JPWO2020088640A5 - - Google Patents

Description

According to the CSI feedback and receiving method, apparatus, device and storage medium provided by the embodiments of the present disclosure, the terminal determines precoding matrix indication information (PMI), the PMI is the first basis vector information, second basis vector information, and second coefficient information, the second coefficient information including second coefficient amplitude information and/or second coefficient phase information; The precoding vectors corresponding to the frequency domain resources within the domain unit are identical, the precoding vectors are linear combinations of the first basis vectors, and the weighting factors used in the linear combination of the first basis vectors are , the first coefficient, and the vector consisting of the first coefficients corresponding to the same first basis vector over a plurality of frequency domain units contained in the CSI feedback band is a linear combination of the second basis vectors and the weighting factor used in the linear combination of the second basis vectors is the second factor, and the terminal feeds back the CSI containing the PMI to the base station. CSI feedback is performed after the frequency domain and spatial domain channel coefficients are compressed, thereby ensuring high CSI feedback performance while reducing CSI feedback overhead.
The present invention provides, for example, the following.
(Item 1)
A channel state information (CSI) feedback method, comprising:
determining, by a terminal, precoding matrix indication information (PMI), the PMI comprising first basis vector information, second basis vector information, and second coefficient information; The second coefficient information comprises at least one of second coefficient amplitude information or second coefficient phase information, and for one transmission layer frequency domain resources within one preset frequency domain unit are: , corresponding to one precoding vector, each precoding vector being a linear combination of first basis vectors, the weighting coefficients in said linear combination of first basis vectors being the first coefficients, and the CSI A vector of first coefficients corresponding to the same first basis vector over a plurality of frequency domain units contained in the feedback band is a linear combination of the second basis vectors, said second basis vectors the weighting factor used in the linear combination of is the second factor;
Feeding back CSI containing the PMI to a base station by the terminal
A method, including
(Item 2)
The frequency domain unit comprises at least one of a subband, a resource block (RB), or a first RB set, and the number of RBs contained in the first RB set is the number of the CSI feedback bands. A method according to item 1, which is less than the number of RBs contained in a subband.
(Item 3)
The method of item 1, wherein the second basis vector is a Discrete Fourier Transform (DFT) vector.
(Item 4)
2. The method of item 1, wherein the dimension of each second basis vector is equal to the number of frequency domain units contained in the CSI feedback band.
(Item 5)
3. The method of item 2, wherein, when the frequency domain unit is the RB, all RBs contained in the CSI feedback band are divided into at least one second RB set.
(Item 6)
Feeding back the CSI containing the PMI to the base station by the terminal
The terminal feeds back second basis vector information corresponding to each of the at least one second RB set and second coefficient information corresponding to each of the at least one second RB set to the base station. to do
6. The method of item 5, comprising
(Item 7)
Feeding back the CSI containing the PMI to the base station by the terminal
The terminal feeds back, to the base station, second coefficient information corresponding to each of the at least one second RB set and second basis vector information common to all of the at least one second RB set. to do
6. The method of item 5, comprising
(Item 8)
a first coefficient corresponding to each of the at least one second RB set, a second coefficient corresponding to each of the at least one second RB set and each of the at least one second RB set 8. A method according to item 6 or 7, obtained based on the second basis vectors corresponding to .
(Item 9)
8. The method of item 6 or 7, wherein the dimension of the second basis vectors corresponding to each of the at least one second set of RBs is equal to the number of RBs contained in each of the at least one second set of RBs. the method of.
(Item 10)
8. The method of item 7, wherein different second sets of RBs within the CSI feedback band have the same number of included RBs.
(Item 11)
Each of the at least one second set of RBs:
the RBs in each of the at least one second set of RBs being a plurality of consecutive RBs within the CSI feedback band;
the RBs in each of the at least one second set of RBs being a plurality of RBs distributed with a preset number of intervals within the CSI feedback band; or
the RBs in each of said at least one second set of RBs being a plurality of RBs distributed with a preset number of intervals over a bandwidth portion (BWP) corresponding to said CSI;
6. The method of item 5, wherein at least one of
(Item 12)
6. The method of item 5, wherein the number of at least one second set of RBs is determined based on the total number of RBs contained in the CSI feedback band.
(Item 13)
determining whether the total number of RBs contained in the CSI feedback band is greater than or equal to a preset threshold;
dividing the CSI feedback band into M second sets of RBs in response to a determination that the total number of RBs contained in the CSI feedback band is greater than or equal to the preset threshold;
dividing the CSI feedback band into a second set of M2 RBs in response to determining that the total number of RBs contained in the CSI feedback band is less than the preset threshold;
further comprising
M1 and M2 are positive integers, M1 is greater than M2, and M2 is 1 or greater;
13. The method of item 12.
(Item 14)
6. The method of item 5, wherein the partitioning strategy of the at least one second set of RBs is determined based on subband distribution information of subbands contained in the CSI feedback band.
(Item 15)
The partitioning strategy comprises: partitioning RBs on multiple contiguous subbands of the CSI feedback band into the same second set of RBs; 15. The method of item 14, comprising partitioning into RB sets of .
(Item 16)
6. The method of item 5, wherein the number of at least one second RB set is determined based on measured channel state information reference signals (CSI-RS).
(Item 17)
When the CSI comprises a first portion and a second portion, feeding back the CSI containing the PMI to the base station by the terminal includes:
feeding back, by the terminal, the first portion and the second portion to the base station, wherein the first portion fed back comprises a number of the at least one second RB set; the feedback overhead of the second portion is determined based on the value of the first portion fed back;
17. The method of item 16.
(Item 18)
determining whether the number of the at least one second set of RBs is above a preset threshold;
determining to select K1 second basis vectors in response to a determination that the number of the at least one second set of RBs exceeds the preset threshold; determining to select K2 second basis vectors in response to the determination result that the number of RB sets of 2 is less than or equal to the preset threshold, wherein K1 and K2 are: is a positive integer and K1 is less than K2;
6. The method of item 5, further comprising:
(Item 19)
A plurality of the second vector information and a plurality of the first base vector information are present, and the plurality of second base vector information fed back to the base station by the terminal are each the plurality of first base vector information. 2. The method of item 1, corresponding to the basis vector information of .
(Item 20)
20. The method of item 19, further comprising determining each of said second basis vector information according to a differential encoding method.
(Item 21)
Determining each of the second basis vector information according to the differential encoding method includes:
by difference encoding on the second basis vector information corresponding to the l first basis vector information or by difference on the second basis vector information corresponding to the (l−1) first basis vector information obtaining second basis vector information corresponding to the lth first basis vector information by encoding, wherein l is a positive integer greater than 1;
21. The method of item 20, comprising
(Item 22)
The second basis vector information indicates a set of second basis vectors, and a plurality of first basis vectors are present and included in the second set of basis vectors fed back to the base station by the terminal. 2. The method of item 1, wherein every second basis vector obtained corresponds to all of the plurality of first basis vectors.
(Item 23)
A second basis vector candidate set to which said second basis vector belongs is determined based on parameter O and parameter N, said second basis vector candidate set being {v ₁ , . . . , v _NO } or {v ₁ , ..., v _NO }, O is a positive integer, and N is the number of frequency domain units contained in the CSI feedback band. Method.
(Item 24)
24. The method of item 23, wherein O is determined according to base station configuration signaling or O is determined according to measured CSI-RS.
(Item 25)
When the second candidate basis vector set is a subset of {v ₁ , . . . , v _NO }, the method for determining the second candidate basis vector set includes:
Determining a vector in {v _{1 ,} . positioned as a vector in the second basis vector candidate set;
determining the second candidate base vector set based on a starting position of the second candidate base vector set configured according to base station configuration signaling and the number of vectors in the second candidate base vector set; ,or
According to base station configuration signaling, a target orthogonal vector group that constitutes the second basis vector candidate set, and a target in the target orthogonal vector group from a plurality of orthogonal vector groups in {v ₁ , . . . , v _NO }. Determining vectors, wherein mutually orthogonal vectors belong to the same orthogonal vector group
24. The method of item 23, comprising at least one of
(Item 26)
2. The method of item 1, wherein the second basis vectors comprise a plurality of mutually orthogonal vectors contained in a target orthogonal vector group selected from a plurality of orthogonal vector groups in a second basis vector candidate set.
(Item 27)
The second basis vectors are a plurality of continuous vectors contained in a target continuous vector group selected from a plurality of continuous vector groups in the second basis vector candidate set, and the plurality of continuous vector groups are continuous The method of item 1, containing basis vectors.
(Item 28)
The second basis vector information is
the vector group index of the selected vector group, or
a vector group index of a selected vector group and a vector index of a vector selected from the selected vector group;
28. The method of item 26 or 27, comprising:
(Item 29)
When the frequency domain unit is an RB, and all RBs contained in the CSI feedback band are divided into a plurality of second RB sets, the terminal transmits the CSI containing the PMI to the base station. to give feedback to
feedback by the terminal to the base station the same vector group index for multiple second sets of RBs in the CSI feedback band; or
The terminal feeds back the same vector group index to the base station for all of the plurality of second RB sets in the CSI feedback band, and for each of the plurality of second RB sets, the plurality of second Feeding back vector indices corresponding to each of the 2 RB sets
29. The method of item 28, comprising
(Item 30)
2. The method of item 1, wherein the second basis vectors comprise K basis vectors selected from X consecutive basis vectors in the second candidate basis vector set, where X and K are positive integers. the method of.
(Item 31)
The second basis vectors are intercepted according to configuration information of the CSI feedback band from DFT vectors having corresponding lengths generated based on the number of frequency domain units contained in the downlink BWP corresponding to the CSI. 2. The method of item 1, comprising the vector to be
(Item 32)
The CSI further comprises channel quality indicators (CQIs) of subbands, and when the frequency domain unit is a unit of less than one subband, the CQIs of the subbands contained in the CSI are equal to the subbands 2. The method according to item 1, wherein the precoding vector corresponding to all frequency domain units contained in .
(Item 33)
Feeding back the CSI containing the PMI to the base station by the terminal
After quantizing two components of the second coefficient amplitude information in the PMI to be between 0 and 1, feeding back the two quantized components to the base station by the terminal. wherein the second coefficient amplitude information is the product of the two components, the two components comprising a first amplitude component and a second amplitude component;
The method of item 1.
(Item 34)
The second amplitude component fed back by the terminal is
the terminal feeding back a common second amplitude component for a plurality of second coefficient amplitude information corresponding to a common first basis vector; or
The terminal feeding back a common second amplitude component for a plurality of second coefficient amplitude information corresponding to a common second basis vector.
34. The method of item 33, wherein at least one of
(Item 35)
Feeding back the CSI containing the PMI to the base station by the terminal
feeding back, by the terminal, two components of the second coefficient phase information in the PMI to the base station, the two components being a first phase component and a second phase component. prepare
The method of item 1.
(Item 36)
The second coefficient phase information is
the second coefficient phase information is the product of the two components or the sum of the two components; or
the value of the first phase component in the second coefficient phase information is determined according to the value of the second phase component;
36. The method of item 35, wherein at least one of
(Item 37)
When the value of the first phase component of the second coefficient phase information is determined according to the value of the second phase component, the second coefficient phase information is equal to the value of the first phase component. , item 36.
(Item 38)
The second phase component fed back by the terminal is
the terminal feeding back a common second phase component for a plurality of second coefficient phase information corresponding to a common first basis vector; or
The terminal feeding back a common second phase component for a plurality of second coefficient phase information corresponding to a common second basis vector.
36. The method of item 35, wherein at least one of
(Item 39)
A channel state information (CSI) receiving method, comprising:
receiving, by a base station, CSI containing precoding matrix indication information (PMI) and fed back by a terminal;
obtaining, by the base station, first basis vector information, second basis vector information, and second coefficient information from the PMI, the second coefficient information being second coefficient amplitude information; or at least one of the second coefficient phase information;
including
For one transmission layer, a frequency domain resource within one preset frequency domain unit corresponds to one precoding vector, each precoding vector being a linear combination of the first basis vectors, the first The weighting factor used in the linear combination of unity basis vectors is the first factor, which corresponds to the same first basis vector on multiple frequency domain units contained in the CSI feedback band. The method of claim 1, wherein the vector of coefficients is a linear combination of second basis vectors, and wherein the weighting factors used in the linear combination of said second basis vectors are the second coefficients.
(Item 40)
The frequency domain unit comprises at least one of a subband, a resource block (RB), or a first RB set, and the number of RBs contained in the first RB set is the number of the CSI feedback bands. 40. The method of item 39, which is less than the number of RBs contained in a subband.
(Item 41)
41. The method of item 40, wherein when the frequency domain unit is the RB, all RBs contained in the CSI feedback band are divided into at least one second set of RBs.
(Item 42)
receiving, by the base station, the CSI containing the PMI and fed back by the terminal;
Second basis vector information corresponding to each of the at least one second RB set and second coefficients corresponding to each of the at least one second RB set fed back by the terminal by the base station to receive information; or
Second coefficient information corresponding to each of the at least one second RB set fed back by the terminal by the base station and a second basis vector common to all of the at least one second RB set to receive information
42. The method of item 41, comprising
(Item 43)
Each of the at least one second set of RBs:
the RBs in each of the at least one second set of RBs being a plurality of consecutive RBs within the CSI feedback band;
the RBs in each of the at least one second set of RBs being a plurality of RBs distributed with a preset number of intervals within the CSI feedback band; or
the RBs in each of said at least one second set of RBs being a plurality of RBs distributed with a preset number of intervals over a bandwidth portion (BWP) corresponding to said CSI;
42. The method of item 41, wherein at least one of
(Item 44)
A plurality of second vector information and a plurality of first basis vector information are present, and the plurality of second basis vector information fed back by the terminal and received by the base station are respectively associated with the plurality of first base vector information. corresponding to 1 basis vector information, or
The second basis vector information indicates a set of second basis vectors, there are a plurality of first basis vectors, and the second basis vectors fed back by the terminal and received by the base station. all second basis vectors contained in the set correspond to all of the plurality of first basis vectors;
The method of any one of items 39-43.
(Item 45)
receiving, by the base station, the CSI containing the PMI and fed back by the terminal;
After the terminal quantizes the two components of the second coefficient amplitude information to be between 0 and 1, the base station contains the two quantized components and is fed back by the terminal. receiving the CSI, wherein the second coefficient amplitude information is the product of the two components, the two components comprising a first amplitude component and a second amplitude component; that or
Receiving the CSI fed back by the terminal containing two components of the second coefficient phase information by the base station, the two components being a first phase component and a second comprising two phase components;
44. The method of any one of items 39-43, comprising at least one of
(Item 46)
A channel state information (CSI) feedback device applied to a terminal, comprising:
A determination module configured to determine precoding matrix indication information (PMI), said PMI combining first basis vector information, second basis vector information and second coefficient information. wherein the second coefficient information comprises at least one of second coefficient amplitude information or second coefficient phase information;
For one transmission layer, a frequency domain resource within one preset frequency domain unit corresponds to one precoding vector, each precoding vector being a linear combination of the first basis vectors, the first The weighting factor used in the linear combination of unity basis vectors is the first factor, which corresponds to the same first basis vector on multiple frequency domain units contained in the CSI feedback band. a determining module, wherein the vector of coefficients is a linear combination of the second basis vectors, and the weighting factor used in the linear combination of the second basis vectors is the second factor;
a feedback module configured to feed back CSI containing the PMI to a base station;
A device comprising:
(Item 47)
A channel state information (CSI) receiver applied to a base station, comprising:
a receiving module configured to receive CSI that contains precoding matrix indication information (PMI) and is fed back by a terminal;
a obtaining module configured to obtain first basis vector information, second basis vector information, and second coefficient information from the PMI, wherein the second coefficient information comprises second coefficient amplitudes; information or second coefficient phase information, and for one transmission layer, frequency domain resources in one preset frequency domain unit correspond to one precoding vector, each precoding vector. The coding vector is a linear combination of the first basis vectors, and the weighting factors used in the linear combination of the first basis vectors are the first factors and a plurality of frequency domains contained in the CSI feedback band. On unity, a vector of first coefficients corresponding to the same first basis vector is a linear combination of the second basis vectors, and the weighting factors used in the linear combination of the second basis vectors are , the second coefficient, the acquisition module and
A device comprising:
(Item 48)
A terminal comprising a first processor, a first memory and a first communication bus,
the first communication bus configured to implement connection communication between the first processor and the first memory;
The first processor executes at least one program stored in the first memory to implement the channel state information (CSI) feedback method of any one of items 1-38. Configured, terminal.
(Item 49)
A base station comprising a second processor, a second memory, and a second communication bus,
the second communication bus configured to implement connection communication between the second processor and the second memory;
said second processor executing at least one program stored in said second memory to implement the channel state information (CSI) receiving method of any one of items 39-45; Configured, base station.
(Item 50)
39. A computer-readable storage medium, said computer-readable storage medium storing at least one program, said at least one program comprising the channel state information (CSI) of any one of items 1-38. A computer readable storage medium executable by at least one processor to implement at least one of the feedback method or the channel state information (CSI) reception method of any one of items 39-45.

Claims (24)

A channel state information (CSI) feedback method, comprising:
A terminal determining precoding matrix indication information (PMI), the PMI comprising first basis vector information associated with a first basis vector and second basis vector information associated with a second basis vector . and second coefficient information used to derive the first and second coefficients , the second coefficient information comprising second coefficient amplitude information and a second and coefficient phase information, wherein the CSI feedback band comprises a plurality of frequency domain units, each frequency domain unit comprising a plurality of frequency domain resources, and a frequency within each of the plurality of frequency domain units of the same transmission layer. The domain resources correspond to the same precoding vector, each precoding vector being a linear combination of said first basis vectors with a weighting factor being said first factor, and the same first basis vector define a first coefficient vector, the first coefficient vector being a linear combination of the second basis vectors with a weighting factor being the second coefficient and
and the terminal feeding back CSI containing the PMI to a base station. A frequency domain unit among the plurality of frequency domain units comprises at least one of subbands or a first RB set, and the number of RBs contained in the first RB set is equal to the CSI 2. The method of claim 1, which is less than the number of RBs contained in subbands of the feedback band. 2. The method of claim 1, wherein the second basis vectors comprise Discrete Fourier Transform (DFT) vectors. 2. The method of claim 1, wherein the dimension of each second basis vector is equal to the number of frequency domain units contained in the CSI feedback band. The second basis vector belongs to a second candidate basis vector set , the second candidate basis vector set is determined based on a parameter N, the second candidate basis vector set is {v ₁ , ..., vN } or a subset of { _v1 , ..., vN _} , where _N is the number of frequency-domain units contained in the CSI feedback band. When the second candidate basis vector set is a subset of {v ₁ , . . . , v _N }, the method for determining the second candidate basis vector set includes :
determining the second candidate base vector set based on the starting position of the second candidate base vector set and the number of vectors in the second candidate base vector set;
6. The method of claim 5 , comprising: 2. The method of claim 1, wherein the second basis vectors comprise K basis vectors selected from X consecutive basis vectors in the second candidate basis vector set, where X and K are positive integers. described method. The second coefficient amplitude information comprises two components to be quantized to be between 0 and 1 to generate two quantized components, the coefficient amplitudes used in the precoding vector being , the product of the two quantized components, the two components comprising a first amplitude component and a second amplitude component. The terminal feeding back CSI containing the PMI to the base station,
feeding back a common second amplitude component for a plurality of second coefficient amplitude information corresponding to a common first basis vector; or
9. The method of claim 8 , comprising at least one of: feeding back a common second amplitude component for a plurality of second coefficient amplitude information corresponding to a common second basis vector. A channel state information (CSI) receiving method, comprising:
a base station receiving CSI containing precoding matrix indication information (PMI) from a terminal ;
the base station obtaining from the PMI first basis vector information associated with a first basis vector, second basis vector information associated with a second basis vector , and second coefficient information; and wherein the second coefficient information is used to derive a first coefficient and a second coefficient
including
the second coefficient information comprises second coefficient amplitude information and second coefficient phase information ;
the CSI feedback band comprises a plurality of frequency domain units, each frequency domain unit comprising a plurality of frequency domain resources;
frequency-domain resources in each of the plurality of frequency-domain units of the same transmission layer correspond to the same precoding vector, each precoding vector with a weighting factor that is the first factor; is a linear combination of the basis vectors of ,
The first coefficients corresponding to the same first basis vector define a first coefficient vector, the first coefficient vector with a weighting factor that is the second coefficient. A method that is a linear combination of basis vectors. The frequency domain unit comprises at least one of a subband or a first RB set, wherein the number of RBs contained in the first RB set is the number of subbands contained in the CSI feedback band. 11. The method of claim 10 , wherein the number of RBs is less than the number of RBs. The base station receiving the CSI containing the PMI from the terminal ,
the base station receiving the CSI including two components of the second coefficient amplitude information;
quantizing the two components to be between 0 and 1 and generating the two quantized components;
including
11. The coefficient amplitude used in the precoding vector is the product of the two quantized components, the two components comprising a first amplitude component and a second amplitude component. The method described in . A channel state information (CSI) feedback device applied to a terminal, comprising:
at least one processor configured to determine precoding matrix indication information (PMI), the PMI comprising first basis vector information associated with a first basis vector and a second basis vector ; and second coefficient information used to derive the first and second coefficients , the second coefficient information comprising second coefficient amplitudes and second coefficient phase information , wherein the CSI feedback band comprises a plurality of frequency domain units, each frequency domain unit comprising a plurality of frequency domain resources, the plurality of frequency domain units of the same transmission layer. correspond to the same precoding vector, each precoding vector being a linear combination of said first basis vectors, with a weighting factor being said first factor, and the same The first coefficients corresponding to the first basis vector define a first coefficient vector, the first coefficient vector is the second basis vector with a weighting factor that is the second coefficient at least one processor that is a linear combination of
A CSI feedback apparatus , comprising: a transmitter in communication with a base station , the transmitter configured to feed back CSI containing the PMI to the base station. a base station,
a memory storing at least one program ;
at least one processor in communication with the memory;
with
The at least one processor is configured to execute the at least one program and perform steps , which include:
receiving CSI containing precoding matrix indication information (PMI) from a terminal;
obtaining from the PMI first basis vector information associated with a first basis vector, second basis vector information associated with a second basis vector, and second coefficient information; the second coefficient information is used to derive the first coefficient and the second coefficient;
including
the second coefficient information comprises second coefficient amplitude information and second coefficient phase information;
the CSI feedback band comprises a plurality of frequency domain units, each frequency domain unit comprising a plurality of frequency domain resources;
frequency-domain resources in each of the plurality of frequency-domain units of the same transmission layer correspond to the same precoding vector, each precoding vector with a weighting factor that is the first factor; is a linear combination of the basis vectors of ,
The first coefficients corresponding to the same first basis vector define a first coefficient vector, the first coefficient vector with a weighting factor that is the second coefficient. A base station, which is a linear combination of basis vectors. The s-th vector of the second basis vector candidate set is

and s is a positive integer. A frequency domain unit among the plurality of frequency domain units,
subband, or
First RB set
, wherein the number of RBs contained in the first RB set is less than the number of RBs contained within subbands of the CSI feedback band. feedback device. 14. The CSI feedback apparatus of claim 13, wherein the second basis vectors comprise Discrete Fourier Transform (DFT) vectors. 14. The CSI feedback apparatus of claim 13, wherein the dimension of each second basis vector is equal to the number of frequency domain units contained in the CSI feedback band. The second basis vectors belong to a second candidate basis vector set, the second candidate basis vector set is determined based on a parameter N, the second candidate basis vector set is {v ₁ , ..., v _N. } or {v ₁ , ..., v _N. } and N is the number of frequency-domain units contained in the CSI feedback band. The at least one processor is configured to determine the second candidate basis vector set based on a starting position of the second candidate basis vector set and a number of vectors in the second candidate basis vector set. 18. The CSI feedback apparatus of claim 17, further configured to: The s-th vector of the second basis vector candidate set is

and s is a positive integer. 14. The method of claim 13, wherein the second basis vectors are K basis vectors selected from X consecutive basis vectors in a second candidate basis vector set, where X and K are positive integers. A CSI feedback device as described. The second coefficient amplitude information comprises two components to be quantized to be between 0 and 1 to generate two quantized components, the coefficient amplitudes used in the precoding vector being , the product of the two quantized components, the two components comprising a first amplitude component and a second amplitude component. To feed back the CSI containing the PMI to the base station, the transmitter:
feeding back a common second amplitude component for a plurality of second coefficient amplitude information corresponding to a common first basis vector; or
Feeding back a common second amplitude component for a plurality of second coefficient amplitude information corresponding to a common second basis vector
22. The CSI feedback apparatus of claim 21, configured to perform at least one of the steps comprising: