method and apparatus for transmitting information

专利摘要:
the present invention relates to a method of transmitting information, comprising: a first communication node determining a resource or parameter used by a second communication node to send a reference signal; indicating the resource or parameter to the second communication node via signaling; the second communication node receiving the signaling sent by the first communication node; determining, in accordance with the signaling, or in accordance with the signaling and a rule agreed with the first communication node, a resource or parameter used to send the reference signal; and send the reference signal using the given resource or parameter.
公开号:BR112019025982A2
申请号:R112019025982-1
申请日:2018-08-22
公开日:2020-07-07
发明作者:Yuxin Wang；Chuangxin JIANG；Shujuan Zhang；Zhaohua Lu；Yu Ngok Li
申请人:Zte Corporation；
IPC主号:

专利说明:

[0001] [0001] This application claims priority to Chinese Patent Application Number 201710939835.7 filed September 30, 2017, the disclosure of which is incorporated herein by reference in its entirety. FIELD OF TECHNIQUE
[0002] [0002] The present description pertains to, but is not limited to, the field of communications. FUNDAMENTALS
[0003] [0003] In Long Term Evolution (LTE for short), a physical downlink control channel (PDCCH for short) is used to support uplink and downlink scheduling information and uplink power control information. Downlink control information (DCI for short) formats include DCI 0, 1, 1A, 1B, 1C, 1D, 2, 2A, 3, 3A, etc. And later DCI formats 2B, 2C and 2D are added to an LTE-A developed Release 12 to support a variety of different applications and transmission modes. A base station (e-Node-B, eNB for short) can configure a user equipment (UE for short) via the downlink control information, or the UE is configured by the high layer, which is also referred to as being configured with the high-level signaling.
[0004] [0004] A polling reference signal (abbreviated SRS) is a signal used between the UE and eNB to measure radio channel status information (abbreviated CSI). In the LTE system, the UE periodically transmits an uplink SRS on the last data symbol of a transmission subframe according to parameters, indicated by the eNB, such as a frequency band, a frequency domain position, a cyclic shift. sequence, a period, and a subframe offset. The eNB determines the UE uplink CSI according to the received SRS, and performs operations such as frequency domain selection programming, closed-loop power control according to the obtained CSI.
[0005] [0005] In a study of LTE-A Release 10 (LTE-A Release 10), it is proposed that in uplink communication, a non-pre-coded SRS, i.e., an antenna-specific SRS must be used, while a signal demodulation reference (abbreviated DMRS) used for demodulation on a physical uplink shared channel (abbreviated PUSCH) is pre-coded. The eNB can estimate the original uplink CSI by receiving the non-precoded SRS, while it cannot estimate the original uplink CSI through the pre-coded DMRS. At this time, when the UE transmits the non-precoded SRS using multiple antennas, more SRS resources are required by each UE, which results in a decrease in the number of UEs that can be simultaneously reused in the system. The UE can transmit the SRS in two trigger modes, that is, via high-layer signaling (also referred to as type 0 trigger) or downlink control information (also referred to as type 1 trigger). A periodic SRS is triggered based on high-layer signaling, and a non-periodic SRS is triggered based on downlink control information. In LTE-A Release 10, a non-periodic SRS transmission mode is added, which improves the utilization rate of SRS resources to a certain degree and improves resource scheduling flexibility.
[0006] [0006] With the development of communication technologies, the demand for data services is growing and low frequency carriers available are scarce. Therefore, high-frequency (30 GHz to 300 GHz) carrier communication, which has not been fully utilized, has become an important communication mode to achieve high-speed data communication in the future. High-frequency carrier communication has a large available bandwidth and can provide effective high-speed data communication. However, a major technical challenge for high frequency carrier communication is that high frequency signals are significantly attenuated in space compared to low frequency signals. Although this causes spatial attenuation losses when high frequency signals are used for external communication, the shorter wavelength of high frequency signals usually allows for more antennas to be used. Therefore, communication is implemented on a beam basis to compensate for spatial attenuation losses.
[0007] [0007] However, as the number of antennas increases, each antenna needs a set of radio frequency connections, and digital beamforming thus creates an increase in costs and a loss in power. Therefore, current studies tend towards hybrid beamforming, that is, a final beam formed by radio frequency beams together with digital beams.
[0008] [0008] In a study of new radio access technology (abbreviated NR) for high frequency communication system, the eNB is configured with a large number of antennas to form downlink transmission beams to compensate for spatial attenuation of the high frequency communication, and the UE is also configured with a large number of antennas to form uplink transmission beams. At this time, the SRS is also transmitted in the form of a beam. In a future study of new radio access technology, the eNB can configure different portions of bandwidth (abbreviated BWP) for each user, and the bandwidth occupied by a user's BWP may be greater than the bandwidth of 20
[0009] [0009] The following is a summary of the subject described here in detail. This summary is not intended to limit the scope of the claims.
[0010] [0010] Embodiments of the present application provide an information transmission method and apparatus for implementing a configuration of a reference signal transmission in an NR system.
[0011] [0011] In a first aspect, an embodiment of the present application provides a method of transmitting information, which includes:
[0012] [0012] determining, by a first communication node, a resource or parameter for a second communication node to transmit a reference signal; and
[0013] [0013] indicate the resource or parameter to the second communication node through signaling.
[0014] [0014] In a second aspect, an embodiment of the present application provides a method of transmitting information, which includes:
[0015] [0015] receiving, by a second communication node, the signaling transmitted by a first communication node;
[0016] [0016] determine, a resource or parameter to transmit a signal-based or signal-based reference signal and a predefined rule by the first communication node and the second communication node; and
[0017] [0017] use the resource or parameter to transmit the reference signal.
[0018] [0018] In a third aspect, an embodiment of the present order provides a method of transmitting information, which includes:
[0019] [0019] determine, by a first communication node, a first level parameter and a second level parameter of a reference signal resource, where the first level parameter includes at least one of: the N1 number of domain symbols of time continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit; and
[0020] [0020] receive, by the first communication node, the reference signal according to the first level parameter and the second level parameter.
[0021] [0021] In a fourth aspect, an embodiment of the present application provides a method of transmitting information, which includes:
[0022] [0022] determine, by a second communication node, a first-level parameter and a second-level parameter of a reference signal resource, where the first-level parameter includes at least one of: the N1 number of domain symbols of time continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit; and
[0023] [0023] transmit, by the second communication node, the reference signal according to the first level parameter and the second level parameter.
[0024] [0024] In a fifth aspect, an embodiment of the present application provides an information transmission apparatus, applied to a first communication node, which includes:
[0025] [0025] a first processing module which is configured to determine a resource or parameter for a second communication node to transmit a reference signal; and
[0026] [0026] a first transmission module, which is configured to indicate the resource or parameter to the second communication node through signaling.
[0027] [0027] In a sixth aspect, an embodiment of the present application provides an information transmission apparatus, applied to a second communication node, which includes:
[0028] [0028] a first receiving module which is configured to receive a signal transmitted by a first communication node;
[0029] [0029] a second processing module, which is configured to determine a resource or parameter to transmit a reference signal based on signaling or based on signaling and a rule predefined by the first communication node and the second processing module; and
[0030] [0030] a second transmission module, which is configured to use the resource or parameter to transmit the reference signal.
[0031] [0031] In a seventh aspect, an embodiment of the present application provides an information transmission apparatus, applied to a first communication node, which includes:
[0032] [0032] a third processing module which is configured to determine a first level parameter and a second level parameter of a reference signal resource, where the first level parameter includes at least one of: the number N1 of time domain symbols continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit; and
[0033] [0033] a second receiving module, which is configured to receive the reference signal according to the first level parameter and the second level parameter.
[0034] [0034] In an eighth aspect, an embodiment of the present application provides an information transmission apparatus, applied to a second communication node, which includes:
[0035] [0035] a fourth processing module, which is configured to determine a first level parameter and a second level parameter of a reference signal resource, where the first level parameter includes at least one of: the number N1 of time domain symbols continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit; and
[0036] [0036] a third transmission module, which is configured to transmit the reference signal according to the first level parameter and the second level parameter.
[0037] [0037] In a ninth aspect, an embodiment of the present application provides a communication node, which includes: a first memory and a first processor, where the first memory is configured to store information transmission programs which when executed by the first processor , implement the steps of the information transmission method described in the first aspect.
[0038] [0038] In a tenth aspect, an embodiment of the present application provides a communication node, which includes: a second memory and a second processor, where the second memory is configured to store information transmission programs which, when executed by the second processor, implement the steps of the information transmission method described in the second aspect.
[0039] [0039] In an eleventh aspect, an embodiment of the present application provides a communication node, which includes: a third memory and a third processor, where the third memory is configured to store information transmission programs which when executed by the third processor, implement the steps of the information transmission method described in the third aspect.
[0040] [0040] In a twelfth aspect, an embodiment of the present application provides a communication node, which includes: a fourth memory and a fourth processor, where the fourth memory is configured to store information transmission programs which when executed by the fourth processor, implement the steps of the information transmission method described in the fourth aspect.
[0041] [0041] In addition, an embodiment of the present application further provides a computer readable medium which is configured to store information transmission programs which, when executed by a processor, implement the steps of the information transmission method described in any of the first through the fourth aspects.
[0042] [0042] In the embodiment of the present application, a first communication node determines a resource or parameter for a second communication node to transmit a reference signal, and indicates the resource or parameter to the second communication node via signaling. The second communication node receives the signaling transmitted by the first communication node, and determines the resource or parameter to transmit the reference signal based on the signaling or based on the signaling and a rule predefined by the first communication node and the second communication node. Communication. In this mode, the design requirements for the reference signal transmission in the NR system are met.
[0043] [0043] In the embodiment of the present application, the first communication node receives the reference signal according to the two-level parameters of the reference signal resource, and the second communication node transmits the reference signal according to the parameters level of the reference signal feature. Through the two-level parameter setting, the control of antenna switching and frequency hopping of the reference signal in the NR system are achieved.
[0044] [0044] Other aspects can be understood after the drawings and detailed description are read and understood. BRIEF DESCRIPTION OF THE DRAWINGS
[0045] [0045] Figure 1 is a flowchart of a method of transmitting information according to an embodiment of the present application;
[0046] [0046] Figure 2 is a flowchart of another method of transmitting information according to an embodiment of the present application;
[0047] [0047] Figure 3 is a flowchart of another method of transmitting information according to an embodiment of the present application;
[0048] [0048] Figure 4 is a flowchart of another method of transmitting information according to an embodiment of the present application;
[0049] [0049] Figure 5 is a schematic diagram 1 of a multi-level bandwidth structure corresponding to a reference signal according to an embodiment of the present application;
[0050] [0050] Figure 6 is a schematic diagram 2 of a multi-level bandwidth structure corresponding to a reference signal according to an embodiment of the present application;
[0051] [0051] Figures 7 (a) to 7 (f) are schematic diagrams showing the frequency domain occupancy of PUCCHs over different time domain symbols;
[0052] [0052] Figures 8(a) to 8(j) are schematic diagrams of an example 7 of the present application;
[0053] [0053] Figure 9 is a schematic diagram of an information transmission apparatus according to an embodiment of the present application;
[0054] [0054] Figure 10 is a schematic diagram of another information transmission apparatus according to an embodiment of the present application;
[0055] [0055] Figure 11 is a schematic diagram of another information transmission apparatus according to an embodiment of the present application;
[0056] [0056] Figure 12 is a schematic diagram of another information transmission apparatus according to an embodiment of the present application;
[0057] [0057] Figure 13 is a schematic diagram of a communication node in accordance with an embodiment of the present application; and
[0058] [0058] Figure 14 is a schematic diagram of another communication node in accordance with an embodiment of the present application. DETAILED DESCRIPTION
[0059] [0059] The embodiments of the present application will be described in detail in conjunction with the drawings, and it is to be understood that the embodiments hereinafter described are intended to describe and explain the present application and not to limit the present application.
[0060] [0060] The steps illustrated in the flowcharts of the drawings can be performed, for example, by a set of computer-executable instructions on a computer system. Although flowcharts illustrate a logical execution order, the illustrated or described steps may, in some cases, be executed in a different order than the one illustrated or described here.
[0061] [0061] Figure 1 is a flowchart of a method of transmitting information according to an embodiment of the present application. As illustrated in Figure 1, the method of transmitting information in the modality may include the steps described below.
[0062] [0062] At S101, a first communication node determines a resource or parameter for a second communication node to transmit a reference signal.
[0063] [0063] In S102, the resource or parameter is indicated to the second communication node through signaling.
[0064] [0064] In the embodiment, the first communication node refers to a node configured to determine a transmission mode of the second communication node and to carry out a signaling indication to the second communication node, and the second communication node refers to up to a node configured to receive the signal. In one implementation mode, the first communication node may be nodes such as a base station of a macro cell, a base station or transmission node of a small cell, a send node in a high frequency communication system, or a sending node in an Internet of Things system, and the second communication node can be nodes in a communication system such as a UE, a mobile phone, a portable device, or a car. In another implementation mode, the base station of a macro cell, the base station or transmission node of a small cell, the sending node in a high-frequency communication system, the sending node in an Internet Things, or the like, can serve as the second communication node, and the UE can serve as the first communication node.
[0065] [0065] In the embodiment, the signaling may include at least one of: radio resource control (RRC) signaling, media access control element (MAC CE) signaling, physical downlink control signaling, or physical layer dynamic control signaling.
[0066] [0066] In embodiment, the reference signal includes one of: an SRS, an uplink demodulation reference signal, a downlink demodulation reference signal, a downlink channel status information (CSI- RS), an uplink phase tracking reference signal (PTRS), and a downlink PTRS. N BWP
[0067] [0067] In mode, it is the bandwidth value of the part UL
[0068] [0068] In an exemplary implementation mode, the resource or parameter at least includes one or more of: a frequency domain start position, a frequency domain end position, a transmission bandwidth, a number of segments, a bandwidth setting index, a bandwidth parameter, a parameter that indicates whether a feature is repeated or the same, an antenna port number or index, a way of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multilevel bandwidth frame, a parameter relative to obtaining the frequency domain start position of the maximum bandwidth of the reference signal in the multiple bandwidth frame levels, or multi-level bandwidth structure information that contains the reference signal.
[0069] [0069] In the modality, the number of segments has the same meaning as N0 , N1 , N 2 , N 3 in the bandwidth configuration table 4a in LTE, or the number of segments can be defined as a ratio of a width transmission bandwidth from a previous level to a transmission bandwidth of a current level in the reference signal tree structure bandwidth configuration.
[0070] [0070] In the modality, the reference signal can be transmitted in at least one of the following modes: a transmit beam, a transmit antenna, a transmit sector, a transmit end precoding, a transmission port indication, antenna, an antenna weight vector indication, an antenna weight matrix indication, a space division multiplexing mode, a frequency domain/time domain transmission diversity mode, a transmission sequence, the number of transmission layers, a transmission model, a modulation and encoding mode, or a reference signal indication.
[0071] [0071] In the mode, the reference signal can be received in at least one of the following modes: a receiving beam; a receiving antenna; a receiving antenna panel; a reception sector; a first beam resource matching mode, where a first beam resource is a beam resource, of the first communication node, indicated in Near Co-Location (QCL) of both the reference signal and an antenna port; or a second beam resource matching mode, where a second beam resource is a beam resource, from the first communication node, indicated in a QCL of both a base reference signal and the antenna port.
[0072] [0072] In an exemplary implementation mode, the step in which a first communication node determines a resource or parameter for a second communication node to transmit a reference signal may include that: the first communication node determines the resource or parameter to the second communication node to transmit the reference signal based on a rule predefined by the first communication node and the second communication node.
[0073] [0073] In an exemplary implementation mode, the step in which a first communication node determines a resource or parameter for a second communication node to transmit a reference signal includes at least one of the steps described below.
[0074] [0074] The first communication node determines a bandwidth configuration index actually used by the second communication node according to at least one of a bandwidth value or the bandwidth configuration index of a part of bandwidth configured for the second communication node.
[0075] [0075] The first communication node determines a set of transmission bandwidth of the reference signal according to the bandwidth setting index of the reference signal.
[0076] [0076] The first communication node determines the transmission bandwidth or the number of segments of the reference signal according to at least one of the bandwidth value, the bandwidth setting index or the width parameter bandwidth of the configured portion of bandwidth for the second communication node.
[0077] [0077] In an exemplary implementation mode, the step in which the first communication node determines a bandwidth configuration index actually used by the second communication node according to at least one of a bandwidth value or the bandwidth configuration index of a configured bandwidth portion for the second communication node includes the step described below.
[0078] [0078] Determining the bandwidth configuration index actually used by the second communication node includes at least one of: 4 ×  N BWP  4  − CSRS
[0079] [0079] (1); 8 ×  N BWP  8  − CSRS
[0080] [0080] (2); 12 ×  N12BWP  − CSRS
[0081] [0081] (3); 16 ×  N16BWP  − CSRS
[0082] [0082] (4); or
[0083] [0083] (5) when a maximum transmission bandwidth of the reference signal that matches the configuration index of
[0084] [0084]   is a round-down function, N BWP is the bandwidth value of the bandwidth part, CSRS is the bandwidth setting index, and the first communication node sets CSRS and N BWP to the second node communicating via the signaling.
[0085] [0085] In an exemplary implementation mode, the step in which the first communication node determines a set of transmission bandwidth of the reference signal according to the bandwidth setting index of the reference signal includes the step described below.
[0086] [0086] When the bandwidth setting index of the reference signal is greater than or equal to 17, or the bandwidth setting index of the reference signal is less than or equal to 14, or the index reference signal bandwidth setting is an integer included in a range from 0 to 31 or from 0 to 63, determine the transmission bandwidth set includes at least one of:
[0087] [0087] (1) 108, 36, 12, 4;
[0088] [0088] (2) 112, 56, 28, 4;
[0089] [0089] (3) 112, 56, 8, 4;
[0090] [0090] (4) 120, 60, 20, 4;
[0091] [0091] (5) 120, 40, 20, 4;
[0092] [0092] (6) 128, 64, 32, 4;
[0093] [0093] (7) 128, 32, 16, 4;
[0094] [0094] (8) 128, 32, 8, 4;
[0095] [0095] (9) 136, 68, 4, 4;
[0096] [0096] (10) 144, 72, 24, 4;
[0097] [0097] (11) 144, 72, 36, 4;
[0098] [0098] (12) 144, 72, 12, 4;
[0099] [0099] (13) 144, 48, 24, 4;
[0100] [0100] (14) 144, 48, 12, 4;
[0101] [0101] (15) 144, 48, 16, 4;
[0102] [0102] (16) 144, 48, 8, 4;
[0103] [0103] (17) 160, 80, 40, 4;
[0104] [0104] (18) 160, 80, 20, 4;
[0105] [0105] (19) 160, 40, 20, 4;
[0106] [0106] (20) 160, 40, 8, 4;
[0107] [0107] (21) 168, 84, 28, 4;
[0108] [0108] (22) 176, 88, 44, 4;
[0109] [0109] (23) 180, 60, 20, 4;
[0110] [0110] (24) 192, 96, 32, 4;
[0111] [0111] (25) 192, 96, 48, 4;
[0112] [0112] (26) 192, 48, 24, 4;
[0113] [0113] (27) 192, 48, 16, 4;
[0114] [0114] (28) 192, 48, 12, 4;
[0115] [0115] (29) 200, 100, 20, 4;
[0116] [0116] (30) 200, 40, 20, 4;
[0117] [0117] (31) 200, 40, 8, 4;
[0118] [0118] (32) 208, 104, 52, 4;
[0119] [0119] (33) 216, 108, 36, 4;
[0120] [0120] (34) 240, 120, 60, 4;
[0121] [0121] (35) 240, 120, 40, 4;
[0122] [0122] (36) 240, 120, 20, 4;
[0123] [0123] (37) 240, 80, 40, 4;
[0124] [0124] (38) 240, 80, 20, 4;
[0125] [0125] (39) 240, 80, 8, 4;
[0126] [0126] (40) 256, 128, 64, 4;
[0127] [0127] (41) 256, 64, 32, 4;
[0128] [0128] (42) 256, 64, 16, 4;
[0129] [0129] (43) 256, 64, 8, 4; or
[0130] [0130] (44) 272, 136, 68, 4.
[0131] [0131] In an exemplary implementation mode, the step in which the first communication node determines the transmission bandwidth or the number of segments of the reference signal according to at least one of the bandwidth value, of the index bandwidth configuration or bandwidth parameter of the configured bandwidth portion for the second communication node is performed in at least one of the following modes, or a set of transmission bandwidth that corresponds to one or more plus bandwidth configuration indexes satisfies one of the following relationships:
[0132] [0132] Mode 1: ( N BWP − 4×CSRS )/ 4 ki = floor ( 2i )
[0133] [0133] Make ,
[0134] [0134] then the transmission bandwidth is: mSRS,0 = 4 × k0 ; 4 × ki+1 , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and ki ∈ Even mSRS,i+1 =  4 , otherwise . Caption: if= if ; and= and; even= even; otherwise= otherwise
[0135] [0135] Mode 2: ( N BWP + 4×CSRS ) / 4 ki = floor ( 2i )
[0136] [0136] Make ,
[0137] [0137] then the transmission bandwidth is: mSRS,0 = 4 × k0 ; 4 × ki +1 , if ((N BWP + 4 × CSRS ) / 4) mod 2i = 0 and k i ∈ Even mSRS,i +1 =  4 , otherwise . Caption: if= if; and= and; even= even; otherwise= otherwise
[0138] [0138] Mode 3:
[0139] [0139] The number of segments is: N0 = 1 ; 2 , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and ki ∈ Even  N i +1 = ki , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and ki ∈ Odd 1 , otherwise  Caption: if= se; and= and; even= even; otherwise= otherwise
[0140] [0140] Mode 4:
[0141] [0141] The transmission bandwidth is ( N BWP − 4×CSRS )/ 4 mSRS ,i = 4 × floor ( 2i ×3 j ×5l ) ; or ( N BWP + 4×CSRS )/ 4 ki = 4 × floor ( 2i ×3 j ×5l ) .
[0142] [0142] Mode 5:
[0143] [0143] The transmit bandwidth is 16 × (N BWP − 16 × CSRS ) /16 /2 , if i < 3 i mSRS,i =  4 , otherwise ; or 16 × (N BWP + 16 × CSRS ) /16 /2 , if i < 3 i mSRS,i = 4 , otherwise . Caption: if= if; otherwise= otherwise
[0144] [0144] Mode 6:
[0145] [0145] The transmit bandwidth is 16 × (N BWP − 16 × CSRS ) /16 /di , if i < 3 mSRS,i =  4 , otherwise ; or
[0146] [0146] is 2 ×3 ×5 , or di is one or more integers in a range from 1 to 17, including 1 and 17, values of i, j and l are non-negative integers, mSRS,i is the transmission bandwidth of the reference signal, floor() is a rounding down function,   is a rounding down function, i = BSRS , BSRS is the width parameter of
[0147] [0147] In an exemplary implementation mode, indicating the resource or parameter to the second communication node via signaling includes the step described below.
[0148] [0148] An offset value from a frequency domain start position that corresponds to a maximum bandwidth in a multilevel bandwidth structure that contains the reference signal relative to a first frequency domain start position is indicated to the second communication node through signaling, where the first frequency domain start position is obtained by the second communication node based on a rule predefined by the first communication node and the second communication node.
[0149] [0149] In an exemplary implementation mode, the method of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multilevel bandwidth structure includes at least one of:
[0150] [0150] (1) ( k0( p ) =  N RB
[0151] [0151] (2) , where the first frequency domain start position is: k1( p ) = ( N RB
[0152] [0152] (3) , where the first frequency domain start position is: k1 = k TC . ( p) ( p) ∆offset PRB
[0153] [0153] is the frequency domain home position offset value that corresponds to the maximum bandwidth in the multilevel bandwidth structure that contains the reference signal relative to the first frequency domain home position and is an integer
[0154] [0154] In an exemplary implementation mode, the method of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multilevel bandwidth structure includes one of:
[0155] [0155] (1);
[0156] [0156] (2);
[0157] [0157] (3);
[0158] [0158] (4) ( k0( p ) =  N RB
[0159] [0159] (5);
[0160] [0160] (6) ( k0( p ) =  N RB
[0161] [0161] (7); or k0( p ) = kTC ( p) + ∆ offset
[0162] [0162] (8); ∆offset PRB
[0163] [0163] is an offset value and an integer in units of
[0164] [0164] In an exemplary implementation mode, a bandwidth of one bth level bandwidths in the multilevel structure containing the reference signal includes one or more one (b+1)th level bandwidths, where b is a non-negative integer.
[0165] [0165] In an exemplary implementation mode, the parameter or a parameter setting range is obtained according to position information of a time domain symbol in a unit of time; or a reference signal feature is located over different time domain symbols in a unit of time, and the parameter or parameter setting range is different
[0166] [0166] In an exemplary implementation mode, the antenna port number or index remains unchanged over M consecutive time domain symbols, where M is an integer greater than 0.
[0167] [0167] In an exemplary implementation mode, when a plurality of resources is indicated via signaling, configuration values or parameter values of the plurality of resources are the same over L consecutive time domain symbols, or configuration values or values parameters of the plurality of resources are different over L consecutive time domain symbols, where L is an integer greater than 0.
[0168] [0168] In an exemplary implementation mode, when a plurality of resources is indicated through signaling, the plurality of resources constitutes a resource set or a resource group, and a parameter of the resource set or resource group is configured to indicate whether the plurality of resources in the resource set or resource group is the same or repeated.
[0169] [0169] In an exemplary implementation mode, when the parameter that indicates whether a resource is repeated or the same has a value of 1 or the state is on, the parameter that indicates whether a resource is repeated or the same indicates that all configuration parameter values of a plurality of SRS resources in a resource set or a group of resources are the same, or that parameter values used to represent transmission beams or antenna ports or frequency domain resources in the plurality of SRS resources are the same, or that the plurality of SRS resources use the same transmit beam or antenna port or frequency domain resource.
[0170] [0170] In an exemplary implementation mode, a plurality of resources is configured to implement at least one function from a group consisting of:
[0171] [0171] switching antennas or transmission ports for a reference signal;
[0172] [0172] transmission of a reference signal over a plurality of time domain resources in the same transmission mode or in the same frequency domain position; and
[0173] [0173] reception over the first communication node of a reference signal transmitted from the second communication node over a plurality of time domain resources in the same reception mode.
[0174] [0174] In an exemplary implementation mode, the number of
[0175] [0175] Figure 2 is a flowchart of a method of transmitting information in accordance with an embodiment of the present application. As illustrated in Figure 2, the method of transmitting information in the modality may include the steps described below.
[0176] [0176] At S201, a second communication node receives a signal transmitted by a first communication node.
[0177] [0177] In S202, a resource or parameter to transmit a reference signal is determined based on the signaling or based on the signaling and a rule predefined by the first communication node and the second communication node.
[0178] [0178] In S203, the resource or parameter is used to transmit the reference signal.
[0179] [0179] In the embodiment, the first communication node refers to a node configured to determine a transmission mode of the second communication node and to perform a signaling indication to the second communication node, and the second communication node refers to up to a node configured to receive the signal. In one implementation mode, the first communication node may be nodes such as a base station of a macro cell, a base station or transmission node of a small cell, a send node in a high frequency communication system, or a sending node in an Internet of Things system, and the second communication node can be nodes in a communication system such as a UE, a mobile phone, a portable device, or a car. In another implementation mode, the base station of a macro cell, the base station or transmission node of a small cell, the sending node in a high-frequency communication system, the sending node in an Internet Things, or the like, can serve as the second communication node, and the UE can serve as the first communication node.
[0180] [0180] In the modality, the signaling may include at least one of: RRC signaling, MAC CE signaling, physical downlink control signaling, or physical layer dynamic control signaling.
[0181] [0181] In mode, the reference signal includes one of: an SRS, an uplink demodulation reference signal, a downlink demodulation reference signal, a CSI-RS, an uplink PTRS, and a downlink PTRS .
[0182] [0182] In an exemplary implementation mode, the resource or parameter includes at least one of: a frequency domain start position, a frequency domain end position, a transmission bandwidth, a number of segments, an index bandwidth configuration, a bandwidth parameter, a parameter configured to indicate whether a resource is repeated or the same, an antenna port number or index, a way of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multilevel bandwidth frame, a parameter relative to getting the frequency domain start position of the maximum bandwidth of the reference signal in the multilevel bandwidth frame , or multilevel bandwidth structure information that contains the reference signal.
[0183] [0183] In an exemplary implementation mode, determining a resource or parameter to transmit a reference signal based on signaling or based on signaling and a rule predefined by the first communication node and the second communication node includes at least one of the steps described below.
[0184] [0184] The second communication node determines a bandwidth configuration index actually used by the second communication node based on at least one of a bandwidth value or the bandwidth configuration index of a part of bandwidth (BWP) configured by signaling to the second communication node and the predefined rule by the first communication node and the second communication node.
[0185] [0185] The second communication node determines a set of transmission bandwidth of the reference signal based on the bandwidth setting index of the reference signal and the rule predefined by the first communication node and the second communication node .
[0186] [0186] The second communication node determines the transmit bandwidth or the number of segments of the reference signal based on at least one of the bandwidth value, the bandwidth setting index or the width parameter bandwidth of the portion of bandwidth configured by the signaling for the second communication node and the predefined rule by the first communication node and the second communication node.
[0187] [0187] In an exemplary implementation mode, the step in which the second communication node determines a bandwidth configuration index actually used by the second communication node based on at least one of a bandwidth value or the bandwidth configuration index of a portion of bandwidth configured by signaling for the second communication node and the rule predefined by the first communication node and the second communication node includes the step described below.
[0188] [0188] Determining the bandwidth configuration index actually used by the second communication node includes at least one of: 4 ×  N BWP  4  − CSRS
[0189] [0189] (1); 8 ×  N BWP  8  − CSRS
[0190] [0190] (2); 12 ×  N12BWP  − CSRS
[0191] [0191] (3); 16 ×  N16BWP  − CSRS
[0192] [0192] (4); or
[0193] [0193] (5) when a maximum transmission bandwidth of the reference signal that corresponds to the configuration index of 4 ×  BWP
[0194] [0194]   is a round-down function, N BWP is the bandwidth value of the bandwidth part, CSRS is the bandwidth setting index, and the first communication node sets CSRS and N BWP to the second node communicating via the signaling.
[0195] [0195] In an exemplary implementation mode, the step in which the second communication node determines a set of transmission bandwidth of the reference signal based on the bandwidth configuration index of the reference signal and the predefined rule by the first communication node and the second communication node includes the step described below.
[0196] [0196] When the bandwidth setting index of the reference signal is greater than or equal to 17, or the bandwidth setting index of the reference signal is less than or equal to 14, or the index reference signal bandwidth setting is an integer comprised in a range from 0 to 31 or from 0 to 63, indicate the transmission bandwidth set includes at least one of:
[0197] [0197] (1) 108, 36, 12, 4;
[0198] [0198] (2) 112, 56, 28, 4;
[0199] [0199] (3) 112, 56, 8, 4;
[0200] [0200] (4) 120, 60, 20, 4;
[0201] [0201] (5) 120, 40, 20, 4;
[0202] [0202] (6) 128, 64, 32, 4;
[0203] [0203] (7) 128, 32, 16, 4;
[0204] [0204] (8) 128, 32, 8, 4;
[0205] [0205] (9) 136, 68, 4, 4;
[0206] [0206] (10) 144, 72, 24, 4;
[0207] [0207] (11) 144, 72, 36, 4;
[0208] [0208] (12) 144, 72, 12, 4;
[0209] [0209] (13) 144, 48, 24, 4;
[0210] [0210] (14) 144, 48, 12, 4;
[0211] [0211] (15) 144, 48, 16, 4;
[0212] [0212] (16) 144, 48, 8, 4;
[0213] [0213] (17) 160, 80, 40, 4;
[0214] [0214] (18) 160, 80, 20, 4;
[0215] [0215] (19) 160, 40, 20, 4;
[0216] [0216] (20) 160, 40, 8, 4;
[0217] [0217] (21) 168, 84, 28, 4;
[0218] [0218] (22) 176, 88, 44, 4;
[0219] [0219] (23) 180, 60, 20, 4;
[0220] [0220] (24) 192, 96, 32, 4;
[0221] [0221] (25) 192, 96, 48, 4;
[0222] [0222] (26) 192, 48, 24, 4;
[0223] [0223] (27) 192, 48, 16, 4;
[0224] [0224] (28) 192, 48, 12, 4;
[0225] [0225] (29) 200, 100, 20, 4;
[0226] [0226] (30) 200, 40, 20, 4;
[0227] [0227] (31) 200, 40, 8, 4;
[0228] [0228] (32) 208, 104, 52, 4;
[0229] [0229] (33) 216, 108, 36, 4;
[0230] [0230] (34) 240, 120, 60, 4;
[0231] [0231] (35) 240, 120, 40, 4;
[0232] [0232] (36) 240, 120, 20, 4;
[0233] [0233] (37) 240, 80, 40, 4;
[0234] [0234] (38) 240, 80, 20, 4;
[0235] [0235] (39) 240, 80, 8, 4;
[0236] [0236] (40) 256, 128, 64, 4;
[0237] [0237] (41) 256, 64, 32, 4;
[0238] [0238] (42) 256, 64, 16, 4;
[0239] [0239] (43) 256, 64, 8, 4; or
[0240] [0240] (44) 272, 136, 68, 4.
[0241] [0241] In an exemplary implementation mode, the step in which the second communication node determines the transmission bandwidth or the number of segments of the reference signal based on at least one of the bandwidth value, of the index the bandwidth configuration parameter or the bandwidth parameter of the bandwidth portion configured by the signaling for the second communication node and the predefined rule by the first communication node and the second communication node is executed in the following modes:
[0242] [0242] Mode 1: ( N BWP − 4×CSRS )/ 4 ki = floor ( 2i )
[0243] [0243] Make ,
[0244] [0244] then the transmission bandwidth is: mSRS,0 = 4 × k0 ;  4 × ki +1 , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and k i ∈ Even mSRS,i +1 =  4 , otherwise . Caption: if= if; and= and; even= even; otherwise= otherwise
[0245] [0245] Mode 2: ( N BWP + 4×CSRS )/ 4 ki = floor ( 2i )
[0246] [0246] Make ,
[0247] [0247] then the transmission bandwidth is: mSRS,0 = 4 × k0 ;  4 × k i +1 , if ((N BWP + 4 × CSRS ) / 4) mod 2i = 0 and k i ∈ Even mSRS,i +1 =  4 , otherwise . Caption: if= if; and= and; even= even; otherwise= otherwise
[0248] [0248] Mode 3:
[0249] [0249] The number of segments is:
[0250] [0250] Mode 4:
[0251] [0251] The transmit bandwidth is 16 × (N BWP − 16 × CSRS ) /16 /2 , if i < 3 i mSRS,i = 4 , otherwise ; or 16 × (N BWP + 16 × CSRS ) /16 /2 , if i < 3 i mSRS,i =  4 , otherwise . Caption: if= if; and= and; even= even; otherwise= otherwise
[0252] [0252] Mode 6:
[0253] [0253] The transmit bandwidth is 16 × (N BWP − 16 × CSRS ) /16 /di , if i < 3 mSRS,i =  4 , otherwise ; or 16 × (N BWP + 16 × CSRS ) /16 /di , if i < 3 mSRS,i =  4 , otherwise . Caption: if= if; otherwise= otherwise i j l di
[0254] [0254] is 2 ×3 ×5 , or di is one or more integers in a range from 1 to 17, including 1 and 17, values of i, j and l are non-negative integers, mSRS,i is the transmission bandwidth of the reference signal, floor() is a rounding down function,   is a rounding down function, i = BSRS , BSRS is the width parameter of
[0255] [0255] In an exemplary implementation mode, determining a resource or parameter to transmit a reference signal based on signaling or based on signaling and a predefined rule by the first communication node and the second communication node includes the steps described below .
[0256] [0256] An offset value from a frequency domain start position that corresponds to the maximum bandwidth in a multi-level bandwidth structure that contains the reference signal relative to a first frequency domain start position is obtained via the signaling or agreed rule, where the first frequency domain start position is obtained by the second communication node based on the rule predefined by the first communication node and the second communication node.
[0257] [0257] In an exemplary implementation mode, the method of calculating an initial frequency domain position of a maximum bandwidth of the reference signal in a multilevel bandwidth structure includes at least one of:
[0258] [0258] (1) ( k0( p ) =  N RB
[0259] [0259] (2) , where the first initial frequency domain position is: k1( p ) = ( N RB
[0260] [0260] ; or k0( p ) = kTC ( p) + ∆ offset
[0261] [0261] (3) , where the first frequency domain start position is: k1 = k TC . ( p) ( p) ∆offset PRB
[0262] [0262] is the frequency domain home position offset value that corresponds to the maximum bandwidth in the multilevel bandwidth structure that contains the reference signal relative to the first frequency domain home position and is an integer
[0263] [0263] In an exemplary implementation mode, the method of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multilevel bandwidth structure includes one of:
[0264] [0264] (1);
[0265] [0265] (2);
[0266] [0266] (3);
[0267] [0267] (4) ( k0( p ) =  N RB
[0268] [0268] (5);
[0269] [0269] (6) ( k0( p ) =  N RB
[0270] [0270] (7); or k0( p ) = kTC ( p) + ∆ offset
[0271] [0271] (8) . ∆offset PRB
[0272] [0272] is an offset value and an integer in units of
[0273] [0273] In an exemplary implementation mode, a bandwidth of one bth level bandwidths in the multilevel structure containing the reference signal includes one or more one (b+1)th level bandwidths, where b is a non-negative integer.
[0274] [0274] In an exemplary implementation mode, the parameter or a parameter setting range is obtained according to position information of a time domain symbol in a unit of time; or a reference signal feature is located over different time domain symbols in a unit of time, and the parameter or parameter setting range is different.
[0275] [0275] In an exemplary implementation mode, the antenna port number or index remains unchanged over M consecutive time domain symbols, where M is an integer greater than 0.
[0276] [0276] In an exemplary implementation mode, when a plurality of resources for transmitting the reference signal is included, configuration values or parameter values of the plurality of resources are the same over L consecutive time domain symbols, or values of configuration or parameter values of the plurality of resources are different over L consecutive time domain symbols, where L is an integer greater than 0.
[0277] [0277] In an exemplary implementation mode, when a plurality of resources for transmitting the reference signal is included, the plurality of resources constitutes a resource set or resource group, and a parameter of the resource set or resource group. resources is set to indicate whether the plurality of resources in the resource set or resource group is the same or repeated.
[0278] [0278] In an exemplary implementation mode, when the parameter that indicates whether a feature is repeated or the same has a value of 1 or the state is on, the parameter that indicates whether a feature is repeated or the same indicates that all configuration parameter values of a plurality of SRS resources in a resource set or a group of resources are the same, or that parameter values used to represent transmission beams or antenna ports or frequency domain resources in the plurality of SRS resources are the same, or that the plurality of SRS resources use the same transmit beam or antenna port or frequency domain resource.
[0279] [0279] Figure 3 is a flowchart of a method of transmitting information in accordance with an embodiment of the present application. As illustrated in Figure 3, the method of transmitting information in the modality may include the steps described below.
[0280] [0280] At S301, a first communication node determines a first level parameter and a second level parameter of a reference signal resource, where the first level parameter includes at least one of: the N1 number of domain symbols of time continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit.
[0281] [0281] At S302, the first communication node receives the reference signal according to the first level parameter and the second level parameter.
[0282] [0282] The antenna ports in an antenna port group are simultaneously broadcast.
[0283] [0283] In an exemplary implementation mode, the step in which the first communication node receives the reference signal according to the first level parameter and the second level parameter includes the step described below.
[0284] [0284] For the reference signal, N1 time domain symbols are first repeatedly received in one frequency domain unit, and then N1 time domain symbols are repeatedly received in another frequency domain unit which is skipped.
[0285] [0285] In an exemplary implementation mode, the step in which the first communication node receives the reference signal according to the first level parameter and the second level parameter includes the step described below.
[0286] [0286] When a plurality of port groups is provided, port group is first used to repeatedly receive N2 time domain symbols and then another port group is used to repeatedly receive N2 time domain symbols.
[0287] [0287] In an exemplary implementation mode, N2 is smaller than N1.
[0288] [0288] In an exemplary implementation mode, over the N1 time domain symbols of a frequency domain unit, different groups of antenna ports are time division multiplexed, and each group of antenna ports continuously receives N2 symbols time domain.
[0289] [0289] In an exemplary implementation mode, the method still includes the step described below.
[0290] [0290] The first communication node indicates the first level parameter and the second level parameter of the reference signal resource to a second communication node via signaling.
[0291] [0291] In an exemplary implementation mode, the number of time domain symbols configured in the reference signal resource is N, N1 is less than or equal to N, and N2 is less than or equal to N.
[0292] [0292] In one mode of implementation of the modality, the first communication node may be nodes such as a base station of a macro cell, a base station or transmit node of a small cell, a sending node in a system of high frequency communication, or a sending node in an Internet of Things system, and the second communication node may be nodes in a communication system such as a UE, a mobile phone, a handheld device, or a car. In another implementation mode, the base station of a macro cell, the base station or transmission node of a small cell, the sending node in a high-frequency communication system, the sending node in an Internet Things, or the like, can serve as the second communication node, and the UE can serve as the first communication node.
[0293] [0293] Figure 4 is a flowchart of a method of transmitting information in accordance with an embodiment of the present application. As illustrated in Figure 4, the method of transmitting information in the modality may include the steps described below.
[0294] [0294] At S401, a second communication node determines a first level parameter and a second level parameter from a reference signal resource, where the first level parameter includes at least one of: the N1 number of domain symbols of time continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna switching switch function A2 of the reference signal in a time domain unit, or a frequency hopping switch function B2 of the reference signal in a time domain unit.
[0295] [0295] At S402, the second communication node transmits the reference signal according to the first level parameter and the second level parameter.
[0296] [0296] The antenna ports in an antenna port group are simultaneously broadcast.
[0297] [0297] In an exemplary implementation mode, the step in which the second communication node transmits the reference signal according to the first level parameter and the second level parameter includes the step described below.
[0298] [0298] For the reference signal, N1 time domain symbols are first repeatedly transmitted in one frequency domain unit, and then N1 time domain symbols are repeatedly transmitted in another frequency domain unit which is skipped.
[0299] [0299] In an exemplary implementation mode, the step in which the second communication node transmits the reference signal according to the first level parameter and the second level parameter includes the step described below.
[0300] [0300] When a plurality of port groups are provided, one port group is first used to repeatedly transmit N2 time domain symbols and then another port group is used to repeatedly transmit N2 time domain symbols.
[0301] [0301] In an exemplary implementation mode, N2 is smaller than N1.
[0302] [0302] In an exemplary implementation mode, over the N1 time domain symbols of a frequency domain unit, different groups of antenna ports are time division multiplexed, and each group of antenna ports continuously transmits N2 symbols time domain.
[0303] [0303] In an exemplary implementation mode, the method still includes the step described below.
[0304] [0304] The second communication node receives signaling whereby a first communication node indicates the first level parameter and the second level parameter of the reference signal resource.
[0305] [0305] In an exemplary implementation mode, the number of time domain symbols configured in the reference signal resource is N, N1 is less than or equal to N, and N2 is less than or equal to N.
[0306] [0306] In one mode of implementation of the modality, the first communication node may be nodes such as a base station of a macro cell, a base station or transmission node of a small cell, a sending node in a system of high-frequency communication, or a sending node in an Internet of Things system, and the second communication node can be nodes in a communication system such as a UE, a mobile phone, a handheld device, or a car. In another implementation mode, the base station of a macro cell, the base station or transmission node of a small cell, the sending node in a high-frequency communication system, the sending node in an Internet Things, or the like, can serve as the second communication node, and the UE can serve as the first communication node.
[0307] [0307] The solution of the present application will be explained below by way of a plurality of examples. Example 1
[0308] [0308] In the example, a first communication node indicates, via signaling, a parameter to a second communication node to transmit an uplink reference signal. Or both the first communication node and the second communication node preset the parameter for the second communication node to transmit the uplink reference signal, e.g. a formula to calculate a transmission bandwidth or the number of transmission segments. an SRS is predefined by the first communication node and the second communication node.
[0309] [0309] In the example, the reference signal is described taking the SRS as an example. The parameter can include at least one of: a bandwidth configuration index, a transmission bandwidth, or a bandwidth parameter.
[0310] [0310] In the example, after receiving the signaling transmitted by the first communication node, the second communication node can determine the transmission bandwidth or the number of SRS segments based on one of the following modes:
[0311] [0311] Mode 1:
[0312] [0312] Make ,
[0313] [0313] then the SRS transmission bandwidth is: mSRS,0 = 4 × k0 ;  4 × ki +1 , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and k i ∈ Even mSRS,i +1 =  4 , otherwise . Caption: if= if; and= and; even= even; otherwise= otherwise
[0314] [0314] Mode 2: ( N BWP + 4×CSRS )/ 4 ki = floor ( 2i )
[0315] [0315] Do ,
[0316] [0316] then the transmission bandwidth is: mSRS,0 = 4 × k0 ;  4 × ki +1 , if ((N BWP + 4 × CSRS ) / 4) mod 2i = 0 and k i ∈ Even mSRS,i +1 =  4 , otherwise . Caption: if= if; and= and; even= even; otherwise= otherwise
[0317] [0317] Mode 3:
[0318] [0318] The number of segments is: N0 = 1 ; 2 , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and ki ∈ Even  N i +1 = ki , if ((N BWP − 4 × CSRS ) / 4) mod 2i = 0 and ki ∈ Odd 1 , otherwise  . Caption: if= if; and= and; even= even; otherwise= otherwise; odd = odd
[0319] [0319] The transmission bandwidth of an i-th level can be determined according to a total bandwidth and the number of segments.
[0320] [0320] Mode 4:
[0321] [0321] The SRS transmission bandwidth is:
[0322] [0322] Mode 5:
[0323] [0323] The transmit bandwidth is 16 × (N BWP − 16 × CSRS ) /16 /2 , if i < 3 i mSRS,i =  4 , otherwise ; or 16 × (N BWP + 16 × CSRS ) /16 /2 , if i < 3 i mSRS,i =  4 , otherwise . Caption: if= if; otherwise= otherwise
[0324] [0324] Mode 6:
[0325] [0325] The transmit bandwidth is 16 × (N BWP − 16 × CSRS ) /16 /di , if i < 3 mSRS,i =  4 , otherwise ; or 16 × (N BWP + 16 × CSRS ) /16 /di , if i < 3 mSRS,i =  4 , otherwise . i j l di
[0326] [0326] is 2 ×3 ×5 , or di is one or more integers in a range from 1 to 17, including 1 and 17, values of i, j and l are non-negative integers, mSRS,i is the transmission bandwidth of the reference signal, floor() is a rounding down function,   is a rounding down function, i = BSRS , BSRS is the width parameter of
[0327] [0327] In the example, a first communication node indicates, through signaling, a parameter to a second communication node to transmit an uplink reference signal. Or both the first communication node and the second communication node preset the parameter for the second communication node to transmit the uplink reference signal, for example, a configuration table of a transmission bandwidth of an SRS is preset by the first communication node and the second communication node.
[0328] [0328] In the example, the reference signal is described taking the SRS as an example. The parameter can include at least one of: a bandwidth setting index, the transmission bandwidth, or a bandwidth parameter.
[0329] [0329] In the example, after receiving signaling from the first communication node, the second communication node can determine the SRS transmission bandwidth according to at least one of NBWP, CSRS and BSRS which are configured with signaling and of according to predefined transmission bandwidth configuration table.
[0330] [0330] For the SRS transmission bandwidth configuration table, the following Table 2a or Table 2b or Table 2c or Table 2d can be referred, where CSRS is the SRS bandwidth configuration index, BSRS is the SRS bandwidth parameter, and NBWP is the bandwidth value of the uplink bandwidth portion. The value of at least one of NBWP , CSRS , and
[0331] [0331] In the example, a first communication node indicates, via signaling, a parameter to a second communication node to transmit an uplink reference signal. Or both the first communication node and the second communication node preset the parameter for the second communication node to transmit the uplink signal, for example, a configuration table of a transmission bandwidth of an SRS is preset by the first node communication and the second communication node.
[0332] [0332] In the example, the reference signal is described taking the SRS as an example. The parameter can include at least one of: a bandwidth setting index, the transmission bandwidth, or a bandwidth parameter.
[0333] [0333] In the example, after receiving signaling from the first communication node, the second communication node can determine the SRS transmission bandwidth according to at least one of CSRS and BSRS that are configured with signaling and according to the default transmission bandwidth configuration table.
[0334] [0334] In the example, for the SRS transmission bandwidth configuration table, the following Table 3a or Table 3b or Table 3c or Table 3d can be referred to, where CSRS is the SRS bandwidth configuration index , and BSRS is the bandwidth parameter of the SRS. The value of at least one of CSRS and BSRS is set by the first communication node to the second communication node via signaling. Table 3a BSRS = 0 BSRS = 1 BSRS = 2 BSRS = 3 CSRS mSRS,0 N0 mSRS,1 N1 mSRS,2 N2 mSRS,3 N3 0 4 1 4 1 4 1 4 1 1 8 1 4 2 4 1 4 1 2 12 1 4 3 4 1 4 1 3 16 1 4 4 4 1 4 1 4 20 1 4 5 4 1 4 1 5 24 1 4 6 4 1 4 1 6 32 1 16 2 8 2 4 2 7 36 1 12 3 4 3 4 1 8 40 1 20 2 4 5 4 1 9 48 1 16 3 8 2 4 2 10 48 1 24 2 12 2 4 3 11 60 1 20 3 4 5 4 1 12 64 1 32 2 16 2 4 4 13 72 1 24 3 12 2 4 3 14 80 1 40 2 20 2 4 5
[0335] [0335] In the example, a first communication node indicates, through signaling, a parameter to a second communication node to transmit an uplink reference signal. Or both the first communication node and the second communication node preset the parameter for the second communication node to transmit the uplink signal, for example, a configuration table of a transmission bandwidth of an SRS is preset by the first node communication and the second communication node.
[0336] [0336] In the example, the reference signal is described taking the SRS as an example. The parameter can include at least one of: a bandwidth setting index, the transmission bandwidth, a bandwidth parameter, or a bandwidth value of a portion of uplink bandwidth.
[0337] [0337] In the example, after receiving signaling from the first communication node, the second communication node determines the transmission bandwidth of the SRS according to at least one of the bandwidth value of a part of bandwidth of uplink, CSRS and
[0338] [0338] When the bandwidth value of the bandwidth part
[0339] [0339] When the bandwidth value of the uplink bandwidth portion is greater than 110 PRBs, Table 4e or Table 4f or Table 4g or Table 4i is used.
[0340] [0340] Table 4a lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 6 ≤ N RB
[0341] [0341] Table 4b lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 6 ≤ N RB
[0342] [0342] Table 4c lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 60 < N RB
[0343] [0343] Table 4d lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 80 < N RB
[0344] [0344] Table 4e lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 110 < N RB
[0345] [0345] Table 4f lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 160 < N RB
[0346] [0346] Table 4g lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 200 < N RB
[0347] [0347] Table 4i lists values of mSRS,b and Nb ( b = 0,1,2,3 ) when 240 < N RB
[0348] [0348] In the example, the first communication node indicates, through signaling, the parameter for the second communication node to transmit the uplink reference signal, where the parameter may include: a frequency domain start position that corresponds to the maximum SRS bandwidth in a multi-level bandwidth structure.
[0349] [0349] For example, the frequency domain home position calculation mode that corresponds to the maximum bandwidth in the multi-level bandwidth structure is indicated by 2-bit physical downlink control signaling or high-layer signaling .
[0350] [0350] Frequency domain home position calculation mode includes at least one of:
[0351] [0351] (1);
[0352] [0352] (2);
[0353] [0353] (3);
[0354] [0354] (4) ( k0( p ) =  N RB
[0355] [0355] (5);
[0356] [0356] (6) ( k0( p ) =  N RB
[0357] [0357] (7); or k0( p ) = kTC ( p) + ∆ offset
[0358] [0358] (8) . ∆offset PRB
[0359] [0359] is an offset value (that is, the number of PRBs offset from the pre-set frequency domain start position).
[0360] [0360] The multilevel bandwidth structure containing the reference signal represents that a bandwidth of one bth level bandwidths includes one or more bandwidths of one (b+1)th level, the which may also be referred to as the tree structure. For example, as shown in Figure 5, a bandwidth of one (b=0)th level includes two bandwidths of one (b=1)th level, and one bandwidth of (b=1)th level includes two bandwidths of a (b=2)th level. In Figure 5, the bandwidth of the bth level always includes 2 bandwidths of the (b+1)th level when b is different. Figure 5 is just an example, and other cases are not excluded, for example, in the multi-level bandwidth structure in Figure 6, a bandwidth of the (b=2)th level corresponds to four bandwidths of the (b=3)th level. Example 6
[0361] [0361] In the example, a first communication node indicates, via signaling, a parameter to a second communication node to transmit an uplink reference signal. Or both the first communication node and the second communication node preset the parameter for the second communication node to transmit the uplink reference signal.
[0362] [0362] The parameter or a parameter setting range is obtained according to position information of a time domain symbol in a unit of time; or a reference signal feature is located over different time domain symbols in a unit of time, and the parameter or parameter setting range is different.
[0363] [0363] SRS parameters about different time domain symbols in a time slot are different (e.g. parameters can be configured at a time domain symbol level), and parameters can include one or more of : a frequency domain length occupied by the SRS, a frequency domain start position of an SRS transmission bandwidth, a frequency domain start position of a tree, a frequency domain end position, a resource of discrete frequency domain, a way of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multi-level bandwidth structure, a relative parameter to obtain the frequency domain start position of the maximum bandwidth of the reference signal in the multi-level bandwidth structure, or configuration information of the multi-level bandwidth structure.
[0364] [0364] The physical uplink control channel (PUCCH) has different lengths, so the frequency domain resources occupied by the PUCCH are different over different time domain symbols. When the SRS time domain symbol positions are different, the corresponding parameters or parameter ranges need to be adjusted. Figure 7 (a) to Figure 7 (f) are different schematic diagrams of the frequency domain positions occupied by the PUCCH over different time domain symbols, and the parameters or parameter ranges of the SRS are obtained according to an index of position of the time domain symbol in a time slot. Parameters may include: the SRS transmission bandwidth over one time domain symbol (that is, the SRS transmission bandwidth may be different over different time domain symbols, similar to the difference in LTE), the frequency domain start position of the SRS transmission bandwidth (that is, the frequency domain start position of the SRS transmission bandwidth may be different over different time domain symbols, similar to the difference in LTE ), a frequency domain start position of a tree (that is, the way of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a similar multi-level bandwidth structure to the description here), a frequency domain ending position (e.g. the frequency domain ending position may be different over different time domain symbols), a frequency domain feature discrete (due to frequency domain fragments caused by the PUCCH, the PRBs occupied by the SRS may be non-contiguous over a time domain symbol, so the sets of PRBs occupied by the SRSs may be different over different time domain symbols ), a parameter relative to obtaining the frequency domain start position of the maximum bandwidth of the reference signal in the multilevel bandwidth structure (as described herein, which may change with the time domain symbol), or multi-level bandwidth configuration information (tree structure parameters are different, e.g. different time domain symbols correspond to different tree structure, where a tree structure can be represented in a similar way in LTE) .
[0365] [0365] In the mode, the parameters or parameter ranges of the reference signal may be different over different time domain symbols, where the SRSs over different time domain symbols may belong to different SRS resources, or they may belong to one SRS feature. A correspondence between a time domain symbol and a parameter (or range of parameters) can be established, and all SRS features that fall on a corresponding time domain symbol can conform to the parameter or range of parameters that corresponds to the time domain symbol. Or a correspondence between different time domain symbols and parameters (or parameter ranges) of an SRS resource is established, and different SRS resources of a user that fall under the same time domain symbol may be different from the above parameters . Example 7
[0366] [0366] In the example, a definition of an SRS resource can be well used to configure SRS parameters. A base station can configure one or more SRS features for a user, and each SRS feature includes a plurality of parameters, such as the number of antenna ports X, a period, a time domain subframe, or slot offset. of time, a comb index, a frequency domain start position, whether a frequency hop exists or whether to perform antenna switching.
[0367] [0367] These parameters are configured with RRC signaling in the LTE system. In the NR system, all parameters can be put into an SRS resource parameter for configuration and are also configured with RRC signaling. As a large number of time domain symbols in a time slot can be used for SRS transmission in the NR system, the SRS resource parameter also includes the number of time domain symbols occupied by the SRS in a time slot N is a time domain symbol position.
[0368] [0368] In LTE, if antenna switching is on, only one antenna port can be mapped onto each time domain symbol. If frequency hopping is on, the SRS will be located over different sub-bands when transmitted continuously. If the SRS resource is configured with N time domain symbols in a time slot, the number of configured antennas is less than N, for example, if N = 4, the number of antennas is 2. If the hop of frequency and antenna switching are turned on at the same time, the antenna and frequency switching will be very frequent, which will increase the complexity of the UE. As shown in Figure 8(a), during SRS transmission, the antenna port needs to be switched 3 times over 4 time domain symbols in one time slot, and the frequency domain position needs to be switched 3 times. s0,
[0369] [0369] To reduce the number of switching times, a new two-level parameter setting can be introduced in the parameter setting of the SRS feature. The first level parameter setting is the number N1 of time domain symbols continuously transmitted by the SRS in the same frequency domain unit. Within N symbols of an SRS resource configuration (defined in a transmission period, that is, in a time slot), the number of symbols continuously transmitted by the SRS in the same frequency domain unit is the value of N1, it does not matter which SRS antenna port is used for transmission. As shown in Figure 8(a), over a subband, as only one time domain symbol is continuously transmitted by the SRS at a time, N1 = 1. As shown in Figures 8(b) and 8(c), over a subband, only two time domain symbols are continuously transmitted by the SRS at a time, so N1 = 2. It should be noted that N1 is the number of time domain symbols continuously transmitted by the SRS in one unit frequency domain without distinguishing the antenna ports.
[0370] [0370] The second level parameter setting is the number of time domain symbols continuously and repeatedly transmitted by any of the SRS ports, and N2 is less than N. N2 refers to the number of time domain symbols continuously and repeatedly transmitted by a group of antenna ports in a frequency domain unit. All antenna ports in an antenna port group occupy the same time domain symbol resource, and may also be located on the same frequency domain unit or on the same subband, but the sequence or comb may be different . As shown in Figure 8(b), each antenna is a group of antenna ports. N1 = 2 and N2 = 2, because each antenna is continuously transmitted twice over a subband. As shown in Figure 8(c), N1 = 2 and N2 = 1, because the number of times each antenna is continuously transmitted over a subband is 1.
[0371] [0371] Therefore, in an SRS resource configuration parameter, any SRS transmission configuration can be achieved by adding two parameters, namely N1 and N2. Thus flexibility is maximized.
[0372] [0372] In a frequency domain unit and over N1 consecutive symbols, N2 time domain symbols are continuously transmitted by one group of antennas, and are not simultaneously transmitted by different groups of antennas. At this time, one or more groups of antennas are continuously transmitted over N1 time domain symbols. As shown in Figure 8(c), an antenna port is a group of antenna ports. At this time, N1 = 2 and N2 = 1, that is, over each subband, each antenna port group is transmitted once, and a time division multiplexing is performed over N1 time domain symbols.
[0373] [0373] When frequency hopping is on, the SRS needs to hop to another subband for transmission after continuously transmitting N1 symbols over a subband. If N1 is less than N, in one time-domain unit, the SRS first repeatedly transmits N1 time-domain symbols in one frequency-domain unit, and then repeatedly transmits N1 time-domain symbols in another domain unit. frequency that is skipped. If N2 is less than N1, over N1 symbols in a frequency domain unit, one group of SRS ports is continuously transmitted N2 times, and then another group of antenna ports is transmitted N2 times until N1 symbols are all occupied. .
[0374] [0374] It should be noted that the N time domain symbols are not necessarily adjacent. An antenna port group can be thought of as a group of antenna ports that can be transmitted simultaneously. For example, if SRS is configured with 4 antennas, ports 0 and 1 are a group, ports 2 and 3 are a group, and user can only transmit one group of antenna ports at a time, it takes 2 times to transmit 4 doors. The port group is also configured by the base station.
[0375] [0375] Any flexible SRS transmission can be achieved based on X, N, N1 and N2 configuration and antenna port group configuration. Other examples are illustrated in Figures 8(d), 8(e), and 8(f). For example, as shown in Figure 8(f), as N2 = 4, a port group 1 (which includes ports 0 and 1) transmits 4 tokens before port group 2 performs transmission. As N1 = 2, the SRS transmits two time domain symbols over subband 0 and then performs a transmission over subband 1.
[0376] [0376] Optionally, the parameter setting of N1 and N2 can be implicitly overridden by other parameters. For example, new parameters G1 and G2 are introduced so that N1 = N / G1, N2 = N / G2. Or N2 = N1 / G2. Or to simplify the complexity of the pattern, N2 can be fixed to a number, no need for configuration, for example N2 = 1.
[0377] [0377] According to the parameter setting of N1 and N2, the frequency hopping definition in LTE 36.211 can be used, and the formula of
[0378] [0378] Similarly, according to the parameter setting of N1 and N2, the antenna switching formula in LTE 36.213 can be used, and it only needs to be simply modified. For an SRS with a total of 2 transmit antennas, and only one antenna port can be transmitted at a time, the new antenna index formula can be changed as follows:
[0379] [0379] a ( nSRS , k ) = ( a LTE ( nSRS ) + k ) mod 2, where k = 0, ... N1 / N2 – 1.
[0380] [0380] The formula is the (nSRS ) in the LTE formula. a(nSRS , k ) represents an index of the transmitted antennas in the kth group among the N1 symbols in the transmission of a(nSRS ) . It is emphasized here that N1 time domain symbols are included in an SRS transmission, the N1 time domain symbols are divided into G2=N/N2 groups, and each group transmits an antenna port, thus k = 0, . .G2-1. If the UE can transmit 2 antenna ports at a time and a total of 4 antenna ports exist, then a broadcast group corresponds to 2 antenna ports. For example, the four antenna ports are divided into two groups, a group of ports 0 includes ports 0 and 1 and a group of ports 1 includes ports 2 and 3, so when k = 0, a(nSRS , k ) = 0 refers to antenna port group 0 transmitted in the kth group and a(nSRS , k )
[0381] [0381] The two-level parameter configuration may further include that: the first level parameter refers to an A1 antenna toggle switch function of the SRS, i.e. a toggle switch between the time slots. If A1 is on, antenna group switching is only performed between time slots and not within a time slot, in which time only one SRS of the antenna group is transmitted in a time slot. If A1 is off, antenna group switching is not performed between time slots. The second level parameter refers to the A2 antenna switching function of the SRS in a time domain unit, i.e. the group of antenna ports switching within a time slot. If A2 is on, different groups of antenna ports in a time slot can be transmitted alternately. As shown in Figure 8(g), both A1 and A2 are connected, and two groups of antenna ports are switched within a time slot and between time slots. As shown in Figure 8(h), A1 is on and A2 is off, so the antenna port group is not switched within a time slot. Thus the complexity of UE can be reduced.
[0382] [0382] The two-level parameter setting may further include that: the first-level parameter refers to a B1 frequency hopping switch function of the SRS, i.e. a frequency hopping between time slots. The second level parameter refers to an SRS frequency hopping switch function B2 within a time slot. If both B1 and B2 are on, the SRS performs frequency hopping both within a time slot and between time slots, as shown in Figure 8(i). If B1 is on and B2 is off, the SRS only performs frequency hopping between time slots, as shown in Figure 8 (j). Thus the complexity of UE can be reduced.
[0383] [0383] In the method described above, in a time slot, an antenna port resource is configured with N symbols, and different antennas can be transmitted over different symbols. For more convenient antenna switching, the following configuration can be implemented: an SRS feature set is configured, where multiple SRS features are included in the set, and each feature corresponds to an antenna port or group of antenna ports from SRS, so the same effect can be achieved. At this time, on an SRS resource, an antenna switch is not allowed, and all antenna ports on a resource are simultaneously broadcast. For example, X resources are configured in the SRS resource set, a resource 0 represents antenna port or antenna port group 0, a resource 1 represents antenna port or port group 1, and a resource X-1 represents an antenna port or group of X-1 antenna ports. If the resource has an ID, the ID can correspond to the SRS Antenna Port Group. If each resource includes X1 antenna ports, the total number of antenna ports is X * X1. The X1 antenna ports that correspond to each resource are a group of antenna ports, and the antennas within a group are broadcast over the same time domain symbol.
[0384] [0384] In the SRS resource set, some parameters configured for all SRS resources are the same, such as a beam ID that indicates the SRS transmission (which corresponds to an ID of an already transmitted SRS resource), the number of time domain symbols included in the resource, a period, SRS transmission bandwidth (similar to CSRS in LTE), BSRS, bhop, power control, and other parameters. Example 8
[0385] [0385] In the example, a first communication node indicates, through signaling, a resource or parameter to a second communication node to transmit a reference signal. Or both the first communication node and the second communication node preset the resource or parameter for the second communication node to transmit the reference signal.
[0386] [0386] The feature or parameter includes at least one of: a parameter that indicates whether a feature is repeated or the same, or an antenna port number or index.
[0387] [0387] Exemplary, the antenna port number or index remains unchanged over M consecutive time domain symbols, where M is an integer greater than 0.
[0388] [0388] Exemplaryly, configuration values or parameter values of a plurality of resources are the same over L consecutive time domain symbols, or configuration values or parameter values of the plurality of resources are different over L time domain symbols consecutive, where L is an integer greater than 0.
[0389] [0389] For example, the plurality of resources constitutes a resource set or a resource group, and a resource set or resource group parameter is set to indicate whether the resource plurality in the resource set or in the resource group is the same or repeated.
[0390] [0390] For example, the first communication node configures a resource pool or resource group for the second communication node. The resource set or resource group includes one or more resources, and simultaneously includes a parameter that indicates whether a resource is repeated or the same. This parameter is assumed to be SRS_Resource_Repetition. If the SRS_ Resource_Repetition parameter has a value of 1 or the state is on, a plurality of SRS resources in the SRS resource pool or resource group are indicated to be the same or repeated; if the SRS_ Resource_Repetition parameter has a value of 0 or the state is off, the SRS resources in the SRS resource pool or resource group are not indicated to be the same or repeated. If the plurality of SRS resources in the SRS resource pool or resource group is the same or repeated, all parameter configuration values of the plurality of SRS resources are indicated to be the same, or parameter values used to represent bundles transmission or antenna ports or frequency domain resources in the plurality of SRS resources are indicated to be the same, or the plurality of SRS resources is indicated to use the same transmit beam or antenna port or frequency domain resource .
[0391] [0391] For example, a resource set or resource group includes two SRS resources, which are marked as an SRS resource 1 and an SRS resource 2. When the SRS resources are indicated to be the same, all Parameter setting values in SRS Resource 1 and SRS Resource 2 are the same, or SRS Resource 1 and SRS Resource 2 use the same transmit beam or antenna port or frequency domain resource. When the SRS features are indicated to be different, either all the parameter setting values on the SRS feature 1 and the SRS feature 2 are different, or the SRS feature 1 and the SRS feature 2 use different transmit beams or ports antenna or frequency domain resources.
[0392] [0392] Figure 9 is a schematic diagram of an information transmission apparatus in accordance with an embodiment of the present application. As shown in Figure 9, the embodiment provides an information transmission apparatus, applied to a first communication node, which includes a first processing module 901 and a first transmission module 902.
[0393] [0393] The first processing module 901 is configured to determine a resource or parameter for a second communication node to transmit a reference signal.
[0394] [0394] The first transmission module 902 is configured to indicate the resource or parameter to the second communication node through signaling.
[0395] [0395] The resource or parameter at least includes one or more of: a frequency domain start position, a frequency domain end position, a transmission bandwidth, a number of segments, a bandwidth configuration index bandwidth, a bandwidth parameter, a parameter indicating whether a resource is repeated or the same, an antenna port number or index, a way of calculating a frequency domain start position of a maximum bandwidth of the reference signal in a multilevel bandwidth structure, a parameter relative to obtaining the frequency domain start position of the maximum bandwidth of the reference signal in the multilevel bandwidth structure, or multi-level bandwidth that contains the reference signal.
[0396] [0396] For a description of the apparatus provided in the embodiment, reference may be made to the embodiment corresponding to Figure 1, and thus no further details are provided here.
[0397] [0397] Figure 10 is a schematic diagram of an information transmission apparatus in accordance with an embodiment of the present application. As shown in Figure 10, the embodiment provides an information transmission apparatus, applied to a second communication node, which includes a first receiving module 1001, a second processing module 1002 and a second transmitting module 1003.
[0398] [0398] The first receive module 1001 is configured to receive a signal transmitted by a first communication node.
[0399] [0399] The second processing module 1002 is configured to determine a resource or parameter to transmit a reference signal based on signaling or based on signaling and a rule predefined by the first communication node and the second processing module.
[0400] [0400] The second transmission module 1003 is configured to use the resource or parameter to transmit the reference signal.
[0401] [0401] The resource or parameter includes at least one of: a frequency domain start position, a frequency domain end position, a transmission bandwidth, a number of segments, a bandwidth configuration index, a bandwidth parameter, a parameter that indicates whether a feature is repeated or the same, an antenna port number or index, a way of calculating a frequency domain start position of a maximum signal bandwidth reference in a multilevel bandwidth frame, a parameter relative to obtaining the frequency domain start position of the maximum bandwidth of the reference signal in the multilevel bandwidth frame, or information from the bandwidth frame multilevel band that contains the reference signal.
[0402] [0402] For a description of the apparatus provided in the embodiment, reference may be made to the embodiment corresponding to Figure 2, and thus no further details are provided here.
[0403] [0403] Figure 11 is a schematic diagram of an information transmission apparatus in accordance with an embodiment of the present application. As shown in Figure 11, the embodiment provides an information transmission apparatus, applied to a first communication node, which includes a third processing module 1101 and a second receiving module 1102.
[0404] [0404] The third processing module 1101 is configured to determine a first level parameter and a second level parameter of a reference signal resource, where the first level parameter includes at least one of: the N1 number of reference symbols time domain continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit.
[0405] [0405] The second receive module 1102 is configured to receive the reference signal according to the first level parameter and the second level parameter.
[0406] [0406] The number of time domain symbols configured in the reference signal resource is N, N1 is less than or equal to N, and N2 is less than or equal to N.
[0407] [0407] For a description of the apparatus provided in the embodiment, reference may be made to the embodiment corresponding to Figure 3, and thus no further details are provided here.
[0408] [0408] Figure 12 is a schematic diagram of an information transmission apparatus in accordance with an embodiment of the present application. As shown in Figure 12, the embodiment provides an information transmission apparatus, applied to a second communication node, which includes a fourth processing module 1201 and a third transmission module 1202.
[0409] [0409] The fourth processing module 1201 is configured to determine a first level parameter and a second level parameter of a reference signal resource, where the first level parameter includes at least one of: the N1 number of reference symbols time domain continuously transmitted by a reference signal in the same frequency domain unit, an antenna switching switch function A1 of the reference signal, or a frequency hopping switch function B1; and the second level parameter includes at least one of: the number N2 of time domain symbols continuously transmitted by a group of antenna ports of the reference signal, an antenna toggle switch function A2 of the reference signal in a time domain unit, or a frequency hop switch function B2 of the reference signal in a time domain unit.
[0410] [0410] The third transmit module 1202 is configured to transmit the reference signal according to the first level parameter and the second level parameter.
[0411] [0411] The number of time domain symbols configured in the reference signal resource is N, N1 is less than or equal to N, and N2 is less than or equal to N.
[0412] [0412] For a description of the apparatus provided in the embodiment, reference may be made to the embodiment corresponding to Figure 4, and thus no further details are provided here.
[0413] [0413] Figure 13 is a schematic diagram of a communication node in accordance with an embodiment of the present application. As shown in Figure 13, the embodiment provides a communication node 1300, such as a base station, which includes a first memory 1301 and a first processor 1302; and the first memory 1301 is configured to store information transmission programs which, when executed by the first processor 1302, implement the steps of the information transmission method illustrated in Figure 1.
[0414] [0414] It should be understood by those skilled in the art that the communication node structure illustrated in Figure 13 does not limit communication node 1300, and communication node 1300 may include more or fewer components than those illustrated, or may be configured by combining certain components or using different components.
[0415] [0415] The first processor 1302 may include, but is not limited to, a microcontroller unit (MCU), a field programmable gate network (FPGA) or other processing apparatus. The first memory 1301 may be configured to store application software software programs, and modules, such as program instructions or modules that correspond to the method of transmitting information in the embodiment. The first processor 1302 executes the software programs and modules stored in the first memory 1301 to perform various functional applications and data processing, for example, to implement the method of transmitting information described in the embodiment. The first memory 1301 may include high-speed random access memory, and may further include non-volatile memory, such as one or more magnetic storage devices, flash memories, or other non-volatile solid-state memories. In some examples, first memory 1301 may include memories which are remotely disposed relative to first processor 1302 and these remote memories may be connected to communication node 1300 via a network. Examples of such a network include, but are not limited to, the Internet, intranets, local area networks, mobile communication networks, and combinations thereof.
[0416] [0416] Exemplaryly, the above-described communication node 1300 may further include a first communication unit 1303; and the first communication unit 1303 can receive or transmit data over a network. In one example, the first communication unit 1303 may be a radio frequency (RF) module, which is configured to communicate wirelessly with the Internet.
[0417] [0417] Figure 14 is a schematic diagram of a communication node in accordance with an embodiment of the present application. As shown in Figure 14, the embodiment provides a communication node 1400, such as a UE, that includes a second memory 1401 and a second processor 1402; and the second memory 1401 is configured to store information transmission programs which, when executed by the second processor 1402, implement the steps of the information transmission method illustrated in Figure 2.
[0418] [0418] It should be understood by those skilled in the art that the communication node structure illustrated in Figure 14 does not limit communication node 1400, and communication node 1400 may include more or fewer components than those illustrated, or may be configured by combining certain components or using different components.
[0419] [0419] Exemplaryly, the above-described communication node 1400 may further include a second communication unit 1403; and the second communication unit 1403 can receive or transmit data over a network.
[0420] [0420] For a description of the second memory, the second processor, and the second communication unit in the mode, reference may be made to the description of the first memory, the first processor, and the first communication unit, and thus no further details are available. here provided.
[0421] [0421] An embodiment of the present application further provides a communication node, which includes: a third memory and a third processor, where the third memory is configured to store information transmission programs which, when executed by the third processor, implement the steps of the information transmission method illustrated in Figure 3.
[0422] [0422] An embodiment of the present application further provides a communication node, which includes: a fourth memory and a fourth processor, where the fourth memory is configured to store information transmission programs which, when executed by the fourth processor, implement the steps of the information transmission method illustrated in Figure 4.
[0423] [0423] For a description of the third memory, the third processor, the fourth memory and the fourth processor, reference may be made to the description of the first memory and the first processor, so no further details are provided here.
[0424] [0424] In addition, an embodiment of the present application further provides a computer readable medium which is configured to store information transmission programs which, when executed by a processor, implement the steps of the information transmission method illustrated in Figure 1, or 2, or 3, or 4.
[0425] [0425] It should be understood by those skilled in the art that the modules or functional units in all or part of the above-described method, system and apparatus steps may be implemented as software, firmware, hardware or appropriate combinations thereof. In hardware implementation, the division of modules or functional units mentioned in the description above may not correspond to the division of physical components. For example, a physical component may have multiple functions, or a function or step may be performed together by several physical components.
[0426] [0426] While the modes of implementation discussed by the present application are as described above, their contents are merely modalities to facilitate understanding of the present application and are not intended to limit the present application.
Any person skilled in the art to which the present application belongs may make any modifications and changes in the forms and details of the implementation without departing from the spirit and scope described by the present application, but the scope of patent protection of the present application is still subject to the defined scope. by the attached claims.

权利要求:
Claims (14)
[1]
1. Wireless communication method, characterized in that it comprises: determining, by a first communication node, a first parameter that indicates a bandwidth of a polling reference signal, a second parameter that indicates a configuration index of bandwidth of the polling reference signal, and a number of units of offset from a second frequency domain home position of the polling reference signal relative to a first frequency domain home position, wherein the second frequency domain home position of frequency domain k0( p) = kTC ( p) + ∆offset
PRB NscRB ∆offset
PRB is determined on the basis of , and where ோ஻ோ஻ is the number of shift units in a unit of ܰ௦௖ , ܰ௦௖ is (௣) a number of subcarriers in a block of physical resources, and LJ ்஼ is the first frequency domain home position; and transmitting a signaling message to a second communication node, wherein the signaling message includes the first parameter, the second parameter and the number of shift units.
[2]
2. Method according to claim 1, characterized in that the second parameter that indicates the bandwidth configuration index of the polling reference signal is an integer in a range from 0 to 63.
[3]
3. Method according to claim 1, characterized in that it comprises: configuring a plurality of resources for the second communication node, wherein the signaling message includes a third parameter to allow the second node to switch antennas using the plurality of resources.
[4]
4. Wireless communication method, characterized in that it comprises: receiving, by a second communication node, a signaling message transmitted by a first communication node, wherein the signaling message includes a first parameter indicating a bandwidth band of a polling reference signal, a second parameter indicating a bandwidth configuration index of the polling reference signal, and a number of units of offset from a second frequency domain start position of the polling reference signal. sounding relative to a first frequency domain start, where the second frequency domain start k0( p) = kTC ( p) + ∆offset
PRB NscRB ∆offset
PRB is determined based on , and where ோ஻ோ஻ is the number of shift units in a unit of ܰ௦௖ , ܰ௦௖ is (௣) a number of subcarriers in a physical resource block, and LJ ்஼ is the first frequency domain home position; determining, by the second communication node, a resource based on the first parameter, the second parameter and the number of displacement units included in the signaling message; and transmitting, by the second communication node, the polling reference signal using the facility.
[5]
5. Method according to claim 4, characterized in that: the second parameter indicating the bandwidth configuration index of the polling reference signal is an integer in a range from 0 to 63.
[6]
6. Method, according to claim 4, characterized in that it comprises: switching, by the second communication node, antennas using a plurality of resources configured by the first communication node.
[7]
7. Method according to claim 1, characterized in that it comprises: determining, by the first communication node, a set of transmission bandwidths of the polling reference signal according to the second parameter that indicates the index of polling reference signal bandwidth configuration, wherein the transmission bandwidth set comprises: 112, 56, 28, 4; 120, 60, 20, 4; 128, 64, 32, 4; 136, 68, 4, 4; 144, 72, 36, 4; 144, 48, 16, 4; 160, 80, 40, 4; 160, 80, 20, 4; 168, 84, 28, 4; 176, 88, 44, 4; 192, 96, 48, 4; 208, 104, 52, 4; 216, 108, 36, 4; 240, 120, 60, 4; 240, 80, 20, 4; 256, 128, 64, 4; and 272, 136, 68, 4.
[8]
8. Method according to claim 4, characterized in that it comprises: determining, by the second communication node, a set of transmission bandwidth of the polling reference signal according to the second parameter that indicates the index of polling reference signal bandwidth configuration, wherein the transmission bandwidth set comprises: 112, 56, 28, 4; 120, 60, 20, 4; 128, 64, 32, 4; 136, 68, 4, 4; 144, 72, 36, 4; 144, 48, 16, 4; 160, 80, 40, 4; 160, 80, 20, 4; 168, 84, 28, 4; 176, 88, 44, 4; 192, 96, 48, 4; 208, 104, 52, 4; 216, 108, 36, 4; 240, 120, 60, 4; 240, 80, 20, 4; 256, 128, 64, 4; and 272, 136, 68, 4.
[9]
9. Wireless communication device, characterized in that it comprises: a processor, and a memory that includes one executable code per processor, in which the executable code per processor when executed by the processor configures the processor to: determine a first parameter that indicates a bandwidth of a polling reference signal, a second parameter indicating a bandwidth configuration index of the polling reference signal, and a number of units of offset from a second frequency domain start position of the polling signal. sounding reference signal relative to a first frequency domain start, where the second frequency domain start k0( p) = kTC ( p) + ∆offset
PRB NscRB ∆offset
PRB is determined based on , and where ோ஻ோ஻ is the number of shift units in a unit of ܰ௦௖ , ܰ௦௖ is (௣) a number of subcarriers in a physical resource block, and LJ ்஼ is the first frequency domain home position; transmitting a signaling message to a second communication node, wherein the signaling message includes the first parameter, the second parameter and the number of shift units.
[10]
10. Wireless communication device, comprising: a processor, and a memory that includes one executable code per processor, wherein the executable code per processor when executed by the processor configures the processor to: receive a signaling message transmitted by a first communication node, wherein the signaling message includes a first parameter that indicates a bandwidth of a polling reference signal, a second parameter that indicates a bandwidth configuration index of the reference signal of sounding, and a number of units of offset from a second frequency domain start position of the sounding reference signal relative to a first frequency domain start position, wherein the second frequency domain start position k0(p) = kTC (p) + ∆offset
PRB NscRB ∆offset
PRB is determined based on , and where ோ஻ோ஻ is the number of shift units in a unit of ܰ௦௖ , ܰ௦௖ is (௣) a number of subcarriers in a physical resource block, and LJ ்஼ is the first frequency domain home position; determining a resource based on the first parameter, the second parameter and the number of displacement units included in the signaling message; and transmit the polling reference signal using the facility.
[11]
11. Device according to claim 9 or 10, characterized in that the second parameter that indicates the bandwidth configuration index of the polling reference signal is an integer in a range from 0 to 63.
[12]
12. Device according to claim 9 or 10, characterized in that the code executable by the processor when executed by the processor configures the processor to: determine a set of transmission bandwidth of the polling reference signal according to with the second parameter indicating the bandwidth configuration index of the polling reference signal, wherein the transmission bandwidth set comprises: 112, 56, 28, 4; 120, 60, 20, 4; 128, 64, 32, 4; 136, 68, 4, 4; 144, 72, 36, 4; 144, 48, 16, 4; 160, 80, 40, 4; 160, 80, 20, 4;
168, 84, 28, 4; 176, 88, 44, 4; 192, 96, 48, 4; 208, 104, 52, 4; 216, 108, 36, 4; 240, 120, 60, 4; 240, 80, 20, 4; 256, 128, 64, 4; and 272, 136, 68, 4.
[13]
13. Device according to claim 9 or 10, characterized in that the code executable by the processor when executed by the processor configures the processor to: configure a plurality of resources for the second communication node, in which the message of signaling includes a third parameter to allow the second communication node to switch antennas using the plurality of resources.
[14]
14. Computer-readable storage medium, characterized in that it stores computer-readable instructions configured to perform the method as defined in any one of claims 1 to 8.

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法律状态:
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