method, apparatus, communication system, computer program storage media, system chip, and computer p

专利摘要:
modalities of this application provide a communication method, a terminal device, and a network device. the method includes: determining, by a terminal device, at least one target way of an air interface technology; and communicating, via the terminal device, with a network device using at least one target way of air interface technology. therefore, according to the method provided in the modalities of that application, a target way that is of an air interface technology and that is used during current communication can be determined from a plurality of optional ways of the air interface technology.
公开号:BR112019013825A2
申请号:R112019013825
申请日:2017-12-27
公开日:2020-01-28
发明作者:Zeng Qinghai；Wang Tingting；Guo Yi
申请人:Huawei Tech Co Ltd；
IPC主号:

专利说明:

“METHOD, APPARATUS, COMMUNICATION SYSTEM, COMPUTER PROGRAM STORAGE MEDIA, SYSTEM CHIP, AND COMPUTER PROGRAM PRODUCT” [001] This application claims priority to Chinese Patent Application No. 201710005557.8 filed with the Chinese Patent Office on January 4, 2017 and entitled “COMMUNICATION METHOD, TERMINAL DEVICE, AND NETWORK DEVICE”, which is fully incorporated in this report as a reference.
TECHNICAL FIELD [002] Modalities of this request refer to the field of communications and, more specifically, to a method of communication, a terminal device and a network device.
FUNDAMENTALS [003] In long term evolution technologies (Long Term Evolution, LTE), several aerial interface technologies (aerial interface technologies, such as a random access mode, an uplink waveform, a multiple mode uplink access, a modulation scheme and a duplexing mode) use one or more specified modes. It is defined in a communications protocol that, for an air interface technology, a particular mode is always used or a particular mode is used under a specified condition.
[004] In an existing LTE system, due to the fact that most air interface technologies use only a fixed mode, for example, a transmission time interval (transmission time interval, TTI duration) has only one mode 1 ms, when a terminal device initially accesses a network device, the terminal device accesses the system in a mode defined in the protocol. However, in a 5G system, each air interface technology can use a plurality of optional modes and the possible modes can, respectively, present conditions of use.
[005] Therefore, a technical means is urgently needed to select, from a plurality of optional modes of air interface technology based on a real situation, a mode that is of air interface technology and that is used during communication between a terminal device and a network device.
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SUMMARY [006] The modalities of this application provide a method of communication to determine, from a plurality of optional modes of an air interface technology, a target mode of the air interface technology used during actual communication.
[007] According to a first aspect, a method of communication is provided, including: determining, by a terminal device, at least one target mode of an air interface technology; and communicating, via the terminal device, with the network device using at least one target mode of air interface technology.
[008] Therefore, according to the method provided in this modality of this application, a target mode that is of an air interface technology and that is used during the real communication can be determined from a plurality of optional modes of the interface technology aerial.
[009] With reference to the first aspect, in a first possible implementation of the first aspect, the determination, by a terminal device, of at least one target mode of an air interface technology includes: receiving, by the terminal device, a notification message sent by the network device, where the notification message carries at least one target mode of the air interface technology and at least one target mode of the air interface technology is determined by the network device from at least one optional mode of the air technology. air interface.
[010] Therefore, the terminal device can determine, from a plurality of optional modes of the air interface technology based on the notification message sent by the network device, the target mode which is of the air interface technology and which is used during real communication, and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[011] With reference to the first aspect and the preceding implementation of the first aspect, in a possible second implementation of the first aspect, the notification message is system information sent by the network device and communication with the network device through use of at least one target mode of air interface technology includes:
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3/36 initially and randomly accessing the network device using at least one target mode of air interface technology.
[012] Therefore, the terminal device can determine, from a plurality of optional modes of the air interface technology based on the notification message sent by the network device, a target mode which is of the air interface technology and which is used during initial random access to a system, and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[013] With reference to the first aspect and the previous implementation of the first aspect, in a possible third implementation of the first aspect, the notification message is message 2 of the initial random access and the communication with the network device through the use of at least one target mode of the air interface technology includes: sending the message 3 from the initial random access to the network device using at least one target mode of the air interface technology.
[014] Therefore, the terminal device can determine, from the plurality of optional modes of the interface technology based on the message 2 sent by the network device, the target mode that is of the air interface technology and that is used by the message 3 initial random access. The terminal device can determine a target mode that will be used by the air interface technology based on an indication of the network device, to better adapt to a real network state.
[015] With reference to the first aspect and the preceding implementation of the first aspect, in a fourth possible implementation of the first aspect, the initial random access message 2 carries at least one target mode of the air interface technology, at least one target mode of the air interface technology includes a target mode of an uplink waveform and sending message 3 from initial random access to the network device using at least one target mode of air interface technology includes: determining a content value of the resource block allocation RB allocation field in the initial random access message 2; determine a resource location for message 3 from initial random access depending on whether the target mode of the uplink waveform is
Petition 870190068748, of 7/19/2019, p. 9/64
4/36 DFT-S-OFDM discrete Fourier transform scattering orthogonal frequency division multiplexing or CP-OFDM cyclic prefix orthogonal frequency division multiplexing, where an initial random access message 3 resource location is determined when the target mode of the uplink waveform is DFT-S-OFDM is different from a resource location of message 3 of the initial random access that is determined when the target mode of the uplink waveform is CP- OFDM; and sending message 3 from initial random access to the network device at the given resource location.
[016] With reference to the first aspect and the preceding implementation of the first aspect, in a fifth possible implementation of the first aspect, the network device is a target network device to which the terminal device expects to be automatically switched, and the message notification is an HO automatic change command.
[017] It should be understood that when the terminal device is automatically switched from a source network device to the target network device, the terminal device learns, based on the HO command sent by the target network device, at least a target mode that is of the air interface technology and that must be used in the subsequent communication.
[018] Therefore, the terminal device can determine, from the plurality of optional modes of the air interface technology based on the notification message sent by the network device, a target mode that is of the air interface technology and that is used during o automatic switching to the network device, and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[019] With reference to the first aspect and the preceding implementation of the first aspect, in a sixth possible implementation of the first aspect, after the terminal device initially accesses the network device, the notification message is one between the following messages: a message physical layer, a MAC media access control message, or an RRC radio resource control message.
[020] With reference to the first aspect and the previous implementation of the first aspect, in a seventh possible implementation of the
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5/36 First aspect, the determination, by a terminal device, of at least one target mode of an air interface technology includes: selecting, by the terminal device, at least one target mode of the air interface technology from at least one optional mode of air interface technology, in accordance with an air interface technology selection policy.
[021] Optionally, the terminal device can determine the policy for selecting air interface technology, according to a stipulation of communications protocol. The terminal device can determine at least one target mode of air interface technology from at least one optional mode of air interface technology, in accordance with the air interface technology selection policy.
[022] Therefore, the terminal device can determine, from the plurality of optional modes of the air interface technology, according to the policy of selection of air interface technology, the target mode that is of the air interface technology and that is used when communicating with the network device. In other words, a more appropriate mode of air interface technology can be flexibly used based on an actual communication situation to adapt to different communication scenarios.
[023] With reference to the first aspect and the previous implementation of the first aspect, in a possible eighth implementation of the first aspect, the method additionally includes: receiving system information sent by the network device, where the system information bears the selection policy interface technology concept.
[024] To be specific, the network device can send the system information carrying the air interface technology selection policy to the terminal device to instruct the UE to determine, from the plurality of optional modes of the overhead interface technology, the target mode that is overhead interface technology and that is used when communicating with the network device.
[025] With reference to the first aspect and the previous implementation of the first aspect, in a ninth possible implementation of the first aspect, communication with the network device through the use of at least one target mode of air interface technology includes: sending a selection notification message for the network device, where the
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6/36 check notification message is used to indicate that the terminal device must communicate with the network device using at least one target mode of air interface technology.
[026] To be specific, after determining the target mode which is of the air interface technology and which is used when communicating with the network device, the terminal device must notify the network device of the target mode that will be used of the technology overhead interface.
[027] With reference to the first aspect and the preceding implementations of the first aspect, in a tenth possible implementation of the first aspect, at least one target mode of the air interface technology includes at least one among the following modes: when the air interface technology is a random access mode, the target mode is one of the following: a random access mode from a long term evolution LTE system or a simple random access mode; when the aerial interface technology is an uplink waveform, the target mode is one of the following: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing mode or an orthogonal frequency division multiplexing mode of scattering of discrete Fourier transform DFT-S-OFDM; when air interface technology is an uplink multiple access mode, the target mode is one of the following: a SCMA scarce multiple access mode, a MUSA multiuser shared access mode, a low broadcast mode code rate, a frequency domain diffusion mode, an NCMA non-orthogonal encoded multiple access mode, a NOMA non-orthogonal multiple access mode, a PDMA standard split multiple access mode, a multi-access diffusion mode RSMA feature, an IGMA interleaving grid multiple access mode, a LDS-SVE low density spread vector signature mode, a shared access NOCA non-orthogonal encrypted access, an IDMA interleaving split access multiple mode, an RDMA repeat split access multiple mode or an encrypted access mode GOCA group orthogonal; when the air interface technology is a modulation scheme, the target mode is one of the following: a phase shift shift scheme
Petition 870190068748, of 7/19/2019, p. 12/64
7/36 quadrature QPSK, a 16 16QAM quadrature amplitude modulation scheme, a 64 64QAM quadrature amplitude modulation scheme, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme, a scheme amplitude modulation in non-uniform QAM quadrature, higher order modulation in conjunction with MIMO, a coded modulation scheme, a spatial modulation scheme, a bit mapping scheme for symbol-scaled quadrature amplitude modulation to switching mappings by bit binary phase shift for symbol-rotated QAM up to BPSK, a bit mapping scheme for symbol-rotated quadrature amplitude to bit-quadratic phase shift switching for symbol-rotated QAM up to QPSK, or a constellation interpolation; when air interface technology is a duplex mode, the target mode is one of the following: an FDD frequency division duplex mode, a TDD time division duplex mode, a TDD time division duplex mode dynamic, a flexible duplex mode, a full space division duplex mode or a full band duplex mode; when the air interface technology is an uplink mobile uplink service uplink control channel encoding mode, the target mode is one of the following: a polar code encoding mode, a repetition encoding mode or a block encoding mode; when the air interface technology is an inactive uplink data transmission mode, the target mode is one of the following: a concession-free transmission mode or a 2-step RACH random access mode; when the air interface technology is a spacing of subcarriers, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer; when air interface technology is an interval type, the target mode is one of the following cases where the interval duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 OFDM orthogonal frequency division multiplexing symbols or mini-interval duration is m OFDM symbols, where ^me I ¹ ' ⁶ ]; and / or when the air interface technology is a TTI transmission duration, the
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8/36
target mode is one of the following: {a short duration of TTI of link downward: 2 OFDM symbols, an duration in TTI short in link ascending: 2 OFDM symbols}, {an duration in TTI short in link downward: 2 OFDM symbols, an duration in TTI short in link ascending: 4 OFDM symbols}, {an duration in TTI short in link downward: 2 OFDM symbols, an duration in TTI short in link ascending: 7 OFDM symbols}, {an duration in TTI short in link downward: 7 OFDM symbols, an duration in TTI short in link ascending: 7 OFDM symbols}, {an duration in TTI short in link downward: 2 OFDM symbols, an duration in TTI short in link ascending: 14 OFDM symbols} or {a duration d ( 9 TTI short in link downward: 7 OFDM symbols, an duration in TTI short in link
ascending: 14 OFDM symbols}.
[028] According to a second aspect, a communication method is provided, including: determining, by a network device, at least one target mode of an air interface technology; and communicating, via the network device, with a terminal device through the use of at least one target mode of air interface technology.
[029] Therefore, according to the method provided in this modality of this application, the target mode that is of the air interface technology and that is used during the real communication can be determined from the plurality of optional modes of the air interface technology.
[030] With reference to the second aspect, in a first possible implementation of the second aspect, the determination, by a network device, of at least one target mode of an air interface technology includes: determining, by the network device, at least a target mode of air interface technology from at least one optional mode of air interface technology; and sending, through the network device, a notification message to the terminal device, where the notification message carries at least one target mode of air interface technology.
[031] With reference to the second aspect, in a second possible implementation of the second aspect, the notification message is system information, so that the terminal device initially and randomly accesses the network device through the use of at least one
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9/36 target mode of air interface technology.
[032] With reference to the second aspect, in a third possible implementation of the second aspect, the notification message is message 2 of an initial random access, so that the terminal device sends message 3 of the initial random access to the device of network based on at least one target mode of air interface technology.
[033] With reference to the second aspect, in a fourth possible implementation of the second aspect, the network device is a target network device for which the terminal device expects to be switched automatically and the notification message is an HO command message.
[034] With reference to the second aspect, in a fifth possible implementation of the second aspect, after the terminal device accesses the network device, the notification message is one between the following messages: a physical layer message, a control message access to MAC media, or an RRC radio resource control message.
[035] With reference to the second aspect, in a sixth possible implementation of the second aspect, at least one target mode of the air interface technology includes at least one among the following modes: when the air interface technology is a random access mode, the target mode is one of the following: a random access mode from an LTE long-term evolution system or a simple random access mode; when the aerial interface technology is an uplink waveform, the target mode is one of the following: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing mode or an orthogonal frequency division multiplexing mode of scattering of discrete Fourier transform DFT-S-OFDM; when air interface technology is an uplink multiple access mode, the target mode is one of the following: a SCMA scarce multiple access mode, a MUSA multiuser shared access mode, a low broadcast mode code rate, a frequency domain diffusion mode, an NCMA non-orthogonal encoded multiple access mode, a NOMA non-orthogonal multiple access mode, a PDMA standard split multiple access mode, a
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10/36 RSMA resource broadcast multiple access mode, IGMA interleaving grid multiple access mode, LDS-SVE low density spread signature vector extension mode, low-level shared access mode LSSA code and subscription fee, an NOCA non-orthogonal encrypted access mode, an IDMA interleaving split access multiple mode, an RDMA repeat split access multiple mode or a GOCA group orthogonal encrypted access mode; when the air interface technology is a modulation scheme, the target mode is one of the following: a QPSK quadrature phase shift switch scheme, a 16 16QAM quadrature amplitude modulation scheme, an amplitude modulation scheme 64 64QAM quadrature, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme, a non-uniform QAM amplitude modulation scheme, higher order modulation in conjunction with MIMO, a modulation scheme coded, a spatial modulation scheme, a bit mapping scheme for symbol-rotated quadrature amplitude up to binary phase shift switching, a bit mapping scheme for symbol-rotated quadrature amplitude modulation up to shift switching quadrature phase or constellation interpolation; when air interface technology is a duplex mode, the target mode is one of the following: an FDD frequency division duplex mode, a TDD time division duplex mode, a TDD time division duplex mode dynamic, a flexible duplex mode, a full space division duplex mode or a full band duplex mode; when air interface technology is an uplink mobile uplink service uplink control channel encoding mode, the target mode is one of the following: a polar code encoding mode, a repetition encoding mode or a block encoding mode; when the air interface technology is an inactive uplink data transmission mode, the target mode is one of the following: a concession-free transmission mode or a 2-step RACH random access mode; when the air interface technology is a spacing of
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11/36 subcarrier, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer; when the air interface technology is an interval type, the target mode is one of the following cases where the interval duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 OFDM orthogonal frequency division multiplexing symbols or mini-interval duration is m OFDM symbols, where ^me {L ⁶ } _; θ / _ου when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 2 symbols OFDM}, {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 4 OFDM symbols}, {a short downlink TTI duration: 2 OFDM symbols, a short TTI duration uplink duration: 7 OFDM symbols}, {a short downlink TTI duration: 7 OFDM symbols, a short uplink TTI duration: 7 OFDM symbols}, {a short downlink TTI duration: 2 OFDM symbols , a short downlink TTI duration: 14 OFDM symbols} or {a short downlink TTI duration: 7 OFDM symbols, a short uphill TTI duration: 14 OFDM symbols}.
[036] Therefore, the network device determines, from the plurality of optional modes of the air interface technology, the target mode that is of the air interface technology and that is used during the communication with the terminal device. In other words, a more appropriate mode of air interface technology can be flexibly used based on an actual communication situation to adapt to different communication scenarios.
[037] According to a third aspect, a terminal device is provided. The terminal device is configured to implement the method in the first aspect or any possible implementation of the first aspect. Specifically, the terminal device includes a unit for carrying out the method in the first aspect or any possible implementation of the first aspect.
[038] According to a fourth aspect, a network device is provided. The network device is configured to implement the method on the
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12/36 second aspect or any possible implementation of the second aspect. Specifically, the network device includes a unit for carrying out the method in the second aspect or any possible implementation of the second aspect.
[039] According to a fifth aspect, a terminal device is provided. The terminal device includes: a transceiver, a memory, a processor and a bus system. The transceiver, memory and processor are connected using the bus system. The memory is configured to store an instruction. The processor is configured to execute the instruction stored in memory, to control the transceiver to receive and / or send a signal. In addition, when the processor executes the instruction stored in memory, execution allows the processor to perform the method on the first aspect or any possible implementation of the first aspect.
[040] According to a sixth aspect, a network device is provided. The network device includes: a transceiver, a memory, a processor and a bus system. The transceiver, memory and processor are connected using the bus system. The memory is configured to store an instruction. The processor is configured to execute the instruction stored in memory, to control the transceiver to receive a signal and / or send a signal. In addition, when the processor executes the instruction stored in memory, execution allows the processor to perform the method on the second aspect or any possible implementation of the second aspect.
[041] According to a seventh aspect, computer-readable media is provided. Computer-readable media is configured to store a computer program. The computer program includes an instruction to carry out the method in the first aspect or any possible implementation of the first aspect.
[042] According to an eighth aspect, computer-readable media is provided. Computer-readable media is configured to store a computer program. The computer program includes an instruction to carry out the method in the second aspect or any possible implementation of the second aspect.
BRIEF DESCRIPTION OF THE DRAWINGS
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13/36 [043] FIG. 1 is a schematic flow chart of a method, according to an embodiment of this application;
[044] FIG. 2 is a flow chart of a method, according to an embodiment of this application;
[045] FIG. 3 is a schematic flow chart of a method, according to an embodiment of this application;
[046] FIG. 4 is a flow chart of a method, according to an embodiment of this application;
[047] FIG. 5 is a schematic flow chart of a method, according to an embodiment of this application;
[048] FIG. 6 is a schematic flow chart of a method, according to an embodiment of this application;
[049] FIG. 7 is a schematic flow chart of a method, according to another embodiment of this application;
[050] FIG. 8 is a schematic block diagram of a terminal device 800, according to an embodiment of this application;
[051] FIG. 9 is a schematic block diagram of a network device 900, according to an embodiment of this application;
[052] FIG. 10 is a schematic structural block diagram of an apparatus 1000, according to another embodiment of this application; and [053] FIG. 11 is a schematic structural block diagram of an apparatus 1100, according to another embodiment of this application.
DESCRIPTION OF THE MODALITIES [054] The technical solutions in the modalities of this application are described below with reference to the attached drawings.
[055] In the modalities of this application, a terminal device can be user equipment (user equipment, UE), 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 wireless communication device, a user agent or a user device. The access terminal can be a cell phone, a cordless phone, a Session Initiation Protocol (SIP) phone, a local wireless loop station (wireless local loop, WLL), a personal digital assistant ( personal digital assistant, PDA), a
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14/36 portable device having a wireless communication function, a communication device, another processing device connected to a wireless modem, a device in the vehicle, a wearable device or a terminal device on a future 5G network.
[056] In addition, in the modalities of this application, a base station can be a network device for communication with the terminal device. For example, the base station can be a transceiver base station (trance base, BTS) in a GSM or CDMA system, or it can be a B Node (Node Β, NB) in a WCDMA system, or it can be a B Node evolved (Evolutional Node B, eNB or eNodeB) in an LTE system. Alternatively, the base station can be a relay station, an access point, a device in the vehicle, a wearable device, a network side device on a future 5G network or the like.
[057] FIG. 1 is a schematic flow chart of a method, according to an embodiment of this application. As shown in FIG. 1, method 100 is performed by a terminal device. As shown in FIG. 1, method 100 includes the following steps.
[058] Step 110. The terminal device determines at least one target mode of an air interface technology.
[059] Step 120. The terminal device communicates with a network device through the use of at least one target mode of air interface technology.
[060] It should be understood that each air interface technology can feature more than one optional mode and a target mode of air interface technology needs to be selected for network communication during actual communication. Therefore, the terminal device must determine the target mode of the air interface technology.
[061] Optionally, in one embodiment of this application, at least one target mode of the air interface technology includes at least one of the following modes: when the air interface technology is a random access mode, the target mode is one among following: a random access mode of a LTE (Long Term Evolution, LTE) long term evolution system or a simple random access mode; when air interface technology is an uplink waveform, the target mode is one among
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Following 15/36: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing, CP-OFDM orthogonal frequency division multiplexing mode or a DFT discrete Fourier transform spreading orthogonal frequency division multiplexing mode -S-OFDM (discrete Fourier transform spread orthogonal frequency division multplexing, DFT-SOFDM); when the air interface technology is an uplink multiple access mode, the target mode is one of the following: a spma code multiple acces (SCMA) multiple access mode, a multiuser shared access mode MUSA (multi-user shared access, MUSA), low code rate spreading mode, frequency domain spreading mode, a non-orthogonal NCMA coded multiple access mode coded multiple acces, NCMA), a non-orthogonal multiple access NOMA (NOMA), a standard division multiple access (PDMA) mode, a diffusion multiple access mode resource spread multiple access, RSMA, a multiple access mode by IGMA interleave-grid multiple access, IGMA, a signature vector extension mode with low density LDS-SVE (low density spreading with signature vector extension, LDS-SVE), a shared access mode based on low code rate and LSSA signature (low code rate and signature based shared access, LSSA), a mode of non-orthogonal coded access (NOCA) non-orthogonal coded access, an interleave division multiple access (IDMA) multiple access mode, a repetition division multiple access (RDMA) multiple access mode, RDMA) or orthogonal coded access mode of GOCA group (group orthogonal coded access, GOCA); when the air interface technology is a modulation scheme, the target mode is one of the following: a quadrature phase shift keying (QPSK) switching scheme, a quadrature amplitude modulation scheme 16 16QAM (quadrature amplitude modulation, QAM), a 64 64QAM quadrature amplitude modulation scheme, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme (constellation
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16/36 mapping among subcarriers), a non-uniform QAM quadrature amplitude modulation scheme (non-uniform QAM), a higher order modulation in conjunction with MIMO, a coded modulation scheme (coded modulations), a spatial modulation scheme, a bit mapping scheme for quadrature amplitude modulation rotated by symbols to phase shift mapping of bit quadrature for QAM rotated by symbols up to QPSK ( mappings of bits to symbol (s) rotated-QAM up to QPSK), or a constellation interpolation (Constellation Interpolation); when the air interface technology is a duplexing mode, the target mode is one of the following: a frequency division duplexing (FDD) mode, a time division TDD (time division duplexing) mode duplex, TDD), a dynamic TDD time division duplex mode (dynamic TDD), a flexible duplex mode (flexible duplex), a space division full-duplex mode or a total in-band duplexing (In full-duplex band); when the air interface technology is an uplink control channel encoding mode of enhanced mobile broadband service eMBB (enhanced mobile broadband, eMBB), the target mode is one of the following: a polar code encoding mode (polar codes), a repetition coding mode (repetition) or a block coding mode; when the air interface technology is an inactive uplink data transmission mode, the target mode is one of the following: a concession-free transmission mode or a 2-step RACH random access mode; when the air interface technology is a sub carrier spacing, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer; when air interface technology is an interval type, the target mode is one of the following cases in which the slot duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 multiplex OFDM symbols per division division orthogonal frequency or mini-slot duration is OFDM symbols, where ^me ; and / or when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a
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17/36 short downlink TTI duration: 2 OFDM symbols, one short downlink TTI duration: 2 OFDM symbols}, {one short downlink TTI duration: 2 OFDM symbols, a short downlink TTI duration upward: 4 OFDM symbols}, {a short downlink TTI duration: 2 OFDM symbols, a short upward TTI duration: 7 OFDM symbols}, {a short downlink TTI duration: 7 OFDM symbols, a duration short uplink TTI duration: 7 OFDM symbols}, {one short downlink TTI duration: 2 OFDM symbols, one short uplink TTI duration: 14 OFDM symbols} or {one short downlink TTI duration: 7 OFDM symbols, a short uplink TTI duration: 14 OFDM symbols}.
[062] Optionally, in an embodiment of this request, the terminal device determines at least one target mode of the air interface technology, according to a communications protocol.
[063] Optionally, the terminal device can alternatively determine at least one target mode of air interface technology in another mode.
[064] Optionally, in an embodiment of this request, that the terminal device determines at least one target mode of an air interface technology includes: receiving, by the terminal device, a notification message sent by the network device, where the notification message port at least one target mode of air interface technology and at least one target mode of air interface technology is determined by the network device from at least one optional mode of air interface technology.
[065] Optionally, in an embodiment of this request, when the air interface technology is a random access mode, the optional mode includes: a random access mode of a long term evolution system LTE (Long Term Evolution, LTE) or a simple random access mode; when the air interface technology is an uplink waveform, the optional mode includes: a cyclic prefix orthogonal frequency division multiplexing (CP-OFDM) or a multiplexing mode by frequency division
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18/36 discrete Fourier transform spreading orthogonal (discrete Fourier transform spread orthogonal frequency division multiplexing, DFT-S-OFDM); when air interface technology is an uplink multiple access mode, the optional mode includes: a SCMA (sparse code multiple access, SCMA) multiple access mode, a MUSA multiuser shared access mode (multi- user shared access, MUSA), low code rate spreading mode, frequency domain spreading mode, a NCMA non-orthogonal coded multiple access mode access, NCMA), a non-orthogonal multiple access mode NOMA (nonorthogonal multiple access, NOMA), a standard division multiple access mode (PDMA), an RSMA resource broadcast multiple access mode ( resource spread multiple access, RSMA), an IGMA interleave-grid multiple access mode (IGMA), a signature vector extension mode with low density spreading LDS-SVE (low density spreading with signature vector extension, LDS-SVE), a shared access mode based on low code rate and LSSA signature (low code rate and signature based shared access, LSSA), an access mode non-orthogonal coded access, NOCA, an interleave division multiple access (IDMA) multiple access mode, a repetition division multiple access (RDMA) multiple access mode ) or orthogonal coded access mode of GOCA group (group orthogonal coded access, GOCA); when air interface technology is a modulation scheme, the optional mode includes: a quadrature phase shift keying (QPSK) shift scheme, a 16 16QAM quadrature amplitude scheme modulation, QAM), a quadrature amplitude modulation scheme 64 64QAM, a quadrature amplitude modulation scheme 256 256QAM, a constellation mapping between subcarriers scheme, a quadrature amplitude modulation scheme Non-uniform QAM, a higher order modulation in conjunction with MIMO (higher order modulation in conjunction with MIMO), a
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19/36 coded modulations, a spatial modulation scheme, a bit mapping scheme for rotating symbol quadrature amplitude to phase shift switching and bit quadrature mapping for rotated QAM by symbols up to QPSK (mappings of bits to symbol (s) rotated-QAM up to QPSK) or a constellation interpolation (Constellation Interpolation); when air interface technology is a duplexing mode, the optional mode includes: a frequency division duplexing (FDD) mode, a time division duplexing (TDD) mode , a dynamic TDD time division duplex mode (dynamic TDD), a flexible duplex mode (flexible duplex), a space division full-duplex mode or a full band duplex mode (In full-duplex band); when the air interface technology is an uplink control channel encoding mode of enhanced mobile broadband service eMBB (enhanced mobile broadband, eMBB), the target mode is one of the following: a polar code encoding mode (polar codes), a repetition coding mode (repetition) or a block coding mode; when air interface technology is an inactive uplink data transmission mode, the optional mode includes: a concession-free transmission mode or a 2-step RACH random access mode; when the air interface technology is a sub carrier spacing, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer; when air interface technology is an interval type, the target mode is one of the following cases in which: the slot duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 division division multiplexing symbols orthogonal OFDM frequency or mini-slot duration is OFDM symbols, where ^me ; and / or when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 2 symbols OFDM}, {a short downlink TTI duration: 2 OFDM symbols, a short upstream TTI duration: 4 OFDM symbols}, {one
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20/36 short downlink TTI duration: 2 OFDM symbols, one short downlink TTI duration: 7 OFDM symbols}, {one short downlink TTI duration: 7 OFDM symbols, one short downlink TTI duration ascending: 7 OFDM symbols}, {a short downlink TTI duration: 2 OFDM symbols, a short uphill TTI duration: 14 OFDM symbols} or {a short downlink TTI duration: 7 OFDM symbols, one duration of short uplink TTI: 14 OFDM symbols}.
[066] It should be understood that each of the listed modes of air interface technology is an optional mode of air interface technology. For example, when the air interface technology is random access mode, the optional mode includes: LTE random access mode or simple random access mode. The target mode of the air interface technology is the LTE random access mode or the target mode of the air interface technology is the simple random access mode.
[067] Therefore, the terminal device can determine, from a plurality of optional modes of the air interface technology based on the notification message sent by the network device, the target mode which is of the air interface technology and which is used during real communication and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[068] Optionally, in one embodiment of this request, the notification message is system information sent by the network device and communication with a network device using at least one target mode of air interface technology includes: access initially the network device through the use of at least one target mode of air interface technology.
[069] FIG. 2 is a flow chart of a method, according to an embodiment of this application. As shown in FIG. 2, the method includes the following steps.
[070] Step 210. A base station sends system information (system information) to the UE, where system information can be sent to the UE with a broadcasting mode and system information
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21/36 carry a target mode which is an aerial interface technology and which is selected by a network device.
[071] Step 220. The UE performs initial random access based on the target mode which is of the air interface technology and which is selected by the network device.
[072] Specifically, for example, when a selected target mode that is of an uplink waveform and that is in the broadcast system information by the base station is the orthogonal transformation frequency spread multiplexing mode. Discrete Fourier (discrete Fourier transform spread orthogonal frequency division multiplexing, DFT-S-OFDM), the UE performs initial random access by using the DFT-S-OFDM mode to access the network device.
[073] Specifically, the base station determines at least one target mode of air interface technology from at least one optional mode of air interface technology based on an actual communication scenario. For example, before the UE initially and randomly accesses the base station, the base station has no information about the UE, does not know a location of the UE currently located in a cell, and does not know what an environment is like in which the UE is. located. Therefore, the base station selects a more robust waveform mode for the UE, that is, the DFT-S-OFDM mode.
[074] Therefore, a terminal device can determine, from the plurality of optional modes of the air interface technology based on the notification message sent by the network device, a target mode that is of the air interface technology and that is used during initial access to a system and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[075] Optionally, in one embodiment of this request, the notification message is an initial random access message 2 and communication with the network device using at least one target mode of air interface technology includes: sending the initial random access message 3 to the network device using at least one target mode of air interface technology.
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22/36 [076] It should be understood that, based on the initial random access message 2, not only at least one target mode that is from the air interface technology and that is applied to the initial random access message 3 can be determined, but also a target mode which is from the air interface technology and which is subsequently used during signaling interaction or data exchange with the network device can be specified. This is not limited in this order.
[077] Specifically, FIG. 3 is a schematic flow chart of a method, according to an embodiment of this application. It should be understood that the procedure can also be considered as a further elaboration of step 220 in FIG. 2. As shown in FIG. 3, the method includes the following steps.
[078] Step 221. The UE sends a preamble sequence (preamble) to the base station. It is to be understood that the UE can use the method of the modality shown in FIG. 2 to determine a target mode of air interface technology for initial random access to send the preamble sequence. The preamble sequence is an initial random access message 1.
[079] Step 222. The base station determines a target mode of air interface technology. To be specific, the network device can again select, based on a changing state of a network environment, a transmission service and the like, the target mode that is of the air interface technology and that is used by the UE to communicate with the base station. In other words, the base station additionally determines at least one target mode of air interface technology from at least one optional mode of air interface technology based on a current communication scenario.
[080] Step 223. The base station sends initial random access message 2 to the UE, where initial random access message 2 carries at least one target mode of air interface technology. In other words, the base station notifies the UE of at least one target mode of the air interface technology through the use of message 2, so that the UE subsequently transmits data or signaling based on at least one target mode which is of the air interface technology and that is carried in the message
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23/36
2.
[081] Step 224. The UE sends message 3 to the base station. To be specific, the UE sends message 3 to the base station using at least one target mode which is air interface technology and which is selected by the base station.
[082] It should be understood that, if an initial UE random access mode is an existing LTE four-step random access mode, based on a preamble ID preamble ID in message 2, all UEs using the preamble in message 1 receive message 2. In other words, all of these UEs receive the target mode which is from the air interface technology and which is selected again by the base station. In this case, all of these UEs perform subsequent transmission based on the option selected again by the base station. If an initial random access of the UE is a simplified mode of random access in 2 steps, the message 1 carries an identifier of the UE. In this case, message 2 is sent only to the UE corresponding to the identifier carried in message 1. To be specific, only the UE receives the target mode which is from the air interface technology and which is selected again by the base station and performs transmission based on the option selected again by the base station.
[083] Optionally, in an embodiment of this request, at least one target mode which is of the air interface technology and which is carried in the initial random access message 2 includes an uplink waveform mode and the sending message initial random access 3 to the network device using at least one target mode of air interface technology includes: determining an RB allocation field content value in the initial random access message 2; determine a resource location of the initial random access message 3 depending on whether the uplink waveform mode is the DFTS-OFDM discrete Fourier transform spread orthogonal frequency division multiplexing mode or the division multiplexing mode CP-OFDM cyclic prefix orthogonal frequency frequency, where a resource location of the initial random access message 3 which is determined when the uplink waveform mode is DFT-S-OFDM is different from a location of
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24/36 resource of the initial random access message 3 which is determined when the uplink waveform mode is CP-OFDM; and sending the initial random access message 3 to the network device at the given resource location.
[084] To be specific, the UE determines the resource location of the initial random access message 3 depending on whether the uplink waveform mode is DFT-S-OFDM or CP-OFDM and based on the value of RB allocation field content in an uplink grant, UL grant in message 2 when the RB allocation field content value is a specified value. In general, a resource location of message 3 varies, according to an uplink waveform mode. This is due to the fact that DFT-S-OFDM always indicates consecutive resources in the frequency domain and CP-OFDM can indicate non-consecutive resources in the frequency domain.
[085] Step 225. The base station sends a contention resolution message to the UE, that is, an initial random access message 4.
[086] In addition, the UE performs data transmission and / or subsequent signaling transmission with the base station based on the target mode which is of the air interface technology and which is selected again by the base station.
[087] When the air interface technology is the uplink waveform, the optional mode includes CP-OFDM and DFT-S-OFDM. In this case, the base station can determine, based on message 1, a cell in which the UE is currently located. If the UE is in a small cell, the base station determines a CP-OFDM waveform mode for the UE to use. If the UE is in a large cell, the base station can approximately determine, based on the signal quality of message 1, whether the UE is in a central region or in a border region of the large cell. If the UE is in the central region, the base station determines a CP-OFDM waveform mode for the UE to use. If the UE is in the border region, the base station determines a DFT-SOFDM waveform mode for the UE to use.
[088] Therefore, the terminal device can determine, from the
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25/36 plurality of optional modes of air interface technology based on the notification message sent by the network device, a target mode which is of air interface technology and which is used during initial random access to a system and can flexibly use a most appropriate way of air interface technology based on a real communication situation to adapt to different communication scenarios.
[089] Optionally, in an embodiment of this request, the network device is a target network device for which the terminal device expects to be switched automatically and the notification message is an HO command.
[090] To be specific, when a source network device accessed by the UE determines that the UE should be automatically switched to the target network device and sends a handover request message to the target network device and the target network device allows the request, the target network device sends the HO command message to the UE. The message carries at least one target mode which is of the air interface technology and which is selected by the target network device.
[091] In other words, specifically, when the originating base station determines, based on a measurement report from the UE, that the UE should be automatically switched to the target base station, the originating base station sends the handover request message to the target network device. If the target network device allows the request, before the UE is automatically switched to the target base station, the target base station selects at least one target mode of the air interface technology from at least one optional mode of the technology air interface based on information, such as UE capacity information and a measurement result of the UE in the automatic change request message received and notifies the UE through the use of the HO command message.
[092] For example, if the target base station determines, based on the capacity information of the UE and the measurement result of the UE in the automatic change request message received to deliver the UE to a small cell served by the base station target, the target base station determines for the UE the use of the CP OFDM waveform mode in the target cell. If the target base station determines to deliver the UE to a large cell
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26/36 served by the target base station, the target base station determines, for the UE, the use of the DFT-S-OFDM waveform mode with stronger robustness in the target cell.
[093] FIG. 4 is a flow chart of a method, according to an embodiment of this application. Referring to FIG. 4, FIG. 4 shows in detail a process of interaction between the UE and each source base station and a target base station in an automatic switching process, including the following steps.
[094] Step 401. The target base station determines a target mode which is an air interface technology and which is to be used by the UE.
[095] Step 402. The target base station sends a handover request acknowledgment message to the originating base station, where the automatic change request confirmation message carries an HO command and the HO command can be used to indicate the target mode which is from the air interface technology and which is selected by the target base station.
[096] Step 403. The originating base station sends an RRC connection reconfiguration message to the UE, where the connection reconfiguration message also carries the preceding HO command.
[097] Step 404. The UE communicates with the target base station and uses the target mode which is from the air interface technology and which is selected by the target base station.
[098] Therefore, a terminal device can determine, from a plurality of optional modes of air interface technology based on a notification message sent by a network device, a target mode that is of air interface technology and that it is used during automatic switching to the network device and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[099] Optionally, in a mode of this request, after the terminal device initially and randomly accesses the network device, the notification message is one of the following messages: a physical layer message, a MAC message, or an RRC message.
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27/36 [0100] In other words, regardless of a mode used by the UE, after the UE initially and randomly accesses the network device, the base station can reset, based on a capacity of the UE and / or an environment in which the UE is located, a mode that is of the air interface technology and that is can be used by the UE.
[0101] Specifically, FIG. 5 is a schematic flow chart of a method, according to an embodiment of this application. FIG. 5 shows that after the UE initially and randomly accesses a network device, the network device reselects a target mode of an air interface technology and provides the target mode of the air interface technology to the UE and the UE communicates with the network device based on the target mode of air interface technology. As shown in FIG. 5, the method includes the following steps.
[0102] Step 501. A base station determines a target mode that is of an air interface technology and that is can be used by the UE.
[0103] Step 502. The base station sends one of the following messages to the UE: a PHY message, a MAC message, or an RRC message. Regardless of a type of message specifically sent by the base station to the UE, the message carries at least one target mode that is air interface technology and that is selected by the base station for the UE.
[0104] Step 503. The UE communicates with the network device.
[0105] Therefore, a terminal device can determine, from a plurality of optional modes of the air interface technology based on a notification message sent by the network device, a target mode that is of the air interface technology and that is used during communication with the network device and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[0106] Optionally, in an embodiment of this application, the determination, by a terminal device, of at least one target mode of an air interface technology includes: selecting, by the terminal device, at least one target mode of the air interface technology to from at least one optional mode of air interface technology, in accordance with a policy
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28/36 selection of air interface technology.
[0107] In other words, the terminal device can perform the selection from at least one optional mode of the air interface technology, in accordance with the air interface technology selection policy, and communicate with the network device using at least the target mode of an air interface technology selected.
[0108] It should be understood that the UE can select a target mode of air interface technology from at least one optional mode of air interface technology, in accordance with the policy for selecting air interface technology and based on information , such as a current network environment, a UE capacity and a service that needs to be transmitted.
[0109] Optionally, in a modality of this request, when the UE needs to communicate the uplink service control information eMBB, the UE determines a coding mode to be used based on a condition that needs to be performed for a duration of uplink control information that needs to be reported. A specific procedure is as follows: The base station broadcasts, in system information, a duration limit for uplink control information using a polar code, or specifies, in a protocol, a duration limit for uplink control information. uplink using a polar code. When the duration of the uplink control information that needs to be reported by the UE is greater than the threshold, the UE uses the polar code to perform channel encoding on the uplink control information, and then performs the transmission. Otherwise, the UE uses another mode. When the UE needs to report the eMBB service uplink control information, the UE selects an appropriate channel encoding mode based on the duration of the uplink control information that needs to be reported. The UE performs channel encoding on the uplink control information using the encoding mode and then performs the transmission. It should be understood that the base station inversely deduces the channel encoding mode using the received data information.
[0110] Optionally, in a modality of this request, when the UE in an inactive mode needs to transmit uplink data, a transmission mode is determined based on an environment in which the UE
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29/36 is currently located and based on a condition that needs to be realized by a data volume of the uplink data that needs to be transmitted. The base station broadcasts, in system information, a condition to use a concession-free transmission mode, or specifies, in a protocol, a condition to use a concession-free transmission mode, for example, based on a threshold loss of cell downlink signal path, depending on whether the UE still remains in a cell in which the UE in idle mode (a third mode) is located or based on a limit of an uplink data volume that needs to be transmitted by the UE. If a path loss that is from the cell's downlink signal and that is detected by the UE is below a specified limit or the UE still remains in the cell in which the UE in idle mode is located, the uplink data they need transmitted by the UE are less than a specified limit, the concession-free transmission mode is used. Otherwise, a 2-step RACH mode is adopted. When the UE in idle mode needs to transmit uplink data, an uplink data transmission mode is selected based on an environment in which the UE is currently located and a data volume of the uplink data needs to be transmitted. The UE transmits the uplink data using the determined transmission mode.
[0111] It should be understood that there may be different policies for selecting air interface technology for different application scenarios. This is not limited in this mode of this application.
[0112] Optionally, in a modality of this request, the previous method also includes: receiving, by the terminal device, system information sent by the network device, where the system information bears the policy of selection of air interface technology.
[0113] It should be understood that the air interface technology selection policy can still carry a plurality of air interface technologies and optional modes of each air interface technology, so that the UE selects the target mode of the air interface technology , in accordance with the air interface technology policy.
[0114] In other words, the UE can select the target mode of the
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30/36 air interface technology, in accordance with a communications protocol or air interface technology policy provided by the base station.
[0115] Optionally, in an embodiment of this request, communication with the network device through the use of at least one target mode of the air interface technology includes: sending a selection notification message to the network device, where the Selection notification message is used to indicate that the terminal device communicates with the network device using at least one target mode.
[0116] To be specific, after selecting the target mode of the air interface technology, the UE needs to notify the network device of the selected air interface technology mode.
[0117] Specifically, FIG. 6 is a schematic flow chart of a method, according to an embodiment of this application. As shown in FIG. 6, the method includes the following steps.
[0118] Step 601. Sending an air interface technology selection policy to the UE.
[0119] Step 602. The UE selects a target mode of an air interface technology from optional modes of the air interface technology, in accordance with the air interface technology selection policy and based on information, such as a current network environment, a UE capacity and a service that needs to be transmitted.
[0120] Step 603. The UE sends a notification message to a base station through the use of dedicated information, where the notification message carries the target mode which is of the air interface technology and which is selected by the UE.
[0121] Step 604. The UE communicates with the base station using the target mode selected from the air interface technology.
[0122] Therefore, a terminal device can determine, from the plurality of optional modes of the air interface technology based on the notification message sent by a network device, the target mode which is of the air interface technology and which is used during communication with the network device and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
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31/36 [0123] FIG. 7 is a schematic flow chart of a method, according to another embodiment of this application. The method can be performed by a network device. For example, the network device can be a base station. As shown in FIG. 7, method 700 includes the following steps.
[0124] Step 710. The network device determines at least one target mode of an air interface technology.
[0125] Step 720. The network device communicates with a terminal device using at least one target mode of air interface technology.
[0126] It should be understood that at least one target mode of the air interface technology is the same as the target mode of the air interface technology in the embodiment shown in FIG. 1. The details are not described again in this report.
[0127] Therefore, according to the method provided in this modality of this application, a target mode that is of an air interface technology and that is used during real communication can be determined from a plurality of optional modes of the interface technology aerial.
[0128] Optionally, in an embodiment of this application, the determination, by the network device, of at least one target mode of an air interface technology includes: determining, by the network device, at least one target mode of the air interface technology from at least one optional mode of air interface technology; and sending, through the network device, a notification message to the terminal device, where the notification message carries at least one target mode of air interface technology.
[0129] Optionally, in a form of this request, the notification message is system information, so that the terminal device initially and randomly accesses the network device through the use of at least one target mode of air interface technology.
[0130] Optionally, in an embodiment of this request, the notification message is an initial random access message 2, so that the terminal device sends the initial random access message 3 to the network device using at least a target mode of air interface technology.
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32/36 [0131] Optionally, in an embodiment of this request, the network device is a target network device for which the terminal device expects to be switched automatically and the notification message is an HO command message.
[0132] Optionally, in a mode of this request, after the terminal device accesses the network device, the notification message is one of the following messages: a physical layer message, a MAC media access control message, or a RRC radio resource control message.
[0133] Therefore, the terminal device can determine, from the plurality of optional modes of the air interface technology based on the notification message sent by the network device, the target mode which is of the air interface technology and which is used during communication with the network device and can flexibly use a more appropriate mode of air interface technology based on a real communication situation to adapt to different communication scenarios.
[0134] The method procedures of the modalities of this application are described in detail with reference to FIG. 1 to FIG. 7. Next, the devices of the modalities of this application are described in detail with reference to FIG. 8 to FIG. 11.
[0135] FIG. 8 is a schematic block diagram of a terminal device 800, according to an embodiment of this application. Terminal device 800 can perform the steps that are performed by the terminal device in the methods in FIG. 1 to FIG. 7. To avoid repetition, the details are not described again in this report. Terminal device 800 includes:
a determination unit 810, where the determination unit 810 is configured to determine at least one target mode of an air interface technology; and a sending unit 820, where sending unit 820 is configured to communicate with a network device using at least one target mode of air interface technology.
[0136] Therefore, the terminal device provided in this modality of this application can determine, from a plurality of optional modes
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33/36 of the air interface technology, the target mode that is of the air interface technology and that is used during real communication.
[0137] FIG. 9 is a schematic block diagram of a network device 900, according to an embodiment of this application. The network device 900 can perform the steps that are performed by the network device in the methods in FIG. 1 to FIG. 7. To avoid repetition, the details are not described again in this report. The 900 network device includes:
a determination unit 910, where determination unit 910 is configured to determine at least one target mode of an air interface technology; and a sending unit 920, where sending unit 920 is configured to communicate with a terminal device through the use of at least one target mode of air interface technology.
[0138] Therefore, the network device provided in this modality of this application can determine, from a plurality of optional modes of the air interface technology, the target mode which is of the air interface technology and which is used during the real communication.
[0139] FIG. 10 is a schematic structural block diagram of an apparatus 1000, according to another embodiment of this application. It should be understood that the apparatus 1000 can perform the steps that are performed by the terminal device in the methods in FIG. 1 to FIG. 7. To avoid repetition, the details are not described again in this report. The device 1000 includes:
a memory 1010 configured to store an instruction;
a transceiver 1020 configured to communicate with another device; and a processor 1030, where processor 1030 is connected to memory 1010 and transceiver 1020 and configured to execute the instruction stored in memory 1010 to perform the following steps when executing the instruction: determine at least one target mode of an interface technology aerial; and communicating, via the terminal device, with the network device using at least one target mode of air interface technology.
[0140] Therefore, the device provided in this modality of this order
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34/36 can determine, from a plurality of optional modes of air interface technology, the target mode which is of air interface technology and which is used during actual communication.
[0141] FIG. 11 is a schematic structural block diagram of an apparatus 1100, according to another embodiment of this application. It is to be understood that the apparatus 1100 can perform the steps that are performed by a network device in the methods in FIG. 1 to FIG. 7. To avoid repetition, the details are not described again in this report. The apparatus 1100 includes: a memory 1110 configured to store an instruction;
a transceiver 1120 configured to communicate with another device; and a processor 1130 configured to execute the instruction in memory 1110, where processor 1130 is connected to memory 1110 and transceiver 1120 and configured to execute the instruction stored in memory 1110 to perform the following steps when executing the instruction: determine at least one target mode of an air interface technology; and communicating with a terminal device using at least one target mode of air interface technology.
[0142] Therefore, the device provided in this modality of this application can determine, from a plurality of optional modes of the air interface technology, the target mode that is of the air interface technology and that is used during the real communication.
[0143] A person skilled in the art may be aware that the units and algorithm steps in the examples described with reference to the modalities disclosed in this specification can be implemented by electronic hardware or a combination of computer software and electronic hardware. Whether the functions are performed by hardware or software, they depend on particular applications and conditions of design restriction of technical solutions. A person skilled in the art can use different methods to implement the functions described for each particular application, but it should not be considered that the implementation goes beyond the scope of this application.
[0144] It can be clearly understood by a technician on the subject that, by convenient and brief description, reference can be made to a corresponding process in the modalities of the method for a work process
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35/36 detailed system, device and unit. The details are not described again in this report.
[0145] In the various modalities provided in this application, it should be understood that the system, apparatus and methods disclosed can be implemented in other modes. For example, the described mode of the apparatus is merely an example. For example, the division of units is merely a division of logical functions 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 features can be ignored or not realized. In addition, the mutual couplings displayed or discussed or direct couplings or communication connections can be implemented through the use of some interfaces. Indirect couplings or communication connections between devices or units can be implemented in electronic, mechanical or other forms.
[0146] The units described as separate parts may or may not be physically separate and parts displayed as units may or may not be physical units, may be located in one position or may be distributed over a plurality of network units. Some or all of the units can be selected, according to the real needs to obtain the objectives of the solutions of the modalities.
[0147] 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.
[0148] When functions are implemented in the form of a functional software unit and sold or used as a standalone product, the functions can be stored on a computer-readable storage medium. Based on such an understanding, the technical solutions of this application essentially, or the part that contributes to the state of the art, or some of the technical solutions can be implemented in the form of a software product. The computer's software product is stored on storage media and includes several instructions for instructing a computer device (which may be a personal computer, a server, or a network device) to perform all or some of the steps in the
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36/36 methods described in the embodiments of the present invention. The previous storage media includes any media that can store a program code, such as a USB flash drive, a removable hard drive, a read-only memory (Read-Only Memory, ROM), a random access memory Memory, RAM), a magnetic disk or an optical disk.
[0149] The preceding descriptions are merely specific implementations of this application, but are not intended to limit the scope of protection of this application. Any variation or substitution promptly determined by a technician in the matter in the technical scope disclosed in this order must be covered in the scope of protection of this order. Therefore, the scope of protection of the present invention will be subject to the scope of protection of the claims.

权利要求:
Claims (63)
[1]
1. Communication method, comprising:
determine, by a terminal device, at least one target mode of an air interface technology; and communicating, via the terminal device, with a network device using at least one target mode of air interface technology.
[2]
A method according to claim 1, wherein determining, by a terminal device, at least one target mode of an air interface technology comprises:
receive, by the terminal device, a notification message sent by the network device, where the notification message carries at least one target mode of air interface technology, and at least one target mode of air interface technology is determined by network device from at least one optional mode of air interface technology.
[3]
3. Method according to claim 2, wherein the notification message is system information sent by the network device, and communication with the network device using at least one target mode of air interface technology comprises:
initially access the network device using at least one target mode of air interface technology.
[4]
A method according to claim 3, wherein the system information carries a target mode of an uplink waveform; and the initial access of the network device through the use of at least one target mode of air interface technology comprises:
send message 3 using the target mode of the uplink waveform that is indicated by the system information, to perform initial random access.
[5]
5. Method according to claim 2, wherein the notification message is message 2 of the initial random access, and the communication with the network device using the at least one target mode of the air interface technology comprises :
send message 3 from initial random access to the network device using at least one target mode of interface technology
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2/21 aerial.
[6]
A method according to claim 5, wherein the initial random access message 2 carries at least one target mode of the air interface technology, the at least one target mode of the air interface technology comprises a target mode of an uplink waveform, and sending message 3 from the initial random access to the network device by using at least one target mode of air interface technology comprises:
determining a resource block allocation field content value in the initial random access message 2;
determine a resource location of the initial random access message 3 depending on whether the target mode of the uplink waveform is DFT-S-OFDM discrete Fourier transform spread orthogonal frequency division multiplexing or orthogonal frequency division multiplexing with a cyclic prefix CP-OFDM, where a resource location of the initial random access message 3 which is determined when the target mode of the uplink waveform is DFT-S-OFDM is different from a resource location of the message 3 of the initial random access that is determined when the target mode of the uplink waveform is CP-OFDM; and sending message 3 from initial random access to the network device at the given resource location.
[7]
7. Method according to claim 2, wherein the network device is a target network device to which the terminal device expects to be automatically switched, and the notification message is an automatic switch command.
[8]
8. Method according to claim 2, wherein after the terminal device initially accesses the network device, the notification message is one of the following messages:
a physical layer message, a MAC media access control message, or an RRC radio resource control message.
[9]
A method according to claim 1, wherein determining, by a terminal device, at least one target mode of an air interface technology comprises:
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3/21 select, by the terminal device, at least one target mode of air interface technology from at least one optional mode of air interface technology according to an air interface technology selection policy.
[10]
A method according to claim 9, wherein the method further comprises:
receive system information sent by the network device, where the system information bears the air interface technology selection policy.
[11]
A method according to claim 9 or 10, wherein communication with the network device using the at least one target mode of air interface technology comprises:
send a check notification message to the network device, where the check notification message is used to indicate that the terminal device must communicate with the network device using at least one target mode of the technology. air interface.
[12]
A method according to any one of claims 1 to 11, wherein at least one target mode of air interface technology comprises at least one of the following:
when the air interface technology is a random access mode, the target mode is one of the following: a random access mode from a long term evolution LTE system or a simple random access mode;
when the aerial interface technology is an uplink waveform, the target mode is one of the following: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing mode or an orthogonal frequency division multiplexing mode of scattering of discrete Fourier transform DFT-S-OFDM;
when the air interface technology is an uplink multiple access mode, the target mode is one of the following: a SCMA scarce multiple access mode, a MUSA multiuser shared access mode, a low spread mode code rate, a frequency domain spreading mode, an NCMA non-orthogonal coded multiple access mode, a non-orthogonal multiple access mode
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4/21
NOMA, a PDMA standard split access multiple mode, an RSMA resource spread multiple access mode, an IGMA interleaving grid multiple access mode, a LDS-SVE low density spread signature vector extension mode , a shared access mode based on the low LSSA code and subscription rate, a NOCA non-orthogonal encrypted access mode, an IDMA interleaving split access mode, an RDMA repeat split access mode, or an GOCA orthogonal coded access mode;
when the air interface technology is a modulation scheme, the target mode is one of the following: a QPSK quadratic phase shift switching scheme, a 16 16QAM quadrature amplitude modulation scheme, an amplitude modulation scheme 64 64QAM quadrature, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme, a non-uniform QAM amplitude modulation scheme, higher order modulation in conjunction with MIMO, a modulation scheme encoded, a spatial modulation scheme, a bit mapping scheme for symbol rotation squared amplitude to binary phase shift switching, a bit mapping scheme for symbol rotation quadrature amplitude modulation to displacement switching quadrature phase, or constellation interpolation;
when air interface technology is a duplex mode, the target mode is one of the following: an FDD frequency division duplex mode, a TDD time division duplex mode, a TDD time division duplex mode dynamic, a flexible duplex mode, a full space division duplex mode, or a full band duplex mode;
when air interface technology is an uplink mobile uplink service uplink control channel encoding mode, the target mode is one of the following: a polar code encoding mode, a repetition encoding mode , or a block encoding mode;
when air interface technology is a transmission mode
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5/21 of uplink data inactive, the target mode is one of the following: a concession-free transmission mode or a 2-step random access mode;
when the air interface technology is a subcarrier spacing, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer;
when air interface technology is an interval type, the target mode is one of the following cases in which the interval duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 OFDM orthogonal frequency division multiplexing symbols or the duration of the mini-interval is m OFDM symbols, where ^me t ^1.6 ]; and / or when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 2 symbols OFDM}, {a short link TTI duration
downward: 2 symbols OFDM, an duration in TTI short in link ascending: 4 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 7 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 14 OFDM symbols} or {a TTI duration short in link downward: 7 symbols OFDM, an duration in TTI short in link
ascending: 14 OFDM symbols}.
[13]
13. Communication method, comprising:
determine, by a network device, at least one target mode of an air interface technology; and communicating, via the network device, with a terminal device through the use of at least one target mode of air interface technology.
[14]
14. The method of claim 13, wherein determining, by a network device, at least one target mode of an air interface technology comprises:
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6/21 determine, by the network device, the at least one target mode of the air interface technology from at least one optional mode of the air interface technology; and sending, through the network device, a notification message to the terminal device, wherein the notification message carries at least one target mode of air interface technology.
[15]
15. The method of claim 14, wherein the notification message is system information, so that the terminal device initially and randomly accesses the network device by using at least one target mode of the interface technology. aerial.
[16]
16. The method of claim 15, wherein the system information carries a target mode used for an uplink waveform, so that the terminal device sends message 3 in the uplink waveform target mode. which is indicated by the system information, to perform initial random access.
[17]
17. The method of claim 14, wherein the notification message is an initial random access message 2, so that the terminal device sends message 3 from the initial random access to the network device based on at least one target mode of air interface technology.
[18]
18. The method of claim 15, wherein the network device is a target network device to which the terminal device expects to be automatically switched, and the notification message is an automatic switch command message.
[19]
19. The method of claim 14, wherein after the terminal device accesses the network device, the notification message is one of the following messages:
a physical layer message, a MAC media access control message, or an RRC radio resource control message.
[20]
20. Method according to any one of claims 13 to 19, wherein the at least one target mode of air interface technology comprises at least one of the following:
when air interface technology is a random access mode, the target mode is one of the following: a random access mode
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7/21 of an LTE long-term evolution system or a simple random access mode;
when the aerial interface technology is an uplink waveform, the target mode is one of the following: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing mode or an orthogonal frequency division multiplexing mode of scattering of discrete Fourier transform DFT-S-OFDM;
when air interface technology is an uplink multiple access mode, the target mode is one of the following: a SCMA scarce multiple access mode, a MUSA multiuser shared access mode, a low spread mode code rate, a frequency domain spreading mode, an NCMA non-orthogonal encoded multiple access mode, a NOMA non-orthogonal multiple access mode, a PDMA standard split access multiple mode, a multiple spreading access mode RSMA feature, a multi-access mode by IGMA interleaving grid, a LDS-SVE low density spread vector signature mode, a shared access mode based on the low code rate and LSSA signature, a NOCA non-orthogonal coded access, an IDMA interleaving split access multiple mode, an RDMA repeat split access multiple mode, or an access mode the orthogonal coded GOCA group;
when the air interface technology is a modulation scheme, the target mode is one of the following: a QPSK quadratic phase shift switching scheme, a 16 16QAM quadrature amplitude modulation scheme, an amplitude modulation scheme 64 64QAM quadrature, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme, a non-uniform QAM amplitude modulation scheme, higher order modulation in conjunction with MIMO, a modulation scheme coded, a spatial modulation scheme, a bit mapping scheme for symbol rotation squared amplitude to binary phase shift switching, a bit mapping scheme for symbol rotation quadrature amplitude modulation to shift switching phase in
Petition 870190068748, of 7/19/2019, p. 50/64
8/21 quadrature, or constellation interpolation;
when air interface technology is a duplex mode, the target mode is one of the following: an FDD frequency division duplex mode, a TDD time division duplex mode, a TDD time division duplex mode dynamic, a flexible duplex mode, a full space division duplex mode, or a full band duplex mode;
when air interface technology is an uplink mobile uplink service uplink control channel encoding mode, the target mode is one of the following: a polar code encoding mode, a repetition encoding mode , or a block encoding mode;
when the air interface technology is an inactive uplink data transmission mode, the target mode is one of the following: a concession-free transmission mode or a 2-step RACH random access mode;
when the air interface technology is a subcarrier spacing, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer;
when air interface technology is an interval type, the target mode is one of the following cases in which the interval duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 OFDM orthogonal frequency division multiplexing symbols, or the mini-interval duration is m OFDM symbols, where HA !; θ / or when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 2 symbols OFDM}, {a short link TTI duration
downward: 2 symbols OFDM, an duration in TTI short in link ascending: 4 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 7 symbols OFDM, an duration in TTI short in link
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Upward 9/21: 7 OFDM symbols}, {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 14 OFDM symbols} or {a short downlink TTI duration: 7 symbols OFDM, a short uplink TTI duration: 14 OFDM symbols}.
[21]
21. A communications apparatus, comprising a determination unit, wherein the determination unit is configured to determine at least one target mode of an air interface technology; and a sending unit, in which the sending unit is configured to communicate with a network device using at least one target mode of air interface technology.
[22]
22. Communications apparatus according to claim 21, wherein the determination unit is specifically configured for:
receiving a notification message sent by the network device, where the notification message carries at least one target mode of air interface technology, and at least one target mode of air interface technology is determined by the network device from at least one optional mode of air interface technology.
[23]
23. Communications apparatus according to claim 22, wherein the notification message is system information sent by the network device, and the sending unit is specifically configured to:
initially access the network device using at least one target mode of air interface technology.
[24]
24. A communications apparatus according to claim 23, wherein the system information carries a target mode of an uplink waveform; and the sending unit is specifically configured to send message 3 using the target mode of the uplink waveform that is indicated by the system information, to perform initial random access.
[25]
25. Communications apparatus according to claim 22, wherein the notification message is an initial random access message 2, and the sending unit is specifically configured for:
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10/21 send message 3 from initial random access to the network device using at least one target mode of air interface technology.
[26]
26. A communications apparatus according to claim 25, wherein the initial random access message 2 carries at least one target mode of the air interface technology, the at least one target mode of the air interface technology comprises a target mode of an uplink waveform, and the sending unit is further specifically configured to:
determining a resource block allocation field content value in the initial random access message 2;
determine a resource location of the initial random access message 3 depending on whether the target mode of the uplink waveform is DFT-S-OFDM discrete Fourier transform spread orthogonal frequency division multiplexing or orthogonal frequency division multiplexing with a cyclic prefix CP-OFDM, where a resource location of the initial random access message 3 which is determined when the target mode of the uplink waveform is DFT-S-OFDM is different from a resource location of the message 3 of the initial random access that is determined when the target mode of the uplink waveform is CP-OFDM; and sending message 3 from initial random access to the network device at the given resource location.
[27]
27. Communications device according to claim 22, wherein the communications device is a target network device to which the terminal device expects to be switched automatically, and the notification message is an automatic switch command.
[28]
28. Communications apparatus according to claim 22, wherein the notification message is one of the following messages:
a physical layer message, a MAC media access control message, or an RRC radio resource control message.
[29]
29. Communications apparatus according to claim 21, wherein the determination unit is specifically configured for:
select at least one target mode of air interface technology from at least one optional mode of air interface technology
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11/21 according to an air interface technology selection policy.
[30]
The communications apparatus according to claim 29, wherein the communications apparatus further comprises:
a receiving unit, where the receiving unit is specifically configured to receive system information sent by the network device, where the system information bears the air interface technology selection policy.
[31]
31. Communications apparatus according to claim 29 or 30, wherein the sending unit is specifically configured for:
send a check notification message to the network device, where the check notification message is used to indicate that the communications device must communicate with the network device using at least one technology target mode overhead interface.
[32]
32. Communications apparatus according to any one of claims 21 to 31, in which at least one target mode of air interface technology comprises at least one of the following:
when air interface technology is a random access mode, the target mode is one of the following: a random access mode from an LTE Long Term Evolution system or a simple random access mode;
when the aerial interface technology is an uplink waveform, the target mode is one of the following: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing mode or an orthogonal frequency division multiplexing mode of scattering of discrete Fourier transform DFT-S-OFDM;
when air interface technology is an uplink multiple access mode, the target mode is one of the following: a SCMA scarce multiple access mode, a MUSA multiuser shared access mode, a low spread mode code rate, a frequency domain spreading mode, an NCMA non-orthogonal encoded multiple access mode, a NOMA non-orthogonal multiple access mode, a PDMA standard split access multiple mode, a multiple spreading access mode RSMA feature, a multiple access mode by IGMA interleaving grid, a vector extension mode of
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12/21 LDS-SVE low density spread signature, a shared access mode based on the low code rate and LSSA signature, a NOCA non-orthogonal encrypted access mode, an IDMA interleaving multiple access mode, a multiple access mode by RDMA repetition division, or a GOCA group orthogonal coded access mode;
when the air interface technology is a modulation scheme, the target mode is one of the following: a QPSK quadratic phase shift switching scheme, a 16 16QAM quadrature amplitude modulation scheme, an amplitude modulation scheme 64 64QAM quadrature, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme, a non-uniform QAM amplitude modulation scheme, higher order modulation in conjunction with MIMO, a modulation scheme encoded, a spatial modulation scheme, a bit mapping scheme for symbol rotation squared amplitude to binary phase shift switching, a bit mapping scheme for symbol rotation quadrature amplitude modulation to displacement switching quadrature phase, or constellation interpolation;
when air interface technology is a duplex mode, the target mode is one of the following: an FDD frequency division duplex mode, a TDD time division duplex mode, a TDD time division duplex mode dynamic, a flexible duplex mode, a full space division duplex mode, or a full band duplex mode;
when air interface technology is an uplink mobile uplink service uplink control channel encoding mode, the target mode is one of the following: a polar code encoding mode, a repetition encoding mode , or a block encoding mode;
when the air interface technology is an inactive uplink data transmission mode, the target mode is one of the following: a concession-free transmission mode or a 2-step random access;
when the air interface technology is a spacing of
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13/21 subcarrier, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer;
when air interface technology is an interval type, the target mode is one of the following cases in which the interval duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 OFDM orthogonal frequency division multiplexing symbols, or the duration of the mini-interval is m OFDM symbols, where ^me t ^1.6 ]; and / or when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 2 symbols OFDM}, {a short link TTI duration
downward: 2 symbols OFDM, an duration in TTI short in link ascending: 4 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 7 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 14 OFDM symbols} or {a TTI duration short in link downward: 7 symbols OFDM, an duration in TTI short in link
ascending: 14 OFDM symbols}.
[33]
33. Communications apparatus, comprising a determination unit, in which the determination unit is configured to determine at least one target mode of an air interface technology; and a sending unit, wherein the sending unit is configured to communicate with a terminal device by using at least one target mode of air interface technology.
[34]
34. Communications apparatus according to claim 33, wherein the determination unit is specifically configured for:
determining at least one target mode of air interface technology from at least one optional mode of air interface technology; and
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14/21 send a notification message to the terminal device, in which the notification message carries at least one target mode of air interface technology.
[35]
35. Communications apparatus according to claim 34, wherein the notification message is system information, so that the terminal device initially and randomly accesses the communications apparatus through the use of at least one target mode of the technology overhead interface.
[36]
36. A communications apparatus according to claim 35, wherein the system information carries a target mode used for an uplink waveform, so that the terminal device sends a message 3 in the target mode of the waveform of uplink that is indicated by the system information, to perform initial random access.
[37]
37. The communications apparatus according to claim 34, wherein the notification message is an initial random access message 2, so that the terminal device sends message 3 from the initial random access to the communications apparatus based on the hair. least one target mode of air interface technology.
[38]
38. Communications apparatus according to claim 37, wherein the communications apparatus is a target communications apparatus to which the terminal device expects to be switched automatically, and the notification message is an automatic switch command message.
[39]
39. Communications apparatus according to claim 34, wherein the notification message is one of the following messages:
a physical layer message, a MAC media access control message, or an RRC radio resource control message.
[40]
40. Communications apparatus according to any one of claims 33 to 39, wherein the at least one target mode of air interface technology comprises at least one of the following:
when air interface technology is a random access mode, the target mode is one of the following: a random access mode from an LTE Long Term Evolution system or a simple random access mode;
when air interface technology is a waveform of
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15/21 uplink, the target mode is one of the following: a CP-OFDM cyclic prefix orthogonal frequency division multiplexing mode or a DFT-S discrete Fourier transform spreading orthogonal frequency division multiplexing mode. -OFDM;
when air interface technology is an uplink multiple access mode, the target mode is one of the following: a SCMA scarce multiple access mode, a MUSA multiuser shared access mode, a low spread mode code rate, a frequency domain spreading mode, an NCMA non-orthogonal encoded multiple access mode, a NOMA non-orthogonal multiple access mode, a PDMA standard split access multiple mode, a multiple spreading access mode RSMA feature, a multi-access mode by IGMA interleaving grid, a LDS-SVE low density spread vector signature mode, a shared access mode based on the low code rate and LSSA signature, a NOCA non-orthogonal coded access, an IDMA interleaving split access multiple mode, an RDMA repeat split access multiple mode, or an access mode the orthogonal coded GOCA group;
when the air interface technology is a modulation scheme, the target mode is one of the following: a QPSK quadratic phase shift switching scheme, a 16 16QAM quadrature amplitude modulation scheme, an amplitude modulation scheme 64 64QAM quadrature, a 256 256QAM quadrature amplitude modulation scheme, a constellation mapping between subcarriers scheme, a non-uniform QAM amplitude modulation scheme, higher order modulation in conjunction with MIMO, a modulation scheme encoded, a spatial modulation scheme, a bit mapping scheme for symbol rotation squared amplitude to binary phase shift switching, a bit mapping scheme for symbol rotation quadrature amplitude modulation to displacement switching quadrature phase, or constellation interpolation;
when the air interface technology is a duplexing mode, the target mode is one of the following: a split division duplexing mode
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16/21 FDD frequency, a TDD time division duplex mode, a dynamic TDD time division duplex mode, a flexible duplex mode, a space division full duplex mode, or a full duplex mode in band;
when air interface technology is an uplink mobile uplink service uplink control channel encoding mode, the target mode is one of the following: a polar code encoding mode, a repetition encoding mode , or a block encoding mode;
when the air interface technology is an inactive uplink data transmission mode, the target mode is one of the following: a concession-free transmission mode or a 2-step random access mode;
when the air interface technology is a subcarrier spacing, the target mode is one of the following: 15 kHz * 2 ⁿ , where n is an integer;
when air interface technology is an interval type, the target mode is one of the following cases in which the interval duration is 7 OFDM orthogonal frequency division multiplexing symbols or 14 OFDM orthogonal frequency division multiplexing symbols, or the duration of the mini-interval is m OFDM symbols, where; θ / or when the air interface technology is a TTI transmission duration, the target mode is one of the following: {a short downlink TTI duration: 2 OFDM symbols, a short uplink TTI duration: 2 symbols OFDM}, {a short link TTI duration
downward: 2 symbols OFDM, an duration in TTI short in link ascending: 4 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 7 symbols OFDM, an duration in TTI short in link ascending: 7 symbols OFDM}, {an duration in TTI short in link downward: 2 symbols OFDM, an duration in TTI short in link ascending: 14 symbols OFDM} or {a TTI duration short in link
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17/21 descending: 7 OFDM symbols, a short TTI duration of uplink: 14 OFDM symbols}.
[41]
41. Communication method, comprising:
receive, by a terminal device, system information sent by a network device, in which the system information bears a first target mode which is an air interface technology or an uplink waveform and which is selected by the network device;
perform, by the terminal device, initial random access based on the first target mode which is of the air interface technology or the uplink waveform and which is selected by the network device;
receiving, by the terminal device, a message from the network device, in which the message carries a second target mode which is of the air interface technology or the uplink waveform and which is selected by the network device for the device terminal; and communicating, via the terminal device, with the network device based on the second target mode of the air interface technology or the uplink waveform.
[42]
42. Communication method according to claim 41, wherein the message from the network device is any one of the following: a physical layer PHY message, a MAC media access control message, and a message RRC radio resource control.
[43]
43. Communication method, comprising:
send, through a network device, system information to a terminal device, where the system information carries a first target mode which is an air interface technology or an uplink waveform and which is selected by the device network, in which the first target mode of the air interface technology or the uplink waveform is used by the terminal device to perform initial random access; and sending, through the network device, a message to the terminal device, in which the message carries a second target mode which is of the air interface technology or the uplink waveform and which is selected by the network device to the device terminal, and the second target mode of air interface technology or link waveform
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Ascending 18/21 is used by the terminal device to communicate with the network device.
[44]
44. A communication method according to claim 43, wherein the message sent by the network device to the terminal device is any one of the following: a PHY physical layer message, a MAC media access control message, and an RRC radio resource control message.
[45]
45. The communication method according to any one of claims 41 to 44, wherein the first target mode of the air interface technology or the uplink waveform is any one of the following: a split-division multiplexing mode orthogonal frequency with cyclic prefix and a discrete Fourier transform scattering orthogonal frequency division multiplexing mode.
[46]
46. The communication method according to any one of claims 41 to 44, wherein the second target mode of the air interface technology or the uplink waveform is any one of the following: a mode of division multiplexing orthogonal frequency with cyclic prefix and a discrete Fourier transform scattering orthogonal frequency division multiplexing mode.
[47]
47. Communication method according to any one of claims 41 to 46, in which the system information is sent in a broadcast mode.
[48]
48. Communications apparatus, in which the communications apparatus comprises a first unit, a second unit, a third unit, and a fourth unit, in which the first unit is configured to receive system information sent by a network device, in that the system information carries a first target mode which is an aerial interface technology or an uplink waveform and which is selected by the network device;
the second unit is configured to perform initial random access based on the first target mode which is of the air interface technology or the uplink waveform and which is selected by the network device; and
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19/21 the third unit is configured to receive a message from the network device, in which the message carries a second target mode which is of the air interface technology or the uplink waveform and which is selected by the network to the communications device, and the fourth unit is configured to communicate with the network device based on the second target mode of the air interface technology or the uplink waveform.
[49]
49. Communications apparatus according to claim 48, wherein the message from the network device is any one of the following: a physical layer PHY message, a MAC media access control message, and a message RRC radio resource control.
[50]
50. A communications apparatus according to claim 48 or 49, wherein the first target mode of aerial interface technology or the uplink waveform is any of the following: an orthogonal frequency division multiplexing mode with cyclic prefix and a discrete Fourier transform scattering orthogonal frequency division multiplexing mode.
[51]
51. The communications apparatus according to claim 48 or 49, wherein the second target mode of the air interface technology or the uplink waveform is any of the following: an orthogonal frequency division multiplexing mode with cyclic prefix and a discrete Fourier transform scattering orthogonal frequency division multiplexing mode.
[52]
52. Communication apparatus according to any one of claims 48 to 51, wherein the system information is sent in a broadcasting mode.
[53]
53. Communications apparatus, comprising a fifth unit and a sixth unit, in which the fifth unit is configured to send system information to a terminal device, in which the system information carries a first target mode which is an interface technology overhead or an uplink waveform and that is selected by the communications device, and the first target mode of air interface technology or uplink waveform is used by the terminal device to
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20/21 perform initial random access; and the sixth unit is configured to send a message to the terminal device, where the message carries a second target mode which is of the air interface technology or of the uplink waveform and which is selected by the communications device for the device terminal, and the second target mode of air interface technology or uplink waveform is used by the terminal device to communicate with the communications device.
[54]
54. Communications device according to claim 53, wherein the message sent by the communications device to the terminal device is any one of the following: a PHY physical layer message, a MAC media access control message, and an RRC radio resource control message.
[55]
55. A communications apparatus according to claim 53 or 54, wherein the first target mode of aerial interface technology or uplink waveform is any of the following: an orthogonal frequency division multiplexing mode with cyclic prefix and a discrete Fourier transform scattering orthogonal frequency division multiplexing mode.
[56]
56. A communications apparatus according to claim 53 or 54, wherein the second target mode of the air interface technology or the uplink waveform is any one of the following: an orthogonal frequency division multiplexing mode with cyclic prefix and a discrete Fourier transform scattering orthogonal frequency division multiplexing mode.
[57]
57. Communications apparatus according to any one of claims 53 to 56, wherein the system information is sent in a broadcasting mode.
[58]
58. Communications apparatus, wherein the communications apparatus comprises a processor, and when an instruction is carried out by the processor, the communications apparatus performs the method as defined in any one of claims 1 to 20, and 41 to 47.
[59]
59. Communications device, where the communications device is configured to perform the method as defined in any of the
Petition 870190068748, of 7/19/2019, p. 63/64
21/21 claims 1 to 12, and 41 to 47.
[60]
60. Communications system, wherein the communications system comprises the communications apparatus as defined in any one of claims 21 to 40, and 48 to 59.
[61]
61. Computer program storage media, wherein the computer program storage media comprises an instruction, and when the instruction is directly or indirectly executed, functions of the method as defined in any of claims 1 to 20, and 41 to 47 are implemented.
[62]
62. System chip, wherein the system chip comprises a processor, and when an instruction is executed by the processor, functions of the method as defined in any of claims 1 to 20, and 41 to 47 are implemented.
[63]
63. Computer program product, in which the computer program product comprises an instruction, and when the instruction is directly or indirectly executed, functions of the method as defined in any one of claims 1 to 20, and 41 to 47 are implemented .

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