WO2017075819A1 - Method and apparatus for transmitting precoding matrix index - Google Patents

Method and apparatus for transmitting precoding matrix index Download PDF

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Publication number
WO2017075819A1
WO2017075819A1 PCT/CN2015/094030 CN2015094030W WO2017075819A1 WO 2017075819 A1 WO2017075819 A1 WO 2017075819A1 CN 2015094030 W CN2015094030 W CN 2015094030W WO 2017075819 A1 WO2017075819 A1 WO 2017075819A1
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Prior art keywords
index
precoding matrix
dimension
base station
pucch
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PCT/CN2015/094030
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French (fr)
Chinese (zh)
Inventor
张瑞齐
刘建琴
吴强
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华为技术有限公司
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Priority to PCT/CN2015/094030 priority Critical patent/WO2017075819A1/en
Priority to CN201580084368.3A priority patent/CN108352875B/en
Publication of WO2017075819A1 publication Critical patent/WO2017075819A1/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04BTRANSMISSION
    • H04B7/00Radio transmission systems, i.e. using radiation field
    • H04B7/02Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas
    • H04B7/04Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas
    • H04B7/06Diversity systems; Multi-antenna system, i.e. transmission or reception using multiple antennas using two or more spaced independent antennas at the transmitting station
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports

Definitions

  • the present invention relates to the field of communications, and in particular, to a method and an apparatus for transmitting a precoding matrix index.
  • W 1 belongs to one codebook set C1 (the codebook set refers to a set of candidate precoding matrices), and W 2 belongs to another codebook set C2.
  • W 1 is used to indicate the broadband/long-term channel characteristics;
  • W 2 is used to indicate the sub-band/instantaneous channel characteristics in W 1 .
  • the UE when the UE and a base station for communication, the UE will determine the first precoding matrix index (PMI, Precoding Matrix Index) W 1 and a second pre-coding matrix index W 2 using a physical uplink control channel (Physical The number of bits (for example, 5 bits) specified in the Uplink Control CHannel, PUCCH) is fed back to the base station, so that the base station determines W 1 and W 2 according to the first precoding matrix index and the second precoding matrix index, and finally according to W 1 and W 2 determines a precoding matrix in which the number of bits carrying the precoding index indication is determined by a pre-preset feedback mode.
  • PMI Precoding Matrix Index
  • W 2 Physical uplink control channel
  • the codebook set C1 can construct 16 W 1 , that is, the UE can use the 4 bits to feed back the first precoding matrix index of W 1 to the base station, and in the two-dimensional sixteen antenna port scenario, the codebook set.
  • C1 may construct 128 W 1 , that is, the UE needs to use 7 bits to feed back the first precoding matrix index of W 1 to the base station, which is far beyond the number of bits specified in the feedback mode existing in the PUCCH, resulting in two In the application scenario of the dimension antenna, the precoding matrix index cannot be transmitted through the PUCCH.
  • An embodiment of the present invention provides a method and an apparatus for transmitting a precoding matrix index, which can transmit a precoding matrix index on a PUCCH in an application scenario of a two-dimensional antenna.
  • the first index and the second index of the second precoding matrix W 2 are sent to the base station to implement transmission of the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
  • the first sampling formula is:
  • the first sampling formula is:
  • the first sampling formula is:
  • l' is an integer greater than or equal to
  • k' is an integer greater than or equal to
  • the number of antenna ports N 1 * N 2 * the number of polarization directions.
  • the determining, by the UE, the sampling frequency of the down sampling according to the configuration information, Acquiring the first dimension vector from the first dimension candidate vector set v l by the second sampling formula The UE collects the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula according to the configuration information.
  • the UE receives configuration information and a pilot sent by the base station After the information, the method further includes: calculating, by the UE, the first dimension of the candidate vector set v l according to the configuration information, The UE calculates the second-dimensional candidate vector set u k according to the configuration information,
  • the UE according to the pilot information, from the K columns Determining, in the vector, the first precoding matrix W 1 and the second precoding matrix W 2 for constructing the precoding matrix, the UE determining, according to the pilot information, the first precoding matrix W from the K column vectors 1; the UE determines that the second precoding matrix W 2 from the first column vector of the precoding matrix W 1 based on the configuration parameters.
  • the UE the first pre-coding matrix W 1 by using a PUCCH Sending the first index and the second index of the second precoding matrix W 2 to the base station, including: the UE adopting PUCCH mode 1-1 submode 1, the first index of the first precoding matrix W 1 and A second index of the second precoding matrix W 2 is sent to the base station.
  • the UE, the first pre-coding matrix W 1 by using a PUCCH The first index and the second index of the second precoding matrix W 2 are sent to the base station, including: the UE passes the PUCCH mode 1-1 submode 2, and the first index of the first precoding matrix W 1 is A second index of the second precoding matrix W 2 is sent to the base station.
  • the receiving, by the UE, the configuration information sent by the base station The UE receives the configuration information sent by the base station by using radio resource control RRC signaling.
  • an embodiment of the present invention provides a method for transmitting a precoding matrix index, including: receiving, by the UE, configuration information and pilot information sent by a base station, where the configuration information includes configuration parameters, and the two-dimensional antenna is in the first dimension.
  • the number of bits on the PUCCH for transmitting the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0; the UE passes the PUCCH according to the Z
  • the number of bits sends the first index and the second index to the base station, so that the base station determines the precoding matrix W according to the first index and the second index.
  • the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the precoding matrix index is transmitted.
  • the number of bits used may be flexibly configured according to changes in configuration parameters, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna.
  • the UE includes a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ⁇ P, wherein the UE determines, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W, including: determining, by the UE, the base station according to the pilot information The rank indicating RI information and the channel quality indicating CQI information; the UE determining, according to the RI information, the first precoding matrix W 1 and the second precoding matrix constructing the precoding matrix W from the P candidate column vectors W 2 .
  • the UE sends the first index and the second index according to the number of Z bits by using the PUCCH
  • the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a two-dimensional index, wherein the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, where the UE jointly encodes the first dimension index and the RI information.
  • the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a second dimension index, wherein the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, where the UE jointly encodes the second dimension index and the RI information.
  • Obtaining a fourth joint code value the UE jointly coding the first dimension index, the second index, and the CQI information to obtain a fifth joint code value; the UE obtains the number of Z bits according to the number of Z bits.
  • the fourth union code value and the fifth union code value are transmitted to the base station through the PUCCH.
  • the method further includes: receiving, by the UE, an encoding indication sent by the base station, where the encoding indication is used to indicate that the RI information is jointly encoded with the first dimension index or the second dimension index.
  • an embodiment of the present invention provides a UE, where the UE includes: a processor, a memory, and a transceiver, where the memory is configured to store a first vector set, where the first vector set includes a pre-configuration a P candidate matrix vector of the coding matrix W, 64 ⁇ P; the transceiver is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna of the two-dimensional antenna in the first dimension a port number N 1 and a first oversampling factor O 1 , and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; the processor configured to use the P according to the configuration information
  • the candidate column vectors are downsampled to obtain K column vectors constituting the precoding matrix W, 0 ⁇ K ⁇ 64 ⁇ P; and, according to the pilot information, determining the precoding matrix from the K column vectors a first precoding matrix W 1 and a second precoding matrix W 2 of W, where
  • the first index and the second index of the second precoding matrix W 2 are sent to the base station to implement transmission of the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
  • the processor is configured to determine a sampling frequency of the down sampling according to the configuration information, and select a candidate to be selected from the first dimension according to the sampling frequency.
  • the processor is configured to calculate, according to the first oversampling factor O 1 , by using a first sampling formula Collecting the first dimension vector from the first dimension candidate vector set v l a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second dimensional candidate vector set u k by using the first sampling formula Sampling frequency
  • the processor is configured to use the second sampling formula to obtain the first Collecting the first dimension vector in the selected vector set v l And acquiring, according to the configuration information, the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula
  • the second sampling formula is: Otherwise, the second sampling formula is:
  • the second sampling formula is:
  • l' is an integer greater than or equal to
  • k' is an integer greater than or equal to
  • the number of antenna ports N 1 * N 2 * the number of polarization directions.
  • the processor is further configured to calculate the The first dimension of the candidate vector set v l , And calculating, according to the configuration information, the second dimension candidate vector set u k ,
  • the processor is specifically configured to use, according to the pilot information, the K is determined from the first column vector in the precoding matrix W 1; and the configuration parameter determines the second precoding matrix W 2 from the first column vector of the precoding matrix W 1 in accordance with.
  • the transceiver is specifically configured to pass the PUCCH mode 1-1 sub-mode 1, the first precoding matrix W 1 of the first index and the second index of precoding matrix W 2 is transmitted to the second base station.
  • the transceiver is specifically configured to pass the PUCCH mode 1-1 sub-mode 2, the first precoding matrix W 1 of the first index and the second index of precoding matrix W 2 is transmitted to the second base station.
  • the transceiver is configured to receive the RRC signaling The configuration information sent by the base station.
  • the configuration information determines that the number of bits used to transmit the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 on the PUCCH is Z, and Z>0;
  • the first index and the second index are sent to the base station according to the number of Z bits by using the PUCCH, so that the base station determines
  • the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the precoding matrix index is transmitted.
  • the number of bits used may be flexibly configured according to changes in configuration parameters, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna.
  • the memory is configured to store a first vector set, where the first vector set includes P candidate column vectors for constructing the precoding matrix W 64 ⁇ P; the processor is specifically configured to determine, according to the pilot information, rank indication RI information and channel quality indication CQI information with the base station; and, according to the RI information, from the P candidate column vectors Determining a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W.
  • the processor is further configured to use the first index of the first precoding matrix W 1 and the RI
  • the information is jointly encoded to obtain a first joint code value
  • the transceiver is further configured to send, by using the PUCCH, the first joint code value of Z1 bits to the base station by using the PUCCH; and, by using the PUCCH,
  • the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a second dimension index
  • the processor is further configured to jointly encode the first dimension index and the RI information to obtain a second union code value
  • the second dimension index, the second index, and the The CQI information is jointly encoded to obtain a third joint code value
  • the transceiver is further configured to send the second joint code value and the third joint code value to the third joint code value according to the Z number of bits. Base station.
  • the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a two-dimensional index, wherein the processor is also used to The second dimension index is jointly encoded with the RI information to obtain a fourth joint code value; and the first dimension index, the second index, and the CQI information are jointly encoded to obtain a fifth joint code value; And sending, by the number of Z bits, the obtained fourth joint code value and the fifth joint code value to the base station by using the PUCCH.
  • the transceiver is further configured to receive an encoding indication sent by the base station, where the encoding indication is used Instructing the RI information to be jointly encoded with the first dimension index or the second dimension index.
  • an embodiment of the present invention provides a precoding matrix index transmission apparatus, where the apparatus includes a first vector set, where the first vector set includes P candidate column vectors for constructing a precoding matrix W.
  • the first index and the second index of the second precoding matrix W 2 are sent to the base station to implement transmission of the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
  • the device further includes a computing unit, and specifically, the calculating unit, specifically, according to the first oversampling
  • the factor O 1 is calculated by the first sampling formula to acquire the first dimension vector from the first dimension of the candidate vector set v l a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second set of candidate vectors u k by the first sampling formula Sampling frequency.
  • the device further includes a computing unit, and the computing unit is specifically configured to pass the configuration information according to the configuration information.
  • the second sampling formula collects the first dimensional vector from the first set of candidate vector sets v l And acquiring, according to the configuration information, the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula
  • the second sampling formula is: Otherwise, the second sampling formula is:
  • the second sampling formula is:
  • l' is an integer greater than or equal to
  • k' is an integer greater than or equal to
  • the number of antenna ports N 1 * N 2 * the number of polarization directions.
  • the calculating unit is further configured to calculate the The first dimension of the candidate vector set v l , And calculating, according to the configuration information, the second dimension candidate vector set u k ,
  • the determining unit is specifically configured to use, according to the pilot information, the K is determined from the first column vector in the precoding matrix W 1; and the configuration parameter determines the second precoding matrix W 2 from the first column vector of the precoding matrix W 1 in accordance with.
  • the sending unit is specifically configured to pass the PUCCH mode 1-1 sub-mode 1, the first precoding matrix W 1 of the first index and the second index of precoding matrix W 2 is transmitted to the second base station.
  • the sending unit is specifically configured to send, by using the PUCCH mode 1-1 sub-mode 2, the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station.
  • the sending unit is further configured to receive the RRC signaling The configuration information sent by the base station.
  • the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the precoding matrix index is transmitted.
  • the number of bits used may be flexibly configured according to changes in configuration parameters, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna.
  • the UE includes a first vector set, where the first vector set includes P candidate column vectors for constructing a precoding matrix W, 64 ⁇ P, wherein the determining unit is specifically configured to determine RI information and CQI information between the base station and the base station according to the pilot information; and, according to the RI information, determine, construct the pre-determination from the P candidate column vectors.
  • the apparatus further includes a joint coding unit, where the first index includes a first dimension index in the first dimension And a second dimension index on the second dimension,
  • the joint coding unit is further configured to jointly encode the first dimension index and the RI information to obtain a second union code value; and perform the second dimension index, the second index, and the CQI information.
  • Joint coding to obtain a third joint code value;
  • the sending unit is further configured to send the second joint code value and the third joint code value to the base station by using the PUCCH according to the number of Z bits.
  • the joint coding unit is further configured to jointly encode the second dimension index and the RI information to obtain a fourth union code value; and, the first dimension index, the second index, and the CQI information Performing joint coding to obtain a fifth joint code value;
  • the sending unit is further configured to send, according to the Z number of bits, the obtained fourth joint code value and the fifth joint code value to the base station by using the PUCCH .
  • the receiving unit is further configured to receive an encoding indication sent by the base station, where the encoding indication is used to indicate the RI
  • the information is jointly encoded with the first dimension index or the second dimension index.
  • an embodiment of the present invention provides a method and an apparatus for transmitting a precoding matrix index
  • the UE selects no more than 64 column vectors from the original P candidate column vectors to form the precoding matrix W by downsampling
  • the number of bits used for the matrix index may be flexibly configured according to the change
  • FIG. 1 is a schematic diagram of an application scenario of transmitting a precoding matrix index according to an embodiment of the present disclosure
  • FIG. 2 is a schematic flowchart 1 of a method for transmitting a precoding matrix index according to an embodiment of the present invention
  • FIG. 3 is a schematic diagram 1 of a downsampling method according to an embodiment of the present invention.
  • FIG. 4 is a second schematic diagram of a downsampling method according to an embodiment of the present invention.
  • FIG. 5 is a schematic flowchart 2 of a method for transmitting a precoding matrix index according to an embodiment of the present disclosure
  • FIG. 6 is a schematic structural diagram 1 of a device for transmitting a precoding matrix index according to an embodiment of the present disclosure
  • FIG. 7 is a schematic structural diagram 2 of a transmission apparatus of a precoding matrix index according to an embodiment of the present disclosure
  • FIG. 8 is a schematic structural diagram 1 of a hardware structure of a user equipment according to an embodiment of the present disclosure.
  • FIG. 9 is a schematic structural diagram 3 of a transmission apparatus of a precoding matrix index according to an embodiment of the present disclosure.
  • FIG. 10 is a schematic structural diagram 4 of a transmission apparatus of a precoding matrix index according to an embodiment of the present disclosure.
  • FIG. 11 is a second schematic structural diagram of a hardware structure of a user equipment according to an embodiment of the present disclosure.
  • first and second are used for descriptive purposes only, and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, features defining “first” and “second” may include one or more of the features either explicitly or implicitly. In the description of the present invention, "a plurality” means two or more unless otherwise stated.
  • FIG. 1 is a schematic diagram of an application scenario of a method for transmitting a precoding matrix index according to an embodiment of the present invention, where a base station may send pilot information to a UE, and further, the UE according to the pilot information and has been determined.
  • the codebook set (that is, the P candidate column vectors used to construct the precoding matrix W, the number of P is usually less than 64 in the application scenario of the one-dimensional antenna) performs channel estimation to determine channel state information (CSI). For example, Rank Indicator (RI) information, Channel Quality Indicator (CQI) information, and Precoding Matrix Indicator (PMI) information, and the like.
  • CSI channel state information
  • RI Rank Indicator
  • CQI Channel Quality Indicator
  • PMI Precoding Matrix Indicator
  • the pre-coding matrix W W 1 * W 2
  • the PMI information may comprise specific configuration of the precoding matrix W of the first precoding matrix W 1 and second precoding matrix W 2
  • the UE further Combining the RI information, the CQI information, and the first index of the first precoding matrix W 1 (ie, the first PMI) and the second index of the second precoding matrix W 2 (ie, the second PMI) by joint coding (Joint source- channel coding, JSCC), etc. to the base station, so the base station can determine the first precoding matrix W based on the first PMI. 1,. 1, the precoding matrix W finally obtained the second PMI precoding matrix W is determined in accordance with a first .
  • the aperiodic feedback can be performed through the PUSCH (Physical Uplink Shared Channel), where the number of bits used to transmit the PMI information follows
  • the configurable parameter changes, or the UE may periodically send back a fixed number (for example, 5 bits) of bits on the PUCCH when transmitting the PMI information to the base station, for example, adopting the PUCCH mode already specified in the 3GPP protocol.
  • 1-1 submode 1 and submode 2 Feedback PMI information when the UE sends the PMI information to the base station.
  • the number of antenna ports and the direction indicated by the antenna port are significantly increased, that is, the number P of candidate column vectors for constructing the precoding matrix W is significantly increased.
  • the number of the first precoding matrix W 1 and the second precoding matrix W 2 constructed from the P candidate column vectors is also increased, and therefore, the PUCCH mode 1-1 already specified in the 3GPP protocol is used.
  • Submode 1 and submode 2 the method of feeding back the first PMI and the second PMI using a fixed number of bits is no longer applicable.
  • the embodiments of the present invention provide two feasible solutions to how to transmit the precoding matrix index (ie, the first PMI and the second PMI) on the PUCCH in the application scenario of the two-dimensional antenna.
  • the pre-coding provided by the embodiment of the present invention may be based on configuration information sent by the base station (ie, configuration parameters, the number of first antenna ports N 1 and the first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and the second dimension) a second antenna port number N 2 and a second oversampling factor O 2 ), and down-sampling the P candidate column vectors to obtain K column vectors constituting the precoding matrix W, since 0 ⁇ K ⁇ 64 ⁇ P, such that the UE can construct the first precoding matrix W 1 and the second precoding matrix W 2 from the downsampled K column vectors on the basis of the existing 3GPP protocol, and use the existing transmission mode in the PUCCH
  • the first PMI and the second PMI are transmitted on.
  • a new PUCCH is defined.
  • a sub-mode of mode 1-1 wherein the UE may determine the number of bits used for transmitting the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined sub-mode,
  • the number of bits used for transmitting the precoding matrix index can be flexibly configured according to the change of the configuration information, and can be applied to the transmission of the precoding matrix index in the application scenario of the two-dimensional antenna.
  • the embodiment of the present invention provides a method for transmitting a precoding matrix index, where the UE includes a first vector set, where the first vector set includes P candidates for constructing the precoding matrix W.
  • Column vector, 64 ⁇ P as shown in Figure 2, the method specifically includes:
  • the UE receives configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second The second antenna port number N 2 and the second oversampling factor O 2 in the dimension.
  • the UE downsamples the P candidate column vectors according to the configuration information, and obtains K column vectors constituting the precoding matrix W, where 0 ⁇ K ⁇ 64 ⁇ P.
  • UE a first index of a first pre-coding matrix W 1 and a second precoding matrix W 2 is the second index to the base station via PUCCH, so that the base station determines the precoding matrix based on the first index and the second index W.
  • the UE may separately receive configuration information and pilot information sent by the base station.
  • the UE may receive a reference signal set sent by the base station, where the reference signal set includes pilot information, that is, the base station continuously transmits the unmodulated direct sequence spread spectrum signal, which enables the UE to obtain the forward code division multiple access channel time limit. Provides a relevant demodulation phase reference.
  • the UE may receive RRC (Radio Resource Control) signaling sent by the base station, where the RRC signaling carries the configuration information.
  • the configuration information includes a configuration parameter (ie, Codebook-Subset-SelectionConfig, referred to as config in the 3GPP protocol), a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension. And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension.
  • config Codebook-Subset-SelectionConfig
  • N 1 refers to the number of antenna ports in the first dimension in a certain polarization direction.
  • N 2 refers to the number of antenna ports in the second dimension in the polarization direction.
  • the first antenna port number N 1 , the first oversampling factor O 1 , the second antenna port number N 2 , and the second oversampling factor O 2 are represented as (N 1 , N 2 ). , (O 1 , O 2 ).
  • step 102 the UE downsamples the P candidate column vectors according to the configuration information acquired in step 101 (that is, samples a sample interval, for example, the P candidate column vectors, are sampled at intervals).
  • the new sequence is the downsampling of the original sequence, and K column vectors constituting the precoding matrix W are obtained, 0 ⁇ K ⁇ 64 ⁇ P.
  • the K column vectors are a subset of the P candidate column vectors, and the number K of the downsampled column vectors is an integer less than or equal to 64, and the existing one for the one-dimensional antenna is In the transmission process of the coding matrix index, the number of vectors constituting the precoding matrix W is also less than or equal to 64. Therefore, the UE can obtain the K column vectors by downsampling the P candidate column vectors.
  • the transmission method of the precoding matrix index in the technology performs the subsequent transmission step, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna based on the existing transmission method of the precoding matrix index.
  • the foregoing P candidate column vectors may be pre-stored in the memory of the UE before performing the transmission method of the precoding matrix index; the P candidate column vectors After the step 101, the UE is calculated according to the configuration information sent by the base station, where the first vector set specifically includes a first dimension candidate vector set v l and a second dimension candidate vector set u k . .
  • the UE calculates the first dimension of the candidate vector set v l according to the first antenna port number N 1 and the first oversampling factor O 1 in the configuration information:
  • the UE calculates the second-dimensional candidate vector set u k according to the second antenna port number N 2 and the second over-sampling factor O 2 in the configuration information:
  • the UE can obtain P candidate column vectors in the first vector set composed of the first-dimensional candidate vector set v l and the first-dimensional candidate vector set v l .
  • the UE further performs the method of down-sampling the P candidate column vectors according to the configuration information in step 102 to obtain K column vectors constituting the precoding matrix W.
  • the UE determines, according to the configuration information, a sampling frequency of the down sampling (ie, determining sampling from each of the P candidate column vectors); and further, the UE selects from the first dimension of the candidate vector according to the sampling frequency.
  • l collect L first dimension vectors
  • the UE calculates L first-dimensional vectores from the first-dimensional candidate vector set v l by using the first sampling formula according to the first over-sampling factor O 1 .
  • Sampling frequency and, according to the second oversampling factor O 2 , the UE calculates J second dimension vectors from the second dimension candidate vector set u k by using the first sampling formula calculation Sampling frequency.
  • the first sampling formula is: Or the first sampling formula is: When the number of antenna ports is 8, the first sampling formula is:
  • the first dimension candidate vector set v l and the second dimension candidate vector set u k in a vector set can obtain a first dimension candidate vector set v l composed of 32 candidate column vectors .
  • the UE may further calculate, according to the first oversampling factor O 1 , the second oversampling factor O 2 , the first antenna port number N 1 , and the second antenna port number N 2 , by using the second sampling formula. Collecting L first-dimensional vectors in the dimension of the candidate vector set v l Sampling frequency, and collecting J second-dimensional vectors from the second-dimensional candidate vector set u k Sampling frequency.
  • the frequency of downsampling needs to be determined by the value of (N 1 , N 2 ) in addition to the value of (O 1 , O 2 ).
  • the UE may also implement a process of downsampling P candidate column vectors by the following method.
  • the UE may preset a local oversampling factor. among them, It may be any one of (2, 4), (4, 2), (2, 2) or (4, 4), such that after the UE obtains (N 1 , N 2 ) in the configuration information in step 101 Can make Further, the values of (N 1 , N 2 ) and (O 1 , O 2 ) are brought into the formulas (11) and (12), and the obtained Further obtained by with The K column vectors that make up.
  • the UE downsamples the P candidate column vectors according to the configuration information to obtain K column vectors constituting the precoding matrix W.
  • the UE based on the pilot information may perform channel estimation, determine the RI information and the CQI information, and further, the UE, determining a first precoding matrix W 1 from the K column vector based on the RI information; the UE according to the configuration parameters ( config) determining a second precoding matrix W 2 from the first column vector of the precoding matrix W 1.
  • the UE performs channel estimation according to the pilot information, determines that RANK is equal to 1, and selects eight first precodings from the K column vectors determined in step 102 according to the RI information.
  • the matrix W 1 since the 64 column vectors can construct at most 16 (2 4 ) 8 columns of the first precoding matrix W 1 , the UE can use 4 bits to indicate the first of the first precoding matrix W 1 in the future. Index (ie the first PMI).
  • the UE needs to determine the second precoding matrix W 2 from the column vectors of the first precoding matrix W 1 according to the configuration parameters determined in step 101.
  • the 3GPP configuration defines four configuration parameters (config1-4) as shown in Table 1 and a second index of the second precoding matrix W 2 ( That is, the correspondence between the second PMI, and the correspondence between the second PMI (indicated by i 2 in Table 2) and the precoding matrix W as shown in Table 2.
  • Config Select the second PMI (s 1 , s 2 ) Config1 0-3 (1,1) Config2 0-7, 16-23 (2,2) Config3 0-3, 8-11, 20-23, 28-31 (2,2) Config4 0-15 (2,2)
  • the UE finally determines the second index of the second precoding matrix W 2 , i' 2 , according to the configuration parameters and the correspondence in Table 2 .
  • step 104 the UE sends the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station through the PUCCH, so that the base station determines according to the first index and the second index.
  • Precoding matrix W Precoding matrix W.
  • the UE may still pass the PUCCH mode 1-1 submode 1 (ie, PUCCH mode 1-1 submode1, which has been defined in the 3GPP protocol, and related description in the 3GPP TS 36.213 protocol), and the first precoding matrix W A first index of 1 and a second index of the second precoding matrix W 2 are transmitted to the base station.
  • PUCCH mode 1-1 submode 1 ie, PUCCH mode 1-1 submode1, which has been defined in the 3GPP protocol, and related description in the 3GPP TS 36.213 protocol
  • the UE uses the PUCCH mode 1-1 submode 2 (PUCCH mode 1-1 submode2, see related description in the 3GPP TS 36.213 protocol), the first index of the first precoding matrix W 1 and the second pre A second index of the coding matrix W 2 is transmitted to the base station.
  • PUCCH mode 1-1 submode 2 PUCCH mode 1-1 submode2, see related description in the 3GPP TS 36.213 protocol
  • the RI information is jointly encoded with the first PMI, and the coded value obtained by the joint coding is carried in the report 1 to feed back to the base station, and the second PMI and the CQI are transmitted.
  • the information is carried in report2 and directly fed back to the base station.
  • the codebook jointly encoded by the RI information and the first PMI in the PUCCH mode 1-1 sub-mode 1 is as shown in Table 3, and occupies 5 bits in the PUCCH.
  • the RI information is carried in the report 1 and is fed back to the base station.
  • the first PMI and the second PMI are jointly coded, and the coded value obtained by the joint coding is carried in the report 2 to feed back to the base station.
  • the codebook jointly coded by the first PMI and the second PMI is as shown in Table 4.
  • the coded value of the joint coding of the first PMI and the second PMI is transmitted by using 4 bits, wherein 3 bits are used to select the first part of W1.
  • An index, 1 bit is used to select the phase of the fixed vector (co-phase) to indicate W2 The second index.
  • the period of transmitting the RI information is greater than or equal to the period of the transmission PMI, and the frequency of the change of the RI is required.
  • the frequency of change of the PMI is slower than that of the PMI.
  • an embodiment of the present invention provides a method for transmitting a precoding matrix index, where the UE includes P candidate column vectors for constructing a precoding matrix W, 64 ⁇ P. Specifically, the UE receives configuration information sent by the base station.
  • the configuration information includes configuration parameters, the number of two-dimensional antenna the first antenna port in a first dimension of the first through N 1 - 1, and the number of sampling factor of the second antenna port in a second dimension of the O N 2 And the second oversampling factor O 2 ;
  • the UE downsamples the P candidate column vectors according to the configuration information, and obtains K column vectors constituting the precoding matrix W, 0 ⁇ K ⁇ 64 ⁇ P; it can be seen that By downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W. Further, the UE can use the existing 3GPP protocol to determine from the K column vectors according to the pilot information.
  • the station is configured to transmit the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
  • the embodiment of the present invention provides a method for transmitting a precoding matrix index, where the UE includes a first vector set, where the first vector set includes P candidates for constructing the precoding matrix W.
  • the UE receives configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second The second antenna port number N 2 and the second oversampling factor O 2 in the dimension.
  • UE based on the configuration information, determining the number of bits transmitted for a first pre-coding matrix W 1 of the first index and the second precoding matrix W 2 is the second index number Z, Z> 0 in the PUCCH.
  • the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, so that the base station determines the precoding matrix W according to the first index and the second index.
  • the UE may receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension. And the second antenna port number N 2 and the second oversampling factor O 2 in the second dimension.
  • the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension.
  • the second antenna port number N 2 and the second oversampling factor O 2 in the second dimension.
  • step 202 since the UE includes a first set of vectors, the first set of vectors includes P candidate column vectors for constructing the precoding matrix W, 64 ⁇ P, and therefore, the UE obtains the method according to step 201.
  • the UE does not need to downsample the P candidate column vectors, but directly determines the constructed precoding matrix from the P candidate column vectors.
  • the UE first performs channel estimation according to the pilot information in step 101, and determines RI information and CQI information between the base station and the base station. Further, the UE determines, according to the RI information, a precoding matrix W from the P candidate column vectors. The first precoding matrix W 1 and the second precoding matrix W 2 .
  • step 203 the UE determines, according to the configuration information obtained in step 201, the number of bits used to transmit the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 on the PUCCH. For Z, Z>0.
  • the UE can only feed back the first PMI and the second PMI using a fixed number of bits, which is new in the embodiment of the present invention.
  • the UE may determine, according to the values of (N 1 , N 2 ), (O 1 , O 2 ), and configuration parameters, that the first precoding matrix W 1 is transmitted on the PUCCH.
  • the number of bits Z of the second index of the first index and the second precoding matrix W 2 so that the UE can be flexibly configured according to the change of the configuration information, so as to achieve the second The transmission of the precoding matrix index in the application scenario of the dimensional antenna.
  • step 204 the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH determined in step 203, so that the base station determines the precoding according to the first index and the second index.
  • Matrix W Matrix W.
  • the UE determines a method of transmitting a precoding matrix index by a different number of bits.
  • the UE determines the number of bits Z1 for transmitting the first PMI according to the values of (N 1 , N 2 ), (O 1 , O 2 ) and the configuration parameters. Specifically, the UE may perform the first precoding.
  • the first index of the matrix W 1 is jointly encoded with the RI information to obtain a first joint code value, and the first joint code value can be represented by Z1 bits. Further, the UE passes the PUCCH to the first of the Z1 bits.
  • the configuration parameter is the case 2
  • the value and Table 5 give the value of the corresponding first PMI(i 1 ).
  • the configuration parameter is the case 2
  • the joint coding is performed to obtain a first joint code value I RI/PMI1 , and then the first joint code value is transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
  • the configuration parameter is 3 or In the case of 4, the UE determines to use 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 with the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
  • the configuration parameter is 2
  • the UE determines to use the 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain the first The union coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
  • the configuration parameter is In the case of 2, the UE determines to use 6 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 7, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 6 bits in the PUCCH.
  • the configuration parameter is 3 or In the case of 4, the UE determines to use 6 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 7, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 6 bits in the PUCCH.
  • the configuration parameter is 2 case, the UE determines to use the first 8 bits for transmission on the PUCCH PMI, specifically, as shown in table 5, UE will first precoding matrix W 1 of the first index and the RI information is jointly encoded, to give first The coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 8 bits in the PUCCH.
  • the configuration parameter is In the case of 2, the UE determines to use 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
  • the configuration parameter is 3 or In the case of 4, the UE determines to use 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 with the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
  • the configuration parameter is 2
  • the UE determines to use 9 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 8, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain the first The union coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 9 bits in the PUCCH.
  • the configuration parameter is In the case of 2, the UE determines to use 8 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 5, the UE jointly encodes the first index of the first precoding matrix W 1 with the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 8 bits in the PUCCH.
  • the configuration parameter is 3 or In the case of 4, the UE determines to use 8 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 5, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 8 bits in the PUCCH.
  • the UE determines to use 8 bits for transmission on the PUCCH.
  • the first PMI specifically, as shown in Table 5, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes through the PUCCH.
  • the 8 bits are transmitted to the base station through the PUCCH.
  • the UE determines to use 7 bits for use in the PUCCH. Transmitting the first PMI, specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes the PUCCH. The 7 bits in the medium are transmitted to the base station through the PUCCH.
  • the UE determines to use 7 bits for use in the PUCCH. Transmitting the first PMI, specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes the PUCCH. The 7 bits in the medium are transmitted to the base station through the PUCCH.
  • the UE determines to use 6 bits for transmission on the PUCCH.
  • the first PMI specifically, as shown in Table 7, the UE combines the first index of the first precoding matrix W 1 with the RI information to obtain a first joint coded value I RI/PMI1 , and then passes through the PUCCH. 6 bits, the first combined code value is transmitted to the base station through the PUCCH.
  • the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes 5 bits in the PUCCH. And transmitting the first joint code value to the base station through the PUCCH.
  • the UE determines to use 5 bits for use in the PUCCH. Transmitting the first PMI, specifically, as shown in Table 9, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint code value I RI/PMI1 , and then passes the PUCCH. The 5 bits in the medium are transmitted to the base station through the PUCCH.
  • the first index of the first precoding matrix W 1 (ie, the first PMI) may be indexed by the first dimension in the first dimension (ie, i 1,1 ) and the second dimension
  • the second dimension index (ie i 1,2 ) is represented.
  • the UE determines, according to the values of (N 1 , N 2 ), (O 1 , O 2 ), and configuration parameters, that Z bits are used to transmit the first PMI and the second PMI, and further, the UE indexes the first dimension.
  • i 1,1 is jointly coded with the RI information to obtain a second joint code value; and the UE jointly encodes the second dimension index i 1,2 , the second index i 2 and the CQI information to obtain a third joint code
  • the UE will obtain the second union code value and the third union code value to be sent to the base station through Z bits in the PUCCH, so that the base station respectively according to the second union code value and the third union code value Determining the first index and the second index, and finally determining the precoding matrix W according to the first index and the second index.
  • the UE may also jointly encode the second dimension index i 1,2 and the RI information to obtain a fourth union code value; further, the UE indexes the first dimension index i 1,1 , the second index i 2 , and the CQI The information is jointly coded to obtain a fifth joint code value; finally, the UE will obtain the fourth joint code value and the fifth joint code value to be transmitted to the base station through Z bits in the PUCCH.
  • the UE may receive an encoding indication sent by the base station, where the encoding indication may be used to indicate that the RI information is jointly encoded with the first dimension index i 1,1 or the second dimension index i 1,2 , so that the UE can be
  • the encoding indicates selection to jointly encode the RI information with the first dimension index i 1,1 or the second dimension index i 1,2 .
  • the UE may determine, according to (N 1 , N 2 ) in the configuration parameter, a first dimension index i 1,1 or a second dimension index i 1,2 jointly encoded with the RI information, for example, when N 1 ⁇ At N 2 , it is determined that the RI information is jointly encoded with the first dimension index i 1,1 ; when N 1 >N 2 , the RI information is determined to be jointly encoded with the second dimension index i 1,2 because the antenna port
  • the number of dimensions is smaller, and the precoding matrix corresponds to a wider beam, so that the beam variation frequency caused by the motion of the user is slower.
  • the PMI of the dimension with a smaller number of antenna ports (for example, the first dimension index i 1, 1 ) Co-coding with RI information, both of which have slow-changing characteristics, can use a longer feedback period, so that the cost of RI and PMI feedback corresponding to this dimension can be saved.
  • the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 10, for the first dimension index i 1,1 , the UE will use the first dimension.
  • the index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 5 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 10 The value of the corresponding first dimension index i 1,1 .
  • the UE jointly encodes the second dimension index i 1,2 , the second index i 2 , and the CQI information to obtain a third joint code value.
  • the configuration parameter is 2, as shown in Table 11, the UE uses 3 bits indicate the second dimension index i 1,2 , and 1 bit is used to indicate the second index (ie, the second PMI) i 2 .
  • the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 14, at this time, the UE determines to use 5 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specific The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station through 5 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 14, the value of the corresponding second dimension index i 1,2 can be obtained.
  • the UE determines to use 4 bits for transmitting the second dimension index i 1,2 and RI information on the PUCCH. As shown in Table 15, the UE jointly encodes the second dimension index i 1,2 and the RI information to obtain the first The quad sum code value is further fed back to the base station through 4 bits in the PUCCH, so that the base station can obtain the value of the corresponding second dimension index i 1,2 according to the fourth joint code value and Table 15.
  • the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value.
  • the configuration parameter is 2, as shown in Table 16, the UE uses The 3 bits indicate the first dimension index i 1,1 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
  • the UE indicates the first dimension index i 1,1 using 2 bits, and indicates the second index (ie, the second PMI) i 2 using 2 bits.
  • the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 10, for the first dimension index i 1,1 , the UE will use the first dimension.
  • the index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 5 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 10 The value of the corresponding first dimension index i 1,1 .
  • the UE jointly encodes the second dimension index i 1,2 , the second index i 2 , and the CQI information to obtain a third joint code value.
  • the configuration parameter is 2, as shown in Table 11, the UE uses The 3 bits indicate the second dimension index i 1,2 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
  • the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 18, at this time, the UE determines to use 6 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specifically The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station through 6 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 14, the value of the corresponding second dimension index i 1,2 can be obtained.
  • the UE determines to use 5 bits for transmitting the second dimension index i 1,2 and RI information on the PUCCH. Specifically, the UE jointly encodes the second dimension index i 1,2 and the RI information. Obtaining a fourth joint code value; further, feeding back to the base station by using 5 bits in the PUCCH, so that the base station can obtain the corresponding second dimension index i 1,2 according to the fourth joint code value and Table 19. value.
  • the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value.
  • the configuration parameter is 2, as shown in Table 16, the UE uses The 3 bits indicate the first dimension index i 1,1 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
  • the UE determines to use 6 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 20, for the first dimension index i 1,1 , the UE will use the first dimension.
  • the index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 6 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 20 The value of the corresponding first dimension index i 1,1 .
  • the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 21, for the first dimension index i 1,1 , the UE indexes the first dimension i 1,1 and RI information are jointly encoded to obtain a second joint code value; and further, 5 bits in the PUCCH are fed back to the base station, so that the base station can obtain the corresponding according to the second joint code value and Table 21. The first dimension indexes the value of i 1,1 .
  • the UE jointly encodes the second dimension index i 1,2 , the second index i 2 and the CQI information to obtain a third joint code value. As shown in Table 13, the UE uses 2 bits to indicate the second dimension index i 1 . 2 , using 2 bits to indicate the second index (ie the second PMI) i 2 .
  • the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 22, at this time, the UE determines to use 4 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specifically The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station by using 4 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 22, the value of the corresponding second dimension index i 1,2 can be obtained.
  • the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value.
  • the UE uses 3 bits to indicate the first dimension index i 1 . , 1 , using 1 bit to indicate the second index (ie, the second PMI) i 2 .
  • the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 10, for the first dimension index i 1,1 , the UE will use the first dimension.
  • the index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 5 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 10 The value of the corresponding first dimension index i 1,1 .
  • the UE determines to use 4 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 23, the UE jointly encodes the first dimension index i 1,1 and the RI information. Obtaining a second union code value; further, feeding back to the base station by using 4 bits in the PUCCH, so that the base station can obtain the corresponding first dimension index i 1,1 according to the second union code value and Table 23. value
  • the UE jointly encodes the second dimension index i 1,2 , the second index i 2 and the CQI information to obtain a third joint code value. As shown in Table 13, the UE uses 2 bits to indicate the second dimension index i 1 . 2 , using 2 bits to indicate the second index i 2 (ie the second PMI).
  • the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 22, at this time, the UE determines to use 4 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specifically The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station by using 4 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 22, the value of the corresponding second dimension index i 1,2 can be obtained.
  • the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value.
  • the configuration parameter is 2, as shown in Table 16, the UE uses The 3 bits indicate the first dimension index i 1,1 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
  • the UE indicates the first dimension index i 1,1 using 2 bits and the second index (ie, the second PMI) i 2 using 2 bits.
  • the embodiment of the present invention provides a method for transmitting a precoding matrix index, and defines a new sub-mode of PUCCH mode 1-1.
  • the UE receives configuration information and pilot information sent by the base station, and the configuration the configuration information includes a parameter, the number of two-dimensional antenna the first antenna port in a first dimension N 1 - 1, the first and second antenna ports O oversampling factor in a second dimension N 2 and the second oversampling factor O 2; Further, the UE information according to the pilot frequency, determining a first precoding matrix configured precoding matrix W W 1 and a second precoding matrix W 2, and, according to the configuration information of the UE, determining a transmission on PUCCH
  • the number of bits of the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0, such that the UE passes the Z bits in the PUCCH, and the first index And transmitting, to the base station, the second index, that is, the UE may determine, according to the
  • the embodiment of the present invention provides The transmission device of the precoding matrix index may be configured according to configuration information sent by the base station (ie, configuration parameters, the number of first antenna ports N 1 of the two-dimensional antenna in the first dimension and the first oversampling factor O 1 , and in the second dimension
  • the second antenna port number N 2 and the second oversampling factor O 2 are used to downsample the P candidate column vectors to obtain K column vectors constituting the precoding matrix W, since 0 ⁇ K ⁇ 64 ⁇ P, so that the UE can be configured to a first precoding matrix W 1 and W 2 second precoding matrix obtained from downsampling the K column vector on the basis of the existing 3GPP protocol, and to use the existing transmission mode
  • the first PMI and the second PMI are transmitted on the PUCCH.
  • the receiving unit 11 is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension;
  • the sampling unit 12 is configured to downsample the P candidate column vectors according to the configuration information, to obtain K column vectors constituting the precoding matrix W, where 0 ⁇ K ⁇ 64 ⁇ P;
  • the sending unit 14 is configured to send, by using a PUCCH, the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station, so that the base station according to the The first index and the second index determine the precoding matrix W.
  • the first vector set includes a first dimension candidate vector set v l and a second dimension candidate vector set u k
  • the determining unit 13 is further configured to determine the downsampled according to the configuration information.
  • the device further includes a calculating unit 15 , specifically, the calculating unit 15 is configured to calculate, according to the first oversampling factor O 1 , by using a first sampling formula Collecting the first dimension vector in the first dimension candidate vector set v l a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second set of candidate vectors u k by the first sampling formula Sampling frequency.
  • the calculating unit 15 is configured to collect, according to the configuration information, the first dimension vector from the first dimension of the candidate vector set v l by using a second sampling formula. And acquiring, according to the configuration information, the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula
  • the second sampling formula is: Otherwise, the second sampling formula is:
  • the second sampling formula is:
  • l' is an integer greater than or equal to
  • k' is an integer greater than or equal to
  • the number of antenna ports N 1 * N 2 * the number of polarization directions.
  • the calculating unit 15 is further configured to calculate the first dimension candidate vector set v l according to the configuration information, And calculating, according to the configuration information, the second dimension candidate vector set u k ,
  • the determining unit 13 is specifically configured to determine, according to the pilot information, the first precoding matrix W 1 from the K column vectors; and, according to the configuration parameter, from the first column vector of the precoding matrix W 1 is determined in the second precoding matrix W 2.
  • the sending unit 14 is specifically configured to pass the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 by using a PUCCH mode 1-1 submode 1 Sent to the base station.
  • the sending unit 14 is specifically configured to send, by using the PUCCH mode 1-1 sub-mode 2, the first index of the first pre-coding matrix W 1 and the second index of the second pre-coding matrix W 2 To the base station.
  • the sending unit 14 is further configured to receive, by using RRC signaling, the configuration information sent by the base station.
  • the transmission device of the precoding matrix index may be a UE (user setting) Prepare).
  • FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • the user equipment provided by the embodiment of the present invention may be used to implement the method implemented by the embodiments of the present invention shown in FIG. 1 to FIG.
  • FIGS. 8 For the convenience of description, only parts related to the embodiments of the present invention are shown. Without specific details, please refer to the embodiments of the present invention shown in FIGS.
  • the user equipment includes a processor 21, a memory 22, a transceiver 23, and a bus 24, and the processor 21, the transceiver 23, and the memory 22 are connected by the bus 14 and complete communication with each other.
  • the memory 22 is configured to store the first vector set, where the first vector set includes P candidate column vectors for constructing the precoding matrix W, 64 ⁇ P; the processor 11 can be configured to execute the sampling unit.
  • the specific function of the determining unit 13 and the calculating unit 15; the transceiver 23 can be used to perform the specific functions of the receiving unit 11 and the transmitting unit 14, and therefore will not be described herein.
  • the processor 21 herein may be a processor or a collective name of multiple processing elements.
  • the processor may be a Central Processing Unit (CPU), an Application Specific Integrated Circuit (ASIC), or one or more integrated circuits configured to implement the embodiments of the present invention.
  • CPU Central Processing Unit
  • ASIC Application Specific Integrated Circuit
  • DSPs digital singal processors
  • FPGAs Field Programmable Gate Arrays
  • the memory 22 may be a storage device or a collective name of a plurality of storage elements, and is used to store executable program code or parameters, data, and the like required for the operation of the access network management device.
  • the memory 22 (or the memory 23) may include a random access memory (RAM), and may also include a non-volatile memory such as a magnetic disk memory, a flash memory, or the like.
  • the bus 24 can be an Industry Standard Architecture (ISA) bus, a Peripheral Component (PCI) bus, or an extended industry standard architecture (Extended Industry Standard). Architecture, EISA) bus, etc. Can be specifically divided into address bus, data bus, control bus and so on. For ease of representation, only one thick line is shown in Figure 8, but it does not mean that there is only one bus or one type of bus.
  • ISA Industry Standard Architecture
  • PCI Peripheral Component
  • EISA Extended Industry Standard
  • Architecture Extended Industry Standard
  • an embodiment of the present invention provides a precoding matrix index transmission apparatus, where the UE includes P candidate column vectors for constructing a precoding matrix W, 64 ⁇ P.
  • the UE receives configuration information sent by the base station and pilot information, the configuration information includes configuration parameters, the number of two-dimensional antenna the first antenna port in a first dimension of the first through N 1 - 1, and the number of sampling factor of the second antenna port in a second dimension of the O N 2 And the second oversampling factor O 2 ; the UE downsamples the P candidate column vectors according to the configuration information, and obtains K column vectors constituting the precoding matrix W, 0 ⁇ K ⁇ 64 ⁇ P; it can be seen that By downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W.
  • the station is configured to transmit the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
  • the precoding matrix index transmission apparatus provided by the present invention,
  • the device specifically includes:
  • the receiving unit 31 is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension;
  • the number of bits is Z, Z>0;
  • the sending unit 33 is configured to send, by using the PUCCH, the first index and the second index to the base station according to the number of Z bits, so that the base station is configured according to the first index and the first The two indices determine the precoding matrix W.
  • the UE includes a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ⁇ P, wherein the determining unit 32 is specifically used Determining RI information and CQI information with the base station according to the pilot information; and determining, according to the RI information, a first pre-configuration of the precoding matrix W from the P candidate column vectors The coding matrix W 1 and the second precoding matrix W 2 .
  • the apparatus further comprising a joint coding unit 34, the joint encoding unit 34, a first W for the first precoding matrix index 1 and the RI information is jointly encoded Obtaining a first joint code value, where the sending unit 33 is further configured to send, by using the PUCCH, the first joint code value of Z1 bits to the base station by using the PUCCH;
  • the first index includes a first dimension index in a first dimension and a second dimension index in a second dimension
  • the joint encoding unit 34 is further configured to index the first dimension Performing joint coding with the RI information to obtain a second union code value; and jointly coding the second dimension index, the second index, and the CQI information to obtain a third union code value
  • the transmitting unit 33 is further configured to send the second joint code value and the third joint code value to the base station by using the PUCCH according to the number of Z bits.
  • the joint coding unit 34 is further configured to jointly encode the second dimension index and the RI information to obtain a fourth union code value; and, the first dimension index, the first The second index and the CQI information are jointly encoded to obtain a fifth joint code value, and the sending unit 33 is further configured to obtain the fourth joint code value and the fifth according to the Z number of bits.
  • the union code value is transmitted to the base station through the PUCCH.
  • the receiving unit 31 is further configured to receive an encoding indication sent by the base station, where the encoding indication is used to indicate that the RI information is jointly encoded with the first dimension index or the second dimension index.
  • the transmission device of the precoding matrix index may be a UE (user equipment).
  • FIG. 11 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • the user equipment provided by the embodiment of the present invention may be used to implement the method implemented by the embodiments of the present invention shown in FIG. 1 to FIG.
  • FIGS. 11 For the convenience of description, only parts related to the embodiments of the present invention are shown. Without specific details, please refer to the embodiments of the present invention shown in FIGS.
  • the user equipment includes a processor 41, a memory 42, a transceiver 43, and a bus 44.
  • the processor 41, the transceiver 43, and the memory 42 are connected by a bus 44 and complete communication with each other.
  • the memory 42 may be configured to store the first set of vectors, where the first set of vectors includes P candidate column vectors for constructing the precoding matrix W, 64 ⁇ P; the processor 41 may be configured to execute the determining unit. 32 and the specific function of the joint coding unit 34; the transceiver 43 can be used to perform the specific functions of the receiving unit 41 and the sending unit 44, and therefore will not be described herein.
  • the processor 41 herein may be a processor or a collective name of multiple processing elements.
  • the processor may be a Central Processing Unit (CPU), an Application Specific Integrated Circuit (ASIC), or one or more integrated circuits configured to implement the embodiments of the present invention. , for example: one or more microprocessors (digital singnal processor, DSP), or one or more Field Programmable Gate Arrays (FPGAs).
  • CPU Central Processing Unit
  • ASIC Application Specific Integrated Circuit
  • FPGAs Field Programmable Gate Arrays
  • the memory 42 may be a storage device or a collective name of a plurality of storage elements, and is used to store executable program code or parameters, data, and the like required for the operation of the access network management device.
  • the memory 22 (or the memory 23) may include a random access memory (RAM), and may also include a non-volatile memory such as a magnetic disk memory, a flash memory, or the like.
  • the bus 44 may be an Industry Standard Architecture (ISA) bus, a Peripheral Component (PCI) bus, or an Extended Industry Standard Architecture (EISA) bus. Can be specifically divided into address bus, data bus, control bus and so on. For ease of representation, only one thick line is shown in Figure 11, but it does not mean that there is only one bus or one type of bus.
  • ISA Industry Standard Architecture
  • PCI Peripheral Component
  • EISA Extended Industry Standard Architecture
  • an embodiment of the present invention provides a precoding matrix index transmission apparatus, which defines a new sub-mode of PUCCH mode 1-1.
  • the UE receives configuration information and pilot information sent by the base station, and the configuration the configuration information includes a parameter, the number of two-dimensional antenna the first antenna port in a first dimension N 1 - 1, the first and second antenna ports O oversampling factor in a second dimension N 2 and the second oversampling factor O 2; Further, the UE information according to the pilot frequency, determining a first precoding matrix configured precoding matrix W W 1 and a second precoding matrix W 2, and, according to the configuration information of the UE, determining a transmission on PUCCH
  • the number of bits of the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0, such that the UE passes the Z bits in the PUCCH, and the first index And transmitting, to the base station, the second index, that is, the UE may determine, according to the foregoing
  • the disclosed system, apparatus, and method may be implemented in other manners.
  • the device embodiments described above are merely illustrative.
  • the division of the modules or units is only a logical function division.
  • there may be another division manner for example, multiple units or components may be used. Combinations can be integrated into another system, or some features can be ignored or not executed.
  • the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be in an electrical, mechanical or other form.
  • the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
  • each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit.
  • the above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
  • the integrated unit if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable storage medium.
  • the technical solution of the present invention which is essential or contributes to the prior art, or all or part of the technical solution, may be embodied in the form of a software product stored in a storage medium.
  • a number of instructions are included to cause a computer device (which may be a personal computer, server, or network device, etc.) or a processor to perform all or part of the steps of the methods described in various embodiments of the present invention.
  • the foregoing storage medium includes: a U disk, a mobile hard disk, and a read-only memory.
  • a medium that can store program code such as a ROM (Read-Only Memory), a random access memory (RAM), a magnetic disk, or an optical disk.

Abstract

Embodiments of the present invention provide a method and apparatus for transmitting a precoding matrix index, which relate to the field of communications, and can transmit a precoding matrix index on a physical uplink control channel (PUCCH) in an application scenario of a two-dimensional antenna. The solution comprises: a UE receives configuration information and pilot information sent by a base station; the UE performs downsampling on P candidate column vectors according to the configuration information to obtain K column vectors that constitute a precoding matrix W, wherein 0<K≤64≤P; the UE determines, from the K column vectors according to the pilot information, a first precoding matrix W1 and a second precoding matrix W2 that constitute the precoding matrix W, wherein the precoding matrix W=W1*W2; and the UE sends a first index of the first precoding matrix W1 and a second index of the second precoding matrix W2 to the base station by means of a PUCCH, such that the base station determines the precoding matrix W according to the first index and the second index.

Description

一种预编码矩阵索引的传输方法及装置Method and device for transmitting precoding matrix index 技术领域Technical field
本发明涉及通信领域,尤其涉及一种预编码矩阵索引的传输方法及装置。The present invention relates to the field of communications, and in particular, to a method and an apparatus for transmitting a precoding matrix index.
背景技术Background technique
在第三代合作伙伴项目(3rd Generation Partnership Project 3GPP)长期演进(Long Term Evolution:LTE)版本13中,关于八天线码本的讨论已经达成以下一致意见。In the 3rd Generation Partnership Project 3GPP Long Term Evolution (LTE) Release 13, the following discussion has been reached regarding the discussion of the eight-antenna codebook.
目前的预编码矩阵W由两部分组成,即:W=W1*W2 The current precoding matrix W consists of two parts, namely: W = W 1 * W 2
其中,W1属于一个码本集合C1(码本集合是指候选的预编码矩阵的集合),W2属于另一个码本集合C2。W1用于指示宽带/长期的信道特性;W2用于指示W1内的子带/瞬时的信道特性。Wherein, W 1 belongs to one codebook set C1 (the codebook set refers to a set of candidate precoding matrices), and W 2 belongs to another codebook set C2. W 1 is used to indicate the broadband/long-term channel characteristics; W 2 is used to indicate the sub-band/instantaneous channel characteristics in W 1 .
具体的,在UE和基站进行通信时,UE会将确定出的W1的第一预编码矩阵索引(PMI,Precoding Matrix Index)和W2的第二预编码矩阵索引使用物理上行控制信道(Physical Uplink Control CHannel,PUCCH)中规定的比特数(例如5比特)反馈给基站,以使得基站根据该第一预编码矩阵索引和第二预编码矩阵索引确定W1和W2,最终根据W1和W2确定预编码矩阵,其中承载预编码索引指示的比特个数由预先预置的反馈模式确定。Specifically, when the UE and a base station for communication, the UE will determine the first precoding matrix index (PMI, Precoding Matrix Index) W 1 and a second pre-coding matrix index W 2 using a physical uplink control channel (Physical The number of bits (for example, 5 bits) specified in the Uplink Control CHannel, PUCCH) is fed back to the base station, so that the base station determines W 1 and W 2 according to the first precoding matrix index and the second precoding matrix index, and finally according to W 1 and W 2 determines a precoding matrix in which the number of bits carrying the precoding index indication is determined by a pre-preset feedback mode.
然而,随着二维天线(即2D天线)的引入,天线端口的数量和天线端口所指示的方向显著增多,直接导致码本集合C1和C2内的码本数量大幅增长,例如,在一维八天线场景下,码本集合C1可构造出16个W1,即UE可以使用4比特向基站反馈W1的第一预编码矩阵索引,而在二维十六天线端口场景下,码本集合C1可能构造出128个W1,即UE需要使用7比特才能向基站反馈W1的第一预编码矩阵索引,这远远超出了PUCCH中已有的反馈模式中规定的比特数,导致在二维天线的应用场景下无法通过PUCCH传输预编码矩阵索 引。However, with the introduction of two-dimensional antennas (ie, 2D antennas), the number of antenna ports and the direction indicated by the antenna ports are significantly increased, which directly leads to a large increase in the number of codebooks in the codebook sets C1 and C2, for example, in one dimension. In the eight-antenna scenario, the codebook set C1 can construct 16 W 1 , that is, the UE can use the 4 bits to feed back the first precoding matrix index of W 1 to the base station, and in the two-dimensional sixteen antenna port scenario, the codebook set. C1 may construct 128 W 1 , that is, the UE needs to use 7 bits to feed back the first precoding matrix index of W 1 to the base station, which is far beyond the number of bits specified in the feedback mode existing in the PUCCH, resulting in two In the application scenario of the dimension antenna, the precoding matrix index cannot be transmitted through the PUCCH.
发明内容Summary of the invention
本发明的实施例提供一种预编码矩阵索引的传输方法及装置,可在二维天线的应用场景下在PUCCH上传输预编码矩阵索引。An embodiment of the present invention provides a method and an apparatus for transmitting a precoding matrix index, which can transmit a precoding matrix index on a PUCCH in an application scenario of a two-dimensional antenna.
为达到上述目的,本发明的实施例采用如下技术方案:In order to achieve the above object, embodiments of the present invention adopt the following technical solutions:
第一方面,本发明的实施例提供一种预编码矩阵索引的传输方法,UE内包含有第一向量集合,该第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,该方法包括:该UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;该UE根据该配置信息,对该P个候选列向量进行下采样,得到构成该预编码矩阵W的K个列向量,0<K≤64≤P;该UE根据该导频信息,从该K个列向量中确定构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2;该UE通过物理上行链路控制信道PUCCH将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站,以使得该基站根据该第一索引和该第二索引确定该预编码矩阵W。In a first aspect, an embodiment of the present invention provides a method for transmitting a precoding matrix index, where a UE includes a first vector set, where the first vector set includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P, the method includes: the UE receiving configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 of the two-dimensional antenna in the first dimension, and a first oversampling factor O 1 , and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; the UE downsamples the P candidate column vectors according to the configuration information, to obtain the precoding matrix K column vectors of W, 0 < K ≤ 64 ≤ P; the UE determines, based on the pilot information, a first precoding matrix W 1 and a second precoding that construct the precoding matrix W from the K column vectors a matrix W 2 , wherein the precoding matrix W=W 1 *W 2 ; the UE passes the first index of the first precoding matrix W 1 and the second precoding matrix W 2 through a physical uplink control channel PUCCH Sending a second index to the base station, so that the base station according to the The first index and the second index determine the precoding matrix W.
可以看出,通过下采样,从原有的P个候选列向量中选择不超过64个列向量构成该预编码矩阵W,进而,UE可沿用现有的3GPP协议,根据导频信息从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2;并通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。It can be seen that, by downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W. Further, the UE can use the existing 3GPP protocol and derive K information according to the pilot information. Determining, in the column vector, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; and the first precoding matrix W 1 through the PUCCH The first index and the second index of the second precoding matrix W 2 are sent to the base station to implement transmission of the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
结合第一方面,在第一方面的第一种可能的实现方式中,该第一向量集合包括第一维待选向量集合vl和第二维待选向量集合uk,其中,该UE根据该配置信息,对该P个候选列向量进行下采样,得到构成该预编码矩阵的K个列向量,包括:该UE根据该配置信息确定 该下采样的采样频率;该UE按照该采样频率从该第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000001
从该第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000002
L*J=K,L、J、l'、k'均为大于等于0的整数。With reference to the first aspect, in a first possible implementation manner of the first aspect, the first vector set includes a first dimension candidate vector set v l and a second dimension candidate vector set u k , where the UE is configured according to The configuration information is used to downsample the P candidate column vectors to obtain K column vectors constituting the precoding matrix, including: determining, by the UE, the sampling frequency of the down sampling according to the configuration information; Collecting L first dimension vectors in the first dimension candidate vector set v l
Figure PCTCN2015094030-appb-000001
Collecting J second dimension vectors from the second dimension candidate vector set u k
Figure PCTCN2015094030-appb-000002
L*J=K, L, J, l', k' are all integers greater than or equal to zero.
结合第一方面的第一种可能的实现方式,在第一方面的第二种可能的实现方式中,该UE根据该配置信息确定该下采样的采样频率,包括:该UE根据该第一过采样因子O1,通过第一采样公式计算从该第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000003
的采样频率;该UE根据该第二过采样因子O2,通过该第一采样公式计算从该第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000004
的采样频率。With reference to the first possible implementation manner of the first aspect, in a second possible implementation manner of the first aspect, the determining, by the UE, the sampling frequency of the down sampling according to the configuration information, Sampling factor O 1 , calculating a first dimensional vector from the first set of candidate vectors v l by using a first sampling formula
Figure PCTCN2015094030-appb-000003
Sampling frequency; the UE calculates a second dimension vector from the second dimension of the candidate vector set u k by using the first sampling formula according to the second oversampling factor O 2
Figure PCTCN2015094030-appb-000004
Sampling frequency.
结合第一方面的第二种可能的实现方式,在第一方面的第三种可能的实现方式中,当天线端口数为12或者16时,该第一采样公式为:
Figure PCTCN2015094030-appb-000005
或者该第一采样公式为:
Figure PCTCN2015094030-appb-000006
当天线端口数为8时,该第一采样公式为:
Figure PCTCN2015094030-appb-000007
其中,l'为大于等于0的整数,k'为大于等于0的整数,该天线端口数=N1*N2*极化方向的数目。With reference to the second possible implementation of the first aspect, in a third possible implementation manner of the first aspect, when the number of antenna ports is 12 or 16, the first sampling formula is:
Figure PCTCN2015094030-appb-000005
Or the first sampling formula is:
Figure PCTCN2015094030-appb-000006
When the number of antenna ports is 8, the first sampling formula is:
Figure PCTCN2015094030-appb-000007
Wherein l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
结合第一方面的第一种可能的实现方式,在第一方面的第四种可能的实现方式中,该UE根据该配置信息确定该下采样的采样频率,包括:该UE根据该配置信息,通过第二采样公式从该第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000008
该UE根据该配置信息,通过该第二采样公式从该第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000009
With reference to the first possible implementation manner of the first aspect, in a fourth possible implementation manner of the foregoing aspect, the determining, by the UE, the sampling frequency of the down sampling according to the configuration information, Acquiring the first dimension vector from the first dimension candidate vector set v l by the second sampling formula
Figure PCTCN2015094030-appb-000008
The UE collects the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula according to the configuration information.
Figure PCTCN2015094030-appb-000009
结合第一方面的第四种可能的实现方式,在第一方面的第五种可能的实现方式中,当天线端口数为16或者12时,若O1=O2,且N1<N2,则该第二采样公式为:
Figure PCTCN2015094030-appb-000010
否则,该第二采样公式为:
Figure PCTCN2015094030-appb-000011
当天线端口数为8时,该第二采样公式为:
Figure PCTCN2015094030-appb-000012
其中,l'为大于等于0的整数,k'为大于等于0的整数,该天线端口数=N1*N2*极化方向的数目。In conjunction with the fourth possible implementation of the first aspect, in a fifth possible implementation manner of the first aspect, when the number of antenna ports is 16 or 12, if O 1 =O 2 , and N 1 <N 2 , the second sampling formula is:
Figure PCTCN2015094030-appb-000010
Otherwise, the second sampling formula is:
Figure PCTCN2015094030-appb-000011
When the number of antenna ports is 8, the second sampling formula is:
Figure PCTCN2015094030-appb-000012
Wherein l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
结合第一方面的第一至第五种可能的实现方式中的任一种实现方式,在第一方面的第六种可能的实现方式中,在该UE接收该基站发送的配置信息和导频信息之后,还包括:该UE根据该配置信息计算该第一维待选向量集合vl
Figure PCTCN2015094030-appb-000013
该UE根据该配置信息计算该第二维待选向量集合uk
Figure PCTCN2015094030-appb-000014
 With reference to any one of the first to fifth possible implementation manners of the first aspect, in a sixth possible implementation manner of the first aspect, the UE receives configuration information and a pilot sent by the base station After the information, the method further includes: calculating, by the UE, the first dimension of the candidate vector set v l according to the configuration information,
Figure PCTCN2015094030-appb-000013
 The UE calculates the second-dimensional candidate vector set u k according to the configuration information,
Figure PCTCN2015094030-appb-000014
结合第一方面的第一至第六种可能的实现方式中的任一种实现方式,在第一方面的第七种可能的实现方式中,该UE根据该导频信息,从该K个列向量中确定构造该预编码矩阵的第一预编码矩阵W1和第二预编码矩阵W2,包括:该UE根据该导频信息,从该K个列向量中确定该第一预编码矩阵W1;该UE根据该配置参数从该第一预编码矩阵W1的列向量中确定该第二预编码矩阵W2With reference to any one of the first to the sixth possible implementation manners of the first aspect, in a seventh possible implementation manner of the first aspect, the UE, according to the pilot information, from the K columns Determining, in the vector, the first precoding matrix W 1 and the second precoding matrix W 2 for constructing the precoding matrix, the UE determining, according to the pilot information, the first precoding matrix W from the K column vectors 1; the UE determines that the second precoding matrix W 2 from the first column vector of the precoding matrix W 1 based on the configuration parameters.
结合第一方面的第一至第七种可能的实现方式中的任一种实现方式,在第一方面的第八种可能的实现方式中,该UE通过PUCCH将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站,包括:该UE通过PUCCH模式1-1子模式1,将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站。With reference to any one of the first to the seventh possible implementation manners of the first aspect, in an eighth possible implementation manner of the first aspect, the UE, the first pre-coding matrix W 1 by using a PUCCH Sending the first index and the second index of the second precoding matrix W 2 to the base station, including: the UE adopting PUCCH mode 1-1 submode 1, the first index of the first precoding matrix W 1 and A second index of the second precoding matrix W 2 is sent to the base station.
结合第一方面的第一至第七种可能的实现方式中的任一种实现方式,在第一方面的第九种可能的实现方式中,该UE通过PUCCH将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站,包括:该UE通过PUCCH模式1-1子模式2,将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站。 With reference to any one of the first to the seventh possible implementation manners of the first aspect, in a ninth possible implementation manner of the first aspect, the UE, the first pre-coding matrix W 1 by using a PUCCH The first index and the second index of the second precoding matrix W 2 are sent to the base station, including: the UE passes the PUCCH mode 1-1 submode 2, and the first index of the first precoding matrix W 1 is A second index of the second precoding matrix W 2 is sent to the base station.
结合第一方面的第一至第九种可能的实现方式中的任一种实现方式,在第一方面的第十种可能的实现方式中,该UE接收该基站发送的配置信息,包括:该UE通过无线资源控制RRC信令接收该基站发送的该配置信息。With reference to any one of the first to the ninth possible implementation manners of the first aspect, in a tenth possible implementation manner of the foregoing aspect, the receiving, by the UE, the configuration information sent by the base station, The UE receives the configuration information sent by the base station by using radio resource control RRC signaling.
第二方面,本发明的实施例提供一种预编码矩阵索引的传输方法,包括:该UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;该UE根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2;该UE根据该配置信息,确定在物理上行链路控制信道PUCCH上用于传输该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0;该UE通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站,以使得该基站根据该第一索引和该第二索引确定该预编码矩阵W。In a second aspect, an embodiment of the present invention provides a method for transmitting a precoding matrix index, including: receiving, by the UE, configuration information and pilot information sent by a base station, where the configuration information includes configuration parameters, and the two-dimensional antenna is in the first dimension. a first antenna port number N 1 and a first oversampling factor O 1 , and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; the UE determines the configuration based on the pilot information a first precoding matrix W 1 and a second precoding matrix W 2 of the precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; the UE determines the physical uplink control channel according to the configuration information The number of bits on the PUCCH for transmitting the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0; the UE passes the PUCCH according to the Z The number of bits sends the first index and the second index to the base station, so that the base station determines the precoding matrix W according to the first index and the second index.
也就是说,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置参数的变化而灵活配置的,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。That is, the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the precoding matrix index is transmitted. The number of bits used may be flexibly configured according to changes in configuration parameters, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna.
结合第二方面,在第二方面的第一种可能的实现方式中,该UE内包含有第一向量集合,该第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,其中,该UE根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,包括:该UE根据该导频信息确定与该基站之间的秩指示RI信息和信道质量指示CQI信息;该UE根据该RI信息,从该P个候选列向量中确定构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2With reference to the second aspect, in a first possible implementation manner of the second aspect, the UE includes a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P, wherein the UE determines, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W, including: determining, by the UE, the base station according to the pilot information The rank indicating RI information and the channel quality indicating CQI information; the UE determining, according to the RI information, the first precoding matrix W 1 and the second precoding matrix constructing the precoding matrix W from the P candidate column vectors W 2 .
结合第二方面的第一种可能的实现方式,在第二方面的第二种 可能的实现方式中,该UE通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站,包括:该UE将该第一预编码矩阵W1的第一索引与该RI信息进行联合编码,得到第一联和编码值;该UE通过该PUCCH,将Z1个比特的该第一联和编码值通过该PUCCH发送至该基站;该UE通过该PUCCH,将Z2个比特的该第二预编码矩阵W2的第二索引与该CQI信息发送至该基站,Z1+Z2=Z,Z1>0,Z2>0。With reference to the first possible implementation manner of the second aspect, in a second possible implementation manner of the second aspect, the UE sends the first index and the second index according to the number of Z bits by using the PUCCH The base station includes: the UE jointly coding the first index of the first precoding matrix W 1 and the RI information to obtain a first joint code value; and the UE uses the PUCCH to set the first bit of Z1 bits And transmitting, by the PUCCH, the second index of the second precoding matrix W 2 of the Z2 bits and the CQI information to the base station, Z1+Z2=Z , Z1>0, Z2>0.
结合第二方面的第一种可能的实现方式,在第二方面的第三种可能的实现方式中,该第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,该UE通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站,包括:该UE将该第一维度索引与该RI信息进行联合编码,得到第二联和编码值;该UE将该第二维度索引、该第二索引和该CQI信息进行联合编码,得到第三联和编码值;该UE按照Z个比特个数,将该第二联和编码值与该第三联和编码值通过该PUCCH发送至该基站。In conjunction with the first possible implementation of the second aspect, in a third possible implementation of the second aspect, the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a two-dimensional index, wherein the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, where the UE jointly encodes the first dimension index and the RI information. Obtaining a second union code value; the UE jointly coding the second dimension index, the second index, and the CQI information to obtain a third union code value; the UE according to the Z number of bits, the first The binary sum code value and the third joint code value are transmitted to the base station through the PUCCH.
结合第二方面的第一种可能的实现方式,在第二方面的第四种可能的实现方式中,该第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,该UE通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站,包括:该UE将该第二维度索引与该RI信息进行联合编码,得到第四联和编码值;该UE将该第一维度索引、该第二索引和该CQI信息进行联合编码,得到第五联和编码值;该UE按照Z个比特个数,将该得到第四联和编码值与该第五联和编码值通过该PUCCH发送至该基站。In conjunction with the first possible implementation of the second aspect, in a fourth possible implementation of the second aspect, the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a second dimension index, wherein the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, where the UE jointly encodes the second dimension index and the RI information. Obtaining a fourth joint code value, the UE jointly coding the first dimension index, the second index, and the CQI information to obtain a fifth joint code value; the UE obtains the number of Z bits according to the number of Z bits. The fourth union code value and the fifth union code value are transmitted to the base station through the PUCCH.
结合第二方面的第三或第四种可能的实现方式,在第二方面的第五种可能的实现方式中,在该UE通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站之前,还包括:该UE接收该基站发送的编码指示,该编码指示用于指示该RI信息与该第一维度索引或该第二维度索引进行联合编码。With reference to the third or fourth possible implementation of the second aspect, in a fifth possible implementation manner of the second aspect, the first index and the number of the Z bits are used by the UE by using the PUCCH Before the second index is sent to the base station, the method further includes: receiving, by the UE, an encoding indication sent by the base station, where the encoding indication is used to indicate that the RI information is jointly encoded with the first dimension index or the second dimension index.
第三方面,本发明的实施例提供一种UE,该UE包括:处理器、 存储器以及收发器,其中,该存储器,用于存储第一向量集合,该第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P;该收发器,用于接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;该处理器,用于根据该配置信息,对该P个候选列向量进行下采样,得到构成该预编码矩阵W的K个列向量,0<K≤64≤P;以及,根据该导频信息,从该K个列向量中确定构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2;该收发器,还用于通过PUCCH将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站,以使得该基站根据该第一索引和该第二索引确定该预编码矩阵W。In a third aspect, an embodiment of the present invention provides a UE, where the UE includes: a processor, a memory, and a transceiver, where the memory is configured to store a first vector set, where the first vector set includes a pre-configuration a P candidate matrix vector of the coding matrix W, 64 ≤ P; the transceiver is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna of the two-dimensional antenna in the first dimension a port number N 1 and a first oversampling factor O 1 , and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; the processor configured to use the P according to the configuration information The candidate column vectors are downsampled to obtain K column vectors constituting the precoding matrix W, 0<K≤64≤P; and, according to the pilot information, determining the precoding matrix from the K column vectors a first precoding matrix W 1 and a second precoding matrix W 2 of W, wherein the precoding matrix W=W 1 *W 2 ; the transceiver is further configured to use the PUCCH to the first precoding matrix W 1 the first index and the second precoding matrix W 2 is the second cable Transmits to the base station, so that the base station determines the precoding matrix based on the first index and the second index W.
可以看出,通过下采样,从原有的P个候选列向量中选择不超过64个列向量构成该预编码矩阵W,进而,UE可沿用现有的3GPP协议,根据导频信息从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2;并通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。It can be seen that, by downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W. Further, the UE can use the existing 3GPP protocol and derive K information according to the pilot information. Determining, in the column vector, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; and the first precoding matrix W 1 through the PUCCH The first index and the second index of the second precoding matrix W 2 are sent to the base station to implement transmission of the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
结合第三方面,在第三方面的第一种可能的实现方式中,该处理器,具体用于根据该配置信息确定该下采样的采样频率;以及,按照该采样频率从第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000015
从第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000016
L*J=K,L、J、l'、k'均为大于等于0的整数;其中,该第一向量集合包括第一维待选向量集合vl和第二维待选向量集合ukWith reference to the third aspect, in a first possible implementation manner of the third aspect, the processor is configured to determine a sampling frequency of the down sampling according to the configuration information, and select a candidate to be selected from the first dimension according to the sampling frequency. Collecting L first dimension vectors in vector set v l
Figure PCTCN2015094030-appb-000015
Collecting J second-dimensional vectors from the second-dimensional candidate vector set u k
Figure PCTCN2015094030-appb-000016
L*J=K, L, J, l', k' are integers greater than or equal to 0; wherein the first vector set includes a first dimension candidate vector set v l and a second dimension candidate vector set u k .
结合第三方面的第一种可能的实现方式,在第三方面的第二种可能的实现方式中,该处理器,具体用于根据该第一过采样因子O1,通过第一采样公式计算从该第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000017
的采样频率;以及,根据该第二过采样因子O2,通过该第一采 样公式计算从该第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000018
的采样频率;With reference to the first possible implementation manner of the third aspect, in a second possible implementation manner of the third aspect, the processor is configured to calculate, according to the first oversampling factor O 1 , by using a first sampling formula Collecting the first dimension vector from the first dimension candidate vector set v l
Figure PCTCN2015094030-appb-000017
a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second dimensional candidate vector set u k by using the first sampling formula
Figure PCTCN2015094030-appb-000018
Sampling frequency
其中,当天线端口数为12或者16时,该第一采样公式为:
Figure PCTCN2015094030-appb-000019
Figure PCTCN2015094030-appb-000020
或者该第一采样公式为:
Figure PCTCN2015094030-appb-000021
当天线端口数为8时,该第一采样公式为:
Figure PCTCN2015094030-appb-000022
l'为大于等于0的整数,k'为大于等于0的整数,该天线端口数=N1*N2*极化方向的数目。Wherein, when the number of antenna ports is 12 or 16, the first sampling formula is:
Figure PCTCN2015094030-appb-000019
Figure PCTCN2015094030-appb-000020
Or the first sampling formula is:
Figure PCTCN2015094030-appb-000021
When the number of antenna ports is 8, the first sampling formula is:
Figure PCTCN2015094030-appb-000022
l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
结合第三方面的第一种可能的实现方式,在第三方面的第三种可能的实现方式中,该处理器,具体用于根据该配置信息,通过第二采样公式从该第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000023
以及,根据该配置信息,通过该第二采样公式从该第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000024
With reference to the first possible implementation manner of the third aspect, in a third possible implementation manner of the third aspect, the processor is configured to use the second sampling formula to obtain the first Collecting the first dimension vector in the selected vector set v l
Figure PCTCN2015094030-appb-000023
And acquiring, according to the configuration information, the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula
Figure PCTCN2015094030-appb-000024
其中,当天线端口数为16或者12时,若O1=O2,且N1<N2,则该第二采样公式为:
Figure PCTCN2015094030-appb-000025
否则,该第二采样公式为:
Figure PCTCN2015094030-appb-000026
当天线端口数为8时,该第二采样公式为:
Figure PCTCN2015094030-appb-000027
Figure PCTCN2015094030-appb-000028
l'为大于等于0的整数,k'为大于等于0的整数,该天线端口数=N1*N2*极化方向的数目。Wherein, when the number of antenna ports is 16 or 12, if O 1 =O 2 and N 1 <N 2 , the second sampling formula is:
Figure PCTCN2015094030-appb-000025
Otherwise, the second sampling formula is:
Figure PCTCN2015094030-appb-000026
When the number of antenna ports is 8, the second sampling formula is:
Figure PCTCN2015094030-appb-000027
Figure PCTCN2015094030-appb-000028
l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
结合第三方面的第一至第三种可能的实现方式中的任一种实现方式,在第三方面的第四种可能的实现方式中,该处理器,还用于根据该配置信息计算该第一维待选向量集合vl
Figure PCTCN2015094030-appb-000029
Figure PCTCN2015094030-appb-000030
以及,根据该配置信息计算该第二维待选向量集合uk
Figure PCTCN2015094030-appb-000031
 With reference to any one of the first to third possible implementation manners of the third aspect, in a fourth possible implementation manner of the third aspect, the processor is further configured to calculate the The first dimension of the candidate vector set v l ,
Figure PCTCN2015094030-appb-000029
Figure PCTCN2015094030-appb-000030
 And calculating, according to the configuration information, the second dimension candidate vector set u k ,
Figure PCTCN2015094030-appb-000031
结合第三方面的第一至第四种可能的实现方式中的任一种实现方式,在第三方面的第五种可能的实现方式中,该处理器,具体用于根据该导频信息,从该K个列向量中确定该第一预编码矩阵W1;以及,根据该配置参数从该第一预编码矩阵W1的列向量中确定该第二预编码矩阵W2With reference to any one of the first to fourth possible implementation manners of the third aspect, in a fifth possible implementation manner of the third aspect, the processor is specifically configured to use, according to the pilot information, the K is determined from the first column vector in the precoding matrix W 1; and the configuration parameter determines the second precoding matrix W 2 from the first column vector of the precoding matrix W 1 in accordance with.
结合第三方面的第一至第五种可能的实现方式中的任一种实现方式,在第三方面的第六种可能的实现方式中,该收发器,具体用于通过PUCCH模式1-1子模式1,将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站。With reference to any one of the first to fifth possible implementation manners of the third aspect, in a sixth possible implementation manner of the third aspect, the transceiver is specifically configured to pass the PUCCH mode 1-1 sub-mode 1, the first precoding matrix W 1 of the first index and the second index of precoding matrix W 2 is transmitted to the second base station.
结合第三方面的第一至第五种可能的实现方式中的任一种实现方式,在第三方面的第七种可能的实现方式中,该收发器,具体用于通过PUCCH模式1-1子模式2,将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站。With reference to any one of the first to fifth possible implementation manners of the third aspect, in a seventh possible implementation manner of the third aspect, the transceiver is specifically configured to pass the PUCCH mode 1-1 sub-mode 2, the first precoding matrix W 1 of the first index and the second index of precoding matrix W 2 is transmitted to the second base station.
结合第三方面的第一至第七种可能的实现方式中的任一种实现方式,在第三方面的第八种可能的实现方式中,该收发器,具体用于通过RRC信令接收该基站发送的该配置信息。With reference to any one of the first to the seventh possible implementation manners of the third aspect, in an eighth possible implementation manner of the third aspect, the transceiver is configured to receive the RRC signaling The configuration information sent by the base station.
第四方面,本发明的实施例提供一种UE,包括:处理器、存储器以及收发器,其中,该收发器,用于接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;该处理器,用于根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2;以及,根据该配置信息,确定在PUCCH上用于传输该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0;该收发器,还用于通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站,以使得该基站根据该第一索引和该第二索引确定该预编码矩阵 W。In a fourth aspect, an embodiment of the present invention provides a UE, including: a processor, a memory, and a transceiver, where the transceiver is configured to receive configuration information and pilot information sent by a base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; And determining, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; The configuration information determines that the number of bits used to transmit the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 on the PUCCH is Z, and Z>0; The first index and the second index are sent to the base station according to the number of Z bits by using the PUCCH, so that the base station determines the precoding matrix according to the first index and the second index. .
也就是说,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置参数的变化而灵活配置的,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。That is, the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the precoding matrix index is transmitted. The number of bits used may be flexibly configured according to changes in configuration parameters, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna.
结合第四方面,在第四方面的第一种可能的实现方式中,该存储器,用于存储第一向量集合,该第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P;该处理器,具体用于根据该导频信息确定与该基站之间的秩指示RI信息和信道质量指示CQI信息;以及,根据该RI信息,从该P个候选列向量中确定构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2With reference to the fourth aspect, in a first possible implementation manner of the fourth aspect, the memory is configured to store a first vector set, where the first vector set includes P candidate column vectors for constructing the precoding matrix W 64 ≤ P; the processor is specifically configured to determine, according to the pilot information, rank indication RI information and channel quality indication CQI information with the base station; and, according to the RI information, from the P candidate column vectors Determining a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W.
结合第四方面的第一种可能的实现方式,在第四方面的第二种可能的实现方式中,该处理器,还用于将该第一预编码矩阵W1的第一索引与该RI信息进行联合编码,得到第一联和编码值;该收发器,还用于通过该PUCCH,将Z1个比特的该第一联和编码值通过该PUCCH发送至该基站;以及,通过该PUCCH,将Z2个比特的该第二预编码矩阵W2的第二索引与该CQI信息发送至该基站,Z1+Z2=Z,Z1>0,Z2>0。In conjunction with the first possible implementation of the fourth aspect, in a second possible implementation manner of the fourth aspect, the processor is further configured to use the first index of the first precoding matrix W 1 and the RI The information is jointly encoded to obtain a first joint code value; the transceiver is further configured to send, by using the PUCCH, the first joint code value of Z1 bits to the base station by using the PUCCH; and, by using the PUCCH, The second index of the second precoding matrix W 2 of Z2 bits and the CQI information are transmitted to the base station, Z1+Z2=Z, Z1>0, and Z2>0.
结合第四方面的第一种可能的实现方式,在第四方面的第三种可能的实现方式中,该第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,该处理器,还用于将该第一维度索引与该RI信息进行联合编码,得到第二联和编码值;以及,将该第二维度索引、该第二索引和该CQI信息进行联合编码,得到第三联和编码值;该收发器,还用于按照Z个比特个数,将该第二联和编码值与该第三联和编码值通过该PUCCH发送至该基站。With reference to the first possible implementation manner of the fourth aspect, in a third possible implementation manner of the fourth aspect, the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a second dimension index, wherein the processor is further configured to jointly encode the first dimension index and the RI information to obtain a second union code value; and, the second dimension index, the second index, and the The CQI information is jointly encoded to obtain a third joint code value. The transceiver is further configured to send the second joint code value and the third joint code value to the third joint code value according to the Z number of bits. Base station.
结合第四方面的第一种可能的实现方式,在第四方面的第四种可能的实现方式中,该第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,该处理器,还用于将该第 二维度索引与该RI信息进行联合编码,得到第四联和编码值;以及,将该第一维度索引、该第二索引和该CQI信息进行联合编码,得到第五联和编码值;该收发器,还用于按照Z个比特个数,将该得到第四联和编码值与该第五联和编码值通过该PUCCH发送至该基站。With reference to the first possible implementation manner of the fourth aspect, in a fourth possible implementation manner of the fourth aspect, the first index includes a first dimension index in a first dimension and a second dimension in a second dimension a two-dimensional index, wherein the processor is also used to The second dimension index is jointly encoded with the RI information to obtain a fourth joint code value; and the first dimension index, the second index, and the CQI information are jointly encoded to obtain a fifth joint code value; And sending, by the number of Z bits, the obtained fourth joint code value and the fifth joint code value to the base station by using the PUCCH.
结合第四方面的第三或第四种可能的实现方式,在第四方面的第五种可能的实现方式中,该收发器,还用于接收该基站发送的编码指示,该编码指示用于指示该RI信息与该第一维度索引或该第二维度索引进行联合编码。In conjunction with the third or fourth possible implementation of the fourth aspect, in a fifth possible implementation manner of the fourth aspect, the transceiver is further configured to receive an encoding indication sent by the base station, where the encoding indication is used Instructing the RI information to be jointly encoded with the first dimension index or the second dimension index.
第五方面,本发明的实施例提供一种预编码矩阵索引的传输装置,该装置内包含有第一向量集合,该第一向量集合中包含有用于构造预编码矩阵W的P个候选列向量,64≤P,该装置具体包括:接收单元,用于接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;采样单元,用于根据该配置信息,对该P个候选列向量进行下采样,得到构成该预编码矩阵W的K个列向量,0<K≤64≤P;确定单元,用于根据该导频信息,从该K个列向量中确定构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2;发送单元,用于通过PUCCH将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站,以使得该基站根据该第一索引和该第二索引确定该预编码矩阵W。In a fifth aspect, an embodiment of the present invention provides a precoding matrix index transmission apparatus, where the apparatus includes a first vector set, where the first vector set includes P candidate column vectors for constructing a precoding matrix W. And 64 ≤ P, the device specifically includes: a receiving unit, configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a number of first antenna ports N 1 of the two-dimensional antenna in the first dimension, and a first oversampling factor O 1 , and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; a sampling unit, configured to perform the P candidate column vectors according to the configuration information Sampling, obtaining K column vectors constituting the precoding matrix W, 0<K≤64≤P; determining unit, configured to determine, according to the pilot information, the first structure of the precoding matrix W from the K column vectors a precoding matrix W 1 and a second precoding matrix W 2 , wherein the precoding matrix W=W 1 *W 2 ; a transmitting unit, configured to use the PUCCH to first index the first precoding matrix W 1 the second precoding matrix W 2 is the second cable Transmits to the base station, so that the base station determines the precoding matrix based on the first index and the second index W.
可以看出,通过下采样,从原有的P个候选列向量中选择不超过64个列向量构成该预编码矩阵W,进而,UE可沿用现有的3GPP协议,根据导频信息从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2;并通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。It can be seen that, by downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W. Further, the UE can use the existing 3GPP protocol and derive K information according to the pilot information. Determining, in the column vector, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; and the first precoding matrix W 1 through the PUCCH The first index and the second index of the second precoding matrix W 2 are sent to the base station to implement transmission of the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
结合第五方面,在第五方面的第一种可能的实现方式中,该第 一向量集合包括第一维待选向量集合vl和第二维待选向量集合uk,该确定单元,还用于根据该配置信息确定该下采样的采样频率;该采样单元,具体用于按照该采样频率从该第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000032
从该第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000033
L*J=K,L、J、l'、k'均为大于等于0的整数。With reference to the fifth aspect, in a first possible implementation manner of the fifth aspect, the first vector set includes a first dimension candidate vector set v l and a second dimension candidate vector set u k , the determining unit, further And determining, by the configuration information, the sampling frequency of the down sampling; the sampling unit is configured to collect L first dimensional vectors from the first dimension of the candidate vector set v l according to the sampling frequency.
Figure PCTCN2015094030-appb-000032
Collecting J second dimension vectors from the second dimension candidate vector set u k
Figure PCTCN2015094030-appb-000033
L*J=K, L, J, l', k' are all integers greater than or equal to zero.
结合第五方面的第一种可能的实现方式,在第五方面的第二种可能的实现方式中,该装置还包括计算单元,具体的,该计算单元,具体用于根据该第一过采样因子O1,通过第一采样公式计算从该第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000034
的采样频率;以及,根据该第二过采样因子O2,通过该第一采样公式计算从该第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000035
的采样频率。With reference to the first possible implementation of the fifth aspect, in a second possible implementation manner of the fifth aspect, the device further includes a computing unit, and specifically, the calculating unit, specifically, according to the first oversampling The factor O 1 is calculated by the first sampling formula to acquire the first dimension vector from the first dimension of the candidate vector set v l
Figure PCTCN2015094030-appb-000034
a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second set of candidate vectors u k by the first sampling formula
Figure PCTCN2015094030-appb-000035
Sampling frequency.
其中,当天线端口数为12或者16时,该第一采样公式为:
Figure PCTCN2015094030-appb-000036
Figure PCTCN2015094030-appb-000037
或者该第一采样公式为:
Figure PCTCN2015094030-appb-000038
当天线端口数为8时,该第一采样公式为:
Figure PCTCN2015094030-appb-000039
l'为大于等于0的整数,k'为大于等于0的整数,该天线端口数=N1*N2*极化方向的数目。Wherein, when the number of antenna ports is 12 or 16, the first sampling formula is:
Figure PCTCN2015094030-appb-000036
Figure PCTCN2015094030-appb-000037
Or the first sampling formula is:
Figure PCTCN2015094030-appb-000038
When the number of antenna ports is 8, the first sampling formula is:
Figure PCTCN2015094030-appb-000039
l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
结合第五方面的第一种可能的实现方式,在第五方面的第三种可能的实现方式中,该装置还包括计算单元,具体的,该计算单元,具体用于根据该配置信息,通过第二采样公式从该第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000040
以及,根据该配置信息,通过该第二采样公式从该第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000041
With reference to the first possible implementation manner of the fifth aspect, in a third possible implementation manner of the fifth aspect, the device further includes a computing unit, and the computing unit is specifically configured to pass the configuration information according to the configuration information. The second sampling formula collects the first dimensional vector from the first set of candidate vector sets v l
Figure PCTCN2015094030-appb-000040
And acquiring, according to the configuration information, the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula
Figure PCTCN2015094030-appb-000041
其中,当天线端口数为16或者12时,若O1=O2,且N1<N2,则该第二采样公式为:
Figure PCTCN2015094030-appb-000042
否则,该第二采样公式为:
Figure PCTCN2015094030-appb-000043
当天线端口数为8时,该第二采样公式为:
Figure PCTCN2015094030-appb-000044
Figure PCTCN2015094030-appb-000045
l'为大于等于0的整数,k'为大于等于0的整数,该天线端口数=N1*N2*极化方向的数目。Wherein, when the number of antenna ports is 16 or 12, if O 1 =O 2 and N 1 <N 2 , the second sampling formula is:
Figure PCTCN2015094030-appb-000042
Otherwise, the second sampling formula is:
Figure PCTCN2015094030-appb-000043
When the number of antenna ports is 8, the second sampling formula is:
Figure PCTCN2015094030-appb-000044
Figure PCTCN2015094030-appb-000045
l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
结合第五方面的第一至第三种可能的实现方式中的任一种实现方式,在第五方面的第四种可能的实现方式中,该计算单元,还用于根据该配置信息计算该第一维待选向量集合vl
Figure PCTCN2015094030-appb-000046
以及,根据该配置信息计算该第二维待选向量集合uk
Figure PCTCN2015094030-appb-000047
 With reference to any one of the first to third possible implementation manners of the fifth aspect, in a fourth possible implementation manner of the fifth aspect, the calculating unit is further configured to calculate the The first dimension of the candidate vector set v l ,
Figure PCTCN2015094030-appb-000046
 And calculating, according to the configuration information, the second dimension candidate vector set u k ,
Figure PCTCN2015094030-appb-000047
结合第五方面的第一至第四种可能的实现方式中的任一种实现方式,在第五方面的第五种可能的实现方式中,该确定单元,具体用于根据该导频信息,从该K个列向量中确定该第一预编码矩阵W1;以及,根据该配置参数从该第一预编码矩阵W1的列向量中确定该第二预编码矩阵W2With reference to any one of the first to fourth possible implementation manners of the fifth aspect, in a fifth possible implementation manner of the fifth aspect, the determining unit is specifically configured to use, according to the pilot information, the K is determined from the first column vector in the precoding matrix W 1; and the configuration parameter determines the second precoding matrix W 2 from the first column vector of the precoding matrix W 1 in accordance with.
结合第五方面的第一至第五种可能的实现方式中的任一种实现方式,在第五方面的第六种可能的实现方式中,该发送单元,具体用于通过PUCCH模式1-1子模式1,将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站。With reference to any one of the first to fifth possible implementation manners of the fifth aspect, in a sixth possible implementation manner of the fifth aspect, the sending unit is specifically configured to pass the PUCCH mode 1-1 sub-mode 1, the first precoding matrix W 1 of the first index and the second index of precoding matrix W 2 is transmitted to the second base station.
或者,该发送单元,具体用于通过PUCCH模式1-1子模式2,将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至该基站。Alternatively, the sending unit is specifically configured to send, by using the PUCCH mode 1-1 sub-mode 2, the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station.
结合第五方面的第一至第六种可能的实现方式中的任一种实现方式,在第五方面的第七种可能的实现方式中,该发送单元,还用于通过RRC信令接收该基站发送的该配置信息。With reference to any one of the first to the sixth possible implementation manners of the fifth aspect, in a seventh possible implementation manner of the fifth aspect, the sending unit is further configured to receive the RRC signaling The configuration information sent by the base station.
第六方面,本发明的实施例提供一种预编码矩阵索引的传输装置,该装置具体包括:接收单元,用于接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天 线端口数N2和第二过采样因子O2;确定单元,用于根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2;以及,根据该配置信息,确定在物理上行链路控制信道PUCCH上用于传输该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0;发送单元,用于通过该PUCCH,按照Z个比特个数将该第一索引和该第二索引发送至该基站,以使得该基站根据该第一索引和该第二索引确定该预编码矩阵W。In a sixth aspect, an embodiment of the present invention provides a precoding matrix index transmission apparatus, where the apparatus specifically includes: a receiving unit, configured to receive configuration information and pilot information sent by a base station, where the configuration information includes configuration parameters, and two-dimensional a first antenna port number N 1 and a first oversampling factor O 1 of the antenna in the first dimension, and a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension; Determining, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; and, according to the configuration information Determining, on the physical uplink control channel PUCCH, the number of bits used to transmit the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0 a sending unit, configured to send, by using the PUCCH, the first index and the second index to the base station according to the number of Z bits, so that the base station determines the precoding matrix according to the first index and the second index. W.
也就是说,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置参数的变化而灵活配置的,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。That is, the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the precoding matrix index is transmitted. The number of bits used may be flexibly configured according to changes in configuration parameters, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna.
结合第六方面,在第六方面的第一种可能的实现方式中,该UE内包含有第一向量集合,该第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,其中,该确定单元,具体用于根据该导频信息确定与该基站之间的RI信息和CQI信息;以及,根据该RI信息,从该P个候选列向量中确定构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2With reference to the sixth aspect, in a first possible implementation manner of the sixth aspect, the UE includes a first vector set, where the first vector set includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P, wherein the determining unit is specifically configured to determine RI information and CQI information between the base station and the base station according to the pilot information; and, according to the RI information, determine, construct the pre-determination from the P candidate column vectors. The first precoding matrix W 1 and the second precoding matrix W 2 of the encoding matrix W.
结合第六方面的第一种可能的实现方式,在第六方面的第二种可能的实现方式中,该装置还包括联合编码单元,该联合编码单元,用于将该第一预编码矩阵W1的第一索引与该RI信息进行联合编码,得到第一联和编码值;该发送单元,还用于通过该PUCCH,将Z1个比特的该第一联和编码值通过该PUCCH发送至该基站;以及,通过该PUCCH,将Z2个比特的该第二预编码矩阵W2的第二索引与该CQI信息发送至该基站,Z1+Z2=Z,Z1>0,Z2>0。With reference to the first possible implementation manner of the sixth aspect, in a second possible implementation manner of the sixth aspect, the apparatus further includes a joint coding unit, where the joint coding unit is configured to use the first precoding matrix a first index for the jointly coded RI information, and the encoded value to obtain a first joint; the transmission unit is further configured to, with the first and the encoded value Z1 to the bits transmitted by the PUCCH by the PUCCH a base station; and, by the PUCCH, transmitting a second index of the second precoding matrix W 2 of Z2 bits and the CQI information to the base station, Z1+Z2=Z, Z1>0, and Z2>0.
结合第六方面的第一种可能的实现方式,在第六方面的第三种可能的实现方式中,该装置还包括联合编码单元,该第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其 中,该联合编码单元,还用于将该第一维度索引与该RI信息进行联合编码,得到第二联和编码值;以及,将该第二维度索引、该第二索引和该CQI信息进行联合编码,得到第三联和编码值;该发送单元,还用于按照Z个比特个数,将该第二联和编码值与该第三联和编码值通过该PUCCH发送至该基站。With reference to the first possible implementation manner of the sixth aspect, in a third possible implementation manner of the sixth aspect, the apparatus further includes a joint coding unit, where the first index includes a first dimension index in the first dimension And a second dimension index on the second dimension, The joint coding unit is further configured to jointly encode the first dimension index and the RI information to obtain a second union code value; and perform the second dimension index, the second index, and the CQI information. Joint coding, to obtain a third joint code value; the sending unit is further configured to send the second joint code value and the third joint code value to the base station by using the PUCCH according to the number of Z bits.
又或者,该联合编码单元,还用于将该第二维度索引与该RI信息进行联合编码,得到第四联和编码值;以及,将该第一维度索引、该第二索引和该CQI信息进行联合编码,得到第五联和编码值;该发送单元,还用于按照Z个比特个数,将该得到第四联和编码值与该第五联和编码值通过该PUCCH发送至该基站。Or the joint coding unit is further configured to jointly encode the second dimension index and the RI information to obtain a fourth union code value; and, the first dimension index, the second index, and the CQI information Performing joint coding to obtain a fifth joint code value; the sending unit is further configured to send, according to the Z number of bits, the obtained fourth joint code value and the fifth joint code value to the base station by using the PUCCH .
结合第六方面的第三种可能的实现方式,在第六方面的第四种可能的实现方式中,该接收单元,还用于接收该基站发送的编码指示,该编码指示用于指示该RI信息与该第一维度索引或该第二维度索引进行联合编码。With reference to the third possible implementation manner of the sixth aspect, in a fourth possible implementation manner of the sixth aspect, the receiving unit is further configured to receive an encoding indication sent by the base station, where the encoding indication is used to indicate the RI The information is jointly encoded with the first dimension index or the second dimension index.
至此,本发明的实施例提供一种预编码矩阵索引的传输方法及装置,UE通过下采样,从原有的P个候选列向量中选择不超过64个列向量构成该预编码矩阵W,进而,UE可沿用现有的3GPP协议,根据导频信息从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2;并通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引;或者,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置参数的变化而灵活配置的,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。So far, an embodiment of the present invention provides a method and an apparatus for transmitting a precoding matrix index, and the UE selects no more than 64 column vectors from the original P candidate column vectors to form the precoding matrix W by downsampling, and further The UE may use the existing 3GPP protocol to determine, from the K column vectors, the first precoding matrix W 1 and the second precoding matrix W 2 that construct the precoding matrix W according to the pilot information, where the precoding matrix W= W 1 *W 2 ; and transmitting the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station by using the PUCCH to implement transmission through the PUCCH in the application scenario of the two-dimensional antenna Precoding matrix index; or, the UE may determine the number of bits used to transmit the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined submode, the transmission precoding The number of bits used for the matrix index may be flexibly configured according to the change of the configuration parameters, so as to transmit the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
附图说明DRAWINGS
为了更清楚地说明本发明实施例或现有技术中的技术方案,下面将对实施例或现有技术描述中所需要使用的附图作简单地介绍。 In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art description will be briefly described below.
图1为本发明实施例提供的一种传输预编码矩阵索引的应用场景示意图;FIG. 1 is a schematic diagram of an application scenario of transmitting a precoding matrix index according to an embodiment of the present disclosure;
图2为本发明实施例提供的一种预编码矩阵索引的传输方法的流程示意图一;2 is a schematic flowchart 1 of a method for transmitting a precoding matrix index according to an embodiment of the present invention;
图3为本发明实施例提供的一种下采样方法的示意图一;3 is a schematic diagram 1 of a downsampling method according to an embodiment of the present invention;
图4为本发明实施例提供的一种下采样方法的示意图二;4 is a second schematic diagram of a downsampling method according to an embodiment of the present invention;
图5为本发明实施例提供的一种预编码矩阵索引的传输方法的流程示意图二;FIG. 5 is a schematic flowchart 2 of a method for transmitting a precoding matrix index according to an embodiment of the present disclosure;
图6为本发明实施例提供的一种预编码矩阵索引的传输装置的结构示意图一;FIG. 6 is a schematic structural diagram 1 of a device for transmitting a precoding matrix index according to an embodiment of the present disclosure;
图7为本发明实施例提供的一种预编码矩阵索引的传输装置的结构示意图二;FIG. 7 is a schematic structural diagram 2 of a transmission apparatus of a precoding matrix index according to an embodiment of the present disclosure;
图8为本发明实施例提供的一种用户设备的硬件结构示意图一;FIG. 8 is a schematic structural diagram 1 of a hardware structure of a user equipment according to an embodiment of the present disclosure;
图9为本发明实施例提供的一种预编码矩阵索引的传输装置的结构示意图三;FIG. 9 is a schematic structural diagram 3 of a transmission apparatus of a precoding matrix index according to an embodiment of the present disclosure;
图10为本发明实施例提供的一种预编码矩阵索引的传输装置的结构示意图四;FIG. 10 is a schematic structural diagram 4 of a transmission apparatus of a precoding matrix index according to an embodiment of the present disclosure;
图11为本发明实施例提供的一种用户设备的硬件结构示意图二。FIG. 11 is a second schematic structural diagram of a hardware structure of a user equipment according to an embodiment of the present disclosure.
具体实施方式detailed description
下面将结合本发明实施例中的附图,对本发明实施例中的技术方案进行清楚、完整地描述,显然,所描述的实施例仅仅是本发明一部分实施例,而不是全部的实施例。The technical solutions in the embodiments of the present invention are clearly and completely described in the following with reference to the accompanying drawings in the embodiments of the present invention. It is obvious that the described embodiments are only a part of the embodiments of the present invention, but not all embodiments.
另外,术语“第一”、“第二”仅用于描述目的,而不能理解为指示或暗示相对重要性或者隐含指明所指示的技术特征的数量。由此,限定有“第一”、“第二”的特征可以明示或者隐含地包括一个或者更多个该特征。在本发明的描述中,除非另有说明,“多个”的含义是两个或两个以上。 In addition, the terms "first" and "second" are used for descriptive purposes only, and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, features defining "first" and "second" may include one or more of the features either explicitly or implicitly. In the description of the present invention, "a plurality" means two or more unless otherwise stated.
本文中术语“和/或”,仅仅是一种描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示:单独存在A,同时存在A和B,单独存在B这三种情况。另外,本文中字符“/”,一般表示前后关联对象是一种“或”的关系。The term "and/or" in this context is merely an association describing the associated object, indicating that there may be three relationships, for example, A and / or B, which may indicate that A exists separately, and both A and B exist, respectively. B these three situations. In addition, the character "/" in this article generally indicates that the contextual object is an "or" relationship.
本发明实施例提供的预编码矩阵索引的传输方法,可应用于LTE系统以及未来的5G系统中的MIMO(Multiple-Input Multiple-Output,多输入多输出)传输场景。具体的,参见图1,为本本发明实施例提供的预编码矩阵索引的传输方法的应用场景示意图,其中,基站可以向UE发送导频信息,进而,UE根据该导频信息以及已经确定好的码本集合(即用于构造预编码矩阵W的P个候选列向量,在一维天线的应用场景下,P的个数通常小于64)进行信道估计,确定信道状态信息(Channel State Information,CSI),例如,秩指示(Rank Indicator,RI)信息、信道质量指示(Channel Quality Indicator,CQI)信息和预编码矩阵指示(Precoding Matrix Indicator,PMI)信息等。The method for transmitting a precoding matrix index provided by the embodiment of the present invention can be applied to a MIMO (Multiple-Input Multiple-Output) transmission scenario in an LTE system and a future 5G system. Specifically, FIG. 1 is a schematic diagram of an application scenario of a method for transmitting a precoding matrix index according to an embodiment of the present invention, where a base station may send pilot information to a UE, and further, the UE according to the pilot information and has been determined. The codebook set (that is, the P candidate column vectors used to construct the precoding matrix W, the number of P is usually less than 64 in the application scenario of the one-dimensional antenna) performs channel estimation to determine channel state information (CSI). For example, Rank Indicator (RI) information, Channel Quality Indicator (CQI) information, and Precoding Matrix Indicator (PMI) information, and the like.
其中,由于预编码矩阵W=W1*W2,因此,该PMI信息可以具体包括构造该预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,这样,UE可进一步将该RI信息、CQI信息以及第一预编码矩阵W1的第一索引(即第一PMI)和第二预编码矩阵W2的第二索引(即第二PMI)通过联合编码(Joint source-channel coding,JSCC)等方式发送至基站,这样,基站便可以根据该第一PMI确定第一预编码矩阵W1,根据该第二PMI确定第一预编码矩阵W1,最终得到预编码矩阵W。Wherein, since the pre-coding matrix W = W 1 * W 2, so that the PMI information may comprise specific configuration of the precoding matrix W of the first precoding matrix W 1 and second precoding matrix W 2, so that, the UE further Combining the RI information, the CQI information, and the first index of the first precoding matrix W 1 (ie, the first PMI) and the second index of the second precoding matrix W 2 (ie, the second PMI) by joint coding (Joint source- channel coding, JSCC), etc. to the base station, so the base station can determine the first precoding matrix W based on the first PMI. 1,. 1, the precoding matrix W finally obtained the second PMI precoding matrix W is determined in accordance with a first .
具体的,在现有的3GPP协议中,UE向基站发送PMI信息时可通过PUSCH(Physical Uplink Shared Channel,物理上行共享信道)进行非周期反馈,其中,用于发送PMI信息的比特个数随着可配置参数的变化而变化,又或者,UE向基站发送PMI信息时可通过PUCCH上的固定个数(例如5比特)的比特位进行周期性反馈,例如,采用3GPP协议中已经规定的PUCCH模式1-1子模式1和子模式 2反馈PMI信息。Specifically, in the existing 3GPP protocol, when the UE sends the PMI information to the base station, the aperiodic feedback can be performed through the PUSCH (Physical Uplink Shared Channel), where the number of bits used to transmit the PMI information follows The configurable parameter changes, or the UE may periodically send back a fixed number (for example, 5 bits) of bits on the PUCCH when transmitting the PMI information to the base station, for example, adopting the PUCCH mode already specified in the 3GPP protocol. 1-1 submode 1 and submode 2 Feedback PMI information.
但是,随着二维天线(即2D天线)的引入,天线端口的数量和天线端口所指示的方向显著增多,也就是说用于构造预编码矩阵W的候选列向量的个数P显著增多,那么,从这P个候选列向量中构造出的第一预编码矩阵W1和第二预编码矩阵W2的个数也随之增加,因此,沿用3GPP协议中已经规定的PUCCH模式1-1子模式1和子模式2,使用固定个数比特位反馈第一PMI和第二PMI的方法已经不再适用。However, with the introduction of a two-dimensional antenna (ie, a 2D antenna), the number of antenna ports and the direction indicated by the antenna port are significantly increased, that is, the number P of candidate column vectors for constructing the precoding matrix W is significantly increased. Then, the number of the first precoding matrix W 1 and the second precoding matrix W 2 constructed from the P candidate column vectors is also increased, and therefore, the PUCCH mode 1-1 already specified in the 3GPP protocol is used. Submode 1 and submode 2, the method of feeding back the first PMI and the second PMI using a fixed number of bits is no longer applicable.
因此,本发明实施例针对二维天线的应用场景下如何在PUCCH上传输预编码矩阵索引(即第一PMI和第二PMI)这一问题给出两种可行的解决方式。Therefore, the embodiments of the present invention provide two feasible solutions to how to transmit the precoding matrix index (ie, the first PMI and the second PMI) on the PUCCH in the application scenario of the two-dimensional antenna.
方式一,为了保证可继续沿用PUCCH模式1-1子模式1和子模式2中使用固定个数比特位传输预编码矩阵索引,同时满足二维天线的应用场景,本发明的实施例提供的预编码矩阵索引的传输方法,可根据基站发送的配置信息(即配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2),对所述P个候选列向量进行下采样,得到构成所述预编码矩阵W的K个列向量,由于0<K≤64≤P,使得UE可以在现有3GPP协议的基础上,从下采样得到的K个列向量中构造第一预编码矩阵W1和第二预编码矩阵W2,并沿用现有的传输模式在PUCCH上传输该第一PMI和第二PMI。In the first mode, in order to ensure that the precoding matrix index can be transmitted in the PUCCH mode 1-1 sub-mode 1 and the sub-mode 2 using a fixed number of bits, and the application scenario of the two-dimensional antenna is satisfied, the pre-coding provided by the embodiment of the present invention The method for transmitting the matrix index may be based on configuration information sent by the base station (ie, configuration parameters, the number of first antenna ports N 1 and the first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and the second dimension) a second antenna port number N 2 and a second oversampling factor O 2 ), and down-sampling the P candidate column vectors to obtain K column vectors constituting the precoding matrix W, since 0<K≤64≤ P, such that the UE can construct the first precoding matrix W 1 and the second precoding matrix W 2 from the downsampled K column vectors on the basis of the existing 3GPP protocol, and use the existing transmission mode in the PUCCH The first PMI and the second PMI are transmitted on.
方式二,为解决针对二维天线的应用场景下如何在PUCCH上传输预编码矩阵索引(即第一PMI和第二PMI)这一问题,本发明的实施例中,定义了一种新的PUCCH模式1-1的子模式,其中,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置信息的变化而灵活配置的,可适用于二维天线的应用场景下预编码矩阵索引的传输。 In the second embodiment, in order to solve the problem of how to transmit the precoding matrix index (ie, the first PMI and the second PMI) on the PUCCH in the application scenario for the two-dimensional antenna, in the embodiment of the present invention, a new PUCCH is defined. a sub-mode of mode 1-1, wherein the UE may determine the number of bits used for transmitting the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, in the newly defined sub-mode, The number of bits used for transmitting the precoding matrix index can be flexibly configured according to the change of the configuration information, and can be applied to the transmission of the precoding matrix index in the application scenario of the two-dimensional antenna.
以下实施例中将针对上述二种解决二维天线的应用场景下预编码矩阵索引的传输问题的解决思路进行详细阐述。In the following embodiments, the solution to the problem of the transmission problem of the precoding matrix index in the application scenario of the two-dimensional antenna is described in detail.
实施例1Example 1
针对上述方式一,本发明的实施例提供一种预编码矩阵索引的传输方法,其中,UE内包含有第一向量集合,该第一向量集合中包含有用于构造预编码矩阵W的P个候选列向量,64≤P,如图2所示,该方法具体包括:For the foregoing manner 1, the embodiment of the present invention provides a method for transmitting a precoding matrix index, where the UE includes a first vector set, where the first vector set includes P candidates for constructing the precoding matrix W. Column vector, 64 ≤ P, as shown in Figure 2, the method specifically includes:
101、UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2101. The UE receives configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second The second antenna port number N 2 and the second oversampling factor O 2 in the dimension.
102、UE根据该配置信息,对该P个候选列向量进行下采样,得到构成预编码矩阵W的K个列向量,0<K≤64≤P。102. The UE downsamples the P candidate column vectors according to the configuration information, and obtains K column vectors constituting the precoding matrix W, where 0<K≤64≤P.
103、UE根据该导频信息,从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2103. The UE determines, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W from the K column vectors, where the precoding matrix W=W 1 *W 2 .
104、UE通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以使得基站根据第一索引和第二索引确定预编码矩阵W。104, UE a first index of a first pre-coding matrix W 1 and a second precoding matrix W 2 is the second index to the base station via PUCCH, so that the base station determines the precoding matrix based on the first index and the second index W.
在步骤101中,UE可以分别接收基站发送的配置信息和导频信息。In step 101, the UE may separately receive configuration information and pilot information sent by the base station.
例如,UE可以接收基站发送的参考信号集,该参考信号集中包含有导频信息,即基站连续发射未经调制的直接序列扩频信号,它使得UE能够获得前向码分多址信道时限,提供相关解调相位参考。For example, the UE may receive a reference signal set sent by the base station, where the reference signal set includes pilot information, that is, the base station continuously transmits the unmodulated direct sequence spread spectrum signal, which enables the UE to obtain the forward code division multiple access channel time limit. Provides a relevant demodulation phase reference.
又例如,UE可以接收基站发送的RRC(Radio Resource Control,无线资源控制)信令,该RRC信令中携带有该配置信息。具体的,该配置信息包括配置参数(即Codebook-Subset-SelectionConfig,3GPP协议中简称为config)、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数 N2和第二过采样因子O2For example, the UE may receive RRC (Radio Resource Control) signaling sent by the base station, where the RRC signaling carries the configuration information. Specifically, the configuration information includes a configuration parameter (ie, Codebook-Subset-SelectionConfig, referred to as config in the 3GPP protocol), a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension. And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension.
需要说明的是,N1是指在某个极化方向上第一维度上的天线端口数目,类似的,N2是指在该极化方向上第二维度上的天线端口数目。It should be noted that N 1 refers to the number of antenna ports in the first dimension in a certain polarization direction. Similarly, N 2 refers to the number of antenna ports in the second dimension in the polarization direction.
为了方便描述,后续实施例中将该第一天线端口数N1、第一过采样因子O1、第二天线端口数N2和第二过采样因子O2表示为(N1,N2)、(O1、O2)。For convenience of description, in the subsequent embodiment, the first antenna port number N 1 , the first oversampling factor O 1 , the second antenna port number N 2 , and the second oversampling factor O 2 are represented as (N 1 , N 2 ). , (O 1 , O 2 ).
在步骤102中,UE根据步骤101中获取的该配置信息,对该P个候选列向量进行下采样(即对于一个样值序列,例如该P个候选列向量,间隔几个样值取样一次,这样得到新序列就是原序列的下采样),得到构成预编码矩阵W的K个列向量,0<K≤64≤P。In step 102, the UE downsamples the P candidate column vectors according to the configuration information acquired in step 101 (that is, samples a sample interval, for example, the P candidate column vectors, are sampled at intervals). Thus, the new sequence is the downsampling of the original sequence, and K column vectors constituting the precoding matrix W are obtained, 0 < K ≤ 64 ≤ P.
可以看出这K个列向量是上述P个候选列向量的一个子集,进过下采样后的列向量的个数K为小于等于64的整数,而在现有的对一维天线的预编码矩阵索引的传输过程中,构成预编码矩阵W的向量的个数也是小于等于64的,因此,UE通过对该P个候选列向量进行下采样得到该K个列向量后,便可沿用现有技术中预编码矩阵索引的传输方法进行后续传输步骤,从而基于现有的预编码矩阵索引的传输方法,实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。It can be seen that the K column vectors are a subset of the P candidate column vectors, and the number K of the downsampled column vectors is an integer less than or equal to 64, and the existing one for the one-dimensional antenna is In the transmission process of the coding matrix index, the number of vectors constituting the precoding matrix W is also less than or equal to 64. Therefore, the UE can obtain the K column vectors by downsampling the P candidate column vectors. The transmission method of the precoding matrix index in the technology performs the subsequent transmission step, so that the precoding matrix index is transmitted through the PUCCH in the application scenario of the two-dimensional antenna based on the existing transmission method of the precoding matrix index.
这里需要说明的是,上述P个候选列向量(即第一向量集合),可以是在执行该预编码矩阵索引的传输方法之前,UE预先存储在自身的存储器中的;上述P个候选列向量也可以是在步骤101之后,UE根据基站发送的该配置信息计算得来的,其中,该第一向量集合中具体包括第一维待选向量集合vl和第二维待选向量集合ukIt should be noted that the foregoing P candidate column vectors (ie, the first vector set) may be pre-stored in the memory of the UE before performing the transmission method of the precoding matrix index; the P candidate column vectors After the step 101, the UE is calculated according to the configuration information sent by the base station, where the first vector set specifically includes a first dimension candidate vector set v l and a second dimension candidate vector set u k . .
示例性的,在步骤101之后,UE根据配置信息中的第一天线端口数N1和第一过采样因子O1,计算所述第一维待选向量集合vlExemplarily, after step 101, the UE calculates the first dimension of the candidate vector set v l according to the first antenna port number N 1 and the first oversampling factor O 1 in the configuration information:
Figure PCTCN2015094030-appb-000048
Figure PCTCN2015094030-appb-000048
并且,UE根据该配置信息中的第二天线端口数N2和第二过采样 因子O2,计算第二维待选向量集合ukAnd, the UE calculates the second-dimensional candidate vector set u k according to the second antenna port number N 2 and the second over-sampling factor O 2 in the configuration information:
Figure PCTCN2015094030-appb-000049
Figure PCTCN2015094030-appb-000049
至此,UE便可以获得由第一维待选向量集合vl和第一维待选向量集合vl组成的第一向量集合中的P个候选列向量。So far, the UE can obtain P candidate column vectors in the first vector set composed of the first-dimensional candidate vector set v l and the first-dimensional candidate vector set v l .
下面将继续进一步阐述步骤102中UE根据该配置信息,对该P个候选列向量进行下采样,得到构成预编码矩阵W的K个列向量的实现方法。In the following, the UE further performs the method of down-sampling the P candidate column vectors according to the configuration information in step 102 to obtain K column vectors constituting the precoding matrix W.
具体的,UE根据该配置信息确定下采样的采样频率(即确定从P个候选列向量中每间隔几个列项向量进行采样);进而UE按照该采样频率从第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000050
并从第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000051
L*J=K,0<L,0<J,l'为大于等于0的整数,k'为大于等于0的整数。Specifically, the UE determines, according to the configuration information, a sampling frequency of the down sampling (ie, determining sampling from each of the P candidate column vectors); and further, the UE selects from the first dimension of the candidate vector according to the sampling frequency. l collect L first dimension vectors
Figure PCTCN2015094030-appb-000050
And collecting J second-dimensional vectors from the second-dimensional candidate vector set u k
Figure PCTCN2015094030-appb-000051
L*J=K, 0<L, 0<J, l' is an integer greater than or equal to 0, and k' is an integer greater than or equal to zero.
例如,UE根据该第一过采样因子O1,通过第一采样公式计算从该第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000052
的采样频率;并且,UE根据第二过采样因子O2,通过该第一采样公式计算从第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000053
的采样频率。For example, the UE calculates L first-dimensional vectores from the first-dimensional candidate vector set v l by using the first sampling formula according to the first over-sampling factor O 1 .
Figure PCTCN2015094030-appb-000052
Sampling frequency; and, according to the second oversampling factor O 2 , the UE calculates J second dimension vectors from the second dimension candidate vector set u k by using the first sampling formula calculation
Figure PCTCN2015094030-appb-000053
Sampling frequency.
其中,当天线端口数为12或者16时,该第一采样公式为:
Figure PCTCN2015094030-appb-000054
Figure PCTCN2015094030-appb-000055
或者所述第一采样公式为:
Figure PCTCN2015094030-appb-000056
当天线端口数为8时,所述第一采样公式为:
Figure PCTCN2015094030-appb-000057
Wherein, when the number of antenna ports is 12 or 16, the first sampling formula is:
Figure PCTCN2015094030-appb-000054
Figure PCTCN2015094030-appb-000055
Or the first sampling formula is:
Figure PCTCN2015094030-appb-000056
When the number of antenna ports is 8, the first sampling formula is:
Figure PCTCN2015094030-appb-000057
本发明实施例中描述的“天线端口数”,是指在每一个极化方向上每一维度内天线端口个数的总和,以2个极化方向为例,该天线端口数=N1*N2*2。The "number of antenna ports" described in the embodiment of the present invention refers to the sum of the number of antenna ports in each dimension in each polarization direction. Taking two polarization directions as an example, the number of antenna ports = N 1 * N 2 *2.
示例性的,若(N1,N2)=(4,2)且(O1,O2)=(8,4),那么,根上述公式(11)和(12),可以计算出第一向量集合中的第一维待选向量集合vl和第二维待选向量集合uk,如图3所示,可以得到由32个候选列向量构 成的第一维待选向量集合vl和由8个候选列向量构成的第二维待选向量集合uk,此时,P=N1*O1*N2*O2=32*8=256。Exemplarily, if (N 1 , N 2 )=(4,2) and (O 1 , O 2 )=(8,4), then the above formulas (11) and (12) can be calculated. The first dimension candidate vector set v l and the second dimension candidate vector set u k in a vector set, as shown in FIG. 3, can obtain a first dimension candidate vector set v l composed of 32 candidate column vectors . And a second-dimensional candidate vector set u k composed of 8 candidate column vectors, at this time, P = N 1 * O 1 * N 2 * O 2 = 32 * 8 = 256.
此时,在天线端口数为12的情况下,第一采样公式为:
Figure PCTCN2015094030-appb-000058
Figure PCTCN2015094030-appb-000059
即l=2l',k=2k′,参见图4,当l分别等于0、1、…、15时,在第一维度上,从32个候选列向量构成的第一维待选向量集合vl中分别选择第0个,第2个,…直至第30个候选列向量为下采样向量;当k分别等于0、1、3、4时,在第二维度上,从8个候选列向量构成的第二维待选向量集合uk中分别选择第0个,第2个,第4个和第6个候选列向量为下采样向量,这样,便可采集到共K个列向量,K=L*J=16*4=64。At this time, in the case where the number of antenna ports is 12, the first sampling formula is:
Figure PCTCN2015094030-appb-000058
Figure PCTCN2015094030-appb-000059
That is, l=2l', k=2k', see FIG. 4, when l is equal to 0, 1, ..., 15, respectively, in the first dimension, the first dimension of the candidate vector set v composed of 32 candidate column vectors l select 0th, 2nd, ... until the 30th candidate column vector is the downsampling vector; when k is equal to 0, 1, 3, 4 respectively, in the second dimension, from 8 candidate column vectors The 0th, 2nd, 4th, and 6th candidate column vectors of the second-dimensional candidate vector set u k are respectively selected as a down-sampling vector, so that a total of K column vectors can be acquired, K =L*J=16*4=64.
类似的,UE还可以根据该第一过采样因子O1、第二过采样因子O2、第一天线端口数N1、第二天线端口数N2,通过第二采样公式计算从该第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000060
的采样频率,以及从第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000061
的采样频率。Similarly, the UE may further calculate, according to the first oversampling factor O 1 , the second oversampling factor O 2 , the first antenna port number N 1 , and the second antenna port number N 2 , by using the second sampling formula. Collecting L first-dimensional vectors in the dimension of the candidate vector set v l
Figure PCTCN2015094030-appb-000060
Sampling frequency, and collecting J second-dimensional vectors from the second-dimensional candidate vector set u k
Figure PCTCN2015094030-appb-000061
Sampling frequency.
其中,当天线端口数为16或者12时,若O1=O2,且N1<N2,则所述第二采样公式为:
Figure PCTCN2015094030-appb-000062
否则,所述第二采样公式为:
Figure PCTCN2015094030-appb-000063
当天线端口数为8时,所述第二采样公式为:
Figure PCTCN2015094030-appb-000064
Figure PCTCN2015094030-appb-000065
 Wherein, when the number of antenna ports is 16 or 12, if O 1 =O 2 and N 1 <N 2 , the second sampling formula is:
Figure PCTCN2015094030-appb-000062
Otherwise, the second sampling formula is:
Figure PCTCN2015094030-appb-000063
When the number of antenna ports is 8, the second sampling formula is:
Figure PCTCN2015094030-appb-000064
Figure PCTCN2015094030-appb-000065
可以看出,与上述第一采样公式不同的是,进行下采样的频率除了由(O1,O2)的取值决定以外,还需要由(N1,N2)的取值决定。It can be seen that, unlike the above first sampling formula, the frequency of downsampling needs to be determined by the value of (N 1 , N 2 ) in addition to the value of (O 1 , O 2 ).
另外,作为上述下采样方法的一种变形,UE还可以通过下述方法实现对P个候选列向量进行下采样的过程。In addition, as a variant of the above downsampling method, the UE may also implement a process of downsampling P candidate column vectors by the following method.
具体的,UE可以预先设置本地过采样因子
Figure PCTCN2015094030-appb-000066
其中,
Figure PCTCN2015094030-appb-000067
可以为(2,4)、(4,2)、(2,2)或者(4,4)中的任一个,这样,UE在步骤101中获得配置信息中的(N1,N2)之后,可以令
Figure PCTCN2015094030-appb-000068
进而将(N1,N2)和(O1、O2)的取值带入公式(11)和(12)中,此时得到的
Figure PCTCN2015094030-appb-000069
进而得到由
Figure PCTCN2015094030-appb-000070
Figure PCTCN2015094030-appb-000071
组成的K个列向量。Specifically, the UE may preset a local oversampling factor.
Figure PCTCN2015094030-appb-000066
among them,
Figure PCTCN2015094030-appb-000067
It may be any one of (2, 4), (4, 2), (2, 2) or (4, 4), such that after the UE obtains (N 1 , N 2 ) in the configuration information in step 101 Can make
Figure PCTCN2015094030-appb-000068
Further, the values of (N 1 , N 2 ) and (O 1 , O 2 ) are brought into the formulas (11) and (12), and the obtained
Figure PCTCN2015094030-appb-000069
Further obtained by
Figure PCTCN2015094030-appb-000070
with
Figure PCTCN2015094030-appb-000071
The K column vectors that make up.
至此,UE根据该配置信息,对该P个候选列向量进行下采样,得到构成预编码矩阵W的K个列向量。So far, the UE downsamples the P candidate column vectors according to the configuration information to obtain K column vectors constituting the precoding matrix W.
在步骤103中,UE根据步骤101中获得的该导频信息,从步骤102中确定的K个列向量中,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2In step 103, the UE determines, according to the pilot information obtained in step 101, the first precoding matrix W 1 and the second precoding matrix W that construct the precoding matrix W from the K column vectors determined in step 102. 2 , wherein the precoding matrix W=W 1 *W 2 .
具体的,UE根据该导频信息可以进行信道估计,确定RI信息、CQI信息,进而,UE根据该RI信息,从该K个列向量中确定第一预编码矩阵W1;UE根据配置参数(config)从第一预编码矩阵W1的列向量中确定第二预编码矩阵W2Specifically, the UE based on the pilot information may perform channel estimation, determine the RI information and the CQI information, and further, the UE, determining a first precoding matrix W 1 from the K column vector based on the RI information; the UE according to the configuration parameters ( config) determining a second precoding matrix W 2 from the first column vector of the precoding matrix W 1.
以下以RANK等于1为例进行具体说明,UE根据该导频信息进行信道估计,确定RANK等于1,并根据该RI信息从步骤102中确定的K个列向量中选择8个构造第一预编码矩阵W1,由于64个列向量至多可以构造出16(24)个8列的第一预编码矩阵W1,因此,UE可以使用4个比特未来指示第一预编码矩阵W1的第一索引(即第一PMI)。The following takes the RANK equal to 1 as an example for specific description. The UE performs channel estimation according to the pilot information, determines that RANK is equal to 1, and selects eight first precodings from the K column vectors determined in step 102 according to the RI information. The matrix W 1 , since the 64 column vectors can construct at most 16 (2 4 ) 8 columns of the first precoding matrix W 1 , the UE can use 4 bits to indicate the first of the first precoding matrix W 1 in the future. Index (ie the first PMI).
进一步地,UE需要根据步骤101中确定的配置参数,从第一预编码矩阵W1的列向量中确定第二预编码矩阵W2。具体的,以RUI信息为1(即rank=1)举例,3GPP协议中规定了如表1中所示的四种配置参数(config1-4)与第二预编码矩阵W2的第二索引(即第二PMI,)之间的对应关系,以及如表2中所示的第二PMI(表2中用i2表示)与预编码矩阵W之间的对应关系。 Further, the UE needs to determine the second precoding matrix W 2 from the column vectors of the first precoding matrix W 1 according to the configuration parameters determined in step 101. Specifically, the RUI information is 1 (ie, rank=1), and the 3GPP configuration defines four configuration parameters (config1-4) as shown in Table 1 and a second index of the second precoding matrix W 2 ( That is, the correspondence between the second PMI, and the correspondence between the second PMI (indicated by i 2 in Table 2) and the precoding matrix W as shown in Table 2.
表1Table 1
ConfigConfig 选择出的第二PMISelect the second PMI (s1,s2)(s 1 , s 2 )
Config1Config1 0-30-3 (1,1)(1,1)
Config2Config2 0-7,16-230-7, 16-23 (2,2)(2,2)
Config3Config3 0-3,8-11,20-23,28-310-3, 8-11, 20-23, 28-31 (2,2)(2,2)
Config4Config4 0-150-15 (2,2)(2,2)
表2Table 2
Figure PCTCN2015094030-appb-000072
Figure PCTCN2015094030-appb-000072
其中,
Figure PCTCN2015094030-appb-000073
among them,
Figure PCTCN2015094030-appb-000073
Figure PCTCN2015094030-appb-000074
Figure PCTCN2015094030-appb-000074
Figure PCTCN2015094030-appb-000075
Figure PCTCN2015094030-appb-000075
这样,UE最终根据配置参数以及表2中的对应关系确定第二预编码矩阵W2的第二索引,即i′2In this way, the UE finally determines the second index of the second precoding matrix W 2 , i' 2 , according to the configuration parameters and the correspondence in Table 2 .
进而,在步骤104中,UE通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以使得基站根据第一索引和第二索引确定预编码矩阵W。Further, in step 104, the UE sends the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station through the PUCCH, so that the base station determines according to the first index and the second index. Precoding matrix W.
具体的,UE仍然可以通过3GPP协议中已经定义的PUCCH模式1-1子模式1(即PUCCH mode 1-1 submode1,可参见3GPP TS 36.213 协议中的相关描述),将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至基站。Specifically, the UE may still pass the PUCCH mode 1-1 submode 1 (ie, PUCCH mode 1-1 submode1, which has been defined in the 3GPP protocol, and related description in the 3GPP TS 36.213 protocol), and the first precoding matrix W A first index of 1 and a second index of the second precoding matrix W 2 are transmitted to the base station.
或者,UE通过PUCCH模式1-1子模式2(PUCCH mode 1-1 submode2,可参见3GPP TS 36.213协议中的相关描述),将该第一预编码矩阵W1的第一索引和该第二预编码矩阵W2的第二索引发送至基站。Alternatively, the UE uses the PUCCH mode 1-1 submode 2 (PUCCH mode 1-1 submode2, see related description in the 3GPP TS 36.213 protocol), the first index of the first precoding matrix W 1 and the second pre A second index of the coding matrix W 2 is transmitted to the base station.
具体的,在PUCCH模式1-1子模式1中,RI信息与第一PMI进行联合编码,将联合编码后得到的编码值携带在report(报告)1中向基站反馈,而第二PMI与CQI信息携带在report2中向基站直接反馈。PUCCH模式1-1子模式1中RI信息与第一PMI进行联合编码的码本如表3所示,共占用PUCCH中的5个比特位。Specifically, in the PUCCH mode 1-1 sub-mode 1, the RI information is jointly encoded with the first PMI, and the coded value obtained by the joint coding is carried in the report 1 to feed back to the base station, and the second PMI and the CQI are transmitted. The information is carried in report2 and directly fed back to the base station. The codebook jointly encoded by the RI information and the first PMI in the PUCCH mode 1-1 sub-mode 1 is as shown in Table 3, and occupies 5 bits in the PUCCH.
表3table 3
Figure PCTCN2015094030-appb-000076
Figure PCTCN2015094030-appb-000076
在PUCCH模式1-1子模式2中,RI信息携带在report 1中向基站反馈,第一PMI和第二PMI进行联合编码,将联合编码后得到的编码值携带在report 2中向基站反馈,第一PMI和第二PMI进行联合编码的码本如表4所示,第一PMI和第二PMI进行联合编码后的编码值采用4个比特进行传输,其中3比特位用于选择W1的第一索引,1个比特位用于选择固定向量的相位(co-phase)来指示W2 的第二索引。In the PUCCH mode 1-1 sub-mode 2, the RI information is carried in the report 1 and is fed back to the base station. The first PMI and the second PMI are jointly coded, and the coded value obtained by the joint coding is carried in the report 2 to feed back to the base station. The codebook jointly coded by the first PMI and the second PMI is as shown in Table 4. The coded value of the joint coding of the first PMI and the second PMI is transmitted by using 4 bits, wherein 3 bits are used to select the first part of W1. An index, 1 bit is used to select the phase of the fixed vector (co-phase) to indicate W2 The second index.
表4Table 4
Figure PCTCN2015094030-appb-000077
Figure PCTCN2015094030-appb-000077
可以看出,无论是采用PUCCH模式1-1子模式1还是PUCCH模式1-1子模式2传输预编码矩阵索引,传输RI信息的周期大于或者等于传输PMI的周期,由于RI的变化的频率要慢于PMI的变化频率,这样可以保证RI信息的反馈周期至少等于PMI的反馈周期,符合信道变化特性,从而节省了反馈RI信息的资源开销。……It can be seen that whether the PUCCH mode 1-1 sub-mode 1 or the PUCCH mode 1-1 sub-mode 2 transmission precoding matrix index is used, the period of transmitting the RI information is greater than or equal to the period of the transmission PMI, and the frequency of the change of the RI is required. The frequency of change of the PMI is slower than that of the PMI. This ensures that the feedback period of the RI information is at least equal to the feedback period of the PMI and conforms to the channel variation characteristics, thereby saving the resource overhead of feeding back the RI information. ......
至此,本发明的实施例提供一种预编码矩阵索引的传输方法,UE内包含有用于构造预编码矩阵W的P个候选列向量,64≤P,具体的,UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;UE根据该配置信息,对该P个候选列向量进行下采样,得到构成预编码矩阵W的K个列向量,0<K≤64≤P;可以看出,通过下采样,从原有的P个候选列向量中选择不超过64个列向量构成该预编码矩阵W,进而,UE可沿用现有的3GPP协议,根据导频信息从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2;并通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以 实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。To this end, an embodiment of the present invention provides a method for transmitting a precoding matrix index, where the UE includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P. Specifically, the UE receives configuration information sent by the base station. pilot information, the configuration information includes configuration parameters, the number of two-dimensional antenna the first antenna port in a first dimension of the first through N 1 - 1, and the number of sampling factor of the second antenna port in a second dimension of the O N 2 And the second oversampling factor O 2 ; the UE downsamples the P candidate column vectors according to the configuration information, and obtains K column vectors constituting the precoding matrix W, 0<K≤64≤P; it can be seen that By downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W. Further, the UE can use the existing 3GPP protocol to determine from the K column vectors according to the pilot information. Constructing a first precoding matrix W 1 and a second precoding matrix W 2 of the precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; and the first index of the first precoding matrix W 1 through the PUCCH And transmitting a second index of the second precoding matrix W 2 to the base The station is configured to transmit the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
实施例2Example 2
针对上述方式二,本发明的实施例提供一种预编码矩阵索引的传输方法,其中,UE内包含有第一向量集合,该第一向量集合中包含有用于构造预编码矩阵W的P个候选列向量,64≤P,如图5所示,该方法具体包括:For the second mode, the embodiment of the present invention provides a method for transmitting a precoding matrix index, where the UE includes a first vector set, where the first vector set includes P candidates for constructing the precoding matrix W. Column vector, 64 ≤ P, as shown in FIG. 5, the method specifically includes:
201、UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2201. The UE receives configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second The second antenna port number N 2 and the second oversampling factor O 2 in the dimension.
202、UE根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2202. The UE determines, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, where the precoding matrix W=W 1 *W 2 .
203、UE根据该配置信息,确定在PUCCH上用于传输第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0。203, UE based on the configuration information, determining the number of bits transmitted for a first pre-coding matrix W 1 of the first index and the second precoding matrix W 2 is the second index number Z, Z> 0 in the PUCCH.
204、UE通过PUCCH,按照Z个比特个数将第一索引和第二索引发送至基站,以使得基站根据第一索引和第二索引确定预编码矩阵W。204. The UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, so that the base station determines the precoding matrix W according to the first index and the second index.
在步骤201中,UE可以接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2,具体可参见实施例1中步骤101的相关描述,故此处不再赘述。In step 201, the UE may receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension. And the second antenna port number N 2 and the second oversampling factor O 2 in the second dimension. For details, refer to the related description of step 101 in Embodiment 1, and therefore no further details are provided herein.
在步骤202中,由于UE内包含有第一向量集合,该第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,因此,UE根据步骤201中得到的该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,该预编码矩阵W=W1*W2In step 202, since the UE includes a first set of vectors, the first set of vectors includes P candidate column vectors for constructing the precoding matrix W, 64 ≤ P, and therefore, the UE obtains the method according to step 201. The pilot information determines a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, wherein the precoding matrix W=W 1 *W 2 .
可以看出,与实施例1中不同的是,在本发明实施例2中,UE 无需对该P个候选列向量进行下采样,而是直接从该P个候选列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2It can be seen that, different from the first embodiment, in the second embodiment of the present invention, the UE does not need to downsample the P candidate column vectors, but directly determines the constructed precoding matrix from the P candidate column vectors. The first precoding matrix W 1 and the second precoding matrix W 2 of W.
具体的,UE首先根据步骤101中的导频信息进行信道估计,确定与基站之间的RI信息和CQI信息;进而,UE根据该RI信息,从P个候选列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2Specifically, the UE first performs channel estimation according to the pilot information in step 101, and determines RI information and CQI information between the base station and the base station. Further, the UE determines, according to the RI information, a precoding matrix W from the P candidate column vectors. The first precoding matrix W 1 and the second precoding matrix W 2 .
在步骤203中,UE根据步骤201中得到的该配置信息,确定在PUCCH上用于传输第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0。In step 203, the UE determines, according to the configuration information obtained in step 201, the number of bits used to transmit the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 on the PUCCH. For Z, Z>0.
不同于上述PUCCH模式1-1的子模式1和PUCCH模式1-1的子模式2中UE只能使用固定个数比特位反馈第一PMI和第二PMI,在本发明实施例定义的新的PUCCH模式1-1的子模式中,UE可以根据(N1,N2)、(O1、O2)以及配置参数的取值,确定在PUCCH上用于传输第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引的比特个数Z,这样一来,由于不用受到固定个数比特位的限制,UE可以根据配置信息的变化而灵活配置,以实现二维天线的应用场景下预编码矩阵索引的传输。In the sub-mode 1 different from the sub-mode 1 of the PUCCH mode 1-1 and the sub-mode 2 of the PUCCH mode 1-1, the UE can only feed back the first PMI and the second PMI using a fixed number of bits, which is new in the embodiment of the present invention. In the sub-mode of PUCCH mode 1-1, the UE may determine, according to the values of (N 1 , N 2 ), (O 1 , O 2 ), and configuration parameters, that the first precoding matrix W 1 is transmitted on the PUCCH. The number of bits Z of the second index of the first index and the second precoding matrix W 2 , so that the UE can be flexibly configured according to the change of the configuration information, so as to achieve the second The transmission of the precoding matrix index in the application scenario of the dimensional antenna.
进一步地的,在步骤204中,UE通过步骤203中确定的PUCCH,按照Z个比特个数将第一索引和第二索引发送至基站,以使得基站根据第一索引和第二索引确定预编码矩阵W。Further, in step 204, the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH determined in step 203, so that the base station determines the precoding according to the first index and the second index. Matrix W.
以下将详细阐述在(N1,N2)、(O1、O2)以及配置参数的取值不同的情况下,UE确定不同的比特个数传输预编码矩阵索引的方法。In the following, in detail, in the case where (N 1 , N 2 ), (O 1 , O 2 ) and the values of the configuration parameters are different, the UE determines a method of transmitting a precoding matrix index by a different number of bits.
方式一,UE根据(N1,N2)、(O1、O2)以及配置参数的取值,确定用于传输第一PMI的比特个数Z1,具体的,UE可以将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值,该第一联和编码值可以用Z1个比特表示,进而,UE通过PUCCH,将Z1个比特的该第一联和编码值通过PUCCH发送至基站;并且,UE通过PUCCH,将Z2个比特的第二预编码矩阵W2的第二索引与CQI信 息发送至基站,其中,Z1+Z2=Z,Z1>0,Z2>0。In the first mode, the UE determines the number of bits Z1 for transmitting the first PMI according to the values of (N 1 , N 2 ), (O 1 , O 2 ) and the configuration parameters. Specifically, the UE may perform the first precoding. The first index of the matrix W 1 is jointly encoded with the RI information to obtain a first joint code value, and the first joint code value can be represented by Z1 bits. Further, the UE passes the PUCCH to the first of the Z1 bits. Transmitting the encoded value to the base station through the PUCCH; and transmitting, by the PUCCH, the second index and CQI information of the second precoding matrix W 2 of the Z2 bits to the base station, where Z1+Z2=Z, Z1>0 , Z2>0.
例如,当(N1,N2)=(4,2)或者(N1,N2)=(3,2),(O1,O2)=(8,4)时,在配置参数为2的情况下,UE确定使用8(Z1=8)比特用于在PUCCH上传输第一PMI,具体的,如表5所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的8个比特位,将该第一联和编码值通过PUCCH发送至基站,这样,基站根据该第一联和编码值以及表5,便可以得到对应的第一PMI(i1)的值。For example, when (N 1 , N 2 )=(4,2) or (N 1 ,N 2 )=(3,2), (O 1 ,O 2 )=(8,4), the configuration parameter is the case 2, the UE determines to use 8 (Z1 = 8) bits for transmission on the first PMI in the PUCCH, specifically, as shown in table 5, UE first precoding matrix W the first index and the RI information is 1 Performing joint coding to obtain a first joint coded value I RI/PMI1 , and then transmitting the first joint coded value to the base station through the PUCCH through 8 bits in the PUCCH, so that the base station according to the first joint code The value and Table 5 give the value of the corresponding first PMI(i 1 ).
表5table 5
Figure PCTCN2015094030-appb-000078
Figure PCTCN2015094030-appb-000078
或者,当(N1,N2)=(4,2)或者(N1,N2)=(3,2),(O1,O2)=(8,4)时,在配置参数为2的情况下,UE确定使用7(Z1=7)比特用于在PUCCH上传输第一PM,具体的,如表6所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。Or, when (N 1 , N 2 )=(4,2) or (N 1 ,N 2 )=(3,2), (O 1 ,O 2 )=(8,4), the configuration parameter is the case 2, the UE determines to use 7 (Z1 = 7) bits for transmission on the PUCCH in the first PM, specifically, such as, the UE first precoding matrix W the first index and the RI information are shown in table 6 The joint coding is performed to obtain a first joint code value I RI/PMI1 , and then the first joint code value is transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
表6Table 6
Figure PCTCN2015094030-appb-000079
Figure PCTCN2015094030-appb-000079
当(N1,N2)=(4,2)或者(N1,N2)=(3,2),(O1,O2)=(8,4)时,在配置参数为3或4的情况下,UE确定使用7比特用于在PUCCH上传输第一PMI,具体的,如表6所示,UE将第一预编码矩阵W1的第 一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(4,2) or (N 1 ,N 2 )=(3,2), (O 1 ,O 2 )=(8,4), the configuration parameter is 3 or In the case of 4, the UE determines to use 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 with the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
当(N1,N2)=(4,2)或者(N1,N2)=(3,2),(O1,O2)=(4,4)时,在配置参数为2的情况下,UE确定使用7比特用于在PUCCH上传输第一PMI,具体的,如表6所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(4,2) or (N 1 ,N 2 )=(3,2), (O 1 ,O 2 )=(4,4), the configuration parameter is 2 In this case, the UE determines to use the 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain the first The union coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
或者,当(N1,N2)=(4,2)或者(N1,N2)=(3,2),(O1,O2)=(4,4)时,在配置参数为2的情况下,UE确定使用6比特用于在PUCCH上传输第一PMI,具体的,如表7所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的6个比特位,将该第一联和编码值通过PUCCH发送至基站。Or, when (N 1 , N 2 )=(4,2) or (N 1 ,N 2 )=(3,2), (O 1 ,O 2 )=(4,4), the configuration parameter is In the case of 2, the UE determines to use 6 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 7, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 6 bits in the PUCCH.
表7Table 7
Figure PCTCN2015094030-appb-000080
Figure PCTCN2015094030-appb-000080
当(N1,N2)=(4,2)或者(N1,N2)=(3,2),(O1,O2)=(4,4)时,在配置参数为3或4的情况下,UE确定使用6比特用于在PUCCH上传输第一PMI,具体的,如表7所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的6个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(4,2) or (N 1 ,N 2 )=(3,2), (O 1 ,O 2 )=(4,4), the configuration parameter is 3 or In the case of 4, the UE determines to use 6 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 7, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 6 bits in the PUCCH.
当(N1,N2)=(2,4)或者(N1,N2)=(2,3),(O1,O2)=(8,4)时,在配置参数为2的情况下,UE确定使用8比特用于在PUCCH上传输 第一PMI,具体的,如表5所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的8个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2,4) or (N 1 ,N 2 )=(2,3), (O 1 ,O 2 )=(8,4), the configuration parameter is 2 case, the UE determines to use the first 8 bits for transmission on the PUCCH PMI, specifically, as shown in table 5, UE will first precoding matrix W 1 of the first index and the RI information is jointly encoded, to give first The coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 8 bits in the PUCCH.
或者,当(N1,N2)=(2,4)或者(N1,N2)=(2,3),(O1,O2)=(8,4)时,在配置参数为2的情况下,UE确定使用7比特用于在PUCCH上传输第一PMI,具体的,如表6所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。Or, when (N 1 , N 2 )=(2,4) or (N 1 ,N 2 )=(2,3), (O 1 ,O 2 )=(8,4), the configuration parameter is In the case of 2, the UE determines to use 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
当(N1,N2)=(2,4)或者(N1,N2)=(2,3),(O1,O2)=(8,4)时,在配置参数为3或4的情况下,UE确定使用7比特用于在PUCCH上传输第一PMI,具体的,如表6所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2,4) or (N 1 ,N 2 )=(2,3), (O 1 ,O 2 )=(8,4), the configuration parameter is 3 or In the case of 4, the UE determines to use 7 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 with the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 7 bits in the PUCCH.
当(N1,N2)=(2,4)或者(N1,N2)=(2,3),(O1,O2)=(8,8)时,在配置参数为2的情况下,UE确定使用9比特用于在PUCCH上传输第一PMI,具体的,如表8所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的9个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2,4) or (N 1 ,N 2 )=(2,3), (O 1 ,O 2 )=(8,8), the configuration parameter is 2 In this case, the UE determines to use 9 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 8, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain the first The union coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 9 bits in the PUCCH.
表8Table 8
Figure PCTCN2015094030-appb-000081
Figure PCTCN2015094030-appb-000081
或者,当(N1,N2)=(2,4)或者(N1,N2)=(2,3),(O1,O2)=(8,8) 时,在配置参数为2的情况下,UE确定使用8比特用于在PUCCH上传输第一PMI,具体的,如表5所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的8个比特位,将该第一联和编码值通过PUCCH发送至基站。Or, when (N 1 , N 2 )=(2,4) or (N 1 ,N 2 )=(2,3), (O 1 ,O 2 )=(8,8), the configuration parameter is In the case of 2, the UE determines to use 8 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 5, the UE jointly encodes the first index of the first precoding matrix W 1 with the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 8 bits in the PUCCH.
当(N1,N2)=(2,4)或者(N1,N2)=(2,3),(O1,O2)=(8,8)时,在配置参数为3或4的情况下,UE确定使用8比特用于在PUCCH上传输第一PMI,具体的,如表5所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的8个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2,4) or (N 1 ,N 2 )=(2,3), (O 1 ,O 2 )=(8,8), the configuration parameter is 3 or In the case of 4, the UE determines to use 8 bits for transmitting the first PMI on the PUCCH. Specifically, as shown in Table 5, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain The first joint coded value I RI/PMI1 is then transmitted to the base station through the PUCCH through 8 bits in the PUCCH.
当(N1,N2)=(2,2),(O1,O2)=(8,8)时,在配置参数为2的情况下,UE确定使用8比特用于在PUCCH上传输第一PMI,具体的,如表5所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的8个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2, 2), (O 1 , O 2 )=(8, 8), in the case where the configuration parameter is 2, the UE determines to use 8 bits for transmission on the PUCCH. The first PMI, specifically, as shown in Table 5, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes through the PUCCH. The 8 bits are transmitted to the base station through the PUCCH.
或者,当(N1,N2)=(2,2),(O1,O2)=(8,8)时,在配置参数为2的情况下,UE确定使用7比特用于在PUCCH上传输第一PMI,具体的,如表6所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。Or, when (N 1 , N 2 )=(2, 2), (O 1 , O 2 )=(8, 8), in the case where the configuration parameter is 2, the UE determines to use 7 bits for use in the PUCCH. Transmitting the first PMI, specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes the PUCCH. The 7 bits in the medium are transmitted to the base station through the PUCCH.
当(N1,N2)=(2,2),(O1,O2)=(8,8)时,在配置参数为3或4的情况下,UE确定使用7比特用于在PUCCH上传输第一PMI,具体的,如表6所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的7个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2, 2), (O 1 , O 2 )=(8, 8), in the case where the configuration parameter is 3 or 4, the UE determines to use 7 bits for use in the PUCCH. Transmitting the first PMI, specifically, as shown in Table 6, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes the PUCCH. The 7 bits in the medium are transmitted to the base station through the PUCCH.
当(N1,N2)=(2,2),(O1,O2)=(4,4)时,在配置参数为2的情况下,UE确定使用6比特用于在PUCCH上传输第一PMI,具体的,如表7所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联 合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的6个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2, 2), (O 1 , O 2 )=(4, 4), in the case where the configuration parameter is 2, the UE determines to use 6 bits for transmission on the PUCCH. The first PMI, specifically, as shown in Table 7, the UE combines the first index of the first precoding matrix W 1 with the RI information to obtain a first joint coded value I RI/PMI1 , and then passes through the PUCCH. 6 bits, the first combined code value is transmitted to the base station through the PUCCH.
或者,当(N1,N2)=(2,2),(O1,O2)=(4,4)时,在配置参数为2的情况下,UE确定使用5比特用于在PUCCH上传输第一PMI,Or, when (N 1 , N 2 )=(2, 2), (O 1 , O 2 )=(4, 4), in the case where the configuration parameter is 2, the UE determines to use 5 bits for use in the PUCCH. Transfer the first PMI,
具体的,如表9所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的5个比特位,将该第一联和编码值通过PUCCH发送至基站。Specifically, as shown in Table 9, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint coded value I RI/PMI1 , and then passes 5 bits in the PUCCH. And transmitting the first joint code value to the base station through the PUCCH.
表9Table 9
Figure PCTCN2015094030-appb-000082
Figure PCTCN2015094030-appb-000082
当(N1,N2)=(2,2),(O1,O2)=(4,4)时,在配置参数为3或4的情况下,UE确定使用5比特用于在PUCCH上传输第一PMI,具体的,如表9所示,UE将第一预编码矩阵W1的第一索引与RI信息进行联合编码,得到第一联和编码值IRI/PMI1,然后通过PUCCH中的5个比特位,将该第一联和编码值通过PUCCH发送至基站。When (N 1 , N 2 )=(2, 2), (O 1 , O 2 )=(4, 4), in the case where the configuration parameter is 3 or 4, the UE determines to use 5 bits for use in the PUCCH. Transmitting the first PMI, specifically, as shown in Table 9, the UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first joint code value I RI/PMI1 , and then passes the PUCCH. The 5 bits in the medium are transmitted to the base station through the PUCCH.
方式二,由于2D天线的引入,第一预编码矩阵W1的第一索引(即第一PMI)可以用第一维度上的第一维度索引(即i1,1)和第二维度上的第二维度索引(即i1,2)来表示。 Manner 2, due to the introduction of the 2D antenna, the first index of the first precoding matrix W 1 (ie, the first PMI) may be indexed by the first dimension in the first dimension (ie, i 1,1 ) and the second dimension The second dimension index (ie i 1,2 ) is represented.
具体的,UE根据(N1,N2)、(O1、O2)以及配置参数的取值,确定Z个比特用于传输第一PMI和第二PMI,进而,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;并且,UE将第二维度索引i1,2、第二索引i2和CQI信息进行联合编码,得到第三联和编码值;最终,UE将得到第二联和编码值与第三联和编码值通过PUCCH中的Z个比特发送至基站,以使得基站根据该第二联和编码值与第三联和编码值分别确定该第一索引和所述第二索引,最终根据该第一索引和所述第二索引确定预编码矩阵W。 Specifically, the UE determines, according to the values of (N 1 , N 2 ), (O 1 , O 2 ), and configuration parameters, that Z bits are used to transmit the first PMI and the second PMI, and further, the UE indexes the first dimension. i 1,1 is jointly coded with the RI information to obtain a second joint code value; and the UE jointly encodes the second dimension index i 1,2 , the second index i 2 and the CQI information to obtain a third joint code Finally, the UE will obtain the second union code value and the third union code value to be sent to the base station through Z bits in the PUCCH, so that the base station respectively according to the second union code value and the third union code value Determining the first index and the second index, and finally determining the precoding matrix W according to the first index and the second index.
当然,UE也可以先将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而,UE将第一维度索引i1,1、第二索引i2和CQI信息进行联合编码,得到第五联和编码值;最终,UE将得到第四联和编码值与第五联和编码值通过PUCCH中的Z个比特发送至基站。Certainly, the UE may also jointly encode the second dimension index i 1,2 and the RI information to obtain a fourth union code value; further, the UE indexes the first dimension index i 1,1 , the second index i 2 , and the CQI The information is jointly coded to obtain a fifth joint code value; finally, the UE will obtain the fourth joint code value and the fifth joint code value to be transmitted to the base station through Z bits in the PUCCH.
示例性的,UE可以接收基站发送的编码指示,该编码指示可用于指示RI信息与第一维度索引i1,1或第二维度索引i1,2进行联合编码,这样,UE便可以很据该编码指示选择将RI信息与第一维度索引i1,1或第二维度索引i1,2进行联合编码。Exemplarily, the UE may receive an encoding indication sent by the base station, where the encoding indication may be used to indicate that the RI information is jointly encoded with the first dimension index i 1,1 or the second dimension index i 1,2 , so that the UE can be The encoding indicates selection to jointly encode the RI information with the first dimension index i 1,1 or the second dimension index i 1,2 .
又或者,UE可以根据配置参数中的(N1,N2),确定与RI信息进行联合编码的第一维度索引i1,1或第二维度索引i1,2,例如,当N1<N2时,确定RI信息与第一维度索引i1,1进行联合编码;当N1>N2时,确定RI信息与第二维度索引i1,2进行联合编码,这是因为,天线端口数较少的维度,其预编码矩阵对应的波束较宽,从而用于用户的运动引起的波束变化频率较慢,因此,天线端口数较少的维度的PMI(例如第一维度索引i1,1)与RI信息进行联合编码,两者都具有慢变的特性,可以采用较长的反馈周期,这样一来,可以节省RI和这一维度对应的PMI反馈的开销。Alternatively, the UE may determine, according to (N 1 , N 2 ) in the configuration parameter, a first dimension index i 1,1 or a second dimension index i 1,2 jointly encoded with the RI information, for example, when N 1 < At N 2 , it is determined that the RI information is jointly encoded with the first dimension index i 1,1 ; when N 1 >N 2 , the RI information is determined to be jointly encoded with the second dimension index i 1,2 because the antenna port The number of dimensions is smaller, and the precoding matrix corresponds to a wider beam, so that the beam variation frequency caused by the motion of the user is slower. Therefore, the PMI of the dimension with a smaller number of antenna ports (for example, the first dimension index i 1, 1 ) Co-coding with RI information, both of which have slow-changing characteristics, can use a longer feedback period, so that the cost of RI and PMI feedback corresponding to this dimension can be saved.
以下通过5个实例,针对不同(N1,N2)、(O1、O2)的取值,示例性的阐述UE按照Z个比特传输第一PMI和第二PMI的详细过程。The following is a detailed description of the detailed process of transmitting the first PMI and the second PMI by the UE according to Z bits for the values of different (N 1 , N 2 ), (O 1 , O 2 ) by using five examples.
实例1:(N1,N2)=(2,4),(2,3),(O1,O2)=(8,4)Example 1: (N 1 , N 2 )=(2,4), (2,3), (O 1 ,O 2 )=(8,4)
此时,UE确定使用5比特用于在PUCCH上传输第一维度索引i1,1和RI信息,具体的,如表10所示,对于第一维度索引i1,1,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;进而通过PUCCH中的5个比特向基站反馈,这样,基站根据该第二联和编码值以及表10,便可以得到对应的第一维度索引i1,1的值。 At this time, the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 10, for the first dimension index i 1,1 , the UE will use the first dimension. The index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 5 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 10 The value of the corresponding first dimension index i 1,1 .
表10Table 10
Figure PCTCN2015094030-appb-000083
Figure PCTCN2015094030-appb-000083
另外,UE将第二维度索引i1,2、第二索引i2和CQI信息进行联合编码,得到第三联和编码值,在配置参数为2的情况下,如表11所示,UE使用3比特指示第二维度索引i1,2,使用1个比特指示第二所索引(即第二PMI)i2,此时,UE传输该第一索引和该第二索引共需要9(即Z=5+4)个比特个数。In addition, the UE jointly encodes the second dimension index i 1,2 , the second index i 2 , and the CQI information to obtain a third joint code value. When the configuration parameter is 2, as shown in Table 11, the UE uses 3 bits indicate the second dimension index i 1,2 , and 1 bit is used to indicate the second index (ie, the second PMI) i 2 . At this time, the UE needs to transmit the first index and the second index by a total of 9 (ie, Z). = 5 + 4) number of bits.
表11Table 11
Figure PCTCN2015094030-appb-000084
Figure PCTCN2015094030-appb-000084
又或者,在配置参数为2的情况下,如表12所示,UE使用2比特指示第二维度索引i1,2,使用2个比特指示第二所索引(即第二PMI)i2,此时,UE传输该第一索引和该第二索引仍需要9(即Z=5+4)个比特个数。Or, in the case where the configuration parameter is 2, as shown in Table 12, the UE indicates the second dimension index i 1,2 using 2 bits, and indicates the second index (ie, the second PMI) i 2 using 2 bits. At this time, the UE still needs 9 (ie, Z=5+4) number of bits to transmit the first index and the second index.
表12Table 12
Figure PCTCN2015094030-appb-000085
Figure PCTCN2015094030-appb-000085
在配置参数为3或4的情况下,如表13所示,UE使用2比特指示第二维度索引i1,2,使用2个比特指示第二所索引(即第二PMI)i2,此时,UE传输该第一索引和该第二索引仍需要9(即Z=5+4)个比 特个数。In the case where the configuration parameter is 3 or 4, as shown in Table 13, the UE indicates the second dimension index i 1,2 using 2 bits, and indicates the second index (ie, the second PMI) i 2 using 2 bits. At the time, the UE still needs 9 (ie, Z=5+4) number of bits to transmit the first index and the second index.
表13Table 13
Figure PCTCN2015094030-appb-000086
Figure PCTCN2015094030-appb-000086
仍以(N1,N2)=(2,4),(2,3),(O1,O2)=(8,4)为例,UE也可以先将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;如表14所示,此时,UE确定使用5比特用于在PUCCH上传输第二维度索引i1,2和RI信息,具体的,UE将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而通过PUCCH中的5个比特向基站反馈,这样,基站根据该第四联和编码值以及表14,便可以得到对应的第二维度索引i1,2的值。Taking (N 1 , N 2 )=(2,4), (2,3), (O 1 , O 2 )=(8,4) as an example, the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 14, at this time, the UE determines to use 5 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specific The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station through 5 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 14, the value of the corresponding second dimension index i 1,2 can be obtained.
表14Table 14
Figure PCTCN2015094030-appb-000087
Figure PCTCN2015094030-appb-000087
或者,UE确定使用4比特用于在PUCCH上传输第二维度索引i1,2和RI信息,如表15所示,UE将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而通过PUCCH中的4个比特向基站反馈,这样,基站根据该第四联和编码值以及表15,便可以得到对应的第二维度索引i1,2的值。 Alternatively, the UE determines to use 4 bits for transmitting the second dimension index i 1,2 and RI information on the PUCCH. As shown in Table 15, the UE jointly encodes the second dimension index i 1,2 and the RI information to obtain the first The quad sum code value is further fed back to the base station through 4 bits in the PUCCH, so that the base station can obtain the value of the corresponding second dimension index i 1,2 according to the fourth joint code value and Table 15.
表15Table 15
Figure PCTCN2015094030-appb-000088
Figure PCTCN2015094030-appb-000088
另外,UE将第一维度索引i1,1、第二索引i2和CQI信息进行联合编码,得到第五联和编码值,在配置参数为2的情况下,如表16所示,UE使用3比特指示第一维度索引i1,1,使用1个比特指示第二所索引(即第二PMI)i2In addition, the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value. In the case that the configuration parameter is 2, as shown in Table 16, the UE uses The 3 bits indicate the first dimension index i 1,1 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
表16Table 16
Figure PCTCN2015094030-appb-000089
Figure PCTCN2015094030-appb-000089
又或者,在配置参数为2的情况下,如表17所示,UE使用2比特指示第一维度索引i1,1,使用2个比特指示第二所索引(即第二PMI)i2Still alternatively, in the case where the configuration parameter is 2, as shown in Table 17, the UE indicates the first dimension index i 1,1 using 2 bits, and indicates the second index (ie, the second PMI) i 2 using 2 bits.
表17Table 17
Figure PCTCN2015094030-appb-000090
Figure PCTCN2015094030-appb-000090
实例2:(N1,N2)=(2,4),(2,3),(O1,O2)=(8,8)Example 2: (N 1 , N 2 )=(2,4), (2,3), (O 1 ,O 2 )=(8,8)
此时,UE确定使用5比特用于在PUCCH上传输第一维度索引i1,1和RI信息,具体的,如表10所示,对于第一维度索引i1,1,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;进而 通过PUCCH中的5个比特向基站反馈,这样,基站根据该第二联和编码值以及表10,便可以得到对应的第一维度索引i1,1的值。At this time, the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 10, for the first dimension index i 1,1 , the UE will use the first dimension. The index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 5 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 10 The value of the corresponding first dimension index i 1,1 .
另外,UE将第二维度索引i1,2、第二索引i2和CQI信息进行联合编码,得到第三联和编码值,在配置参数为2的情况下,如表11所示,UE使用3比特指示第二维度索引i1,2,使用1个比特指示第二所索引(即第二PMI)i2In addition, the UE jointly encodes the second dimension index i 1,2 , the second index i 2 , and the CQI information to obtain a third joint code value. When the configuration parameter is 2, as shown in Table 11, the UE uses The 3 bits indicate the second dimension index i 1,2 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
仍以(N1,N2)=(2,4),(2,3),(O1,O2)=(8,8)为例,UE也可以先将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;如表18所示,此时,UE确定使用6比特用于在PUCCH上传输第二维度索引i1,2和RI信息,具体的,UE将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而通过PUCCH中的6个比特向基站反馈,这样,基站根据该第四联和编码值以及表14,便可以得到对应的第二维度索引i1,2的值。Taking (N 1 , N 2 )=(2,4), (2,3), (O 1 , O 2 )=(8,8) as an example, the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 18, at this time, the UE determines to use 6 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specifically The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station through 6 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 14, the value of the corresponding second dimension index i 1,2 can be obtained.
表18Table 18
Figure PCTCN2015094030-appb-000091
Figure PCTCN2015094030-appb-000091
或者,如表19所示,UE确定使用5比特用于在PUCCH上传输第二维度索引i1,2和RI信息,具体的,UE将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而通过PUCCH中的5个比特向基站反馈,这样,基站根据该第四联和编码值以及表19,便可以得到对应的第二维度索引i1,2的值。 Or, as shown in Table 19, the UE determines to use 5 bits for transmitting the second dimension index i 1,2 and RI information on the PUCCH. Specifically, the UE jointly encodes the second dimension index i 1,2 and the RI information. Obtaining a fourth joint code value; further, feeding back to the base station by using 5 bits in the PUCCH, so that the base station can obtain the corresponding second dimension index i 1,2 according to the fourth joint code value and Table 19. value.
表19Table 19
Figure PCTCN2015094030-appb-000092
Figure PCTCN2015094030-appb-000092
另外,UE将第一维度索引i1,1、第二索引i2和CQI信息进行联合编码,得到第五联和编码值,在配置参数为2的情况下,如表16所示,UE使用3比特指示第一维度索引i1,1,使用1个比特指示第二所索引(即第二PMI)i2In addition, the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value. In the case that the configuration parameter is 2, as shown in Table 16, the UE uses The 3 bits indicate the first dimension index i 1,1 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 .
实例3:(N1,N2)=(4,2)/(3,2),(O1,O2)=(8,4)Example 3: (N 1 , N 2 )=(4,2)/(3,2), (O 1 ,O 2 )=(8,4)
此时,UE确定使用6比特用于在PUCCH上传输第一维度索引i1,1和RI信息,具体的,如表20所示,对于第一维度索引i1,1,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;进而通过PUCCH中的6个比特向基站反馈,这样,基站根据该第二联和编码值以及表20,便可以得到对应的第一维度索引i1,1的值。At this time, the UE determines to use 6 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 20, for the first dimension index i 1,1 , the UE will use the first dimension. The index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 6 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 20 The value of the corresponding first dimension index i 1,1 .
表20Table 20
Figure PCTCN2015094030-appb-000093
Figure PCTCN2015094030-appb-000093
或者,UE确定使用5比特用于在PUCCH上传输第一维度索引i1,1和RI信息,具体的,如表21所示,对于第一维度索引i1,1,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;进而通过PUCCH中的5个比特向基站反馈,这样,基站根据该第二联和编码值以及表21,便可以得到对应的第一维度索引i1,1的值。 Alternatively, the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 21, for the first dimension index i 1,1 , the UE indexes the first dimension i 1,1 and RI information are jointly encoded to obtain a second joint code value; and further, 5 bits in the PUCCH are fed back to the base station, so that the base station can obtain the corresponding according to the second joint code value and Table 21. The first dimension indexes the value of i 1,1 .
表21Table 21
Figure PCTCN2015094030-appb-000094
Figure PCTCN2015094030-appb-000094
另外,UE将第二维度索引i1,2、第二索引i2和CQI信息进行联合编码,得到第三联和编码值,如表13所示,UE使用2比特指示第二维度索引i1,2,使用2个比特指示第二所索引(即第二PMI)i2In addition, the UE jointly encodes the second dimension index i 1,2 , the second index i 2 and the CQI information to obtain a third joint code value. As shown in Table 13, the UE uses 2 bits to indicate the second dimension index i 1 . 2 , using 2 bits to indicate the second index (ie the second PMI) i 2 .
仍以(N1,N2)=(4,2)/(3,2),(O1,O2)=(8,4)为例,UE也可以先将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;如表22所示,此时,UE确定使用4比特用于在PUCCH上传输第二维度索引i1,2和RI信息,具体的,UE将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而通过PUCCH中的4个比特向基站反馈,这样,基站根据该第四联和编码值以及表22,便可以得到对应的第二维度索引i1,2的值。Taking (N 1 , N 2 )=(4, 2)/(3, 2), (O 1 , O 2 )=(8, 4) as an example, the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 22, at this time, the UE determines to use 4 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specifically The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station by using 4 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 22, the value of the corresponding second dimension index i 1,2 can be obtained.
表22Table 22
Figure PCTCN2015094030-appb-000095
Figure PCTCN2015094030-appb-000095
另外,UE将第一维度索引i1,1、第二索引i2和CQI信息进行联合编码,得到第五联和编码值,如表16所示,UE使用3比特指示第一维度索引i1,1,使用1个比特指示第二所索引(即第二PMI)i2In addition, the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value. As shown in Table 16, the UE uses 3 bits to indicate the first dimension index i 1 . , 1 , using 1 bit to indicate the second index (ie, the second PMI) i 2 .
实例4:(N1,N2)=(4,2)/(3,2),(O1,O2)=(4,4)Example 4: (N 1 , N 2 )=(4,2)/(3,2), (O 1 ,O 2 )=(4,4)
此时,UE确定使用5比特用于在PUCCH上传输第一维度索引i1,1和RI信息,具体的,如表10所示,对于第一维度索引i1,1,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;进而通过PUCCH中的5个比特向基站反馈,这样,基站根据该第二联和 编码值以及表10,便可以得到对应的第一维度索引i1,1的值。At this time, the UE determines to use 5 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 10, for the first dimension index i 1,1 , the UE will use the first dimension. The index i 1,1 is jointly encoded with the RI information to obtain a second joint code value; and further, the base station feeds back 5 bits in the PUCCH, so that the base station can obtain the second coded value according to the second and the table 10 The value of the corresponding first dimension index i 1,1 .
或者,UE确定使用4比特用于在PUCCH上传输第一维度索引i1,1和RI信息,具体的,如表23所示,UE将第一维度索引i1,1与RI信息进行联合编码,得到第二联和编码值;进而通过PUCCH中的4个比特向基站反馈,这样,基站根据该第二联和编码值以及表23,便可以得到对应的第一维度索引i1,1的值Alternatively, the UE determines to use 4 bits for transmitting the first dimension index i 1,1 and RI information on the PUCCH. Specifically, as shown in Table 23, the UE jointly encodes the first dimension index i 1,1 and the RI information. Obtaining a second union code value; further, feeding back to the base station by using 4 bits in the PUCCH, so that the base station can obtain the corresponding first dimension index i 1,1 according to the second union code value and Table 23. value
表23Table 23
Figure PCTCN2015094030-appb-000096
Figure PCTCN2015094030-appb-000096
另外,UE将第二维度索引i1,2、第二索引i2和CQI信息进行联合编码,得到第三联和编码值,如表13所示,UE使用2比特指示第二维度索引i1,2,使用2个比特指示第二所索引i2(即第二PMI)。In addition, the UE jointly encodes the second dimension index i 1,2 , the second index i 2 and the CQI information to obtain a third joint code value. As shown in Table 13, the UE uses 2 bits to indicate the second dimension index i 1 . 2 , using 2 bits to indicate the second index i 2 (ie the second PMI).
仍以(N1,N2)=(4,2)/(3,2),(O1,O2)=(4,4)为例,UE也可以先将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;如表22所示,此时,UE确定使用4比特用于在PUCCH上传输第二维度索引i1,2和RI信息,具体的,UE将第二维度索引i1,2与RI信息进行联合编码,得到第四联和编码值;进而通过PUCCH中的4个比特向基站反馈,这样,基站根据该第四联和编码值以及表22,便可以得到对应的第二维度索引i1,2的值。Taking (N 1 , N 2 )=(4, 2)/(3, 2), (O 1 , O 2 )=(4, 4) as an example, the UE may also index the second dimension i1 first. 2 jointly coding with the RI information to obtain a fourth joint code value; as shown in Table 22, at this time, the UE determines to use 4 bits for transmitting the second dimension index i 1, 2 and RI information on the PUCCH, specifically The UE jointly encodes the second dimension index i 1,2 and the RI information to obtain a fourth joint code value, and further feeds back to the base station by using 4 bits in the PUCCH, so that the base station according to the fourth joint code value and Table 22, the value of the corresponding second dimension index i 1,2 can be obtained.
另外,UE将第一维度索引i1,1、第二索引i2和CQI信息进行联合编码,得到第五联和编码值,在配置参数为2的情况下,如表16所示,UE使用3比特指示第一维度索引i1,1,使用1个比特指示第二所索引(即第二PMI)i2。又或者,如表17所示,UE使用2比特指示第一维度索引i1,1,使用2个比特指示第二所索引(即第二PMI)i2In addition, the UE jointly encodes the first dimension index i 1,1 , the second index i 2 and the CQI information to obtain a fifth union code value. In the case that the configuration parameter is 2, as shown in Table 16, the UE uses The 3 bits indicate the first dimension index i 1,1 , and the 1st bit is used to indicate the second index (ie, the second PMI) i 2 . Still alternatively, as shown in Table 17, the UE indicates the first dimension index i 1,1 using 2 bits and the second index (ie, the second PMI) i 2 using 2 bits.
至此,本发明的实施例提供一种预编码矩阵索引的传输方法,定义了一种新的PUCCH模式1-1的子模式,具体的,UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在 第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;进而,UE根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,并且,UE根据该配置信息,确定在PUCCH上用于传输第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0,以使得UE通过PUCCH中的Z个比特,将第一索引和第二索引发送至基站,也就是说,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置参数的变化而灵活配置的,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。So far, the embodiment of the present invention provides a method for transmitting a precoding matrix index, and defines a new sub-mode of PUCCH mode 1-1. Specifically, the UE receives configuration information and pilot information sent by the base station, and the configuration the configuration information includes a parameter, the number of two-dimensional antenna the first antenna port in a first dimension N 1 - 1, the first and second antenna ports O oversampling factor in a second dimension N 2 and the second oversampling factor O 2; Further, the UE information according to the pilot frequency, determining a first precoding matrix configured precoding matrix W W 1 and a second precoding matrix W 2, and, according to the configuration information of the UE, determining a transmission on PUCCH The number of bits of the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0, such that the UE passes the Z bits in the PUCCH, and the first index And transmitting, to the base station, the second index, that is, the UE may determine, according to the foregoing configuration information sent by the base station, the number of bits used for transmitting the precoding matrix index on the PUCCH, that is, in the newly defined submode. Transmission precoding moment The number of bits used by the index may change according to the configuration parameters and flexible configuration to achieve PUCCH transmission by a precoding matrix index in the two-dimensional antenna scenario.
实施例3Example 3
针对上述方式一,为了保证可继续沿用PUCCH模式1-1子模式1和子模式2中使用固定个数比特位传输预编码矩阵索引,同时满足二维天线的应用场景,本发明的实施例提供的预编码矩阵索引的传输装置,可根据基站发送的配置信息(即配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2),对所述P个候选列向量进行下采样,得到构成所述预编码矩阵W的K个列向量,由于0<K≤64≤P,使得UE可以在现有3GPP协议的基础上,从下采样得到的K个列向量中构造第一预编码矩阵W1和第二预编码矩阵W2,并沿用现有的传输模式在PUCCH上传输该第一PMI和第二PMI,如图6所示,该装置具体包括:For the first mode, in order to ensure that the PUCCH mode 1-1 sub-mode 1 and the sub-mode 2 are used to transmit the precoding matrix index by using a fixed number of bits, and the application scenario of the two-dimensional antenna is satisfied, the embodiment of the present invention provides The transmission device of the precoding matrix index may be configured according to configuration information sent by the base station (ie, configuration parameters, the number of first antenna ports N 1 of the two-dimensional antenna in the first dimension and the first oversampling factor O 1 , and in the second dimension The second antenna port number N 2 and the second oversampling factor O 2 ) are used to downsample the P candidate column vectors to obtain K column vectors constituting the precoding matrix W, since 0<K≤ 64≤P, so that the UE can be configured to a first precoding matrix W 1 and W 2 second precoding matrix obtained from downsampling the K column vector on the basis of the existing 3GPP protocol, and to use the existing transmission mode The first PMI and the second PMI are transmitted on the PUCCH. As shown in FIG. 6, the device specifically includes:
接收单元11,用于接收基站发送的配置信息和导频信息,所述配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2The receiving unit 11 is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension;
采样单元12,用于根据所述配置信息,对所述P个候选列向量进行下采样,得到构成所述预编码矩阵W的K个列向量,0<K≤64 ≤P;The sampling unit 12 is configured to downsample the P candidate column vectors according to the configuration information, to obtain K column vectors constituting the precoding matrix W, where 0<K≤64 ≤P;
确定单元13,用于根据所述导频信息,从所述K个列向量中确定构造所述预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,所述预编码矩阵W=W1*W2a determining unit 13 configured to determine, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W from the K column vectors, where Precoding matrix W = W 1 * W 2 ;
发送单元14,用于通过PUCCH将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站,以使得所述基站根据所述第一索引和所述第二索引确定所述预编码矩阵W。The sending unit 14 is configured to send, by using a PUCCH, the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station, so that the base station according to the The first index and the second index determine the precoding matrix W.
进一步地,所述第一向量集合包括第一维待选向量集合vl和第二维待选向量集合uk,所述确定单元13,还用于根据所述配置信息确定所述下采样的采样频率;所述采样单元12,具体用于按照所述采样频率从所述第一维待选向量集合vl中采集L个第一维向量
Figure PCTCN2015094030-appb-000097
从所述第二维待选向量集合uk中采集J个第二维向量
Figure PCTCN2015094030-appb-000098
L*J=K,L、J、l'、k'均为大于等于0的整数。Further, the first vector set includes a first dimension candidate vector set v l and a second dimension candidate vector set u k , and the determining unit 13 is further configured to determine the downsampled according to the configuration information. The sampling unit 12 is configured to collect L first dimension vectors from the first dimension of the candidate vector set v l according to the sampling frequency.
Figure PCTCN2015094030-appb-000097
Collecting J second dimension vectors from the second dimension candidate vector set u k
Figure PCTCN2015094030-appb-000098
L*J=K, L, J, l', k' are all integers greater than or equal to zero.
进一步地,如图7所示,所述装置还包括计算单元15,具体的,所述计算单元15,具体用于根据所述第一过采样因子O1,通过第一采样公式计算从所述第一维待选向量集合vl中采集第一维向量的采样频率;以及,根据所述第二过采样因子O2,通过所述第一采样公式计算从所述第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000100
的采样频率。Further, as shown in FIG. 7 , the device further includes a calculating unit 15 , specifically, the calculating unit 15 is configured to calculate, according to the first oversampling factor O 1 , by using a first sampling formula Collecting the first dimension vector in the first dimension candidate vector set v l a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second set of candidate vectors u k by the first sampling formula
Figure PCTCN2015094030-appb-000100
Sampling frequency.
其中,当天线端口数为12或者16时,所述第一采样公式为:
Figure PCTCN2015094030-appb-000101
或者所述第一采样公式为:
Figure PCTCN2015094030-appb-000102
当天线端口数为8时,所述第一采样公式为:
Figure PCTCN2015094030-appb-000103
l'为大于等于0的整数,k'为大于等于0的整数,所述天线端口数=N1*N2*极化方向的数目。Wherein, when the number of antenna ports is 12 or 16, the first sampling formula is:
Figure PCTCN2015094030-appb-000101
Or the first sampling formula is:
Figure PCTCN2015094030-appb-000102
When the number of antenna ports is 8, the first sampling formula is:
Figure PCTCN2015094030-appb-000103
l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
或者,所述计算单元15,具体用于根据所述配置信息,通过第二采样公式从所述第一维待选向量集合vl中采集第一维向量
Figure PCTCN2015094030-appb-000104
以 及,根据所述配置信息,通过所述第二采样公式从所述第二维待选向量集合uk中采集第二维向量
Figure PCTCN2015094030-appb-000105
Or the calculating unit 15 is configured to collect, according to the configuration information, the first dimension vector from the first dimension of the candidate vector set v l by using a second sampling formula.
Figure PCTCN2015094030-appb-000104
And acquiring, according to the configuration information, the second dimension vector from the second dimension candidate vector set u k by using the second sampling formula
Figure PCTCN2015094030-appb-000105
其中,当天线端口数为16或者12时,若O1=O2,且N1<N2,则所述第二采样公式为:
Figure PCTCN2015094030-appb-000106
否则,所述第二采样公式为:
Figure PCTCN2015094030-appb-000107
当天线端口数为8时,所述第二采样公式为:
Figure PCTCN2015094030-appb-000108
Figure PCTCN2015094030-appb-000109
l'为大于等于0的整数,k'为大于等于0的整数,所述天线端口数=N1*N2*极化方向的数目。Wherein, when the number of antenna ports is 16 or 12, if O 1 =O 2 and N 1 <N 2 , the second sampling formula is:
Figure PCTCN2015094030-appb-000106
Otherwise, the second sampling formula is:
Figure PCTCN2015094030-appb-000107
When the number of antenna ports is 8, the second sampling formula is:
Figure PCTCN2015094030-appb-000108
Figure PCTCN2015094030-appb-000109
l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
进一步地,所述计算单元15,还用于根据所述配置信息计算所述第一维待选向量集合vl
Figure PCTCN2015094030-appb-000110
以及,根据所述配置信息计算所述第二维待选向量集合uk
Figure PCTCN2015094030-appb-000111
 Further, the calculating unit 15 is further configured to calculate the first dimension candidate vector set v l according to the configuration information,
Figure PCTCN2015094030-appb-000110
 And calculating, according to the configuration information, the second dimension candidate vector set u k ,
Figure PCTCN2015094030-appb-000111
进一步地,所述确定单元13,具体用于根据所述导频信息,从所述K个列向量中确定所述第一预编码矩阵W1;以及,根据所述配置参数从所述第一预编码矩阵W1的列向量中确定所述第二预编码矩阵W2Further, the determining unit 13 is specifically configured to determine, according to the pilot information, the first precoding matrix W 1 from the K column vectors; and, according to the configuration parameter, from the first column vector of the precoding matrix W 1 is determined in the second precoding matrix W 2.
进一步地,所述发送单元14,具体用于通过PUCCH模式1-1子模式1,将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站。Further, the sending unit 14 is specifically configured to pass the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 by using a PUCCH mode 1-1 submode 1 Sent to the base station.
或者,所述发送单元14,具体用于通过PUCCH模式1-1子模式2,将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站。Or the sending unit 14 is specifically configured to send, by using the PUCCH mode 1-1 sub-mode 2, the first index of the first pre-coding matrix W 1 and the second index of the second pre-coding matrix W 2 To the base station.
进一步地,所述发送单元14,还用于通过RRC信令接收所述基站发送的所述配置信息。Further, the sending unit 14 is further configured to receive, by using RRC signaling, the configuration information sent by the base station.
其中,该预编码矩阵索引的传输装置可以为一种UE(用户设 备)。The transmission device of the precoding matrix index may be a UE (user setting) Prepare).
示例性的,图8为本发明实施例提供的一种用户设备的结构示意图,本发明实施例提供的用户设备可以用于实施上述图1-图5所示的本发明各实施例实现的方法,为了便于说明,仅示出了与本发明实施例相关的部分,具体技术细节未揭示的,请参照图1-图5所示的本发明各实施例。Illustratively, FIG. 8 is a schematic structural diagram of a user equipment according to an embodiment of the present invention. The user equipment provided by the embodiment of the present invention may be used to implement the method implemented by the embodiments of the present invention shown in FIG. 1 to FIG. For the convenience of description, only parts related to the embodiments of the present invention are shown. Without specific details, please refer to the embodiments of the present invention shown in FIGS.
具体的,如图8所示,用户设备包括:处理器21、存储器22、收发器23和总线24,该处理器21、收发器23和存储器22通过总线14连接并完成相互间的通信。Specifically, as shown in FIG. 8, the user equipment includes a processor 21, a memory 22, a transceiver 23, and a bus 24, and the processor 21, the transceiver 23, and the memory 22 are connected by the bus 14 and complete communication with each other.
其中,存储器22,可用于存储该第一向量集合,该第一向量集合中包含有用于构造预编码矩阵W的P个候选列向量,64≤P;所述处理器11可用于执行上述采样单元12、确定单元13以及计算单元15的具体功能;所述收发器23可用于执行上述接收单元11以及发送单元14的具体功能,故此处不再赘述。The memory 22 is configured to store the first vector set, where the first vector set includes P candidate column vectors for constructing the precoding matrix W, 64≤P; the processor 11 can be configured to execute the sampling unit. The specific function of the determining unit 13 and the calculating unit 15; the transceiver 23 can be used to perform the specific functions of the receiving unit 11 and the transmitting unit 14, and therefore will not be described herein.
需要说明的是,这里的处理器21可以是一个处理器,也可以是多个处理元件的统称。例如,该处理器可以是中央处理器(Central Processing Unit,CPU),也可以是特定集成电路(Application Specific Integrated Circuit,ASIC),或者是被配置成实施本发明实施例的一个或多个集成电路,例如:一个或多个微处理器(digital singnal processor,DSP),或,一个或者多个现场可编程门阵列(Field Programmable Gate Array,FPGA)。It should be noted that the processor 21 herein may be a processor or a collective name of multiple processing elements. For example, the processor may be a Central Processing Unit (CPU), an Application Specific Integrated Circuit (ASIC), or one or more integrated circuits configured to implement the embodiments of the present invention. For example, one or more digital singal processors (DSPs), or one or more Field Programmable Gate Arrays (FPGAs).
存储器22可以是一个存储装置,也可以是多个存储元件的统称,且用于存储可执行程序代码或接入网管理设备运行所需要参数、数据等。且存储器22(或存储器23)可以包括随机存储器(RAM),也可以包括非易失性存储器(non-volatile memory),例如磁盘存储器,闪存(Flash)等。The memory 22 may be a storage device or a collective name of a plurality of storage elements, and is used to store executable program code or parameters, data, and the like required for the operation of the access network management device. And the memory 22 (or the memory 23) may include a random access memory (RAM), and may also include a non-volatile memory such as a magnetic disk memory, a flash memory, or the like.
总线24可以是工业标准体系结构(Industry Standard Architecture,ISA)总线、外部设备互连(Peripheral Component,PCI)总线或扩展工业标准体系结构(Extended Industry Standard  Architecture,EISA)总线等。可具体分为地址总线、数据总线、控制总线等。为便于表示,图8中仅用一条粗线表示,但并不表示仅有一根总线或一种类型的总线。The bus 24 can be an Industry Standard Architecture (ISA) bus, a Peripheral Component (PCI) bus, or an extended industry standard architecture (Extended Industry Standard). Architecture, EISA) bus, etc. Can be specifically divided into address bus, data bus, control bus and so on. For ease of representation, only one thick line is shown in Figure 8, but it does not mean that there is only one bus or one type of bus.
至此,本发明的实施例提供一种预编码矩阵索引的传输装置,UE内包含有用于构造预编码矩阵W的P个候选列向量,64≤P,具体的,UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;UE根据该配置信息,对该P个候选列向量进行下采样,得到构成预编码矩阵W的K个列向量,0<K≤64≤P;可以看出,通过下采样,从原有的P个候选列向量中选择不超过64个列向量构成该预编码矩阵W,进而,UE可沿用现有的3GPP协议,根据导频信息从K个列向量中确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,预编码矩阵W=W1*W2;并通过PUCCH将第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引发送至基站,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。So far, an embodiment of the present invention provides a precoding matrix index transmission apparatus, where the UE includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P. Specifically, the UE receives configuration information sent by the base station and pilot information, the configuration information includes configuration parameters, the number of two-dimensional antenna the first antenna port in a first dimension of the first through N 1 - 1, and the number of sampling factor of the second antenna port in a second dimension of the O N 2 And the second oversampling factor O 2 ; the UE downsamples the P candidate column vectors according to the configuration information, and obtains K column vectors constituting the precoding matrix W, 0<K≤64≤P; it can be seen that By downsampling, no more than 64 column vectors are selected from the original P candidate column vectors to form the precoding matrix W. Further, the UE can use the existing 3GPP protocol to determine from the K column vectors according to the pilot information. Constructing a first precoding matrix W 1 and a second precoding matrix W 2 of the precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ; and the first index of the first precoding matrix W 1 through the PUCCH And transmitting a second index of the second precoding matrix W 2 to the base The station is configured to transmit the precoding matrix index through the PUCCH in the application scenario of the two-dimensional antenna.
实施例4Example 4
针对上述方式二,为解决针对二维天线的应用场景下如何在PUCCH上传输预编码矩阵索引(即第一PMI和第二PMI)这一问题,本发明提供的预编码矩阵索引的传输装置,适用于实施例2中新定义的PUCCH模式1-1的子模式,其中,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置信息的变化而灵活配置的,可适用于二维天线的应用场景下预编码矩阵索引的传输,如图9所示,该装置具体包括:For the foregoing method 2, in order to solve the problem of how to transmit a precoding matrix index (ie, a first PMI and a second PMI) on a PUCCH in an application scenario for a two-dimensional antenna, the precoding matrix index transmission apparatus provided by the present invention, The sub-mode of the newly defined PUCCH mode 1-1 in the second embodiment, wherein the UE can determine the number of bits used for transmitting the precoding matrix index on the PUCCH according to the foregoing configuration information sent by the base station, that is, In the newly defined sub-mode, the number of bits used for transmitting the precoding matrix index may be flexibly configured according to the change of the configuration information, and may be applicable to the transmission of the precoding matrix index in the application scenario of the two-dimensional antenna. As shown in FIG. 9, the device specifically includes:
接收单元31,用于接收基站发送的配置信息和导频信息,所述配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和 第二过采样因子O2The receiving unit 31 is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension;
确定单元32,用于根据所述导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,所述预编码矩阵W=W1*W2;以及,根据所述配置信息,确定在物理上行链路控制信道PUCCH上用于传输所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0;Determining unit 32, based on the pilot information for determining a first precoding matrix configured precoding matrix W W 1 and a second precoding matrix W 2, wherein the precoding matrix W = W 1 * W 2 And determining, according to the configuration information, the first index for transmitting the first precoding matrix W 1 and the second index of the second precoding matrix W 2 on the physical uplink control channel PUCCH The number of bits is Z, Z>0;
发送单元33,用于通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站,以使得所述基站根据所述第一索引和所述第二索引确定所述预编码矩阵W。The sending unit 33 is configured to send, by using the PUCCH, the first index and the second index to the base station according to the number of Z bits, so that the base station is configured according to the first index and the first The two indices determine the precoding matrix W.
进一步地,所述UE内包含有第一向量集合,所述第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,其中,所述确定单元32,具体用于根据所述导频信息确定与所述基站之间的RI信息和CQI信息;以及,根据所述RI信息,从所述P个候选列向量中确定构造所述预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2Further, the UE includes a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64≤P, wherein the determining unit 32 is specifically used Determining RI information and CQI information with the base station according to the pilot information; and determining, according to the RI information, a first pre-configuration of the precoding matrix W from the P candidate column vectors The coding matrix W 1 and the second precoding matrix W 2 .
进一步地,如图10所示,所述装置还包括联合编码单元34,所述联合编码单元34,用于将所述第一预编码矩阵W1的第一索引与所述RI信息进行联合编码,得到第一联和编码值;所述发送单元33,还用于通过所述PUCCH,将Z1个比特的所述第一联和编码值通过所述PUCCH发送至所述基站;以及,通过所述PUCCH,将Z2个比特的所述第二预编码矩阵W2的第二索引与所述CQI信息发送至所述基站,Z1+Z2=Z,Z1>0,Z2>0。Further, as shown in FIG. 10, the apparatus further comprising a joint coding unit 34, the joint encoding unit 34, a first W for the first precoding matrix index 1 and the RI information is jointly encoded Obtaining a first joint code value, where the sending unit 33 is further configured to send, by using the PUCCH, the first joint code value of Z1 bits to the base station by using the PUCCH; The PUCCH transmits a second index of the second precoding matrix W 2 of Z2 bits and the CQI information to the base station, Z1+Z2=Z, Z1>0, and Z2>0.
进一步地,所述第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,所述联合编码单元34,还用于将所述第一维度索引与所述RI信息进行联合编码,得到第二联和编码值;以及,将所述第二维度索引、所述第二索引和所述CQI信息进行联合编码,得到第三联和编码值;所述发送单元33,还用于按照Z个比特个数,将所述第二联和编码值与所述第三联和编码值通过所述PUCCH发送至所述基站。 Further, the first index includes a first dimension index in a first dimension and a second dimension index in a second dimension, where the joint encoding unit 34 is further configured to index the first dimension Performing joint coding with the RI information to obtain a second union code value; and jointly coding the second dimension index, the second index, and the CQI information to obtain a third union code value; The transmitting unit 33 is further configured to send the second joint code value and the third joint code value to the base station by using the PUCCH according to the number of Z bits.
又或者,所述联合编码单元34,还用于将所述第二维度索引与所述RI信息进行联合编码,得到第四联和编码值;以及,将所述第一维度索引、所述第二索引和所述CQI信息进行联合编码,得到第五联和编码值;所述发送单元33,还用于按照Z个比特个数,将所述得到第四联和编码值与所述第五联和编码值通过所述PUCCH发送至所述基站。Or the joint coding unit 34 is further configured to jointly encode the second dimension index and the RI information to obtain a fourth union code value; and, the first dimension index, the first The second index and the CQI information are jointly encoded to obtain a fifth joint code value, and the sending unit 33 is further configured to obtain the fourth joint code value and the fifth according to the Z number of bits. The union code value is transmitted to the base station through the PUCCH.
进一步地,所述接收单元31,还用于接收所述基站发送的编码指示,所述编码指示用于指示所述RI信息与所述第一维度索引或所述第二维度索引进行联合编码。Further, the receiving unit 31 is further configured to receive an encoding indication sent by the base station, where the encoding indication is used to indicate that the RI information is jointly encoded with the first dimension index or the second dimension index.
其中,该预编码矩阵索引的传输装置可以为一种UE(用户设备)。The transmission device of the precoding matrix index may be a UE (user equipment).
示例性的,图11为本发明实施例提供的一种用户设备的结构示意图,本发明实施例提供的用户设备可以用于实施上述图1-图5所示的本发明各实施例实现的方法,为了便于说明,仅示出了与本发明实施例相关的部分,具体技术细节未揭示的,请参照图1-图5所示的本发明各实施例。Illustratively, FIG. 11 is a schematic structural diagram of a user equipment according to an embodiment of the present invention. The user equipment provided by the embodiment of the present invention may be used to implement the method implemented by the embodiments of the present invention shown in FIG. 1 to FIG. For the convenience of description, only parts related to the embodiments of the present invention are shown. Without specific details, please refer to the embodiments of the present invention shown in FIGS.
具体的,如图11所示,用户设备包括:处理器41、存储器42、收发器43和总线44,该处理器41、收发器43和存储器42通过总线44连接并完成相互间的通信。Specifically, as shown in FIG. 11, the user equipment includes a processor 41, a memory 42, a transceiver 43, and a bus 44. The processor 41, the transceiver 43, and the memory 42 are connected by a bus 44 and complete communication with each other.
其中,存储器42,可用于存储该第一向量集合,该第一向量集合中包含有用于构造预编码矩阵W的P个候选列向量,64≤P;所述处理器41可用于执行上述确定单元32以及联合编码单元34的具体功能;所述收发器43可用于执行上述接收单元41以及发送单元44的具体功能,故此处不再赘述。The memory 42 may be configured to store the first set of vectors, where the first set of vectors includes P candidate column vectors for constructing the precoding matrix W, 64≤P; the processor 41 may be configured to execute the determining unit. 32 and the specific function of the joint coding unit 34; the transceiver 43 can be used to perform the specific functions of the receiving unit 41 and the sending unit 44, and therefore will not be described herein.
需要说明的是,这里的处理器41可以是一个处理器,也可以是多个处理元件的统称。例如,该处理器可以是中央处理器(Central Processing Unit,CPU),也可以是特定集成电路(Application Specific Integrated Circuit,ASIC),或者是被配置成实施本发明实施例的一个或多个集成电路,例如:一个或多个微处理器 (digital singnal processor,DSP),或,一个或者多个现场可编程门阵列(Field Programmable Gate Array,FPGA)。It should be noted that the processor 41 herein may be a processor or a collective name of multiple processing elements. For example, the processor may be a Central Processing Unit (CPU), an Application Specific Integrated Circuit (ASIC), or one or more integrated circuits configured to implement the embodiments of the present invention. , for example: one or more microprocessors (digital singnal processor, DSP), or one or more Field Programmable Gate Arrays (FPGAs).
存储器42可以是一个存储装置,也可以是多个存储元件的统称,且用于存储可执行程序代码或接入网管理设备运行所需要参数、数据等。且存储器22(或存储器23)可以包括随机存储器(RAM),也可以包括非易失性存储器(non-volatile memory),例如磁盘存储器,闪存(Flash)等。The memory 42 may be a storage device or a collective name of a plurality of storage elements, and is used to store executable program code or parameters, data, and the like required for the operation of the access network management device. And the memory 22 (or the memory 23) may include a random access memory (RAM), and may also include a non-volatile memory such as a magnetic disk memory, a flash memory, or the like.
总线44可以是工业标准体系结构(Industry Standard Architecture,ISA)总线、外部设备互连(Peripheral Component,PCI)总线或扩展工业标准体系结构(Extended Industry Standard Architecture,EISA)总线等。可具体分为地址总线、数据总线、控制总线等。为便于表示,图11中仅用一条粗线表示,但并不表示仅有一根总线或一种类型的总线。The bus 44 may be an Industry Standard Architecture (ISA) bus, a Peripheral Component (PCI) bus, or an Extended Industry Standard Architecture (EISA) bus. Can be specifically divided into address bus, data bus, control bus and so on. For ease of representation, only one thick line is shown in Figure 11, but it does not mean that there is only one bus or one type of bus.
至此,本发明的实施例提供一种预编码矩阵索引的传输装置,定义了一种新的PUCCH模式1-1的子模式,具体的,UE接收基站发送的配置信息和导频信息,该配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2;进而,UE根据该导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,并且,UE根据该配置信息,确定在PUCCH上用于传输第一预编码矩阵W1的第一索引和第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0,以使得UE通过PUCCH中的Z个比特,将第一索引和第二索引发送至基站,也就是说,UE可以根据基站发送的上述配置信息自行确定在PUCCH上传输预编码矩阵索引所使用的比特个数,也就是说,在这种新定义的子模式中,传输预编码矩阵索引所使用的比特个数可以是根据配置参数的变化而灵活配置的,以实现在二维天线的应用场景下通过PUCCH传输预编码矩阵索引。So far, an embodiment of the present invention provides a precoding matrix index transmission apparatus, which defines a new sub-mode of PUCCH mode 1-1. Specifically, the UE receives configuration information and pilot information sent by the base station, and the configuration the configuration information includes a parameter, the number of two-dimensional antenna the first antenna port in a first dimension N 1 - 1, the first and second antenna ports O oversampling factor in a second dimension N 2 and the second oversampling factor O 2; Further, the UE information according to the pilot frequency, determining a first precoding matrix configured precoding matrix W W 1 and a second precoding matrix W 2, and, according to the configuration information of the UE, determining a transmission on PUCCH The number of bits of the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 is Z, Z>0, such that the UE passes the Z bits in the PUCCH, and the first index And transmitting, to the base station, the second index, that is, the UE may determine, according to the foregoing configuration information sent by the base station, the number of bits used for transmitting the precoding matrix index on the PUCCH, that is, in the newly defined submode. Transmission precoding moment The number of bits used by the index may change according to the configuration parameters and flexible configuration, the PUCCH transmission in order to achieve a pre-coding matrix index by application scenario of the two-dimensional antenna.
所属领域的技术人员可以清楚地了解到,为描述的方便和简洁,仅以上述各功能模块的划分进行举例说明,实际应用中,可以根据 需要而将上述功能分配由不同的功能模块完成,即将装置的内部结构划分成不同的功能模块,以完成以上描述的全部或者部分功能。上述描述的系统,装置和单元的具体工作过程,可以参考前述方法实施例中的对应过程,在此不再赘述。It will be clearly understood by those skilled in the art that for the convenience and brevity of the description, only the division of the above functional modules is illustrated. In practical applications, The above functions are allocated by different functional modules as needed, that is, the internal structure of the device is divided into different functional modules to complete all or part of the functions described above. For the specific working process of the system, the device and the unit described above, reference may be made to the corresponding process in the foregoing method embodiments, and details are not described herein again.
在本申请所提供的几个实施例中,应该理解到,所揭露的系统,装置和方法,可以通过其它的方式实现。例如,以上所描述的装置实施例仅仅是示意性的,例如,所述模块或单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个系统,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性,机械或其它的形式。In the several embodiments provided by the present application, it should be understood that the disclosed system, apparatus, and method may be implemented in other manners. For example, the device embodiments described above are merely illustrative. For example, the division of the modules or units is only a logical function division. In actual implementation, there may be another division manner, for example, multiple units or components may be used. Combinations can be integrated into another system, or some features can be ignored or not executed. In addition, the mutual coupling or direct coupling or communication connection shown or discussed may be an indirect coupling or communication connection through some interface, device or unit, and may be in an electrical, mechanical or other form.
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。The units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, may be located in one place, or may be distributed to multiple network units. Some or all of the units may be selected according to actual needs to achieve the purpose of the solution of the embodiment.
另外,在本发明各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。上述集成的单元既可以采用硬件的形式实现,也可以采用软件功能单元的形式实现。In addition, each functional unit in each embodiment of the present invention may be integrated into one processing unit, or each unit may exist physically separately, or two or more units may be integrated into one unit. The above integrated unit can be implemented in the form of hardware or in the form of a software functional unit.
所述集成的单元如果以软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。基于这样的理解,本发明的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的全部或部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)或处理器(processor)执行本发明各个实施例所述方法的全部或部分步骤。而前述的存储介质包括:U盘、移动硬盘、只读存 储器(ROM,Read-Only Memory)、随机存取存储器(RAM,Random Access Memory)、磁碟或者光盘等各种可以存储程序代码的介质。The integrated unit, if implemented in the form of a software functional unit and sold or used as a standalone product, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present invention, which is essential or contributes to the prior art, or all or part of the technical solution, may be embodied in the form of a software product stored in a storage medium. A number of instructions are included to cause a computer device (which may be a personal computer, server, or network device, etc.) or a processor to perform all or part of the steps of the methods described in various embodiments of the present invention. The foregoing storage medium includes: a U disk, a mobile hard disk, and a read-only memory. A medium that can store program code, such as a ROM (Read-Only Memory), a random access memory (RAM), a magnetic disk, or an optical disk.
以上所述,仅为本发明的具体实施方式,但本发明的保护范围并不局限于此,任何熟悉本技术领域的技术人员在本发明揭露的技术范围内,可轻易想到变化或替换,都应涵盖在本发明的保护范围之内。因此,本发明的保护范围应以所述权利要求的保护范围为准。 The above is only a specific embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily think of changes or substitutions within the technical scope of the present invention. It should be covered by the scope of the present invention. Therefore, the scope of the invention should be determined by the scope of the appended claims.

Claims (32)

  1. 一种预编码矩阵索引的传输方法,其特征在于,UE内包含有第一向量集合,所述第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,所述方法包括:A method for transmitting a precoding matrix index, wherein a UE includes a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P, The methods include:
    所述UE接收基站发送的配置信息和导频信息,所述配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2Receiving, by the UE, configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second antenna port number N 2 and a second oversampling factor O 2 in two dimensions;
    所述UE根据所述配置信息,对所述P个候选列向量进行下采样,得到构成所述预编码矩阵W的K个列向量,0<K≤64≤P;The UE downsamples the P candidate column vectors according to the configuration information, to obtain K column vectors constituting the precoding matrix W, 0<K≤64≤P;
    所述UE根据所述导频信息,从所述K个列向量中确定构造所述预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,所述预编码矩阵W=W1*W2Determining, by the UE, the first precoding matrix W 1 and the second precoding matrix W 2 that construct the precoding matrix W from the K column vectors according to the pilot information, where the precoding matrix W = W 1 * W 2 ;
    所述UE通过物理上行链路控制信道PUCCH将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站,以使得所述基站根据所述第一索引和所述第二索引确定所述预编码矩阵W。Transmitting, by the UE, a first index of the first precoding matrix W 1 and a second index of the second precoding matrix W 2 to the base station by using a physical uplink control channel PUCCH, such that the base station The precoding matrix W is determined according to the first index and the second index.
  2. 根据权利要求1所述的方法,其特征在于,所述第一向量集合包括第一维待选向量集合vl和第二维待选向量集合ukThe method according to claim 1, wherein the first set of vectors comprises a first dimension candidate vector set v l and a second dimension candidate vector set u k ,
    其中,所述UE根据所述配置信息,对所述P个候选列向量进行下采样,得到构成所述预编码矩阵的K个列向量,包括:The UE performs downsampling on the P candidate column vectors according to the configuration information, to obtain K column vectors constituting the precoding matrix, including:
    所述UE根据所述配置信息确定所述下采样的采样频率;Determining, by the UE, the sampling frequency of the down sampling according to the configuration information;
    所述UE按照所述采样频率从所述第一维待选向量集合vl中采集L个第一维向量
    Figure PCTCN2015094030-appb-100001
    从所述第二维待选向量集合uk中采集J个第二维向量
    Figure PCTCN2015094030-appb-100002
    L*J=K,L、J、l'、k'均为大于等于0的整数。    Collecting, by the UE, L first dimension vectors from the first dimension candidate vector set v l according to the sampling frequency
    Figure PCTCN2015094030-appb-100001
    Collecting J second dimension vectors from the second dimension candidate vector set u k
    Figure PCTCN2015094030-appb-100002
    L*J=K, L, J, l', k' are all integers greater than or equal to zero.
  3. 根据权利要求2所述的方法,其特征在于,所述UE根据所述配置信息确定所述下采样的采样频率,包括:The method according to claim 2, wherein the determining, by the UE, the sampling frequency of the downsampling according to the configuration information comprises:
    所述UE根据所述第一过采样因子O1,通过第一采样公式计算从所述第一维待选向量集合vl中采集第一维向量
    Figure PCTCN2015094030-appb-100003
    的采样频率;     And acquiring, by the first sampling factor O 1 , the first dimension vector from the first dimension of the candidate vector set v l according to the first sampling factor
    Figure PCTCN2015094030-appb-100003
    Sampling frequency
    所述UE根据所述第二过采样因子O2,通过所述第一采样公式计算从所述第二维待选向量集合uk中采集第二维向量
    Figure PCTCN2015094030-appb-100004
    的采样频率。    The UE calculates a second dimension vector from the second dimension candidate vector set u k by using the first sampling formula according to the second oversampling factor O 2
    Figure PCTCN2015094030-appb-100004
    Sampling frequency.
  4. 根据权利要求3所述的方法,其特征在于,The method of claim 3 wherein:
    当天线端口数为12或者16时,所述第一采样公式为:
    Figure PCTCN2015094030-appb-100005
    Figure PCTCN2015094030-appb-100006
    或者所述第一采样公式为:
    Figure PCTCN2015094030-appb-100007
         When the number of antenna ports is 12 or 16, the first sampling formula is:
    Figure PCTCN2015094030-appb-100005
    Figure PCTCN2015094030-appb-100006
     Or the first sampling formula is:
    Figure PCTCN2015094030-appb-100007
    当天线端口数为8时,所述第一采样公式为:
    Figure PCTCN2015094030-appb-100008
    When the number of antenna ports is 8, the first sampling formula is:
    Figure PCTCN2015094030-appb-100008
    其中,l'为大于等于0的整数,k'为大于等于0的整数,所述天线端口数=N1*N2*极化方向的数目。Wherein l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
  5. 根据权利要求2所述的方法,其特征在于,所述UE根据所述配置信息确定所述下采样的采样频率,包括:The method according to claim 2, wherein the determining, by the UE, the sampling frequency of the downsampling according to the configuration information comprises:
    所述UE根据所述配置信息,通过第二采样公式从所述第一维待选向量集合vl中采集第一维向量
    Figure PCTCN2015094030-appb-100009
    And acquiring, by the UE, the first dimension vector from the first dimension of the candidate vector set v l according to the configuration information by using a second sampling formula
    Figure PCTCN2015094030-appb-100009
    所述UE根据所述配置信息,通过所述第二采样公式从所述第二维待选向量集合uk中采集第二维向量
    Figure PCTCN2015094030-appb-100010
    The UE collects a second dimension vector from the second dimension candidate vector set u k by using the second sampling formula according to the configuration information.
    Figure PCTCN2015094030-appb-100010
  6. 根据权利要求5所述的方法,其特征在于,The method of claim 5 wherein:
    当天线端口数为16或者12时,若O1=O2,且N1<N2,则所述第二采样公式为:
    Figure PCTCN2015094030-appb-100011
    否则,所述第二采样公式为:
    Figure PCTCN2015094030-appb-100012
         When the number of antenna ports is 16 or 12, if O 1 =O 2 and N 1 <N 2 , the second sampling formula is:
    Figure PCTCN2015094030-appb-100011
    Otherwise, the second sampling formula is:
    Figure PCTCN2015094030-appb-100012
    当天线端口数为8时,所述第二采样公式为:
    Figure PCTCN2015094030-appb-100013
    When the number of antenna ports is 8, the second sampling formula is:
    Figure PCTCN2015094030-appb-100013
    其中,l'为大于等于0的整数,k'为大于等于0的整数,所述天线端口数=N1*N2*极化方向的数目。Wherein l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
  7. 根据权利要求2-6中任一项所述的方法,其特征在于,在所述UE接收所述基站发送的配置信息和导频信息之后,还包括: The method according to any one of claims 2-6, after the receiving, by the UE, the configuration information and the pilot information sent by the base station, the method further includes:
    所述UE根据所述配置信息计算所述第一维待选向量集合vl
    Figure PCTCN2015094030-appb-100014
         The UE calculates the first dimension candidate vector set v l according to the configuration information,
    Figure PCTCN2015094030-appb-100014
    所述UE根据所述配置信息计算所述第二维待选向量集合uk
    Figure PCTCN2015094030-appb-100015
         The UE calculates the second dimension candidate vector set u k according to the configuration information,
    Figure PCTCN2015094030-appb-100015
  8. 根据权利要求1-7中任一项所述的方法,其特征在于,所述UE根据所述导频信息,从所述K个列向量中确定构造所述预编码矩阵的第一预编码矩阵W1和第二预编码矩阵W2,包括:The method according to any one of claims 1 to 7, wherein the UE determines, according to the pilot information, a first precoding matrix that constructs the precoding matrix from the K column vectors. W 1 and a second precoding matrix W 2 include:
    所述UE根据所述导频信息,从所述K个列向量中确定所述第一预编码矩阵W1Determining, by the UE, the first precoding matrix W 1 from the K column vectors according to the pilot information;
    所述UE根据所述配置参数从所述第一预编码矩阵W1的列向量中确定所述第二预编码矩阵W2The UE determines the second precoding matrix W 2 from the column vectors of the first precoding matrix W 1 according to the configuration parameter.
  9. 根据权利要求1-8中任一项所述的方法,其特征在于,所述UE通过PUCCH将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站,包括:The method according to any one of claims 1 to 8, wherein the UE passes the first index of the first precoding matrix W 1 and the second precoding matrix W 2 by using a PUCCH. Sending the second index to the base station includes:
    所述UE通过PUCCH模式1-1子模式1,将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站。The UE transmits the first index of the first precoding matrix W 1 and the second index of the second precoding matrix W 2 to the base station by using PUCCH mode 1-1 submode 1.
  10. 根据权利要求1-8中任一项所述的方法,其特征在于,所述UE通过PUCCH将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站,包括:The method according to any one of claims 1 to 8, wherein the UE passes the first index of the first precoding matrix W 1 and the second precoding matrix W 2 by using a PUCCH. Sending the second index to the base station includes:
    所述UE通过PUCCH模式1-1子模式2,将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站。The UE transmits a first index of the first precoding matrix W 1 and a second index of the second precoding matrix W 2 to the base station by using a PUCCH mode 1-1 submode 2.
  11. 根据权利要求1-10中任一项所述的方法,其特征在于,所述UE接收所述基站发送的配置信息,包括:The method according to any one of claims 1-10, wherein the receiving, by the UE, configuration information sent by the base station includes:
    所述UE通过无线资源控制RRC信令接收所述基站发送的所述配置信息。The UE receives the configuration information sent by the base station by using radio resource control RRC signaling.
  12. 一种预编码矩阵索引的传输方法,其特征在于,包括:A method for transmitting a precoding matrix index, comprising:
    所述UE接收基站发送的配置信息和导频信息,所述配置信息包 括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2Receiving, by the UE, configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 and a first oversampling factor O 1 of the two-dimensional antenna in the first dimension, and a second antenna port number N 2 and a second oversampling factor O 2 in two dimensions;
    所述UE根据所述导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,所述预编码矩阵W=W1*W2The UE determines, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, where the precoding matrix W=W 1 *W 2 ;
    所述UE根据所述配置信息,确定在物理上行链路控制信道PUCCH上用于传输所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0;Determining, according to the configuration information, the first index used by the first uplink precoding matrix W 1 and the second index of the second precoding matrix W 2 on the physical uplink control channel PUCCH The number of bits is Z, Z>0;
    所述UE通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站,以使得所述基站根据所述第一索引和所述第二索引确定所述预编码矩阵W。Sending, by the PUCCH, the first index and the second index to the base station according to the number of Z bits, so that the base station determines, according to the first index and the second index, The precoding matrix W.
  13. 根据权利要求12所述的方法,其特征在于,所述UE内包含有第一向量集合,所述第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P,The method according to claim 12, wherein the UE includes a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P,
    其中,所述UE根据所述导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,包括:The determining, by the UE, the first precoding matrix W 1 and the second precoding matrix W 2 that construct the precoding matrix W according to the pilot information, including:
    所述UE根据所述导频信息确定与所述基站之间的秩指示RI信息和信道质量指示CQI信息;Determining, by the UE, rank indication RI information and channel quality indication CQI information with the base station according to the pilot information;
    所述UE根据所述RI信息,从所述P个候选列向量中确定构造所述预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2Determining, by the UE, the first precoding matrix W 1 and the second precoding matrix W 2 that construct the precoding matrix W from the P candidate column vectors according to the RI information.
  14. 根据权利要求13所述的方法,其特征在于,所述UE通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站,包括:The method according to claim 13, wherein the UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, including:
    所述UE将所述第一预编码矩阵W1的第一索引与所述RI信息进行联合编码,得到第一联和编码值;The UE jointly encodes the first index of the first precoding matrix W 1 and the RI information to obtain a first union code value;
    所述UE通过所述PUCCH,将Z1个比特的所述第一联和编码值通过所述PUCCH发送至所述基站;Transmitting, by the UE, the first joint coded value of Z1 bits to the base station by using the PUCCH by using the PUCCH;
    所述UE通过所述PUCCH,将Z2个比特的所述第二预编码矩阵W2的第二索引与所述CQI信息发送至所述基站,Z1+Z2=Z,Z1>0,Z2 >0。Transmitting, by the PUCCH, a second index of the second precoding matrix W 2 of Z2 bits and the CQI information to the base station, where Z1+Z2=Z, Z1>0, Z2>0 .
  15. 根据权利要求13所述的方法,其特征在于,所述第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,The method according to claim 13, wherein the first index comprises a first dimension index in a first dimension and a second dimension index in a second dimension,
    其中,所述UE通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站,包括:The UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, including:
    所述UE将所述第一维度索引与所述RI信息进行联合编码,得到第二联和编码值;The UE jointly encodes the first dimension index and the RI information to obtain a second union code value;
    所述UE将所述第二维度索引、所述第二索引和所述CQI信息进行联合编码,得到第三联和编码值;The UE jointly encodes the second dimension index, the second index, and the CQI information to obtain a third union code value;
    所述UE按照Z个比特个数,将所述第二联和编码值与所述第三联和编码值通过所述PUCCH发送至所述基站。Transmitting, by the UE, the second union code value and the third union code value to the base station by using the PUCCH according to the number of Z bits.
  16. 根据权利要求13所述的方法,其特征在于,所述第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,The method according to claim 13, wherein the first index comprises a first dimension index in a first dimension and a second dimension index in a second dimension,
    其中,所述UE通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站,包括:The UE sends the first index and the second index to the base station according to the number of Z bits by using the PUCCH, including:
    所述UE将所述第二维度索引与所述RI信息进行联合编码,得到第四联和编码值;The UE jointly encodes the second dimension index and the RI information to obtain a fourth union code value;
    所述UE将所述第一维度索引、所述第二索引和所述CQI信息进行联合编码,得到第五联和编码值;The UE jointly encodes the first dimension index, the second index, and the CQI information to obtain a fifth union code value;
    所述UE按照Z个比特个数,将所述得到第四联和编码值与所述第五联和编码值通过所述PUCCH发送至所述基站。And the UE sends the obtained fourth joint code value and the fifth joint code value to the base station by using the PUCCH according to the number of Z bits.
  17. 根据权利要求15或16所述的方法,其特征在于,在所述UE通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站之前,还包括:The method according to claim 15 or 16, wherein before the UE transmits the first index and the second index to the base station according to the number of Z bits by using the PUCCH, include:
    所述UE接收所述基站发送的编码指示,所述编码指示用于指示所述RI信息与所述第一维度索引或所述第二维度索引进行联合编码。The UE receives an encoding indication sent by the base station, where the encoding indication is used to indicate that the RI information is jointly encoded with the first dimension index or the second dimension index.
  18. 一种用户设备UE,其特征在于,所述UE包括:处理器、存储器以及收发器,其中, A user equipment (UE), the UE includes: a processor, a memory, and a transceiver, where
    所述存储器,用于存储第一向量集合,所述第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P;The memory is configured to store a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P;
    所述收发器,用于接收基站发送的配置信息和导频信息,所述配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2The transceiver is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 of the two-dimensional antenna in the first dimension, and a first oversampling factor O 1 And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension;
    所述处理器,用于根据所述配置信息,对所述P个候选列向量进行下采样,得到构成所述预编码矩阵W的K个列向量,0<K≤64≤P;以及,根据所述导频信息,从所述K个列向量中确定构造所述预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,所述预编码矩阵W=W1*W2The processor is configured to perform downsampling on the P candidate column vectors according to the configuration information, to obtain K column vectors constituting the precoding matrix W, where 0<K≤64≤P; Deriving, from the K column vectors, a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W, wherein the precoding matrix W=W 1 *W 2 ;
    所述收发器,还用于通过物理上行链路控制信道PUCCH将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站,以使得所述基站根据所述第一索引和所述第二索引确定所述预编码矩阵W。The transceiver is further configured through a physical uplink control channel PUCCH of the first pre-coding matrix W 1 of the first index and the second index of the second precoding matrix W 2 is transmitted to the base station, So that the base station determines the precoding matrix W according to the first index and the second index.
  19. 根据权利要求18所述的UE,其特征在于,The UE according to claim 18, characterized in that
    所述处理器,具体用于根据所述配置信息确定所述下采样的采样频率;以及,按照所述采样频率从第一维待选向量集合vl中采集L个第一维向量
    Figure PCTCN2015094030-appb-100016
    从第二维待选向量集合uk中采集J个第二维向量
    Figure PCTCN2015094030-appb-100017
    L*J=K,L、J、l'、k'均为大于等于0的整数;    The processor is specifically configured to determine, according to the configuration information, a sampling frequency of the downsampling; and, according to the sampling frequency, collect L first dimensional vectors from a first set of candidate vector sets v l
    Figure PCTCN2015094030-appb-100016
    Collecting J second-dimensional vectors from the second-dimensional candidate vector set u k
    Figure PCTCN2015094030-appb-100017
    L*J=K, L, J, l', k' are integers greater than or equal to 0;
    其中,所述第一向量集合包括第一维待选向量集合vl和第二维待选向量集合ukThe first vector set includes a first dimension candidate vector set v l and a second dimension candidate vector set u k .
  20. 根据权利要求19所述的UE,其特征在于,The UE according to claim 19, characterized in that
    所述处理器,具体用于根据所述第一过采样因子O1,通过第一采样公式计算从所述第一维待选向量集合vl中采集第一维向量
    Figure PCTCN2015094030-appb-100018
    的采样频率;以及,根据所述第二过采样因子O2,通过所述第一采样公式计算从所述第二维待选向量集合uk中采集第二维向量
    Figure PCTCN2015094030-appb-100019
    的采样频率;    The processor is configured to: collect, according to the first oversampling factor O 1 , a first dimension vector from the first dimension of the candidate vector set v l by using a first sampling formula
    Figure PCTCN2015094030-appb-100018
    a sampling frequency; and, according to the second oversampling factor O 2 , calculating a second dimensional vector from the second set of candidate vectors u k by the first sampling formula
    Figure PCTCN2015094030-appb-100019
    Sampling frequency
    其中,当天线端口数为12或者16时,所述第一采样公式为:
    Figure PCTCN2015094030-appb-100020
    或者所述第一采样公式为:
    Figure PCTCN2015094030-appb-100021
    当天线端口数为8时,所述第一采样公式为:
    Figure PCTCN2015094030-appb-100022
    l'为大于等于0的整数,k'为大于等于0的整数,所述天线端口数=N1*N2*极化方向的数目。    Wherein, when the number of antenna ports is 12 or 16, the first sampling formula is:
    Figure PCTCN2015094030-appb-100020
    Or the first sampling formula is:
    Figure PCTCN2015094030-appb-100021
    When the number of antenna ports is 8, the first sampling formula is:
    Figure PCTCN2015094030-appb-100022
    l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
  21. 根据权利要求19所述的UE,其特征在于,The UE according to claim 19, characterized in that
    所述处理器,具体用于根据所述配置信息,通过第二采样公式从所述第一维待选向量集合vl中采集第一维向量
    Figure PCTCN2015094030-appb-100023
    以及,根据所述配置信息,通过所述第二采样公式从所述第二维待选向量集合uk中采集第二维向量
    Figure PCTCN2015094030-appb-100024
    The processor is configured to collect a first dimension vector from the first dimension of the candidate vector set v l by using a second sampling formula according to the configuration information.
    Figure PCTCN2015094030-appb-100023
    And acquiring, according to the configuration information, the second dimension vector from the second dimension of the candidate vector set u k by using the second sampling formula
    Figure PCTCN2015094030-appb-100024
    其中,当天线端口数为16或者12时,若O1=O2,且N1<N2,则所述第二采样公式为:
    Figure PCTCN2015094030-appb-100025
    否则,所述第二采样公式为:
    Figure PCTCN2015094030-appb-100026
    当天线端口数为8时,所述第二采样公式为:
    Figure PCTCN2015094030-appb-100027
    Figure PCTCN2015094030-appb-100028
    l'为大于等于0的整数,k'为大于等于0的整数,所述天线端口数=N1*N2*极化方向的数目。    Wherein, when the number of antenna ports is 16 or 12, if O 1 =O 2 and N 1 <N 2 , the second sampling formula is:
    Figure PCTCN2015094030-appb-100025
    Otherwise, the second sampling formula is:
    Figure PCTCN2015094030-appb-100026
    When the number of antenna ports is 8, the second sampling formula is:
    Figure PCTCN2015094030-appb-100027
    Figure PCTCN2015094030-appb-100028
    l' is an integer greater than or equal to 0, k' is an integer greater than or equal to 0, and the number of antenna ports = N 1 * N 2 * the number of polarization directions.
  22. 根据权利要求19-21中任一项所述的UE,其特征在于,The UE according to any one of claims 19 to 21, characterized in that
    所述处理器,还用于根据所述配置信息计算所述第一维待选向量集合vl
    Figure PCTCN2015094030-appb-100029
    以及,根据所述配置信息计算所述第二维待选向量集合uk
    Figure PCTCN2015094030-appb-100030
    Figure PCTCN2015094030-appb-100031
         The processor is further configured to calculate, according to the configuration information, the first dimension candidate vector set v l ,
    Figure PCTCN2015094030-appb-100029
     And calculating, according to the configuration information, the second dimension candidate vector set u k ,
    Figure PCTCN2015094030-appb-100030
    Figure PCTCN2015094030-appb-100031
  23. 根据权利要求18-22中任一项所述的UE,其特征在于,The UE according to any one of claims 18 to 22, characterized in that
    所述处理器,具体用于根据所述导频信息,从所述K个列向量中确定所述第一预编码矩阵W1;以及,根据所述配置参数从所述第一预 编码矩阵W1的列向量中确定所述第二预编码矩阵W2The processor is specifically configured to determine, according to the pilot information, the first precoding matrix W 1 from the K column vectors; and, from the first precoding matrix W according to the configuration parameter. 1 column vector determining the second precoding matrix W 2.
  24. 根据权利要求18-23中任一项所述的UE,其特征在于,The UE according to any one of claims 18 to 23, characterized in that
    所述收发器,具体用于通过PUCCH模式1-1子模式1,将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站。The transceiver is specifically configured to send, by using a PUCCH mode 1-1 sub-mode 1, a first index of the first precoding matrix W 1 and a second index of the second precoding matrix W 2 to the Base station.
  25. 根据权利要求18-23中任一项所述的UE,其特征在于,The UE according to any one of claims 18 to 23, characterized in that
    所述收发器,具体用于通过PUCCH模式1-1子模式2,将所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引发送至所述基站。The transceiver is specifically configured to send, by using a PUCCH mode 1-1 sub-mode 2, a first index of the first precoding matrix W 1 and a second index of the second precoding matrix W 2 to the Base station.
  26. 根据权利要求18-25中任一项所述的UE,其特征在于,The UE according to any one of claims 18 to 25, characterized in that
    所述收发器,具体用于通过无线资源控制RRC信令接收所述基站发送的所述配置信息。The transceiver is specifically configured to receive, by using radio resource control RRC signaling, the configuration information sent by the base station.
  27. 一种用户设备UE,其特征在于,包括:处理器、存储器以及收发器,其中,A user equipment (UE), comprising: a processor, a memory, and a transceiver, wherein
    所述收发器,用于接收基站发送的配置信息和导频信息,所述配置信息包括配置参数、二维天线在第一维度上的第一天线端口数N1和第一过采样因子O1,以及在第二维度上的第二天线端口数N2和第二过采样因子O2The transceiver is configured to receive configuration information and pilot information sent by the base station, where the configuration information includes configuration parameters, a first antenna port number N 1 of the two-dimensional antenna in the first dimension, and a first oversampling factor O 1 And a second antenna port number N 2 and a second oversampling factor O 2 in the second dimension;
    所述处理器,用于根据所述导频信息,确定构造预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2,其中,所述预编码矩阵W=W1*W2;以及,根据所述配置信息,确定在物理上行链路控制信道PUCCH上用于传输所述第一预编码矩阵W1的第一索引和所述第二预编码矩阵W2的第二索引的比特个数为Z个,Z>0;The processor is configured to determine, according to the pilot information, a first precoding matrix W 1 and a second precoding matrix W 2 that construct a precoding matrix W, where the precoding matrix W=W 1 *W And determining, according to the configuration information, a first index for transmitting the first precoding matrix W 1 and a second index of the second precoding matrix W 2 on a physical uplink control channel PUCCH The number of bits is Z, Z>0;
    所述收发器,还用于通过所述PUCCH,按照Z个比特个数将所述第一索引和所述第二索引发送至所述基站,以使得所述基站根据所述第一索引和所述第二索引确定所述预编码矩阵W。The transceiver is further configured to send, by using the PUCCH, the first index and the second index to the base station according to a number of Z bits, so that the base station is configured according to the first index and the The second index determines the precoding matrix W.
  28. 根据权利要求27所述的UE,其特征在于,The UE according to claim 27, characterized in that
    所述存储器,用于存储第一向量集合,所述第一向量集合中包含用于构造预编码矩阵W的P个候选列向量,64≤P; The memory is configured to store a first set of vectors, where the first set of vectors includes P candidate column vectors for constructing a precoding matrix W, 64 ≤ P;
    所述处理器,具体用于根据所述导频信息确定与所述基站之间的秩指示RI信息和信道质量指示CQI信息;以及,根据所述RI信息,从所述P个候选列向量中确定构造所述预编码矩阵W的第一预编码矩阵W1和第二预编码矩阵W2The processor is specifically configured to determine, according to the pilot information, rank indication RI information and channel quality indication CQI information with the base station; and, according to the RI information, from the P candidate column vectors. Determining a first precoding matrix W 1 and a second precoding matrix W 2 that construct the precoding matrix W.
  29. 根据权利要求28所述的UE,其特征在于,The UE according to claim 28, characterized in that
    所述处理器,还用于将所述第一预编码矩阵W1的第一索引与所述RI信息进行联合编码,得到第一联和编码值;The processor is further configured to jointly encode the first index of the first precoding matrix W 1 and the RI information to obtain a first union code value;
    所述收发器,还用于通过所述PUCCH,将Z1个比特的所述第一联和编码值通过所述PUCCH发送至所述基站;以及,通过所述PUCCH,将Z2个比特的所述第二预编码矩阵W2的第二索引与所述CQI信息发送至所述基站,Z1+Z2=Z,Z1>0,Z2>0。The transceiver is further configured to send, by using the PUCCH, the first joint coded value of Z1 bits to the base station by using the PUCCH; and, by using the PUCCH, the Z2 bits of the The second index of the second precoding matrix W 2 and the CQI information are sent to the base station, Z1+Z2=Z, Z1>0, and Z2>0.
  30. 根据权利要求28所述的UE,其特征在于,所述第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,The UE according to claim 28, wherein the first index comprises a first dimension index in a first dimension and a second dimension index in a second dimension, wherein
    所述处理器,还用于将所述第一维度索引与所述RI信息进行联合编码,得到第二联和编码值;以及,将所述第二维度索引、所述第二索引和所述CQI信息进行联合编码,得到第三联和编码值;The processor is further configured to jointly encode the first dimension index and the RI information to obtain a second union code value; and, the second dimension index, the second index, and the The CQI information is jointly encoded to obtain a third joint code value;
    所述收发器,还用于按照Z个比特个数,将所述第二联和编码值与所述第三联和编码值通过所述PUCCH发送至所述基站。The transceiver is further configured to send the second union code value and the third union code value to the base station by using the PUCCH according to the number of Z bits.
  31. 根据权利要求28所述的UE,其特征在于,所述第一索引包括在第一维度上的第一维度索引和在第二维度上的第二维度索引,其中,The UE according to claim 28, wherein the first index comprises a first dimension index in a first dimension and a second dimension index in a second dimension, wherein
    所述处理器,还用于将所述第二维度索引与所述RI信息进行联合编码,得到第四联和编码值;以及,将所述第一维度索引、所述第二索引和所述CQI信息进行联合编码,得到第五联和编码值;The processor is further configured to jointly encode the second dimension index and the RI information to obtain a fourth union code value; and, the first dimension index, the second index, and the The CQI information is jointly encoded to obtain a fifth joint code value;
    所述收发器,还用于按照Z个比特个数,将所述得到第四联和编码值与所述第五联和编码值通过所述PUCCH发送至所述基站。The transceiver is further configured to send the obtained fourth joint code value and the fifth joint code value to the base station by using the PUCCH according to the number of Z bits.
  32. 根据权利要求30或31所述的UE,其特征在于,The UE according to claim 30 or 31, characterized in that
    所述收发器,还用于接收所述基站发送的编码指示,所述编码指 示用于指示所述RI信息与所述第一维度索引或所述第二维度索引进行联合编码。 The transceiver is further configured to receive an encoding indication sent by the base station, where the encoding refers to The indication is used to indicate that the RI information is jointly encoded with the first dimension index or the second dimension index.
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