the preamble of random access, and only include UE ID information of the paged terminal.
[0275] [0275] In an implementation, the base station indicates a paging message format or content before sending the paging message or DCI corresponding to the paging message, for example, the paging message format or content is one of the previous modalities.
[0276] [0276] In another implementation, the specific formats or the content of the paging messages corresponding to different blocks of sync signals from the same cell is different, or when the blocks of sync signals corresponding to the preambles of random access used to request messages paging messages are different, the formats or content of paging messages is different. For example, the paging information corresponding to some downlink signal blocks may include UE ID information from a paged terminal, an uplink scheduling concession and a TA (for example, in an area relatively close to the network device or having a relatively small ta value, all users can share the same TA); and paging information corresponding to some other sync signal blocks include a paged terminal UE ID and a non-contention based random access preamble (for example, in an area relatively distant from the base station, a TA is inaccurate) . For another example, the paging information corresponding to some blocks of synchronization signals may include a UE ID of a paged terminal and a non-contention based random access preamble (for example, when an area covered by the synchronization signal block has a relatively small number of terminals or a relatively large number of non-contention based random access resources); and paging information corresponding to some other sync signal blocks include a paged terminal UE ID (for example, when an area covered by the sync signal block has a relatively large number of terminals or a relatively small amount of random access not based on contention).
[0277] [0277] In another implementation, the specific formats or the content of the paging messages corresponding to different blocks of synchronization signals from the same cell are completely the same. Optionally, the format or content of the paging message is specified by the network device using signaling. Signaling can be radio resource control signaling (radio resource control, RRC), system information (system information, SI), media access control element control signaling (MAC) CE), downlink control information, DCI, a physical downlink control channel order, PDCCH order, and the like.
[0278] [0278] In another implementation, the paging message includes all of a non-contention based random access preamble, a message uplink scheduling concession 3, a C-RNTI (or a TC-RNTI) and a TA , and the paging message can be applied to paging a terminal in an inactive state.
[0279] [0279] In the previous modality, the paging message includes the uplink programming concession (UL concession) of message 3, the C-RNTI (or TC-RNTI), the non-contention based random access preamble or the timing advance (TA), so that the random access preamble to trigger the paging message is completely used, to prevent contention-based random access from being performed again after the terminal is paged, thereby reducing a delay.
[0280] [0280] In a possible project, after sending the preamble of random access and successfully receiving a paging message in the paging message window, the terminal device stops receiving a paging message. In a possible design, after the terminal device sends the random access preamble and receives no paging message in a corresponding paging message window, sending the random access preamble is considered to have a problem, and a layer can determine whether to send a random access preamble again to request a paging message again. In another possible project, after the terminal device sends the random access preamble and successfully receives a paging message in the paging message window, if the terminal device is not paged in the paging message, the terminal device continues to receive a paging message. paging message, or the terminal device can autonomously select whether to continue receiving a paging message, or the terminal device determines, based on indication information configured by the network device, a number of paging messages that continue to be received ( for example, the network device indicates a number of subsequent paging messages for using the paging message already sent, or the network device indicates a number of paging messages for using other signaling), or the terminal device stops receiving a paging message, and considers that the terminal device is not paged on the network, or the dis positive terminal stops receiving a paging message, and considers that all terminal devices have been paged on the network.
[0281] [0281] In a possible design, the method additionally includes: when the random access preamble needs to be retransmitted, if a retransmission amount reaches a maximum retransmission amount (maximum preamble transmission number) associated with the random access preamble or a maximum amount of retransmission associated with the paging message, stopping retransmission; or if the terminal device reaches a next DRX cycle, stopping retransmission; or if the paging message received by the terminal device does not carry the identifier of the terminal device, stopping retransmission.
[0282] [0282] Specifically, the maximum amount of retransmission associated with the random access preamble and the maximum amount of retransmission associated with the paging message can be configured by the network device, and are notified by the network device to the terminal device. A form of notification includes, but is not limited to, at least one of the following signals: Sl, an RRC message, a MAC-CE message and a PDCCH order. The maximum amount of retransmission can alternatively be obtained by the terminal device by consulting a pre-stored mapping table. The terminal device pre-stores the mapping table indicating a mapping relationship between the random access preamble and the maximum amount of retransmission. In the mapping table, different random access preambles can correspond to different maximum amounts of retransmission, or a plurality of random access preambles corresponds to the same maximum amount of retransmission. This is not limited in this mode.
[0283] [0283] In the method shown in FIG. 2a, the network device sends the paging message to the terminal device based on triggering by the random access preamble, and can use an existing random access procedure, to reduce signaling overheads.
[0284] [0284] FIG. 3a is a schematic flowchart of a pagination method, according to an embodiment of the present invention. In this embodiment of the present invention, the method includes:
[0285] [0285] S301: A terminal device sends a random access preamble to a network device, and the network device receives the random access preamble from the terminal device.
[0286] [0286] The terminal devices in the same pagination occasion are grouped in n groups of paging users, where n is an integer greater than 0. Each group of paging users is associated with a preamble of random access and a message of pagination.
[0287] [0287] In a possible design, before the network device receives the preamble of random access from the terminal device, the method additionally includes the following: the network device sends a paging indication message to the terminal device, where a pagination indication bit that is carried by the pagination indication message and that belongs to the terminal device's paging user group is a pre-established value.
[0288] [0288] Specifically, the paging indication bit is set for each group of paging users. When it is necessary to page the terminal device, the network device determines the group of paging users of the terminal device, and sends the paging indication message to the terminal device. The pagination indication bit that is carried by the pagination indication message and that belongs to the terminal device's paging user group is the default value. The terminal device receives the paging indication message from the network device, and upon determining that a paging indication bit value of the paging user group of the terminal device is the preset value, the terminal device sends the preamble of random access corresponding to the paging user group for the network device.
[0289] [0289] When the paging indication bit is the preset value, the terminal device or a terminal device in the associated paging user group sends the random access preamble to the network device. The paging indication message can be carried in information, such as DCI, RMSI, an NR-SIB1, an NR-SIB2, a system message or a PDSCH of the paging indication message. When DCIs are used to carry the paging indication message or the DCIs indicate the PDSCH of the paging indication message, the DCI of the paging indication message must be encrypted using a temporary radio network identifier (RNTI) . The RNTI can be a temporary radio network identifier specifically used to encrypt DCI, to be distinguished from a temporary radio network identifier corresponding to another message. In an implementation, an RNTI corresponding to the paging indication message is different from that corresponding to the paging message. In another implementation, the RNTI corresponding to the paging indication message is the same as the corresponding paging message. For example, the paging indication message and the paging message are sent at different points in time and / or frequencies. For another example, the 1-bit indication information in DCI is used to indicate that DCI is one of the two previous types. For another example, an implicit way is used to indicate that DCIs are one of the two previous types, where the implicit way includes a demodulation reference signal, a CRC mask, a cyclic shift, encryption and the like.
[0290] [0290] For example, three groups of paging users are obtained through advance grouping: a group of paging users 1, a group of paging users 2 and a group of paging users
[0291] [0291] In a possible design, before the network device receives the preamble of random access from the terminal device, the method additionally includes the following: The network device sends configuration information from the paging message to the terminal device.
[0292] [0292] Specifically, configuration information may include information, such as a PO length, a PO amount, a DRX cycle length and a PO location (time and / or frequency). When paging messages in one or more POs or a paging indication control feature or a paging indication control feature is multiplexed with a synchronization signal block, SS block, an index of the Paging occasion can be configured in the configuration information. A specific configuration method is mod (index, K) = m, where K indicates an amount of PO in a period of the burst burst (SS burst set), and the index indicates a PO index. The network device can configure m to indicate that the PO is multiplexed with the SS block.
[0293] [0293] S302: The network device sends a random access response to the terminal device, and the terminal device receives the random access response from the network device.
[0294] [0294] The network device determines that a type of the random access preamble is used to request the paging message, and the network device determines paging programming information and / or a paging identifier corresponding to the random access preamble. Paging schedule information includes, but is not limited to, at least one of an RNTI, frequency information, time information, a coding and modulation scheme, a reference signal, subcarrier and DCI spacing, and the paging programming information is carried on a MAC RAR corresponding to the preamble of random access. For example, a MAC RAR in a random access response includes information shown in FIG. 3b. The terminal device obtains the paging programming information from the random access response received. The paging identifier can be an RNTI. For a way in which the network device determines the RNTI, see the description in the embodiment of FIG. 2a, and the details are not described in this report again.
[0295] [0295] S303: The network device sends a paging message to the terminal device, and the terminal device receives the paging message from the network device.
[0296] [0296] The network device sends the paging message based on the paging programming information, and the terminal device receives the paging message from the network device based on the paging programming information.
[0297] [0297] In the embodiment shown in FIG. 3a, the network device sends the paging message to the terminal device based on activation by the random access preamble, and can use an existing random access procedure to reduce signaling overheads.
[0298] [0298] In another mode, after sending a paging indication message to the terminal device, the network device sends the paging message to the terminal device. The terminal device receives the paging indication message. If a paging indication bit that is carried in the paging indication message and that is from the terminal device's paging user group is a pre-established value, the terminal device continues to receive a paging message corresponding to the paging user group the terminal device; otherwise, the terminal device group is not paged. FIG. 3c is a schematic flow chart of a pagination method, according to an embodiment of the present invention. In this embodiment of the present invention, the method includes:
[0299] [0299] S311: A network device sends a paging indication message to a terminal device, and the terminal device receives the paging indication message from the network device.
[0300] [0300] A paging indication bit that is carried in the paging indication message and that is from the terminal device's paging user group is a pre-established value. A method for sending the paging indication message may be the same as the method in the modalities of FIG. 2a and FIG. 3a, and the details are not described in this report again.
[0301] [0301] S312: The network device sends a paging message to the terminal device, and the terminal device receives the paging message from the network device.
[0302] [0302] The network device sends the paging message based on paging schedule information, and the terminal device receives the paging message from the network device based on paging scheduling information. The programming information is a PDCCH of the paging message or PDCCH DCI. Programming information for the paging message may be sent along with the paging message, or it may not be sent with the paging message.
[0303] [0303] In a possible design, the network device first sends the paging indication message and then sends a plurality of corresponding paging and DCI messages (or PDCCHs). Optionally, the DCIs (or PDCCHs) of the plurality of paging messages are encrypted separately by using different RNTIs, where the RNTI corresponds to the group of paging users or the paging message based on a predefined or pre-stored rule or specified by the network device; or the DCI (or PDCCHs) of the plurality of paging messages are encrypted using the same RNTI, where the paging indication message indicates the paging messages corresponding to the DCI (and one or more groups of paging users corresponding to the paging messages); or the DCI (or PDCCHs) of the plurality of paging messages are encrypted by using the same RNTI, where the DCI (or PDCCHs) of the plurality of paging messages indicate the paging messages corresponding to the DCI (and one or more paging user groups corresponding to paging messages) In one implementation, different paging messages are encrypted by using different RNTIs in a way that is the same as that in the modality corresponding to FIG. 3a, for example, is the same as Table 3 or Table 4 or an RNTI calculation formula. The details are not described in this report again. In one implementation, a paging message sending time is the same as in the method of FIG. 3a. For example, the terminal device receives the paging message in a paging message receipt window. The paging message receiving window is the same as in the method of FIG. 3a, and the details are not described in this report again. For another example, information about the paging message receiving window is indicated by the base station using signaling.
[0304] [0304] This embodiment of the present invention and the embodiment of the method in FIG. 3a are based on a similar idea, and also have the same technical effects. For a specific process, see the description of the method in FIG. 3a, and the details are not described in this report again.
[0305] [0305] In a possible design, a type of interval of the paging indication message is the same as that of one or more corresponding paging messages in the present invention. In a possible design, a subcarrier spacing of the paging indication message is the same as that of one or more corresponding paging messages. In a possible design, a paging indication message sending time and a sending interval of one or more corresponding paging messages can be configured, and can be configured using a MIB, RMSI, SI, an NR-SIB1 , an NR-SIB2, RRC, a MAC-CE, DCI and the like. In a possible project, the paging indication message is sent based on a time window, and one or more paging messages are also sent based on the time window. A time window size and a time window start time can be configured using a MIB, RMSI, SI, NR-SIB1, NR-SIB2, RRC, MAC-CE, DCI and the like .
[0306] [0306] In a possible design, the network device can determine, based on previous information from the terminal device, whether to send the paging message on some time frequency resources that are associated with a block of synchronization signals or that are QCL.
[0307] [0307] In a possible project, the base station indicates a way to send the paging message, for example, by using FlagPaging signaling. When FlagPaging = O, the manner in FIG. 3a is indicated when
[0308] [0308] The following modalities use the following parameters:
[0309] [0309] T; indicates a basic time unit (ie, a sampling interval, which can be predefined or pre-stored, or can be a specific value set by the network device, or T; is related to a subcarrier spacing and amount of sampling points) of the terminal device and / or the network device.
[0310] [0310] The number of sampling points is a predefined or pre-configured constant or a value configured by the network device. For example, when a subcarrier spacing is 15 kHz and a bandwidth is 20 MHz, the number of sampling points is 2048. For another example, the number of sampling points is a size of the fast inverse Fourier transform. (Inverse Fast Fourier Transform, IFFT) or a maximum amount of the subcarrier.
[0311] [0311] u indicates a subcarrier index. For example, when u = O, the subcarrier spacing is 15 kHz; when u = 1, the subcarrier spacing is 30 kHz; when u = 2, the subcarrier spacing is 60 kHz; when u = 3, the subcarrier spacing is 120 kHz; when u = 4, the subcarrier spacing is 240 kHz; and when u = 5, the subcarrier spacing is 480 kHz.
[0312] [0312] Mia ”Nr! Au XN559), where ras indicates a maximum subcarrier spacing supported by the terminal device;
[0313] [0313] For example, the spacing of Max subcarrier is 480 kHz, Yrmx = 4096, V = 15 kHz and Vi = 2048, In this case, IS: = 1 / (480000x4096) and x = 64.
[0314] [0314] FIG. 4 is a schematic flow chart of a communication timing method, according to an embodiment of the present invention. In this embodiment of the present invention, the method includes:
[0315] [0315] S401: A terminal device sends a random access preamble to a network device, and the network device receives the random access preamble from the terminal device.
[0316] [0316] The terminal device starts a random access procedure when it is necessary to carry out the uplink synchronization. The terminal device sends the random access preamble to the network device, where a random access preamble format is not limited, for example, a sequence length of the random access preamble is 31, 63, 71, 127, 139 or 839.
[0317] [0317] S402: The network device determines a format of a TAC and / or a scale factor based on the format of the preamble of random access.
[0318] [0318] The format of the random access preamble includes a type and / or a length, and the format of the TAC includes a length of the TAC. The network device determines the format of the TAC and / or the scaling factor of a timing advance based on the shape of the random access preamble. The network device can pre-store or pre-configure a mapping table, where the mapping table indicates a mapping relationship between a random access preamble index and the length of the TAC and / or the scale factor. The network device queries the table to obtain the length of the TAC and / or the scale factor based on the index of the random access preamble sent by the terminal device.
[0319] [0319] In a possible design, the length of the TAC increases along with a length of the preamble of random access. For example, when the sequence length of the random access preamble is 839, the length of the TAC is 11 bits; when the sequence length of the random access preamble is 31, 63, 71, 127 or 139, the length of the TAC is less than 11 bits and the length of the TAC can be any length between 1 bit and 11 bits. For another example, when the sequence length of the random access preamble is 127 or 139, the length of the TAC is 8 bits.
[0320] [0320] In a possible design, the scale factor increases along with the length of the random access preamble. For example, when the sequence length of the random access preamble is 839, the scale factor value is 16; when the sequence length of the random access preamble is 31, 63, 71, 127 or 139, the scale factor value is less than 16, and the scale factor can be, for example, 0.25, 0.5 , 1, 2, 4 or 8. For another example, when the sequence length of the random access preamble is 839, the scale factor is greater than 16.
[0321] [0321] In a possible design, the scale factor increases along with the length of the random access preamble. For example, when the sequence length of the random access preamble is 839, the scale factor is & = 16xK: and when the sequence length of the random access preamble is 31, 63, 71, 127 or 139, the scale is less than 16xxX, For example, the scale factor is 4 = 0.125xx, 0.25xx, 0.5XxK, xx, 2xx, 4xK or 16xKX, For example, when the sequence length of the random access preamble is 839, the scale factor is greater than 16xKx,
[0322] [0322] S403: The network device sends a random access response to the terminal device, and the terminal device receives the random access response from the network device.
[0323] [0323] The random access response carries the TAC, or the random access response carries the TAC and the scale factor determined in S402. The terminal device receives the random access response from the network device and determines the TAC and another field in the random access response.
[0324] [0324] S404: The terminal device determines a timing advance and a timing advance offset.
[0325] [0325] S405: The terminal device sends uplink data to the network device, and the network device receives uplink data from the terminal device.
[0326] [0326] The terminal device sends the uplink data (for example, msg3) to the network device based on a timing setting (timing advance and / or timing advance offset) determined in S404, and the network device receives the uplink data from the terminal device.
[0327] [0327] Specifically, the timing adjustment (ie timing / timing adjustment / timing advance / time advance) can also be referred to as a transmission timing adjustment and, specifically, it includes a forward T1 timing (for example, indicated as T1 = NtaxTs, where Nra indicates an adjusted number of sampling points) and a timing advance offset (fixed timing advance offset) T2 (for example, indicated as T2 = NaxTs, where Na indicates a set number of sampling points) between an uplink and a downlink. For example, T1 can be a time shift between uplink and downlink communication links that are caused by a spatial transmission channel, and T2 can be a time shift required by uplink to downlink switching. In addition, T1 is related to an actual transmission channel and therefore changes in a transmission process. An initial value is estimated and obtained by a random access process, and is adjusted in a data communication process based on an uplink reference signal.
[0328] [0328] In a possible project, the initial value of the T1 time advance is obtained in a random access process, and is updated in a transmission uplink process.
[0329] [0329] IN a possible project, in an initial uplink synchronization process (that is, depending on random access), the terminal device determines an initial timing advance based on at least one of a TAC value, an index of subcarrier spacing, a scale factor, the sequence length of the random access preamble and a basic time unit. For example, the initial value of the time advance T1 is obtained based on the following formula: N, = T, xaxT, EXITO where Nu indicates the time advance, Ta indicates the TAC value and is notified by the network device to the device terminal by using the random access response, & indicates the scale factor, eu is the subcarrier spacing index.
[0330] [0330] For another example, the initial value of the timing advance
[0331] [0331] A unit of the formula is Ts, Nú indicates the timing advance, T, indicates the TAC value and is notified by the network device to the terminal device by using the random access response,% indicates the scale factor, & = 16xxx2 "and u is the subcarrier spacing index. Specifically, when the string length of the random access preamble is 139, u can be a subcarrier spacing index of the random access preamble. More specifically, u can be an index corresponding to a subcarrier spacing of an initial access bandwidth (a corresponding subcarrier spacing is 15x2 'kHz, i is an integer, for example, u = 0, 1, 2, ..., or 8; for another example, u indicates an index corresponding to a subcarrier spacing of a random access message 3).
[0332] [0332] The format of the TAC and / or the scale factor is related to the sequence length of the preamble of random access. For example, when the sequence length of the random access preamble is 839, the length of the TAC is 11 bits. For another example, when the sequence length of the random access preamble is 127 or 139, the length of the TAC is not greater than 8 bits (for example, 8 bits). For another example, when the sequence length of the random access preamble is 839,% = 16. For another example, when the sequence length of the random access preamble is 127 or 139, º = 8.
[0333] [0333] The format of the TAC and / or the scale factor is related to the sequence length of the random access preamble. For example, when the sequence length of the random access preamble is 839, the length of the TAC is 11 bits. For another example, when the sequence length of the random access preamble is 127 or 139, the length of the TAC is not greater than 8 bits (for example, 8 bits). For another example, when the sequence length of the random access preamble is 839, & = 16xx For another example, when the sequence length of the random access preamble is 127 or 139, a = 8xK,
[0334] [0334] For another example, u indicates a subcarrier index corresponding to a subcarrier spacing used for a message 3 and / or other uplink data transmission.
[0335] [0335] In a possible project, the TAC format and / or the scaling factor can be obtained based on signaling information from the network device, where the signaling can be at least one of an RRC message, a MAC- CE, SI, RMSI or DCI. For example, the network device adds FlagTAC indication information to the SI. FlaglAC = O corresponds to an 11-bit format of the TAC and the scale factor of 16. Flag TAC = 1 corresponds to an 11-bit format of the TAC and the scale factor of 8.
[0336] [0336] In a possible project, the TAC format and / or the scaling factor can be obtained based on signaling information from the network device, where the signaling can be at least one of an RRC message, a MAC- CE, SI, RMSI or DCI. For example, the network device adds FlagTAC indication information to the SI. FlaglAC = O corresponds to an 11-bit format of the TAC and the scale factor of 16xK. FIlagTAC = 1 corresponds to an 11-bit format of the TAC and the scale factor of 8XK.,
[0337] [0337] In another possible project, during the timing advance update, the terminal device can determine the initial timing advance based on at least one of the TAC value, the subcarrier spacing index, the scale factor, the sequence length of the random access preamble and the basic time unit. For example, the timing advance is calculated using the following formula: Names = Nro HT, -Ny) XAXKX2, where Niraou indicates a previously updated TAC value, and No is a constant, for example, No can be a value, such like 31, 15 or 7.
[0338] [0338] For another example, the timing advance is calculated based on the following formula: Nrines = Nrsau FT = No) XA
[0339] [0339] In another embodiment, No can be determined based on at least one of the subcarrier spacing, the length of the random access preamble sequence and the TAC format. For example, the length of the TAC is 6 bits and Ny is 31. For another example, the length of the TAC is 5 bits and No is 15. For another example, the length of the TAC is 4 bits and Vo is 7. For the selection of another parameter, refer to the method in the formula in the initial synchronization update process. The details are not described in this report again.
[0340] [0340] In another modality, a value of No, and the format of the TAC and / or the scale factor are related to the format of the preamble of random access, the length of the preamble of random access, a carrier frequency of the preamble of access random, a random access preamble band (a carrier frequency and a random access resource band corresponding to the random access preamble), a number of random access occasions (RACH, RO occasion) in a range, an amount of downlink signals in a random access resource in an interval, an amount of random access response messages corresponding to an interval, an amount of random access preambles in an RO, an amount of ROs associated with a link signal downstream, a total amount of random access preambles or resources associated with a downlink signal, a number of downlink signals actually send dos, an RO time length, a subcarrier spacing, a bandwidth, a frame structure and a type of service. A specific method is similar to that of the previous paging message window, and the details are not described in this report again.
[0341] [0341] In another modality, a scaling factor used when an upward forward link is updated is the same as that obtained in a random access process. In another mode, the scale factor used when the uplink timing advance is updated is different from that obtained in the random access process. For example, the scale factor used during random access is 16, but the scale factor used when the uplink timing advance is updated is 8. For another example, a subcarrier spacing used for a message 3 during access random is 15 kHz and a scale factor used is 16; and a subcarrier spacing used during uplink data communication is 30 kHz and the scale factor used when the timing advance is updated is 8.
[0342] [0342] When the length of the random access preamble decreases, the network device supports less coverage, and a corresponding TAC value decreases. In this case, the network device can reduce the length of the TAC and / or reduce the value of the scale factor.
[0343] [0343] For example, when the length L of the random access preamble is 127/139, the length of the TAC is any value from 1 to 10, for example, the length of the TAC is 8 bits.
[0344] [0344] For another example, when the length L of the random access preamble is 127/139, the scale factor is any value from 0 to 16 and, more specifically, can be any value from 0.25, 0.5, 1, 2, 4, 8, 16, 32 and 64.
[0345] [0345] For another example, when the length L of the random access preamble is 127/139, the length of the TAC is any value from 1 to 10, and the scale factor is any value from 0.25, 0.5, 1, 2, 4, 8, 16, 32 and 64.
[0346] [0346] In a possible design, determining the fixed time advance offset includes: determining the fixed time advance offset based on at least one parameter of the random access preamble format, the sequence length of the access preamble random, the carrier frequency of the preamble of random access, the band of the preamble of random access (a carrier frequency and a band of a random access resource corresponding to the preamble of random access), a number of occasions of random access (occasion RACH, RO) in an interval, an uplink data subcarrier spacing (or an uplink data subcarrier spacing index), an amount of downlink signals in a random access resource in an interval, a number of random access response messages corresponding to an interval, a number of random access preambles in an RO, u a number of ROs associated with a downlink signal, a total number of random access preambles or resources associated with a downlink signal, a number of downlink signals actually sent, a number of downlink signals actually transmitted, an RO time length, a subcarrier spacing, a bandwidth, a frame structure and a type of service. For example, the time advance offset can be applied so that the terminal device sends the data to the network device for times ahead (Nr FNtaoma) XT Nraoma is a fixed time advance offset, or it can be referred to as a timing advance offset. For another example, the time advance offset is used for switching between uplink and downlink data transmission.
[0347] [0347] For example, the time advance offset is determined based on the following formula: N, = B, xT, x2, where Na is the time advance offset, where the time advance offset is used for switching between uplink and downlink data transmission, P. indicates a displacement factor corresponding to a subcarrier of the terminal device, T; indicates a basic time unit of the terminal device, and u indicates a subcarrier index.
[0348] [0348] For another example, the time advance offset is determined based on the following formula: basic time units Va = A.Xx% º a is a scale factor, for example, 2 = C0XK, and is any value of 0.125, 0.25, 0.5, 1, 2, 4.8, 16, 32 and 64.
[0349] [0349] For another example, the timing advance offset is determined based on the following formula: N, = 0, XxNome xT, x2º, where x indicates a scale factor corresponding to a subcarrier of the No. terminal device, * 74ef% indicates a reference timing advance offset, T; indicates a basic time unit of the terminal device, and u indicates a current subcarrier index.
[0350] [0350] For another example, the timing advance offset is determined based on the following formula: basic time units Na = Nippa *% I indicates a scale factor corresponding to a subcarrier of the terminal device, I indicates a subcarrier index current.
[0351] [0351] Specifically, an NR system supports a plurality of numerologies, for example, subcarrier spacing, such as 15 kHz, kHz, 120 kHz, 240 kHz and 480 kHz. Different subcarrier spacing has different sampling frequencies. For example, a 15 kHz subcarrier spacing has a sampling frequency of 30.72 MHz and, correspondingly, Tso = 1 / 30.72e6; a sub-carrier spacing of 30 kHz has a sampling frequency of 61.44 MHz and, correspondingly, Ts1 = 1 / 61.44e € 6; a subcarrier spacing of 60 kHz has a sampling frequency of 122.88 MHz and, correspondingly, Ts2 = 1 / 122.88e6; a 120 kHz subcarrier spacing has a sampling frequency of 245.76 MHz and, correspondingly, Ts, 3 = 1 / 245.76e6; and a 240 kHz subcarrier spacing has a sampling frequency of 491.52 MHz and, correspondingly, Tsa = 1 / 491.52e6. Different sampling frequencies have different sampling intervals (i.e., basic time units), a relatively large subcarrier spacing has a relatively small sampling interval, a relatively small subcarrier spacing has a relatively large sampling interval, and the interval sampling can also be a time unit or a basic time unit.
[0352] [0352] Based on different subcarrier spacing, the terminal device or the network device can calculate the timing advance offset based on the previous formula. For example, when the subcarrier spacing is 15 kHz, a displacement factor Na = 156xTs.0; when the subcarrier spacing is 30 kHz, a displacement factor is 312xTs, 1; when the sub carrier spacing is 60 kHz,
[0353] [0353] In a possible project based on different subcarrier spacing, the terminal device or the network device can calculate the time advance offset based on the previous formula. For example, when the subcarrier spacing is 15 kHz, the timing advance offset Na = 156xTso; when the subcarrier spacing is 30 kHz, the timing advance offset is 312xTs, 1; when the subcarrier spacing is 60 kHz, the timing advance offset Na = 624xTs2>; when the subcarrier spacing is 120 kHz, the time advance offset Na = 1248xTs, 3; and when the subcarrier spacing is 240 kHz, the timing advance offset Na = 1248xTsa.
[0354] [0354] In a possible project, determining the timing advance offset includes: NE BT KT
[0355] [0355] b. indicates a displacement factor of the terminal device's subcarrier and is a constant. The Foot displacement factor related to the shape of the random access preamble, the length of the random access preamble, the carrier frequency of the random access preamble, the random access preamble band (a carrier frequency and a band of a resource random access preambles), a number of random access occasions (RACH, RO occasion) in an interval, an uplink data sub carrier spacing (or a link data u carrier spacing index) (ascending), a number of downlink signals on a random access resource in an interval, a number of random access response messages corresponding to an interval, a number of random access preambles in an RO, an associated number of ROs to a downlink signal, a total amount of random access preambles or resources associated with a downlink signal downstream, a number of downlink signals actually sent, a number of downlink signals actually transmitted, an RO time length, a subcarrier spacing, a bandwidth, a frame structure and a type of service.
[0356] [0356] For another example, determining the time advance offset includes: basic time units N. = P, xa
[0357] [0357] In a possible project, the determination of the time advance offset includes: N, = 0, XNÍ fia xT, EXT where%, indicates a scale factor corresponding to the nn subcarrier: Nifoga ind terminal device, and 74% “Indicates a reference time advance offset.
[0358] [0358] For another example, determining the time advance offset includes basic time units Na. = Nifona “E
[0359] [0359] Shift factor 2 ”is related to the shape of the random access preamble, the length of the random access preamble, the carrier frequency of the random access preamble, the band of the random access preamble (a carrier frequency and a random access resource band corresponding to the random access preamble), a number of random access occasions (RACH, RO occasion) in an interval, an uplink data sub carrier spacing (or a sub carrier spacing index) u of uplink data), a number of downlink signals in a random access resource in an interval, a number of random access response messages corresponding to an interval, a number of random access preambles in an RO, a number of ROs associated with a downlink signal, a total number of random access preambles or resources associated with a downlink, a number of downlink signals actually sent, a number of downlink signals actually transmitted, an RO time length, a subcarrier spacing, a bandwidth, a frame structure and a type of service.
[0360] [0360] For another example, the time advance offset is related to the shape of the random access preamble, the length of the random access preamble, the carrier frequency of the random access preamble, the band of the random access preamble (a carrier frequency and a random access resource band corresponding to the preamble of random access), a number of random access occasions (RACH, RO occasion) in an interval, an uplink data sub carrier carrier spacing (or an index uplink data sub carrier spacing u), a number of downlink signals on a random access resource in an interval, a number of random access response messages corresponding to an interval, a number of random access preambles in an RO, a number of ROs associated with a downlink signal, a total amount of random access preambles or re strokes associated with a downlink signal, an amount of downlink signals actually sent, an amount of downlink signals actually transmitted, an RO time length, a subcarrier spacing, a bandwidth, a frame structure and a type of service.
[0361] [0361] In a possible project, when the subcarrier spacing is the same, different sampling frequencies correspond to different timing advance displacements. For example, when the subcarrier spacing is 480 kHz, two terminal devices having a sampling frequency of 480x2048 kHz and a sampling frequency of 480x4096 kHz can have different timing advance offsets.
[0362] [0362] In a possible project, different bands correspond to different displacement factors.
[0363] [0363] For example, when the frequency is less than 6 GHz, the displacement factor is K1 (for example, K1 = 624); and when the frequency is greater than 6 GHz, the displacement factor is K2 (for example, K2 = 312). Optionally, K1> K2, and K1 and K2 can be any values between 1 and 624.
[0364] [0364] In a possible project, different bands correspond to different timing advance displacements. For example, when the frequency is less than 6 GHz, the time advance offset is K1 (for example, K1 = 624); and when the frequency is greater than 6 GHz, the time advance offset is K2xx (for example, K2 = 312). Optionally, K1> K2, and K1 and K2 can be any values between 1 and 624.
[0365] [0365] In a possible design, the timing advance offset is a fixed value. For example, the timing advance offset is any of 20 us, 10 us, 5 us or 2.5 us for different subcarrier spacing and different sampling frequencies.
[0366] [0366] For example, the time advance offset are K3 reference time units for different subcarrier spacing and different sampling frequencies. The reference time unit can be a minimum basic time unit. A method of calculating the minimum basic time unit is as follows: The Mox subcarrier spacing is 480 kHz and Norma = 4096, and the minimum basic time unit is Tt = 1 / (480000x4096). The reference time unit may alternatively be a maximum time unit. A method of calculating the maximum basic time unit is as follows: The Mox subcarrier spacing is 15 kHz and Nrma = 2048, and the maximum basic time unit is = 1 / (15000x2048). The reference time unit can alternatively be an intermediate value of the minimum basic time unit and the maximum basic time unit. K3 can be any of 624, 312, 156, 78, 39, 32, 16, 8, 4 and 2, or any between 1 and 624.
[0367] [0367] For another example, the fixed time advance offset is additionally related to another parameter. The other parameter includes, but is not limited to at least one of the following: the shape of the random access preamble, the sequence length, the carrier frequency and the band of the random access preamble, a number of ROs in a range (or a number of downlink signals in a random access resource associated with an interval, or a number of random access response messages corresponding to an interval), a number of random access preambles in an RO, a number of ROs associated with a downlink signal, a total amount of random access preambles associated with a downlink signal, an RO time length, a subcarrier spacing, a type of service, a number of paging user groups, a number of paging messages and a number of random access preambles associated with the paging message.
[0368] [0368] A fixed time advance shift factor is additionally related to another parameter. The other parameter includes, but is not limited to at least one of the following: the shape of the random access preamble, the sequence length, the carrier frequency and the band of the random access preamble, a number of ROs in a range (or a number of downlink signals in a random access resource associated with an interval, or a number of random access response messages corresponding to an interval), a number of random access preambles in an RO, a number of ROs associated with a downlink signal, a total amount of random access preambles associated with a downlink signal, an RO time length, a subcarrier spacing, a type of service, a number of paging user groups, a number of paging messages and a number of random access preambles associated with the paging message.
[0369] [0369] In a possible design, in a random access procedure, a unit of time in each step is related to a subcarrier spacing used by the terminal device. For example, steps in the random access process include: steps for transmitting a message 1 (msg1, also referred to as a preamble to random access), a message 2 (msg2, also referred to as a random access response), a message 3 (msg3) and a message 4 (msg4).
[0370] [0370] In an implementation, after sending the preamble of random access (message 1), the terminal device needs to monitor, in a random access response window, a PDCCH corresponding to message 2. A start time of the random access response is determined based on at least one of the last message sending time 1, a predefined kO constant or pre-stored or configured by the network device, and a subcarrier spacing of message 2; or a length of the random access response window is determined based on the subcarrier spacing of message 2 and / or an initial length that is of the random access response window and is configured by the network device.
[0371] [0371] After the terminal device receives the random access response corresponding to the preamble of random access, a start time in which the terminal device sends the message 3 is determined based on at least one of the last time the message was received 2, the subcarrier spacing of message 3, a predefined k1 constant and a delay k2 configured by the network device. A value of k2 can be configured by using at least one of a random access response, a MAC CE, DCI, SI and RRC signaling.
[0372] [0372] After sending message 3, the terminal device needs to monitor message 4 at the time and frequency locations corresponding to message 4 (or a CORESET from a PDCCH of message 4). The time location in which message 4 is monitored can be determined based on at least one of a predefined or pre-stored k4 time or configured by the network device and the subcarrier spacing of message 4, and the frequency location in that message 4 is monitored is predefined or pre-stored or configured by the network device.
[0373] [0373] In the random access process, based on different subcarrier spacing, the timing device units of the terminal device or the network device are also different. The time unit is an interval or subframe for different subcarrier spacing. For example, a time unit interval of an uplink signal (message 1 and / or message 3) having a 15 kHz subcarrier spacing is 1 ms; and a time unit interval of a downlink signal (message 2 and / or message 4) having a 120 kHz subcarrier spacing is 125 us. Therefore, message 1, message 2, message 3, and message 4 are related to different units of time.
[0374] [0374] Mode A1: A unit of time (marked as S1) and a specific time of message 1 are specified by setting using a random access feature. A unit of time (marked as S2) of message 2 is determined based on the subcarrier spacing of message 2; a unit of time (marked as S3) of message 3 is determined based on the subcarrier spacing of message 3; and a time unit (marked as S4) of message 4 is determined based on the subcarrier spacing of message 4. However, by the fact that the subcarrier spacing of message 1, message 2, message 3 and message 4 they can be different and there is a time sequence relationship, the time alignment of message 1, message 2, message 3 and message 4 needs to be considered. Specifically, the time to send message 2 is determined based on a time when the sending of message 1 is completed, and a time to message 2 is determined based on the random access response window, including the start time and the size of the random access response window; the sending time of message 3 is determined based on an uplink schedule concession in message 2; and a sending time of message 4 is determined by the base station, and a CORESET of message 4 (referring to the frequency and time resource locations of a PDCCH corresponding to message 4) is predefined in a protocol or configured by the base station through the use of signage.
[0375] [0375] Mode A2: In an implementation, the time unit S2 of message 2 is determined based on the subcarrier spacing of message 2 and / or base station indication information. The random access response window and the window size start time can be determined based on at least one of the time unit S2 of message 2, the time unit S1 of message 1, the initial length of time Kk0 of the random access response window and a length L of the random access response window. For example, the time by which message 1 is sent is T (based on the time unit S1 of message 1). If the start time of the random access response window is based on the time unit S1 and the initial length of time is kO, the time unit of the start time of the random access response window is ceil ((T + k0 ) * S1 / S2) in message 2. If the response window start time is based on time unit S1 and the initial length of time is k0O, the time unit of the random access response window start time is ceil (T * S1 / S2) + kO0 in message 2. For another example, if the length of the random access response window is based on the time unit S1 and the length is L, the time unit of the start time of the random access response window is ceil (L * S1 / S2) in message 2.
[0376] [0376] Mode A3: In an implementation, the time unit S3 of message 3 is determined based on at least one of the subcarrier spacing of message 3 and / or the indication information of the base station. The sending time of message 3 is determined based on at least one of the receiving time n of message 2, a message processing delay 2, an uplink and downlink switching delay k1 (predefined in a protocol or pre-stored or configured by the base station using signaling),
[0377] [0377] Mode A4: In an implementation, the time unit S4 of message 4 is determined based on the subcarrier spacing of message 4 and / or the indication information of the base station. The CORESET time location of message 4 can be specified as k4 (which can be a time location or can be a set of time location) based on a system message, and is determined based on at least one of the time unit S3 of message 3, a sending time T3 of message 3 (based on the time unit S3 of message 3), a synchronization signal, and / or the time unit SO of the system message. For example, if the CORESET k4 time location of message 4 is based on the system message SO time unit, a possible CORESET time location is ceil ((T3 * S3 + k4 * S0) / S4); and if the CORESET k4 time location of message 4 is based on the S4 time unit of message 4, a possible CORESET time location is ceil ((T3 * S3 + k4 * S4) / S4) or ceil (T3 * S3 / S4) + k4.
[0378] [0378] In the previous modality, any two from SO to S4 are based on different time granularities and subcarrier spacing. For example, SO is based on a 15 kHz mini-range (for example, 1 to 13 OFDM symbols, specifically 2/4/7 OFDM symbols), S1 is based on a 15 kHz range, S2 is based on a mini 15 kHz range (eg 1 to 13 OFDM symbols, specifically 2/4/7 OFDM symbols), S3 is based on a 15 kHz range and S4 is based on a 15 kHz range. More other examples are shown in Table 7 below. In the table, the second to the fourth and the sixth to the eighth columns in the same row, separately correspond to a possible combination of sub carrier spacing of different carrier frequencies. In each subcarrier spacing, a time granularity can be based on an interval, or a mini-interval of different amounts of OFDM symbol. This is not limited in this report, that is, the combination can be performed in any way.
[0379] [0379] In all the modalities A1 to A4, the measure of time and the unit of time have the same meaning, and can be a subframe, an interval, a mini-interval, an OFDM symbol or an absolute time. The interval, the mini-interval and the OFDM symbol, are a length of time corresponding to a subcarrier of a corresponding message (for example, a synchronization signal, a system message, the random access preamble, message 2, the message 3 or message 4). In another implementation, previous time measures (or time units) can be converted to each other, or converted to an absolute time (for example, one millisecond and one second), or converted to a combination of a plurality of measures of time (for example, 18 OFDM symbols can be converted into 1 interval and 4 OFDM symbols).
[0380] [0380] In another implementation, random access may fail. For example, sending the random access preamble fails, sending the random access response fails, sending message 3 fails or a conflict occurs. After random access fails, retransmission is required, and a retransmission time can be determined based on at least one of a return time, a time to receive the random access response, the last time of the access response window. random, the subcarrier spacing of message 1, a carrier frequency and a type of service.
[0381] [0381] Mode 1: If the random access response is received in a ninth time (in this report, time is based on the time unit of message 2, and can be a subframe, an interval, a mini interval or a symbol OFDM), a corresponding downlink shared channel does not include a response from a random access preamble already sent, and instructs an upper layer to continue to retransmit message 1, the terminal device must send a new random access preamble after a k1st time no later than the nth time (in this report, time is based on the time unit of message 1, and can be a subframe, an interval, a mini-interval or an OFDM symbol). Specifically, for example, the time unit of message 2 is S2, the time unit of message 1 is S1, and the time unit of k1 is S1 (i.e., the same time unit as that of message 1). In this case, a sending time for a new random access preamble is ceil (n * S2 / S1) + kK1, where k1 is a non-negative integer, for example, k1 = 0, k1 = 1, kK1 = 2, k1 = 3, k1 = 4 or k1 = 5. For another example, S1 = 1 ms and S2 = 125 us, that is, a time for sending a new random access preamble is ceil (n / 8) + k1.
[0382] [0382] Mode 2: If the random access response is received in a nési ”º time (in this report, the time is based on the time unit of message 2, and can be a subframe, an interval, a mini interval or an OFDM symbol), a corresponding downlink shared channel does not include a response from an already sent random access preamble, and instructs an upper layer to continue to retransmit message 1, the terminal device must send a new random access preamble in a $ k1th time, not later than the right * time (in this report, time is based on the time unit of message 2, and can be a subframe, an interval, a mini-interval or an OFDM symbol). Specifically, for example, the time unit of message 2 is S2, the time unit of message 1 is S1, and the time unit of k1 is S2 (i.e., the same time unit as that of message 2). In this case, a time for sending a new random access preamble is ceil ((n + k1) * S2 / S1), where k1 is a non-negative integer, for example, k1 = O to 40. For another example, S1 = 1 month and S2 = 125 us, that is, a time for sending a new preamble of random access is ceil ((n + k1) / 8).
[0383] [0383] Mode 3: If the random access response is received in a nési »º time (in this report, the time is based on the time unit of message 2, and can be a subframe, an interval, a mini interval or an OFDM symbol), a corresponding downlink shared channel does not include a response from an already sent random access preamble, and instructs an upper layer to continue to retransmit message 1, the terminal device must send a new random access preamble in a k1st time, not later than the nth time (in this report, time is based on the time unit S3 other than that of message 2 or message 1). Specifically, for example, the time unit of message 2 is S2, the time unit of message 1 is S1 and the time unit of k1 is S3. In this case, a sending time for the new random access preamble is ceil ((n * S2 + k1 * S3) / S1), where k1 is a non-negative integer, for example, k1 = O to 40. For another example , S1 = 1 ms, S2 = 125uyse S3 = 0.5 ms, that is, the sending time of the new random access preamble is ceil ((n + 4 * k1) / 8).
[0384] [0384] Mode 4: If no random access response (that is, message 2) is received in the last ninth time in the random access response window (in this report, time is based on the time unit of message 2, and can be a subframe, an interval, a mini-interval or an OFDM symbol), and instructs an upper layer to continue to retransmit message 1, the terminal device must send a new random access preamble after a k2nd time, no more later than the nth time (in this report, time is based on the time unit of message 1, and can be a subframe, an interval, a mini-interval or an OFDM symbol). Specifically, for example, the time unit of message 2 is S2, the time unit of message 1 is S1 and the time unit of k2 is S1 (i.e., the same time unit as that of message 1). In this case, a sending time of the new preamble of random access is ceil (n * S2 / S1) + k2, where k2 is a non-negative integer, for example, k2 = 0, k2 = 1, k2 = 2, k2 = 3 or k2 = 4, For another example, S1 = 1 ms and S2 = 125 us, that is, the sending time of the new preamble of random access is ceil (n / 8) + k2.
[0385] [0385] Mode 5: If no random access response (that is, message 2) is received in the last ninth time in the random access response window (in this report, time is based on the time unit of message 2, and can be a subframe, an interval, a mini-interval or an OFDM symbol), and instructs an upper layer to continue to retransmit message 1, the terminal device must send a new random access preamble in a second period, not later than the nth time (in this report, time is based on the time unit of message 2, and can be a subframe, an interval, a mini-interval or an OFDM symbol). Specifically, for example, the time unit of message 2 is S2, the time unit of message 1 is S1 and the time unit of k2 is S2 (i.e., the same time unit as that of message 2). In this case, a sending time for the new random access preamble is ceil ((n + k2) * S2 / S1), where k2 is a non-negative integer, for example, k2 = 0 to 40. For another example, S1 = 1mseS2 = 125 us, that is, the sending time of the new preamble of random access is ceil ((n + k2) / 8).
[0386] [0386] Mode 6: If no random access response (that is, message 2) is received in the last ninth time in the random access response window (in this report, time is based on the time unit of message 2, and can be a subframe, an interval, a mini-interval or an OFDM symbol), and instructs an upper layer to continue to retransmit message 1, the terminal device must send a new random access preamble in a k2nd time, not later than the nth time (in this report, the time is based on the time unit S3 different from that of message 2 or message 1). Specifically, for example, the time unit of message 2 is S2, the time unit of message 1 is Sl and the time unit of k2 is S3. In this case, a time for sending the new random access preamble is ceil ((n * S2 + k2 * S3) / S1), where k2 is a non-negative integer, for example, k2 = 0 to 40. For another example , S1 = 1 ms, S2 = 125 Use S3 = 0.5 ms, that is, the sending time of the new random access preamble is ceil ((n + 4 * k2) / 8).
[0387] [0387] In another mode, the time units of ki in Mode 1 to Mode 3 and k2 in Mode 4 to Mode 6 are, respectively, completely equal, and only the conditions under which the preamble of random access is sent again, are different. The time units of message 1 in Mode 1 to Mode 3 and message 1 in Mode 4 to Mode 6 are, respectively, completely equal, and only the conditions under which the preamble of random access is sent again, are different. The time units of message 2 in Mode 1 to Mode 3 and message 2 in Mode 4 to Mode 6 are, respectively, completely equal, and only the conditions under which the preamble of random access is sent again, are different.
[0388] [0388] In another modality, the values of k1 and k2 are related to at least one among a cause, an event and a type of service that trigger random access and a random access carrier frequency. For example, a type of service that triggers a random access preamble is a low-delay service, k1 = 2 and k2 = 2; otherwise, k1 = 5ek2 = 4.
[0389] [0389] In all previous modalities, ceil (xX / y) indicates rounding of a result obtained by dividing x by y to the nearest whole number. If x is an integer multiple of y, no ceiling operation may be necessary. In another modality, the ceiling function can be replaced by another function, for example, rounded or the floor that, respectively, corresponds to rounding and rounding down to the nearest whole number.
[0390] [0390] In all of the previous modalities 1 to 6, the measure of time and the unit of time have the same meaning, and can be a subframe, an interval, a mini-interval or an OFDM symbol. The interval, the mini-interval and the OFDM symbol, are a length of time corresponding to a subcarrier of a corresponding message (for example, a synchronization signal, a system message, the random access preamble, message 2, the message 3 or message 4). In another implementation, previous time measures (or time units) can be converted to each other, or converted to an absolute time (for example, one millisecond and one second), or converted to a combination of a plurality of measures of time (for example, 18 OFDM symbols can be converted into 1 interval and 4 OFDM symbols).
[0391] [0391] In another modality, message 2 includes information on indication of return value BI (return indicator). A timeout measure that is specified in the field and that is used by the UE to retransmit a random access preamble sequence is related to the format of the random access preamble, the length of the random access preamble, the carrier frequency of the preamble random access, the random access preamble band (a carrier frequency and a random access resource band corresponding to the random access preamble), a number of random access occasions (RACH, RO occasion) in an interval, an uplink data subcarrier spacing (or an uplink data subcarrier spacing index), an amount of downlink signals on a random access resource in an interval, an amount of access response messages random corresponding to an interval, a number of preambles of random access in an RO, a number of ROs associated with a link signal downlink, a total amount of random access preambles associated with a downlink signal, a number of downlink signals actually transmitted, a RO time length, a subcarrier spacing, a bandwidth, a frame structure, a type of service, a random access period resource (or a number of random access resources associated with a downlink signal in a set of downlink signals or a length of time occupied by the random access resources), a number of blocks of synchronization signals of a downlink signal, a number of downlink signals actually sent, a type of service, a carrier frequency, a frame structure, a band and a bandwidth. The subcarrier spacing can be a subcarrier spacing of an SS / PBCH, RMSI, msg1, msg2, msg3 and the like. A specific related way is similar to that in the previous modalities, and the details are not described in this report again.
[0392] [0392] Based on the description in the embodiment of FIG. 4, the network device determines different TAC formats and different TA accuracy based on different lengths of the random access preambles, to reduce the overhead of RAR signaling and improve the accuracy of TA on one EU side. The uplink and downlink switching time offsets of different numerologies are different, and different uplink and downlink switching time offsets are defined for different numerologies to improve application flexibility. Random access processes of different numerologies require different time units to improve the timing accuracy.
[0393] [0393] In a next generation communications system (for example, an NR communications system), the same TAG (timing advance group) can have a plurality of bandwidths having different shape parameters. wave. Bandwidths have different subcarrier and CP's spacing (cyclic prefix, cyclic prefix) and therefore have different requirements on transmission timing adjustments scale factors and transmission timing adjustment ranges. For example, the plurality of different subcarrier spacing and / or CPs in the same TAG can be subcarrier spacing and / or CPs of all channels / frequency bands configured semi-statically (semi-static) for the transmission of uplink data. Frequency channels / bands for uplink data transmission include: a portion of the initial access uplink bandwidth part, a supplementary uplink, SOUTH), a component carrier, a uplink bandwidth part, UL BWP, or an activated uplink bandwidth part
[0394] [0394] In a current solution, the transmission timing adjustment scale factor is a fixed value. For example, the scale factor is fixed as a scale factor corresponding to a minimum subcarrier spacing in the TAG. For another example, the scale factor is fixed as a scale factor corresponding to a maximum subcarrier spacing in the TAG. For another example, the scale factor is related to a carrier frequency. When the carrier frequency is greater than C: GHz and less than C2> GHz (for example, C1 = 0 GHz and Cr = 3 GHz, for another example, C1 = 0 GHz and C2 = 6 GHz, for another example, C1 = 0 GHz and Ca = 30 GHz, for another example, C1 = O GHz and C2 = 40 GHz, for another example, C1 = 3 GHz and Co = 6 GHz, for another example, C1 = 6 GHz and C2 = 30 GHz , for another example, C1 = 6 GHz and C2 = 40 GHz, for another example, C1 = 40 GHz and C2 = 100 GHz, and for another example, C1 = 100 GHz and C2 = GHz infinite), the scale factor is fixed as basic time units & = 16xXx2 "uy is an index corresponding to a 15x2º kHz subcarrier spacing, for example, u is equal to any integer from 0 to 7. For another example, when the carrier frequency is higher than GHz and less than 6 GHz, the scale factor is fixed as & = 16xx or a = 8XxKk qu a = 4XK, For another example, when the carrier frequency is greater than 6 GHz and less than 40 GHz, the factor scale is fixed as 2 = 4XxK or & = 2XK or & = 1XxK. For another example, when the carrier frequency is greater than 40 GHz and less than 100 GHz, the scale factor is fixed as & = 1xK or & = 0.5xKx qu a = 0.125xK
[0395] [0395] If the same scaling factor (or referred to as granularity) and the same transmission timing adjustment range are used in the same TAG, there is a problem with an excessively large scaling factor or a timing adjustment range of excessively small transmission. Therefore, a flexible scaling factor configuration solution is required.
[0396] [0396] This application provides a new random access method to solve the previous technical problem, and the method may additionally correspond to a proposed future 5G. An example is as follows:
[0397] [0397] The TAC format in MAC CE should be able to provide both the time setting range and granularity for a plurality of uplink bandwidth (UL BWP) parts, which possibly have different numerologies. In an example with two UL BWPs, the SCS of UL BWP1 is 60 kHz and the SCS of UL BWP 2 is 15 kHz. If the 60 kHz and 15 kHz share the same TAC format and the granularity of 60 kHz, the maximum time setting value for 15 kHz will be reduced by 1/4, ie reduced by + 5 km (+ 16.67 us ) for + 1.25 km (+ 4.17 us). In TS 25,104, the path changes will be up to 10 us, for example, the Route 1 changes from -5 us to 5 us (copy and paste in this report to facilitate the reference). If 1 bit in the 6-bit TA command is used to indicate the granularity of TA, the range can actually be + ((16.67 + 4.17)) 2 = + 10.42 us. Although slightly less than the LTE value, this can satisfy the following TS test requirement 25,104.
[0398] [0398] 1. Two routes, Route1 and Route are selected randomly from the group [-5, -4, -3, -2, -1, 0, 1, 2, 3, 4, 5] us. The paths have equal magnitudes and equal phases.
[0399] [0399] 2. After 191 ms, Route1 disappears and reappears immediately in a new location selected at random from the group [-5, 4, -3, -2, -1, 0, 1, 2, 3, 4 , 5) US but excludes the point from Way2. The magnitudes and phases of the derivation coefficients for Route 1 and Route 2 must remain unchanged.
[0400] [0400] 3. After an additional 191 ms, Route2 disappears and reappears immediately in a new location selected at random from the group [-5, 4, -3, -2, -1, 0, 1, 2, 3 , 4, 5] us, but excludes the point from Route1. The magnitudes and phases of the derivation coefficients for Route 1 and Route 2 must remain unchanged.
[0401] [0401] 4. The sequence in 2) and 3) is repeated.
[0402] [0402] In addition, for an NR cell with both normal and supplementary uplink carrier in the same TAG, the problem of sharing a fixed and common granularity will be deteriorated due to the greater difference between the subcarrier spacing. For example, the UL BWP SCS on the normal uplink is 120 kHz and the UL BWP SCS on the supplementary uplink is 15 kHz. If the 120 kHz and 15 kHz share the same TAC format and the granularity of 120 kHz, the maximum time setting value for 15 kHz will be reduced by 1/8, that is, reduced from +5 km to +0.625 km. If the 120 kHz and 15 kHz share the same TAC format and the granularity of 15 kHz, the minimum time setting value + 16 * x64 Ts, which is almost the same as the normal cyclic prefix of 120 kHz (18x64 Ts). Similarly, the performance of the uplink transmission system above normal UL will be degraded due to misaligned uplink timing.
[0403] [0403] To avoid insufficient or imprecise time adjustment, the timing granularity must be adaptable, as well as to satisfy the multiple numerologies. A bit in the 6-bit TA command should be used to indicate the granularity and timing of TA, for example, as shown in Figure 3. Note that if the maximum and minimum SCS is the same, that is, only one
[0404] [0404] Proposal 7: A bit in the 6-bit TAC indicates the granularity for a plurality of UL BWPs with different possible numerologies, where 0/1 means that the granularity follows the maximum / minimum SCS of all UL BWPs activated within the TAG . Specifically, the TA adjustment value is given by: Bit = O: granularity X follows the maximum SCS: Nranos = Nro TA 15) XX Bit = 1: granularity Y follows the minimum SCS: Ne fe + (TA4, -15 ) XY -16xX, TA, <16 and Naa FTA -15) XY + 16XxX, TA, 216
[0405] [0405] The table below shows the granularity of a TA command for different SCSs. Unit Spacing Nota serasa o et
[0406] [0406] FIG. 17 is a schematic flow chart of a data transmission method, according to an embodiment of the present invention. In this embodiment of the present invention, the method includes the following steps.
[0407] [0407] S1701: A network device determines an indication information value and a TAC value.
[0408] [0408] Specifically, the indication information is N1 bits, the TAC is N2 bits and NT and N2 are integers greater than or equal to 1. Different values of the indication information correspond to different scaling factors and time adjustment ranges transmission timing adjustment. N1 is any integer from 1 to 3, and N2 is any integer from 3 to 8. For example, N1 = 1 and N2 = 5. Optionally, N1 + N2 = 6.
[0409] [0409] For example, N1 = 1. When the value of the indication information is equal to O, a corresponding scale factor is% and the transmission time adjustment time adjustment range is indicated as: Nranor = Nraca Ta = 15) x06
[0410] [0410] When the value of the indication information is equal to 1, a corresponding scaling factor is%, and the time adjustment range of the transmission timing adjustment is indicated as: "e lara 6a, T, <16 Mo Bare FT, -15) xa + l16xa ,, T, 216
[0411] [0411] The time setting range of the transmission timing setting is shown in FIG. 18.
[0412] [0412] For another example, a correspondence between a subcarrier spacing and the scale factor is shown in the following table: e ow [e
[0413] [0413] For another example, G = O corresponds to the kHz scale factor and G = 1 corresponds to the 15 kHz scale factor, and% = 8xx, 0 = 16xKx For another example, G = O corresponds to the scale factor 60 kHz and G = 1 corresponds to the 15 kHz scale factor, and & 7 IX% a = l6xk for another example, G = O corresponds to the 120 kHz scale factor and G = 1 corresponds to the scale factor of 15 kHz, and% & = 2Xx *%. & 4 = 16xX for another example, G = O corresponds to the 240 kHz scale factor and G = 1 corresponds to the 15 kHz scale factor, and% FIx *, & 4 = 16x% For another example, G = O corresponds to the 480 kHz scale factor and G = 1 corresponds to the 15 kHz scale factor, and% 705xK, & = 16XxX for another example, G = O corresponds to the 960 kHz scale factor and G = 1 corresponds to the 15 kHz scale factor, and a = 025xK, 0 = 16XxX for another example, G = O corresponds to the 1920 kHz scale factor and G = 1 corresponds to the 15 kHz scale factor, and a = 0.125xx, a & = 16Xx% X for another example, G = O corresponds to the 60 kHz scale factor and G = 1 corresponds to the 30 kHz scale factor, and a = 4xK, 0, = 8X% X For another example, G = O corresponds to the 120 kHz scale factor and G = 1 corresponds to the 30 kHz scale factor, and a = 2xK, 0, = 8X% X For another example, G = O corresponds to the 240 kHz scale factor and G = 1 corresponds to the 30 kHz scale factor, and the xx, = 8x% X For another example, G = O corresponds to the 480 kHz scale factor and G = 1 corresponds to the 30 kHz scale factor, and a = 05xx, 0 = 8xKX For another example, G = O corresponds to the 960 kHz scale factor and G = 1 corresponds to the 30 kHz scale factor, and a = 025xKx, 04 = 8XK For another example, G = 0 corresponds to the 1920 kHz scale factor and G = 1 corresponds to the factor 30 kHz scale, and a = 0125xK, a = 8XxX for another example, G = O corresponds to the 120 kHz scale factor and G = 1 corresponds to the 60 kHz scale factor, and
[0414] [0414] In another possible implementation, N1 = 1. A TAG includes uplink bandwidth parts from a plurality of different subcarrier spacing. When the indication information G = 0, the indication information indicates the scale factor of a maximum subcarrier spacing in a TAG associated with a terminal device. When the indication information G = 1, the indication information indicates the scale factor of a minimum subcarrier spacing in the TAG associated with the terminal device. In all of the above modes, the scaling factors and time setting ranges corresponding to the G = O indication information and the G = 1 indication information can be exchanged. For example, the value of the O indication information indicates a relatively small time setting range and the scaling factor corresponding to the maximum subcarrier in the TAG associated with the terminal device; and the indication information value of 1 indicates a relatively large time setting range and the scaling factor corresponding to the minimum subcarrier in the TAG associated with the terminal device.
[0415] [0415] S1702: The network device sends a signaling message to the terminal device carrying the indication information and the TAC, and the terminal device receives the signaling message from the network device.
[0416] [0416] Specifically, the signaling message can be a MAC CE or DCl. Optionally, the signaling message additionally includes a TAG index of the timing advance group index, and the timing advance group is used to indicate a TAG index associated with the terminal device. For example, the signaling message is shown in FIG. 18.
[0417] [0417] S1703: The terminal device determines a transmission timing adjustment based on the TAC value and the scale factor corresponding to the value of the indication information.
[0418] [0418] Specifically, the terminal device determines the associated scaling factor based on the value of the indication information, determines the transmission timing adjustment based on the scaling factor and the TAC value, and sends an uplink signal with based on the determined transmission timing setting.
[0419] [0419] In a possible implementation, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to O, the value of the indication information is related to a minimum subcarrier spacing in the TAG associated with the terminal device.
[0420] [0420] In a possible implementation, Ni = 1, and when the value of the indication information is equal to O, the scale factor indicated by the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the indication information indicates the scale factor of a maximum subcarrier spacing in the TAG associated with the terminal device.
[0421] [0421] In a possible implementation, Ni = 1, and when the value of the indication information is equal to O, the scale factor indicated by the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 1, the indication information indicates the scale factor corresponding to the minimum subcarrier spacing in the TAG associated with the terminal device.
[0422] [0422] The fixed value is related to a carrier frequency. For example, when the carrier frequency is greater than O GHz and less than 6 GHz, a fixed scale factor is 16x% or 8xK, another scale factor is the scale factor corresponding to the maximum subcarrier spacing in the TAG associated with the device terminal; or another scale factor is a fixed value, for example, 8X% X or 4xK; or another scale factor is the scale factor corresponding to the minimum subcarrier spacing in the TAG associated with the terminal device. For another example, when the carrier frequency is greater than 6 GHz and less than 40 GHz, the fixed scale factor is 4xx or 2xK, another scale factor is the scale factor corresponding to the maximum subcarrier spacing in the TAG associated with the device terminal; or another scale factor is a fixed value, for example, 2xx or 1x% *; or another scale factor is the scale factor corresponding to the minimum subcarrier spacing in the TAG associated with the terminal device. When the carrier frequency is greater than 40 GHz and less than 100 GHz, the fixed scale factor is 1x or 0.5xK, another scale factor is the scale factor corresponding to the maximum subcarrier spacing in the TAG associated with the terminal device; or another scale factor is a fixed value, for example, 0.5XK or 0.25xK; or another scale factor is the scale factor corresponding to the minimum subcarrier spacing in the TAG associated with the terminal device.
[0423] [0423] In a possible implementation, Ni = 1, and when the value of the indication information is equal to O, the value of the indication information is a first pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the value of the indication information is a second pre-configured or pre-stored fixed value.
[0424] [0424] For example, the first fixed value is FINAL the second fixed value is 9% F16Xx * X2 * where% e “are different non-negative integers, for example, any two different integers from 0 to 7. The corresponding time setting ranges are respectively: Nranow = Nr1oa FT, -15) Xxa ,, and N a Nriou FT, -15) xa l6xa ,, T, <16, Mo | Naked FOT15) xa + 16x0 ,, T,> 216.
[0425] [0425] The first fixed value and the second fixed value are related to a carrier frequency range. For example, when the carrier frequency is greater than O GHz and less than 6 GHz, the first fixed value and the second fixed value are, respectively:% 7 4 * t E mM l6xK. o,% = 8XxK an = l6xx: 7 M = 4xK q ME $ XK For example, when the carrier frequency is greater than 6 GHz and less than 40 GHz, the first fixed value and the second fixed value are, respectively:% 7 1X * g Mm = 4XxK. 1, & 72XK & a = 4XxK, or% = lxx and “= 2xK
[0426] [0426] In another possible implementation, N1 = 2and N2 = 4.0 value of the indication information includes 00, 01, 10 and 11, and different values of the indication information correspond separately to different scaling factors and time adjustment ranges . Examples are as follows:
[0427] [0427] The indication information G = 00 correspond to the scale factor * º and correspond to the following time adjustment range: Nano = Nrs, 0a HT 7) X%
[0428] [0428] The indication information G = 01 correspond to the scale factor% 'and correspond to the following time adjustment range: when T, <8 Nramow = Nrao FT, 7) XA, -8x ,. and when T,> 8; Names = Nro FT, xa + 8x “%
[0429] [0429] The indication information G = 10 corresponds to the scale factor% 2 and correspond to the following time adjustment range: when T. <8, Nrisa = Nraaa Tax = 8x (A +). q when T: 28, Nena = Nr Ta = 7) Xx0 + BXx (AG FA).
[0430] [0430] The indication information G = 11 correspond to the scale factor * and correspond to the following time adjustment range: when T, <8 Nramow = Nro FT, T) xa, -8x (A, + A +); and when T.> 8 Nrtmes = FT Nro, 7) xA, + 8X (A + A HA)
[0431] [0431] In another possible implementation, in all the previous modalities in which the scale factor of the TAG is related to the carrier frequency, the carrier frequency bands of all uplink channels TAG channels are the same. For example, the carrier frequency range is greater than O GHz and less than 6 GHz. For another example, the carrier frequency range is greater than 6 GHz and less than 40 GHz. For another example, the carrier frequency range is carrier is greater than 40 GHz and less than 100 GHz.
[0432] [0432] In another possible implementation, a TAG has a total of different scale factors N. The TAC has possible N values, and a Tenth scale factor% º corresponds to the following time adjustment range: N. Nranos = Nraaa Ta 22 + DxA,
[0433] [0433] A time adjustment range corresponding to the nth scale factor * is: T, <M2 Ninth = Nro O, Pivxa MxSa, when 2, 2 2 =; and when 2, so
[0434] [0434] The parameters in the previous mode are described below:
[0435] [0435] In a possible implementation, the scale factor of the TAC can be additionally indicated by DCI.
[0436] [0436] In a possible implementation, the TAC scale factor and the TAG Index can be sent additionally by using another field of a MAC CE. For example, the TAC scale factor, the adjustment range, and / or The TAG Index are sent using an LCID field (logical channel identity, the logical channel index) in a MAC subheader, and / or they are indicated together by other fields in a MAC subheader. Specifically, the TAC scale factor can be indicated by using an LCID, and different LCID values indicate different scale factors, for example, the LCID values of 11, 12, 13 and 14 indicate, respectively, the scale factors : 16xK, 8XK 4xK, AND 2xK,
[0437] [0437] In this embodiment of the present invention, the terminal device determines the transmission timing adjustment based on the TAC and different scale factors indicated in the indication information carried in the signaling message, and can adjust the sending time based on different granularities and adapt to different scenarios.
[0438] [0438] FIG. 17 shows a method of transmitting data in an embodiment of the present invention in detail. Next, a data receiving apparatus 19 (apparatus 19 for low brevity) in an embodiment of the present invention is provided.
[0439] [0439] It should be noted that the apparatus 19 shown in FIG. 19 can implement one side of the terminal device in the embodiment shown in FIG. 17. Apparatus 19 includes a receiving unit 1901 and a determining unit 1902. Receiving unit 1901 is configured to receive a signaling message from a network device, where the signaling message includes indication information and a TAC timing advance command, the indication information is N1 bits, the TAC is N2 bits, different values of the indication information correspond to different scale factors and N1 and N2 are integers greater than or equal to 1.
[0440] [0440] The unit of determination 1902 is configured to determine a transmission timing adjustment based on a TAC value and a scale factor corresponding to a value of the indication information.
[0441] [0441] In a possible project, N1 = 1.20u3eN2 = 3,4,5,6,7 or
[0442] [0442] In a possible project, Ni = 1; and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a feed advance group. TAG timing associated with the terminal device; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0443] [0443] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0444] [0444] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the scale factor corresponding to the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0445] [0445] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 1, the scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0446] [0446] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0447] [0447] In a possible project, Nt = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a first pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a second pre-configured or pre-stored fixed value.
[0448] [0448] In a possible design, the signaling message includes a MAC CE or DCI and the signaling message additionally includes a TAG index of the timing advance group index.
[0449] [0449] Device 19 can be a terminal device, or device 19 can be an array of field-programmable gate array, FPGA, a dedicated integrated chip, a system on chip, SoC ), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit, or a microcontroller unit (micro controller unit, MCU) to perform a function or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0450] [0450] This embodiment of the present invention and the embodiment of the method in FIG. 17, are based on the same idea, and also have the same technical effects. For a specific process, see the description of the method in FIG. 17, and the details are not described in this report again.
[0451] [0451] It should be noted that a data sending device 20 (device 20 for brevity below) shown in FIG. 20 can implement one side of the network in the embodiment shown in FIG. 17. Device 20 includes a determination unit 2001 and a sending unit 2002. The determination unit 2001 is configured to determine a value of indication information and a value of a TAC, where indication information is N1 bits, the TAC is N2 bits, different values of the indication information correspond to different scale factors and N1 and N2 are integers greater than or equal to 1.
[0452] [0452] The sending unit 2002 is configured to send, to a terminal device, a signaling message bearing the indication information and the TAC.
[0453] [0453] In a possible project, N1 = 1.20u3eN2 = 3,4,5,6,7 or
[0454] [0454] In a possible project, Ni = 1; and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a feed advance group TAG timing associated with the terminal device; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0455] [0455] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the scale factor corresponding to the indication information value is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0456] [0456] In a possible project, Ni = 1, and when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the indication information value is equal to 0, the scale factor corresponding to the indication information value is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0457] [0457] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a maximum subcarrier spacing in a TAG associated with the terminal device.
[0458] [0458] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is related to a minimum subcarrier spacing in a TAG associated with the terminal device.
[0459] [0459] In a possible project, Ni = 1, and when the value of the indication information is equal to O, the scale factor corresponding to the value of the indication information is a first pre-configured or pre-stored fixed value; or when the value of the indication information is equal to 1, the scale factor corresponding to the value of the indication information is a second pre-configured or pre-stored fixed value.
[0460] [0460] In a possible design, the signaling message includes a MAC CE or DCI and the signaling message additionally includes a TAG index of the timing advance group index.
[0461] [0461] Device 20 can be a network device, or device can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a chip system (system on chip, SoC ), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit, or a microcontroller unit (micro controller unit, MCU) to perform a function or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0462] [0462] This embodiment of the present invention and the embodiment of the method in FIG. 17 are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 17, and the details are not described in this report again.
[0463] [0463] FIG. 2a shows a pagination method in one embodiment of the present invention in detail. Next, a paging apparatus 5 (apparatus 5 for brevity below) in an embodiment of the present invention is provided.
[0464] [0464] It should be noted that the apparatus 5 shown in FIG. 5 can implement one side of the network device in the embodiment shown in FIG. 2a. The apparatus 5 includes a receiving unit 501, a processing unit 502 and a sending unit 503. The receiving unit 501 is configured to receive a random access preamble from a terminal device, where the random access preamble is used to request a paging message. For example, receiving unit 501 performs S201. Processing unit 502 is configured to obtain a paging identifier associated with the random access preamble. For example, processing unit 502 performs S203. Sending unit 503 is configured to send a paging message to the terminal device based on the paging identifier. For example, sending unit 503 performs S204.
[0465] [0465] Device 5 can be a network device, or device 5 can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a chip system (system on chip, SoC), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit, or a microcontroller unit (micro controller unit, MCU) to perform a related function, or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0466] [0466] This embodiment of the present invention and the embodiment of the method in FIG. 2a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 2a, and the details are not described in this report again.
[0467] [0467] It should be noted that a paging apparatus 6 (apparatus 6 for brevity below) shown in FIG. 6 can implement the end device side in the embodiment shown in FIG. 2a. The apparatus 6 includes: a sending unit 601, a processing unit 602 and a receiving unit 603. The sending unit 601 is configured to send a random access preamble to a network device, where the random access preamble is used to request a paging message corresponding to a group of paging users on the device. For example, the sending unit 601 performs S201. Processing unit 602 is configured to obtain a paging identifier associated with the random access preamble. For example, processing unit 602 performs
[0468] [0468] Device 6 can be a network device, or device 6 can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a chip system (system on chip, SoC), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit, or a microcontroller unit (micro controller unit, MCU) to perform a related function, or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0469] [0469] This embodiment of the present invention and the embodiment of the method in FIG. 2a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 2a, and the details are not described in this report again.
[0470] [0470] As shown in FIG. 7, an embodiment of the present invention additionally provides a paging apparatus 7 (apparatus 7 for brevity below).
[0471] [0471] In a possible design, device 7 is a network device, and the network device includes:
[0472] [0472] Receiver 703, transmitter 704, memory 702 and processor 701 communicate with each other via an internal connection path, for example, they are connected via a bus.
[0473] [0473] In a possible design, device 7 can be a chip, for example, it can be a communications chip on the network device, and it is configured to perform a related function of processor 701 on the network device. The chip can be an array of field programmable ports, an application-specific integrated chip, a system chip, a central processing unit, a network processor, a digital signal processing circuit, or a microcontroller to perform a function related, or it can be a programmable controller or other integrated chip. The chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0474] [0474] All or some of the chips can be implemented by software, hardware, firmware or any combination of them. When a software program is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions (sometimes also referred to as code or a program). When program instructions from the computer are loaded and executed on the computer, the procedure or functions, according to the modalities of this order, are all or partially generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instructions can be stored on a computer-readable storage medium or can be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example, infrared, radio or microwave). Computer-readable storage media can be any usable media accessible by a computer or a data storage device, such as a server or a data center, integrating one or more usable media. Usable media can be a magnetic media (for example, a floppy disk, a hard disk or a magnetic tape), an optical media (for example, a DVD), a semiconductor media (for example, a solid-state drive (solid- state drive, SSD)) or the like.
[0475] [0475] This embodiment of the present invention and the embodiment of the method in FIG. 2a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 2a, and the details are not described in this report again.
[0476] [0476] As shown in FIG. 8, an embodiment of the present invention additionally provides a paging apparatus 8 (apparatus 8 for brevity below).
[0477] [0477] In a possible design, device 8 is a terminal device. The terminal device includes: a processor 801, an 802 memory, a receiver 803 and a transmitter 804.
[0478] [0478] 802 memory is configured to store a program and data, where it can be one or more memories, the memory can be any form of storage media, for example, the memory can be a random access memory (English: random access memory, RAM for abbreviation), a read-only memory (English: read only memory, ROM for abbreviation), or a flash, and 802 memory can be located separately on the terminal device or it can be located on the processor
[0479] [0479] Transmitter 804 is configured to transmit a signal, where transmitter 804 can be a separate chip or it can be a transmitter circuit or an output interface on processor 801, optionally, transmitter 804 can additionally include a transmitting antenna, the transmitting antenna included in transmitter 804 and a receiving antenna included in receiver 803 can be two separately arranged antennas or they can be an antenna, and transmitter 804 is configured to send a random access preamble to a network device, where the random access preamble is used to request a paging message corresponding to a group of paging users of the device, for example, transmitter 804 performs S201.
[0480] [0480] Processor 801 is configured to execute the program code stored by the 802 memory, where when the program code is executed, processor 801 is configured to obtain a paging identifier associated with the preamble of random access, for example, the 801 processor performs S202.
[0481] [0481] Receiver 803 is configured to receive a signal, where receiver 803 can be a separate chip or it can be a receiver circuit or an input interface on processor 801, optionally, receiver 803 can additionally include a receiving antenna , and receiver 803 is configured to receive a paging message from the network device based on the paging identifier, for example, receiver 803 performs S204.
[0482] [0482] Receiver 803, transmitter 804, memory 802 and processor 801 communicate with each other via an internal connection path, for example, they are connected via a bus.
[0483] [0483] In a possible design, device 8 can be a chip, for example, it can be a communications chip on the terminal device, and it is configured to perform a related function of processor 801 on the terminal device. The chip can be an array of field programmable ports, an application-specific integrated chip, a system chip, a central processing unit, a network processor, a digital signal processing circuit, or a microcontroller to perform a related function , or it can be a programmable controller or other integrated chip. The chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0484] [0484] All or some of the chips can be implemented by software, hardware, firmware or any combination of them. When a software program is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions (sometimes also referred to as code or a program). When program instructions from the computer are loaded and executed on the computer, the procedure or functions, according to the modalities of this order, are all or partially generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instructions can be stored on a computer-readable storage medium or they can be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example, infrared, radio or microwave). Computer-readable storage media can be any usable media accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media. Usable media can be a magnetic media (for example, a floppy disk, a hard drive or a magnetic tape), an optical media (for example, a DVD), a semiconductor media (for example, a solid-state drive (solid- state drive, SSD)) or the like.
[0485] [0485] This embodiment of the present invention and the embodiment of the method in FIG. 2a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 2a, and the details are not described in this report again.
[0486] [0486] FIG. 3a shows a pagination method in one embodiment of the present invention in detail. Next, a paging apparatus 9 (apparatus 9 for brevity below) in an embodiment of the present invention is provided.
[0487] [0487] It should be noted that the apparatus 9 shown in FIG. 9 can implement one side of the network device in the embodiment shown in FIG. 3a. Apparatus 9 includes a receiving unit 901 and a sending unit
[0488] [0488] Device 9 can be a network device, or device 9 can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a system on chip, SoC), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit, or a microcontroller unit (micro controller unit, MCU) to perform a related function, or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0489] [0489] This embodiment of the present invention and the embodiment of the method in FIG. 3a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 3a, and the details are not described in this report again.
[0490] [0490] It should be noted that a paging apparatus 10 (apparatus 10 for brevity below) shown in FIG. 10 can implement one side of the terminal device in the embodiment shown in FIG. 3a. The apparatus 10 includes: a sending unit 1001 and a receiving unit 1002. The sending unit 1001 is configured to send a random access preamble to a network device, where the random access preamble is associated with a group of users paging device of the terminal device, for example, performs S301. Receiving unit 1002 is configured to receive a random access response from the network device, where the random access response carries paging scheduling information and / or a paging identifier associated with the preamble of random access, the paging information. Paging programming includes at least one of the frequency information, an encoding and modulation scheme, a reference signal, subcarrier spacing information and DCI, for example, performs S302. Receiving unit 1002 is additionally configured to receive a paging message from the network device based on the paging programming information, for example, it performs S303.
[0491] [0491] Device 10 can be a terminal device, or device can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a chip system (system on chip, SoC) , a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit, or a microcontroller unit (micro controller unit, MCU) to perform a related function , or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0492] [0492] This embodiment of the present invention and the embodiment of the method in FIG. 3a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 3a, and the details are not described in this report again.
[0493] [0493] As shown in FIG. 11, an embodiment of the present invention additionally provides a paging apparatus 11 (apparatus 11 for brevity below).
[0494] [0494] In a possible project, the device 11 is a network device, and the network device includes: a memory 1102, configured to store a program and data, where it can be one or more memories, the memory can be any form of storage media, for example, the memory can be a random access memory (English: random access memory, RAM for short), a read-only memory (English: read only memory, ROM for short), or a flash, and memory 1102 may be located separately on the network device or may be located on a processor 1101; a receiver 1103, configured to receive a signal, where receiver 1103 can be a separate chip or it can be a receiver circuit or input interface on processor 1101, optionally, receiver 1103 can additionally include a receiving antenna, and the receiver 1103 is configured to receive a random access preamble from a terminal device, where the random access preamble is associated with a group of paging users of the terminal device, and the random access preamble is used to request a message. pagination, for example, performs S301; processor 1101, configured to execute an instruction corresponding to the program code stored by memory 1102; and a transmitter 1104, configured to transmit a signal, where transmitter 1104 can be a separate chip or it can be a transmitter circuit or an output interface on processor 1101, optionally, transmitter 1104 can additionally include a transmitting antenna, the antenna transmitter included in transmitter 1104 and the receiving antenna included in receiver 1103 can be two separately arranged antennas or can be an antenna, transmitter 1104 is configured to send a measured media signal quality value to a data server on a uplink port, a media signal quality value measured on a uplink port, a network device identifier, and a port type corresponding to each media signal quality value. For example, transmitter 1104 is configured to send a random access response to the terminal device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, programming information. Paging features include at least one of the frequency information, time information, an encoding and modulation scheme, a reference signal, sub carrier spacing, and downlink control information, DCI, for example, performs
[0495] [0495] Transmitter 1104 is additionally configured to send a paging message to the terminal device based on the paging programming information, for example, performs S303.
[0496] [0496] Receiver 1103, transmitter 1104, memory 1102 and processor 1101 communicate with each other via an internal connection path, for example, they are connected via a bus.
[0497] [0497] In a possible design, device 11 may be a chip, for example, it may be a communications chip on the network device, and it is configured to perform a related function of processor 1101 on the network device. The chip can be an array of field programmable ports, an application-specific integrated chip, a system chip, a central processing unit, a network processor, a digital signal processing circuit, or a microcontroller to perform a related function , or it can be a programmable controller or other integrated chip. The chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0498] [0498] All or some of the chips can be implemented by software, hardware, firmware or any combination of them. When a software program is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions (sometimes also referred to as code or a program). When program instructions from the computer are loaded and executed on the computer, the procedure or functions, according to the modalities of this order, are all or partially generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instructions can be stored on a computer-readable storage medium or they can be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example,
[0499] [0499] This embodiment of the present invention and the embodiment of the method in FIG. 3a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 3a, and the details are not described in this report again.
[0500] [0500] As shown in FIG. 12, an embodiment of the present invention additionally provides a paging apparatus 12 (apparatus 12 for brevity below).
[0501] [0501] In a possible design, device 12 is a terminal device. The terminal device includes: a processor 1201, a memory 1202, a receiver 1203 and a transmitter 1204.
[0502] [0502] Memory 1202 is configured to store a program and data, where it can be one or more memories, the memory can be any form of storage media, for example, the memory can be a random access memory (English: random access memory, RAM for abbreviation), a read-only memory (English: read only memory, ROM for abbreviation), or a flash, and memory 1202 can be located separately on the terminal device or it can be located on the processor
[0503] [0503] Processor 1201 is configured to execute the program code stored in memory 1202.
[0504] [0504] Transmitter 1204 is configured to transmit a signal, where transmitter 1204 can be a separate chip or it can be a transmitter circuit or an output interface on processor 1201, optionally, transmitter 1204 can additionally include a transmission antenna the transmitting antenna included in transmitter 1204 and a receiving antenna included in receiver 1203 can be two separately arranged antennas or can be an antenna, and transmitter 1204 is configured to send a random access preamble to a network device, where the random access preamble is associated with a group of paging users of the terminal device, for example, performs S301.
[0505] [0505] The 1203 receiver is configured to receive a signal. Receiver 1203 can be a separate chip, or it can be a receiver circuit or an input interface to processor 1201. Optionally, receiver 1203 can additionally include a receiving antenna. The receiver 1203 is configured to receive a random access response from the network device, where the random access response carries paging programming information and / or a paging identifier associated with the random access preamble, programming information. pagination includes at least one of the frequency information, an encoding and modulation scheme, a reference signal, subcarrier spacing information and DCI, for example, performs S302.
[0506] [0506] Receiver 1203 is additionally configured to receive a paging message from the network device based on the paging programming information, for example, performs S303.
[0507] [0507] Receiver 1203, transmitter 1204, memory 1202 and processor 1201 communicate with each other via an internal connection path, for example, they are connected via a bus.
[0508] [0508] In a possible design, device 12 may be a chip, for example, it may be a communications chip on the terminal device and is configured to perform a related function of processor 1201 on the terminal device. The chip can be an array of field programmable ports, an application-specific integrated chip, a system chip, a central processing unit, a network processor, a digital signal processing circuit, or a microcontroller to perform a related function , or it can be a programmable controller or other integrated chip. The chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0509] [0509] All or some of the chips can be implemented by software, hardware, firmware or any combination of them. When a software program is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions (sometimes also referred to as code or a program). When program instructions from the computer are loaded and executed on the computer, the procedure or functions, according to the modalities of this order, are all or partially generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instructions can be stored on a computer-readable storage medium or they can be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example, infrared, radio or microwave). Computer-readable storage media can be any usable media accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media. Usable media can be a magnetic media (for example, a floppy disk, a hard drive or a magnetic tape), an optical media (for example, a DVD), a semiconductor media (for example, a solid-state drive (solid- state drive, SSD)) or the like.
[0510] [0510] This embodiment of the present invention and the embodiment of the method in FIG. 3a are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 3a, and the details are not described in this report again.
[0511] [0511] FIG. 4 shows a communication timing method in an embodiment of the present invention in detail. Next, a communication timing apparatus 13 (apparatus 13 for brevity below) is provided in an embodiment of the present invention.
[0512] [0512] It should be noted that the apparatus 13 shown in FIG. 13 can implement one side of the network device shown in FIG. 4. Apparatus 13 includes a receiving unit 1301, a processing unit 1302 and a sending unit 1303. Receiving unit 1301 is configured to receive a random access preamble from a terminal device, for example, performs S401 . The processing unit 1302 is configured to determine a format of a TAC and / or a scale factor of a timing advance based on a format of the random access preamble, for example, realizes S402. The sending unit 1303 is configured to send, to the terminal device, a random access response carrying the TAC and / or the scale factor, for example, performs S403.
[0513] [0513] Device 13 can be a network device, or device 13 can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a chip system (system on chip, SoC), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit or a microcontroller unit (micro controller unit, MCU) to perform a function or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0514] [0514] This embodiment of the present invention and the embodiment of the method in FIG. 4 are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 4, and the details are not described in this report again.
[0515] [0515] It should be noted that a communication timing device 14 (device 14 for brevity below) shown in FIG. 14 can implement one side of the terminal device in the embodiment shown in FIG. 4. Apparatus 14 includes: a receiving unit 1401, a processing unit 1402 and a sending unit 1403. Receiving unit 1401 is configured to receive a TAC time advance command from a network device, for example. example, performs S403. Processing unit 1402 is configured to obtain a scale factor and determine a timing advance and / or to determine a timing advance offset based on at least one of the TAC from the network device, the scale factor obtained , a basic unit of time currently used, a number of sampling points currently used, a carrier frequency currently used, a current service type, a currently used subcarrier spacing, a currently used subcarrier index, a maximum subcarrier spacing , a maximum number of sampling points and a displacement factor currently used, for example, performs S404. Sending unit 1403 is configured to send uplink data based on the timing advance and timing advance offset, for example, it performs S405.
[0516] [0516] Device 14 can be a terminal device, or device 14 can be an array of field-programmable gate array (FPGA), a dedicated integrated chip, a chip system (system on chip, SoC ), a central processing unit (CPU), a network processor (network processor, NP), a digital signal processing circuit or a microcontroller unit (micro controller unit, MCU) to perform a related function , or it can be a programmable controller (programmable logic device, PLD) or another integrated chip.
[0517] [0517] This embodiment of the present invention and the embodiment of the method in FIG. 4 are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 4, and the details are not described in this report again.
[0518] [0518] As shown in FIG. 15, an embodiment of the present invention additionally provides a communication timing apparatus (apparatus 15 for brevity below).
[0519] [0519] In a possible project, the device 15 is a network device, and the network device includes: a memory 1502, configured to store a program and data, where it can be one or more memories, the memory can be any form for storage media, for example, the memory can be a random access memory (English: random access memory, RAM for short), a read-only memory (English: read only memory, ROM for short), or a flash, and memory 1502 may be located separately on the network device or may be located on a processor 1501; a receiver 1503, configured to receive a signal, where receiver 1503 can be a separate chip or it can be a receiver circuit or an input interface on processor 1501, optionally, receiver 1503 can additionally include a receiving antenna, and the receiver 1503 is configured to receive a random access preamble from a terminal device, for example, performs S401; processor 1501, configured to execute program code stored by memory 1502, where when program code is executed, processor 1501 is configured to determine a TAC format and / or a scale factor of a time advance with based on a random access preamble format, for example, performs S402; and a transmitter 1504, configured to transmit a signal, where transmitter 1504 can be a separate chip or it can be a transmitter circuit or an output interface on processor 1501, optionally, transmitter 1504 can additionally include a transmitting antenna, the antenna transmitter included in transmitter 1504 and the receiving antenna included in receiver 1503 can be two separately arranged antennas or can be an antenna, and transmitter 1504 is configured to send a random access response to the terminal device carrying the TAC and / or the scale factor, for example, realizes S403.
[0520] [0520] Receiver 1503, transmitter 1504, memory 1502 and processor 1501 communicate with each other via an internal connection path, for example, they are connected via a bus.
[0521] [0521] In a possible design, device 15 can be a chip, for example, it can be a communications chip on the network device, and it is configured to perform a related function of processor 1501 on the network device. The chip can be an array of field programmable ports, an application-specific integrated chip, a system chip, a central processing unit, a network processor, a digital signal processing circuit, or a microcontroller to perform a related function , or it can be a programmable controller or other integrated chip. The chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0522] [0522] All or some of the chips can be implemented by software, hardware, firmware or any combination of them. When a software program is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions (sometimes also referred to as code or a program). When program instructions from the computer are loaded and executed on the computer, the procedure or functions, according to the modalities of this order, are all or partially generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instructions can be stored on a computer-readable storage medium or can be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example, infrared, radio or microwave). Computer-readable storage media can be any usable media accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media. Usable media can be a magnetic media (for example, a floppy disk, a hard disk or a magnetic tape), an optical media (for example, a DVD), a semiconductor media (for example, a solid-state drive (solid- state drive, SSD)) or the like.
[0523] [0523] This embodiment of the present invention and the embodiment of the method in FIG. 4 are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 4, and the details are not described in this report again.
[0524] [0524] As shown in FIG. 16, an embodiment of the present invention additionally provides a communication timing apparatus 16 (apparatus 16 for brevity below).
[0525] [0525] In a possible design, device 16 is a terminal device. The terminal device includes: a processor 1601, a memory 1602, a receiver 1603 and a transmitter 1604.
[0526] [0526] Memory 1602 is configured to store a program and data, where it can be one or more memories, the memory can be any form of storage media, for example, the memory can be a random access memory (English: random access memory, RAM for abbreviation), a read-only memory (English: read only memory, ROM for abbreviation), or a flash, and memory 1602 can be located separately on the terminal device or it can be located on the processor
[0527] [0527] Receiver 1603 is configured to receive a signal, where receiver 1603 can be a separate chip or it can be a receiver circuit or an input interface on processor 1601. Optionally, receiver 1603 can additionally include a receiving antenna , and receiver 1603 is configured to receive a TAC timing advance command from a network device, for example, performs S403.
[0528] [0528] Processor 1601 is configured to execute program code stored in memory 1602. When program code is executed, processor 1601 is configured to obtain a scale factor and determine a timing advance and / or determine an offset timing advance based on at least one of the TAC from the network device, the scale factor obtained, a basic unit of time currently used, a number of sampling points currently used, a carrier frequency currently used, a current service type, a currently used subcarrier spacing, a currently used subcarrier index, a maximum subcarrier spacing, a maximum number of sampling points, and a currently used displacement factor, for example, performs S404.
[0529] [0529] Transmitter 1604 is configured to transmit a signal, where transmitter 1604 can be a separate chip or it can be a transmitter circuit or an output interface on processor 1601. Optionally, transmitter 1604 can additionally include a transmitting antenna, the transmitting antenna included in transmitter 1604 and the receiving antenna included in receiver 1603 can be two separately arranged antennas or can be an antenna, and transmitter 1604 is configured to send uplink data based on timing advance and offset timing advance, for example, performs S405.
[0530] [0530] Receiver 1603, transmitter 1604, memory 1602 and processor 1601 communicate with each other via an internal connection path, for example, they are connected via a bus.
[0531] [0531] In a possible design, device 16 can be a chip, for example, it can be a communications chip on the terminal device, and it is configured to perform a related function of processor 1601 on the terminal device. The chip can be an array of field programmable ports, an application-specific integrated chip, a system chip, a central processing unit, a network processor, a digital signal processing circuit, or a microcontroller to perform a related function , or it can be a programmable controller or other integrated chip. The chip can optionally include one or more memories, configured to store the program code. When the program code is executed, the processor is enabled to perform a corresponding function.
[0532] [0532] All or some of the chips can be implemented by software, hardware, firmware or any combination of them. When a software program is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions (sometimes also referred to as code or a program). When program instructions from the computer are loaded and executed on the computer, the procedure or functions, according to the modalities of this order, are all or partially generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instructions can be stored on a computer-readable storage medium or they can be transmitted from a computer-readable storage medium to another computer-readable storage medium. For example, computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a digital subscriber line (digital subscriber line, DSL)) or wireless (for example, infrared, radio or microwave). Computer-readable storage media can be any usable media accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media. Usable media can be a magnetic media (for example, a floppy disk, a hard drive or a magnetic tape), an optical media (for example, a DVD), a semiconductor media (for example, a solid-state drive (solid- state drive, SSD)) or the like.
[0533] [0533] This embodiment of the present invention and the embodiment of the method in FIG. 4 are based on the same idea and also have the same technical effects. For a specific process, see the description of the method in FIG. 4, and the details are not described in this report again.
[0534] [0534] It should be noted that the sending unit or the transmitter performs the sending steps in the previous method, the receiving unit or the receiver performs the receiving steps in the previous method, and other steps are performed by the unit processing or processor. The sending unit and the receiving unit can form a transceiver unit, and the receiver and transmitter can form a transceiver.
[0535] [0535] A person skilled in the art may be aware that, in combination with the examples described in the modalities disclosed in this specification, algorithm units and steps can be implemented by electronic hardware or a combination of computer software and electronic hardware. Whether the functions are performed by hardware or software depends on the particular applications and restrictive conditions of the design of the technical solutions. A person skilled in the art can use different methods to implement the functions described for each particular application, but implementation should not be considered to be beyond the scope of this request.
[0536] [0536] It can be clearly understood by a technician on the subject that, for the purpose of convenient and brief description, for a detailed work process of the previous system, device and unit, consult a corresponding process in the modalities of the previous method, and the details are not described in this report again.
[0537] [0537] In the various modalities provided in this application, it should be understood that the system, apparatus and method can be implemented in other ways. For example, the mode of the apparatus described is merely an example. For example, the unit division is merely a logical function division and can be another division in the actual implementation. For example, a plurality of units or components can be combined or integrated into another system, or some standards can be ignored or not realized. In addition, the mutual couplings displayed or discussed, or direct couplings or communication connections can be implemented using some interfaces. Indirect couplings or communication connections between devices or units can be implemented in electronic, mechanical or other forms.
[0538] [0538] The units described as separate parts may or may not be physically separate, and the parts displayed as units may or may not be physical units, may be located in one position, or may be distributed across a plurality of network units. Some or all of the units can be selected based on the actual requirements to achieve the objectives of the modalities solutions.
[0539] [0539] In addition, the functional units in the modalities of this order can be integrated into a processing unit, or each of the units can exist physically alone, or two or more units are integrated into one unit.
[0540] [0540] All or some of the previous modalities can be implemented by software, hardware, firmware or any combination thereof. When software is used to implement the modalities, the modalities can be implemented completely or partially in a form of a computer program product. The computer program product includes one or more computer instructions. When program instructions from the computer are loaded and executed on the computer, the procedure or functions according to the modalities of the present invention are all or partly generated. The computer can be a general purpose computer, a dedicated computer, a computer network or other programmable devices. Computer instruction can be stored on computer-readable storage media, or it can be transmitted using computer-readable storage media. Computer instructions can be transmitted from one website, computer, server or data center to another website, computer, server or data center in a wired manner (for example, a coaxial cable, an optical fiber or a line digital subscriber (DSL)) or wireless (for example, infrared, radio or microwave). Computer-readable storage media can be any usable media accessible by a computer, or a data storage device, such as a server or a data center, integrating one or more usable media. Usable media can be a magnetic media (for example, a floppy disk, a hard drive or a magnetic tape), an optical media (for example, DVD), a semiconductor media (for example, a Solid-state drive (SSD)) or the like.
[0541] [0541] A person skilled in the art can understand that all or some of the method methods in the modalities can be implemented by a computer program instructing the relevant hardware. The program can be stored on a computer-readable storage medium. When the program is executed, the method processes in the modalities are carried out. The previous storage media includes: any media that can store the program code, such as a ROM, a RAM random access memory, a magnetic disk or an optical disk.

权利要求:
Claims (16)
[1]
1. Communication method, CHARACTERIZED by the fact that it comprises: sending a preamble of random access to a network device; receiving a random access response from the network device, the random access response corresponds to the random access preamble; and; send a message 3 to the network device; wherein: a time for sending message 3 is related to a last receiving time n of the random access response, a delay kl, and a configured delay k2.
[2]
2. Method, according to claim 1, CHARACTERIZED by the fact that, the delay k2 is configured by the use of the random access response; or the delay is configured by the use of the random access response and radio access control (RRC) signaling.
[3]
3. Method according to claim 1, CHARACTERIZED by the fact that the delay k2 is related to a subcarrier spacing of message 3.
[4]
4, Method, according to claim 1, CHARACTERIZED by the fact that the delay k1 is related to a subcarrier spacing of the message 3.
[5]
5. Method, according to claim 1, CHARACTERIZED by the fact that a time interval in which a message sending time 3 is located satisfies: floor ((n * S2) / S3) + (kK1 + k2) S2 is a unit of time determined based on the subcarrier spacing of message 2, and S3 is a unit of time determined based on the subcarrier spacing of message 3.
[6]
6. Method, according to claim 5, CHARACTERIZED by the fact that the unit of time is an interval.
[7]
7. Method, according to claim 1, CHARACTERIZED by the fact that the random access response comprises an uplink programming concession (UL grant), and message 3 is uplink data sent based on the programming concession uplink link.
[8]
8. Communication method, CHARACTERIZED by the fact that it comprises: receiving a preamble of random access from a terminal device; sending a random access response to the terminal device, the random access response corresponds to the random access preamble; and; receiving a message 3 from the terminal device; where: a message sending time 3 is related to a last receiving time n of the random access response, a delay kl, and a configured delay k2.
[9]
9. Method, according to claim 8, CHARACTERIZED by the fact that, the delay k2 is configured by the use of the random access response; or the delay is configured by the use of the random access response and radio access control (RRC) signaling.
[10]
10. Method according to claim 8, CHARACTERIZED by the fact that the delay k2 is related to a subcarrier spacing of message 3.
[11]
11. Method, according to claim 8, CHARACTERIZED by the fact that delay k1 is related to a subcarrier spacing of message 3.
[12]
12. Method, according to claim 8, CHARACTERIZED by the fact that a time interval in which a message sending time 3 is located satisfies: floor ((n * S2) / S3) + (k1 + k2) S2 is a unit of time determined based on the subcarrier spacing of message 2, and S3 is a unit of time determined based on the subcarrier spacing of message 3.
[13]
13. Method according to claim 12, CHARACTERIZED by the fact that the unit of time is an interval.
[14]
14. Method according to claim 8, CHARACTERIZED by the fact that the random access response comprises an uplink programming concession (UL grant), and message 3 is uplink data sent based on the programming concession uplink link.
[15]
15. Communication device, CHARACTERIZED by the fact that it comprises: a transmitter, configured to send a preamble of random access to a network device; a receiver, configured to receive a random access response from the network device, the random access response corresponds to the random access preamble; and; the transmitter is additionally configured to send a message 3 to the network device; wherein: a time for sending message 3 is related to a last receiving time n of the random access response, a delay kl, and a configured delay k2.
[16]
16. Communication device, CHARACTERIZED by the fact that it comprises: a receiver, configured to receive a preamble of random access from a terminal device; a transmitter, configured to send a random access response to the terminal device, the random access response corresponds to the random access preamble; and; the receiver is further configured to receive a message 3 from the terminal device; wherein: a time for sending message 3 is related to a last receiving time n of the random access response, a delay kl, and a configured delay k2.

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