JPWO2019096271A5 - - Google Patents

Description

The present invention relates to the field of communications, and in particular to methods and apparatus, storage media and processors for encoding channel state information (CSI).

In 5G NR (New Radio), channel control uses a polar code encoding method. The encoding of polar codes is denoted by x=u×G. In the formula, u represents information bits and parity check bits, x represents a bit string after encoding , and G represents a polar code generator matrix. The dimension of the generator matrix G is N×N, where N is a power of two. For polar codes, different input bit indices (bit index, 0 to N−1) have different reliability and BER (Bit Error Ratio). In order to improve the performance of a polar code, it is generally necessary to map the input bitstream of the polar code to index positions with high reliability or low BER.

In 5G NR (New Radio), some CSI (Channel State Information) reporting uses a Joint Coding mechanism. That is, information of different content (for example, CRI (CSI-RS Resource Index, CSI resource index), RI (Rank Indicator, rank indicator), PMI (Precoding Matrix Indicator, precoding matrix indicator) and CQI (Channel Quality Indicator, channel quality indicator)) together . However, since the length of the CSI information is different in different situations, the CSI information is padded to a similar length in different situations in order to reduce (avoid) blind detection. In order to determine the length of padding bits and the content of various information in different situations, or to improve the overall performance of the CSI report, the position of various information in the CSI report should be rationalized. must be arranged in In the related art, there is still no method for rationally arranging the position of various information in a CSI report.

At present, there is no effective solution to the problems of the related art described above.
SUMMARY OF THE INVENTION Embodiments of the present disclosure provide methods and apparatus, storage media and processors for encoding channel state information (CSI), at least to rationally arrange the location of various types of information in CSI reports. To solve the problem of the related technology that it is not possible to

One embodiment of the present disclosure provides a method for encoding CSI. The method includes arranging the CSI and the fourth type of information bits according to the indices in the position index set, the CSI comprising the first type of information bits, the second type of information bits and the third type of information bits. and the method of arrangement is to place the first type of information bit at the first type of position index in the position index set, and the first type of position index determined by the first type of information bit Determine the indices in the position index set of the second type information bit, the third type information bit and the fourth type information bit from the indices in the position index set excluding the placing the information bits at a fourth type of position index within the position index set, and from the indices within the position index set excluding the fourth type of position index determined by the fourth type of information bit, the first type of information bit , determining the indices in the position index set of the second type information bit and the third type information bit, and performing polar coding coding on the arranged CSI and the fourth type information bit, encoding Including getting the later bitstream.

Another embodiment of the present disclosure provides an apparatus for encoding CSI. The apparatus includes an arrangement module configured to arrange the CSI and the fourth type of information bits according to the indices in the position index set, the CSI being the first type of information bits, the second type of information bits and a third kind of information bits, wherein the method of arrangement is to place the first kind of information bits at the first kind of position indices in the position index set, and the first kind of information bits determined by the first kind of information bits determining the indices in the position index set of the second type of information bit, the third type of information bit and the fourth type of information bit from the indices in the position index set excluding the position index of placing the four types of information bits in a fourth type of position index in the position index set, and from the indices in the position index set excluding the fourth type of position index determined by the fourth type of information bit, the first type by determining the indices in the positional index set of the information bits of the second type and the third type of information bits, and performing polar code encoding on the arranged CSI and the fourth type of information bits , including an encoding module configured to obtain an encoded bitstream.

Another embodiment of the disclosure further provides a storage medium. The storage medium includes a stored program which, when executed, performs the method for encoding CSI described above.

Yet another embodiment of the disclosure further provides a processor. The processor is configured to execute the program. This program, when executed, performs the method for encoding CSI described above.

Yet another embodiment of the present disclosure further provides a communication device. This communication device comprises a memory configured to store CSI and a fourth type of information bit, and a coded bit string by performing polar coding on the CSI and the fourth type of information bit. a polar code encoder configured to obtain a CSI comprising a first type of information bits, a second type of information bits and a third type of information bits, the CSI and a fourth type of information The bits are arranged as follows: the first kind of information bits, the second kind of information bits, the third kind of information bits and the fourth kind of information bits, in the order of the values of the position indices of the polar code Or arranged in order according to the order of reliability of the position index.

Yet another embodiment of the present disclosure further provides a communication device. This communication device includes a polar code encoder configured to obtain an encoded bit string by performing polar code encoding on CSI and the fourth type of information bits, and a polar code encoder configured to decode the polar code. a polar code decoder configured to perform polar code encoding on the CSI and the fourth type of information bits to obtain an encoded bitstream; The CSI comprises a first type of information bit, a second type of information bit and a third type of information bit, and the CSI and the fourth type of information bit are arranged as follows: The kind of information bit, the second kind of information bit, the third kind of information bit and the fourth kind of information bit are arranged in order according to the order of the value of the position index of the polar code or the order of the reliability of the position index. .

According to the present disclosure, a first type of information bit in the CSI is placed at a first type of position index in a position index set, and a position index other than the first type of position index determined by the first type of information bit is From the indices in the set, determine the indices in the positional index set of the second type of information bit, the third type of information bit and the fourth type of information bit, or the fourth type of information bit in the positional index set. , and from the indices in the position index set excluding the fourth type position index determined by the fourth type information bit, the first type information bit contained in the CSI, the Determine the indices in the position index set for the two types of information bits and the third type of information bits. Therefore, the above method improves the BLER performance of the CSI report by determining the index of each class of information bits jointly encoded in the CSI report, and reasonably locates each class of information in the CSI report. To solve the problem of related technology that arrangement is impossible.

The drawings of the present disclosure are used to provide a further understanding of the present disclosure and form part of the present application. The exemplary embodiments of the present disclosure and their descriptions are used to explain the present disclosure and not to unduly limit the present disclosure.

2 is a block diagram showing the hardware configuration of an apparatus that performs a method for encoding channel state information (CSI) according to one embodiment of the present disclosure; FIG. 4 is a flowchart illustrating CSI encoding , in accordance with one embodiment of the present disclosure; FIG. 4 is a schematic diagram illustrating a relationship simulation between index and BER, in accordance with an embodiment of the present disclosure; FIG. 2 is a schematic diagram illustrating performance simulation, in accordance with one embodiment of the present disclosure; 1 is a block diagram showing the configuration of an apparatus for encoding CSI according to one embodiment of the present disclosure; FIG. 2 is a block diagram showing the structure of a communication device according to one embodiment of the present disclosure; FIG. FIG. 4 is a block diagram illustrating the structure of another communication device, according to an embodiment of the present disclosure;

Description of Embodiments Hereinafter, the present disclosure will be described in detail using embodiments together with reference to the drawings. It should be noted that all embodiments and features described in embodiments in this application can be combined with each other unless they are inconsistent.

It should be noted that terms such as "first" and "second" used in the specification, claims, and accompanying drawings of the present disclosure are used to distinguish similar objects, and a particular order or order is used. It does not represent

Embodiment 1
The method provided by Embodiment 1 of the present disclosure can be implemented in a device, computer terminal or similar computing device. As an example of an apparatus implementation, FIG. 1 is a block diagram illustrating the hardware configuration of an apparatus that implements a method for encoding channel state information (CSI) according to one embodiment of the present disclosure. As shown in FIG. 1, device 10 includes one or more (only one shown) processors 102 (processors 102 may include processing devices such as microprocessor MCUs or field programmable gate array FPGAs). ), a memory 104 for storing data, and a transmission device 106 for communicating. As can be appreciated by those skilled in the art, the structure shown in FIG. 1 is exemplary only and does not limit the structure of the electronic device described above. For example, device 10 may include more or fewer components than those shown in FIG. 1, and may include different configurations than those shown in FIG.

The memory 104 is configured to store application software programs and modules, eg, program instructions/modules corresponding to the method for encoding CSI of the present disclosure. Processor 102 executes the software programs and modules stored in memory 104 to perform the various functional applications and data processing, thus implementing the methods described above. Memory 104 may include high speed random access memory and may include non-volatile memory such as one or more magnetic storage devices, flash memory, or other non-volatile solid state memory. In some examples, memory 104 can further include memory remotely located relative to processor 102 . These remote memories can be connected to device 10 via a network. Examples of the networks mentioned above include, but are not limited to, the Internet, internal corporate networks, local area networks, mobile communication networks and combinations thereof.

Transmission device 106 is configured to receive or transmit data over a network. Examples of the networks described above may include wireless networks provided by the communication provider of device 10 . In one example, the transmission device 106 includes a network interface controller (NIC) that can be connected to other network devices via base stations to communicate with the Internet. In one example, transmission device 106 may be a radio frequency (RF) module configured to wirelessly communicate with the Internet.

This embodiment provides a method for encoding CSI that runs on the apparatus described above. FIG. 2 shows a flowchart for encoding CSI, according to one embodiment of the present disclosure. As shown in FIG. 2, this flow includes the following steps, specifically:
including a step S202 of arranging the CSI and the fourth type of information bits according to the indices in the position index set, the CSI being the first type of information bits, the second type of information bits and the third type of information bits; and the method of ordering includes placing the first type of information bit at the first type of position index in the position index set, except for the first type of position index determined by the first type of information bit. From the indices in the index set, determine the indices in the positional index set of the second type information bit, the third type information bit and the fourth type information bit, or the method of arranging the fourth type information bit The first type of information bits, the second determining the indices in the set of position indices for the type of information bits and the third type of information bits;
A step S204 of obtaining an encoded bit string by performing polar encoding on the arranged CSI and the fourth type of information bits.

Through the steps S202 and S204 described above, each type of information bit in the CSI can be arranged in the position index set, specifically, the first type of information bit in the CSI can be arranged in the first type in the position index set. From the indices in the position index set excluding the position index of the first type determined by the information bit of the first type, the information bit of the second type, the information bit of the third type and the information bit of the fourth type. The index in the position index set of the information bits may be determined, or the fourth type of information bit may be placed at the fourth type of position index in the position index set and the fourth type of information bit determined by the fourth type of information bit may be determined. From the indices in the position index set excluding the four types of position indices, the indices in the position index set for the first type information bits, the second type information bits and the third type information bits can be determined.

In the case of polar codes, different input bit indices (bit indices, 0 to N−1) have different reliability and BER (Bit Error Ratio). In order to improve the performance of a polar code, it is generally necessary to map the input bitstream of the polar code to index positions with high reliability or low BER. Encoding CSI is mapping the CSI and the parity-check bits obtained by encoding the CSI to index positions with high reliability or low BER. In this case the confidence can be calculated by density evolution or Gaussian approximation, or obtained from the position of the index in a predefined sequence. BER can be obtained by computer simulation. Specifically, FIG. 3(a) shows the simulation relationship between index and BER.

Since the length of the CSI information is different in different situations, the CSI information is padded to a similar length in different situations in order to reduce (avoid) blind detection. However, in CSI reports, the length of PMI and CQI is related to RI, so placing RI (and CRI) (CRI and RI are co- encoded in LTE) at a specific position will determine RI first can be used to determine the length and other information content of the padding bits. On the other hand, since the length of the parity check bits is related to the length of the CSI, after placing the parity check information in a specific position in the CSI report, and then placing the RI in another specific position, the polar code can be decoded. Afterwards, the RI can be easily determined, which allows the length of the padding bits and other information content to be determined. Furthermore, after determining the length and position of the padding bits, the padding bits can be used as known bits (or frozen bits) in the decoding process to improve decoding performance. FIG. 3(b) is a performance curve associated with different frozen bits.

Therefore, the above-described method can use joint coding to determine the index of various information bits in the CSI report, improve the BLER performance of the CSI report, and thereby reasonably locate the various information bits in the CSI report. It is possible to solve the problem of the related technology that it cannot be arranged in

In a specific implementation of this embodiment, the first type of information bits according to this embodiment includes at least one of CRI and RI.

Further, the first type of information bits according to the present embodiment are a bit string obtained by encoding the CRI according to the first encoding method, and a bit string obtained by encoding the RI according to the first encoding method. and at least one of a bitstream and a bitstream obtained by encoding the CRI and RI according to the first encoding method.

In CSI information, CRI may affect the number of bits of RI, RI may affect the number of bits of PMI, and RI and PMI may affect the number of bits of CQI. Therefore, before encoding the CSI, first encode the CRI and RI (i.e., the first type of bit information) using the first encoding method, and then encode the encoded bit string and other CRI and RI performance can be improved by performing polar code encoding on the information of .

For example, if CRI and RI are each 3 bits, the length of the first type information bits is 6 bits. Using the first encoding method, the 6-bit first type information bits are encoded into 7 bits, 9 bits or 12 bits.

For example, using the first encoding method, the K-bit first type information bits are encoded into a length of floor(K/R) or ceil(K/R) bits. R represents the coding rate and 0<R<1, floor(.) represents the operator that rounds down to the nearest integer, and ceil(.) represents the operator that rounds up to the nearest integer. represents

The first encoding method is Reed-Muller encoding , parity check codes, cyclic redundancy check encoding , BCH encoding , Hamming code encoding . Hamming code encoding, convolutional encoding , generator matrix encoding , Turbo encoding , low density parity check encoding , or hash encoding (Hash encoding).

In a preferred embodiment of this embodiment, the second type of information bits according to this embodiment are padding bits. The third type of information bits includes at least one of precoding matrix indicator (PMI) and channel quality indicator (CQI). A fourth type of information bit is a parity check bit.

Based on the specific information bits of CSI in the preferred embodiment described above, the fourth type of information bits according to the present embodiment are the first type of information bits , the second type of information bits and Obtained by encoding at least one information bit of the third type of information bit.

The first encoding method or the second encoding method includes Reed-Muller encoding , parity check encoding, cyclic redundancy check encoding , BCH encoding , Hamming code encoding , convolutional encoding , generator matrix encoding , and turbo encoding . , low-density parity-check encoding , and hash encoding .

The arrangement method of step S202 described above in the present embodiment is the first type information bit, the second type information bit, the third type information bit according to the order of the value of the position index of the polar code or the order of the reliability of the index. The information bits and the fourth type of information bits are arranged in order.

In the arrangement method of step S202 described above in this embodiment, if the index of the information bit of the first type is determined first, the position index of the first type according to this embodiment is the lowest index number and the first type is an index with the same number of information bits as in .

It should be noted that, based on the computer simulation results of FIG. 3( a ), since the bits with lower numbered position indices have lower BER, the first type of bit information (CRI and RI) should be placed in the lowest numbered index. can improve the performance of CSI reporting.

Based on the above-described first type of position index, the second type of information bit from the index excluding the first type of position index determined by the first type of information bit from the position index set in step S202 of the present embodiment, Determining the indices in the position index set of the third type information bit and the fourth type information bit specifically includes the following steps:
Step S202-1: Determining the index having the same number of the fourth type information bits and the largest index number among the indices in the position index set as the index of the fourth type information bit;
Step S202-2: From the undetermined index in the position index set, according to the array of values of the position index and the number of each of the second type information bit and the third type information bit, the second type information bit or sequentially determining the index of the third type of information bit and the index of the second type of information bit from the undetermined index of the position index set; or, depending on the order of reliability of the position indices and the number of each of the second type information bits and the third type information bits, from the undetermined indices in the position index set, the indices of the second type information bits and sequentially determining the index of the third type of information bit, or sequentially determining the index of the third type of information bit and the index of the second type of information bit from the undetermined indices in the position index set.

Based on the above-described first type of position index, the second type of information bit from the index excluding the first type of position index determined by the first type of information bit from the position index set in step S202 of the present embodiment, Determining the indices in the position index set of the third type information bit and the fourth type information bit specifically includes the following steps:
Step S202-3: Among indices in the position index set excluding the first type of position index determined by the first type of information bit, the index having the same number as the second type of information bit and having the lowest reliability is selected. determining as indices of information bits of the second type; and
Step S202-4: From the undetermined index in the position index set, according to the array of values of the position index and the number of each of the third type information bit and the fourth type information bit, the third type information bit and the fourth type of information bits in order, or determining the fourth type of information bits and the third type of information bits from the undetermined indices in the position index set, or the order of reliability of the position indices. and according to the number of each of the third type of information bits and the fourth type of information bits, from the undetermined indices in the position index set, the indices of the third type of information bits and the indices of the fourth type of information bits. Determining in order or determining indices of the fourth type information bit and the third type information bit in order from the undetermined indices in the position index set.

In another preferred implementation of this embodiment, when the index of the information bit of the first type is determined first, the position index of the first type is the most reliable and the first of the indices in the position index set. It is an index that has the same number of one type of information bits.

In addition, due to the attributes of the polar code itself, the position index with high reliability has a small BER. can be improved.

Based on the above-described first type of position index, the second type of information bit from the index excluding the first type of position index determined by the first type of information bit from the position index set in step S202 of the present embodiment, Determining the indices in the position index set of the third type information bit and the fourth type information bit specifically includes the following steps:
Step S202-5: Among the indices of the position index set excluding the first type of position index determined by the first type of information bits, the index having the same number and the largest index number as the fourth type of information bits is selected as the first index. determining as an index of four types of information bits; and
Step S202-6: From the undetermined index in the position index set, according to the array of values of the position index and the number of each of the second type information bit and the third type information bit, the second type information bit or sequentially determining the index of the third type of information bit and the index of the second type of information bit from the undetermined index of the position index set; or,
Step S202-7: According to the order of reliability of the position indices and the number of each of the second type information bits and the third type information bits, from the undetermined indices in the position index set, the second type information bits or sequentially determining the index of the third type information bit and the index of the second type information bit from the undetermined indices in the position index set. including.

Based on the above-described first type of position index, the second type of information bit from the index excluding the first type of position index determined by the first type of information bit from the position index set in step S202 of the present embodiment, Determining the indices in the position index set of the third type information bit and the fourth type information bit specifically includes the following steps:
Step S202-8: Among indices in the position index set excluding the first type of position index determined by the first type of information bit, the index having the same number as the second type of information bit and the lowest reliability is selected. determining as indices of information bits of the second type; and
Step S202-9: From the undetermined index in the position index set, according to the array of values of the position index and the number of each of the third type information bit and the fourth type information bit, the third type information bit sequentially determining the index of the and the index of the information bit of the fourth type, or determining the index of the information bit of the fourth type and the index of the information bit of the third type from the undetermined indices in the position index set; or, depending on the order of reliability of the position indices and the number of each of the third type information bits and the fourth type information bits, from the undetermined indices in the position index set, the indices of the third type of information bits and sequentially determining the index of the fourth type of information bit, or sequentially determining the index of the fourth type of information bit and the index of the third type of information bit from the undetermined indices in the position index set.

In another preferred implementation of this embodiment, when the index of the information bit of the fourth type is determined first, the positional index of the fourth type is the highest index number and the highest index number among the indices in the positional index set. It is an index that has the same number of four types of information bits.

Based on the above-described fourth type of position index, the first type of information bit from the index excluding the fourth type of position index determined by the fourth type of information bit from the position index set in step S202 of the present embodiment, Determining the indices in the position index set of the second type information bit and the third type information bit specifically includes the following steps:
Step S202-10: Among indices in the position index set excluding the fourth type of position index determined by the fourth type of information bit, the index having the same number as the first type of information bit and having the largest index number is selected. determining as an index of the first type of information bits; and
Step S202-11: From the undetermined index in the position index set, according to the array of values of the position index and the number of each of the second type information bit and the third type information bit, the second type information bit or sequentially determining the index of the third type of information bit and the index of the second type of information bit from the undetermined index of the position index set; or, depending on the order of reliability of the position indices and the number of each of the second type information bits and the third type information bits, from the undetermined indices in the position index set, the indices of the second type information bits and sequentially determining the index of the third type of information bit, or sequentially determining the index of the third type of information bit and the index of the second type of information bit from the undetermined indices in the position index set.

Based on the above-described fourth type of position index, the first type of information bit from the index excluding the fourth type of position index determined by the fourth type of information bit from the position index set in step S202 of the present embodiment, Determining the indices in the position index set of the second type information bit and the third type information bit specifically includes the following steps:
Step S202-12: Selecting an index having the same number as the first type information bits and having the highest reliability among the indices in the position index set excluding the fourth type position index determined by the fourth type information bits; determining as an index of the first type of information bits; and
Step S202-13: From the undetermined index in the position index set, according to the array of values of the position index and the number of each of the second type of information bits and the third type of information bits, the second type of information sequentially determine the index of the bit and the index of the third type of information bit, or sequentially determine the index of the third type of information bit and the index of the second type of information bit from the undetermined indices in the position index set; or, depending on the order of reliability of the position indices and the number of each of the second type information bits and the third type information bits, from the undetermined indices in the position index set, the number of the second type information bits sequentially determining the index and the index of the third type of information bit, or sequentially determining the index of the third type of information bit and the index of the second type of information bit from the undefined indices in the position index set; include.

As for the positional relationship between the CRI and the RI in the first type of information bits, the position of the CRI is before the position of the RI, the position of the RI is before the position of the CRI, or the position of the RI is before the position of the CRI. The position of the bit string obtained by encoding the CRI according to the encoding method is before the position of the bit string obtained by encoding the RI according to the first encoding method, or the first encoding method The position of the bit string obtained by encoding the CRI according to follows the position of the bit string obtained by encoding the RI according to the first encoding method.

Since the value of CRI may affect the number of bits of RI, for example, if the number of ports of CSI-RS corresponding to the value of CRI is 2, the number of bits of RI may be 1. . Therefore, the position of the CRI can be placed before the position of the RI, or the bitstream obtained by encoding the CRI according to the first encoding method can be encoded with the RI according to the first encoding method. It can be placed before the position of the resulting bit string.

Also, regarding the positional relationship between the PMI and the CQI in the third type of information bits, the position of the PMI is before the position of the CQI, or the position of the CQI is before the position of the PMI.

Since the value of PMI can affect the number of bits in CQI, the position of PMI can be placed before the position of CQI.

If the CSI report does not include the first type of information bit, the second type of information bit, the third type of information bit, or the fourth type of information bit, when determining each type of information bit, the type , and continue with subsequent steps.

Hereinafter, the present disclosure will be described by taking specific examples of the present embodiment as illustrations.
In the CCSI report, since the length of PMI and CQI is related to RI, placing RI (and CRI) (CRI and RI are co- coded in LTE) in a certain position, first determine RI , which allows the length and other information content of the padding bits to be determined.

On the other hand, since the length of the fourth type of information bits, namely the parity check bit, is related to the length of the CSI, after the parity check information is placed in a specific position in the CSI report, the RI is placed in another specific position. Then, after decoding the polar code, the RI can be easily determined, thereby determining the length of the padding bits and other information content.

Therefore, assume that the lengths of each of CRI, RI, PMI, CQI, parity check bits and padding bits are L_CRI, L_RI, L_PMI, L_CQI, L_A and L_Pad.

FIG. 3(a) is a schematic diagram illustrating a simulation of the relationship between index and BER, according to one embodiment of the present disclosure.

Preferred embodiment 1
As shown in FIG. 3(a), since the BER corresponding to the position with the small index number is small, in this embodiment, the CSI is arranged in the position index set as follows. i.e.
(1) arranging the first type of information bits in (L_CRI+L_RI) indices with the smallest numbers among the position indices;
(2) locating the fourth type of information bits in L_A indices with the largest number among the position indices;
(3.1) Arrange the second type information bits and the third type information bits in the remaining positions in order according to the index values (from small to large or from large to small).

In this case, the arrangement order of various information in the CSI report is as follows.

or,

According to the above-described embodiment, the first type of information bits can be decoded the earliest during polar code decoding, thereby determining the length and position of the second type of information bits and the third type of information bits. can be estimated. Also, the second type of information bits, padding bits, can be used as known bits (or frozen bits) to improve decoding performance. Details can be found in FIG. 3(b) and reference [1] (3GPP, RAN1#91 meeting, R1-1719520).

Specifically, if joint encoding is utilized for CSI reporting, the CRI bit length L_CRI=3, the RI bit length L_RI=3, and the information bits of the CSI (including CRI, RI, PMI and CQI) The length is a minimum of 14 and a maximum of 23, padding all jointly encoded CSI bits to 24 bits, the parity check bit length is 11, and the position index set is 1 to 35.

(1) CRI and RI are placed in the lowest numbered (L_CRI+L_RI) indices among the position indices, that is, CRI and RI are placed in indices numbered 1 to 6 in the position indices;
(2) placing the parity check bits in the L_A indices with the largest number among the position indices, that is, placing the parity check bits in the indices with numbers 25 to 35 in the position indices;
(3.1) placing the padding bits, PMI and CQI in the remaining positions in order according to the value of the index (from small to large or from large to small); or
(3.2) Place the second type information bits and the third type information bits in the remaining positions in order according to the index reliability (from small to large or from large to small).

Preferred embodiment 2
As shown in FIG. 3(a), since the BER corresponding to the position with the small index number is small, in this embodiment, the CSI is arranged in the position index set as follows. i.e.
(1) arranging the first type of information bits in (L_CRI+L_RI) indices with the smallest numbers among the position indices;
(2) placing the second type of information bits in L_Pad indexes having the lowest reliability among the position indexes;
(3.1) placing the third type of information bits and the fourth type of information bits in order in the remaining positions according to the value of the index (from small to large or from large to small); or
(3.2) Arrange the third type information bits and the fourth type information bits in the remaining positions in order according to the index reliability (from small to large or from large to small).

Preferred embodiment 3
As shown in FIG. 3(a), the BER corresponding to the index with high reliability is small, so in this embodiment, the CSI is arranged in the location index set as follows. i.e.
The first type information bits are arranged in (L_CRI+L_RI) indexes having the highest reliability among the position indexes.

Specifically, if joint encoding is utilized for CSI reporting, the CRI bit length L_CRI=3, the RI bit length L_RI=3, and the information bits of the CSI (including CRI, RI, PMI and CQI) The length is a minimum of 14 and a maximum of 23, padding all jointly encoded CSI bits to 23 or 24 bits, the parity check bit length is 11, and the position index set is Table 1 shows the index positions of the first type information bits (ie, CRI and RI) calculated at different coding rates using a computer, if 1-34 or 1-35.
Table 1 Positions of information bits of the first kind at different coding rates

(2) placing the fourth type of information bits in L_A indices with the largest numbers among the remaining position indices;
(3.1) placing the third type of information bits and the fourth type of information bits in order in the remaining positions according to the value of the index (from small to large or from large to small); or
(3.2) Arrange the third type information bits and the fourth type information bits in the remaining positions in order according to the index reliability (from small to large or from large to small).

Preferred embodiment 4
As shown in FIG. 3(a), since the BER corresponding to the index with high reliability is small, in this embodiment, the CSI is arranged in the position index set as follows. i.e.
(1) placing the first type of information bits in (L_CRI+L_RI) indexes with the highest reliability among the position indexes;
(2) placing the second type of information bits in L_Pad indices with the lowest reliability among the remaining position indices;
(3.1) placing the third type of information bits and the fourth type of information bits in order in the remaining positions according to the value of the index (from small to large or from large to small); or
(3.2) Arrange the third type information bits and the fourth type information bits in the remaining positions in order according to the index reliability (from small to large or from large to small).

Preferred embodiment 5
Since the length of the parity check bits is related to the length of the CSI, if the parity check information is placed in a specific position in the CSI report and then the RI is placed in another specific position, after decoding the polar code, RI can be easily determined, which allows the length of padding bits and other information content to be determined. Therefore, in this embodiment, we arrange the CSI into the location index set as follows. i.e.
(1) locating the fourth type of information bits in L_A indices with the largest number among the position indices;
(2) placing the first type of information bits in (L_CRI+L_RI) indices with the highest reliability among the remaining position indices;
(3.1) placing the second type information bits and the third type information bits in order in the remaining positions according to the value of the index (from small to large or from large to small); or
(3.2) Arrange the second type information bits and the third type information bits in the remaining positions in order according to the index reliability (from small to large or from large to small).

Preferred embodiment 6
Since the length of the parity check bits is related to the length of the CSI, if the parity check information is placed in a specific position in the CSI report and then the RI is placed in another specific position, after decoding the polar code, RI can be easily determined, which allows the length of padding bits and other information content to be determined. Therefore, in this embodiment, we arrange the CSI into the location index set as follows. i.e.
(1) locating the fourth type of information bits in L_A indices with the largest number among the position indices;
(2) arranging the first type of information bits in (L_CRI+L_RI) indices with the largest numbers among the remaining position indices;
(3.1) placing the second type information bits and the third type information bits in order in the remaining positions according to the value of the index (from small to large or from large to small); or
(3.2) Arrange the second type information bits and the third type information bits in the remaining positions in order according to the index reliability (from small to large or from large to small).

In the preferred embodiments 1-6 described above, the first type of information bits may be CRI and/or RI, or bits after encoding the CRI and/or RI information. The encoding method can be Reed-Muller encoding , parity check encoding, cyclic redundancy check encoding , BCH encoding , Hamming code encoding , convolutional encoding , generator matrix encoding , turbo encoding , low density parity check encoding , or hashing. It may be encoding .

After decoding the polar code, the receiver obtains the length and position of the padding bits based on the contents of the CRI and RI, and uses the CRI, RI and padding bits as known bits to decode the polar code again. This can improve the performance of the remaining information. Specifically, the performance curve is shown in FIG. 3(b).

With the above description of the embodiments, those skilled in the art can implement the methods described in the above embodiments using software and the necessary general-purpose hardware platforms. Of course, hardware can be used to implement the methods described in the above examples, although the former is often preferred. Based on such understanding, the essential part of the technical solution of the present disclosure or the part contributing to the prior art can be embodied in the form of a software product, and the computer software product comprises a storage medium (e.g. , ROM/RAM, magnetic disk, optical disk) and includes a plurality of instructions that cause a terminal device (e.g., mobile phone, computer, server, or network device) to perform the method described in each embodiment of the present disclosure. .

Embodiment 2
The embodiment further provides an apparatus for encoding CSI. This apparatus is used to implement the above-described embodiments and preferred embodiments. These embodiments and preferred examples have already been described above and will not be described further. As used below, the term "module" is a combination of software and/or hardware that implements a given function. The devices described in the following embodiments are preferably implemented in software, but may also be implemented in hardware or a combination of software and hardware.

FIG. 4 is a block diagram illustrating the structure of an apparatus for encoding CSI, according to one embodiment of the present disclosure. As shown in Figure 4, the device
An arrangement module 42 configured to arrange the CSI and the fourth type of information bits according to an index within the positional index set, the CSI comprising the first type of information bits, the second type of information bits and the third type of information bits. a first type of information bit, the method of arranging the first type of information bit at a first type of position index in the position index set, and the first type of position index determined by the first type of information bit Determine the indices in the position index set of the second type information bit, the third type information bit and the fourth type information bit from the indices in the position index set excluding the placing the information bits at a fourth type of position index within the position index set, and from the indices within the position index set excluding the fourth type of position index determined by the fourth type of information bit, the first type of information bit , determining the indices in the positional index sets of the second type of information bits and the third type of information bits;
An encoding module 44 configured to obtain an encoded bitstream by performing polar code encoding on the arranged CSI and the fourth type of information bits.

Each module described above can be realized by software or hardware. In the latter case, it can be realized by the following method, but is not limited to this. Any of the modules described above may be located within the same processor, or may be located in different processors in any combination.

Embodiments of the present disclosure further provide a storage medium storing the program. This program, when executed, performs any of the methods described above.

Preferably, in this embodiment, the storage medium described above may be configured to store program code for performing the following steps.

S1: arranging the CSI according to the index in the position index set;
In this case, the arrangement method places the first type of information bits contained in the CSI at the first type of position index in the position index set, and the first type of position determined by the first type of information bit. Determine the index in the position index set of the second type information bit, the third type information bit and the fourth type information bit from the index in the position index set excluding the index, or the arrangement method is the fourth type at a position index of the fourth type in the position index set, and from the indices in the position index set excluding the position index of the fourth type determined by the information bit of the fourth type, the information of the first type Determine the indices in the positional index set of the bit, the second type of information bit and the third type of information bit.

S2: Obtaining an encoded bit string by performing polar encoding on the arranged CSI and the information bits of the fourth kind.

Preferably, in the present embodiment, the storage medium mentioned above includes media capable of storing program code, such as USB, ROM (read only memory), RAM (random access memory), portable hard disk, magnetic disk or optical disk. is not limited to

Embodiments of the disclosure further provide a processor for executing the program. This program, when executed, performs any of the methods described above.

Preferably, in this embodiment, the above program is configured to perform the following steps.

S1: arranging the CSI according to the index in the position index set;
In this case, the arrangement method places the first type of information bits contained in the CSI at the first type of position index in the position index set, and the first type of position determined by the first type of information bit. Determine the index in the position index set of the second type information bit, the third type information bit and the fourth type information bit from the index in the position index set excluding the index, or the arrangement method is the fourth type at a position index of the fourth type in the position index set, and from the indices in the position index set excluding the position index of the fourth type determined by the information bit of the fourth type, the information of the first type Determine the indices in the positional index set of the bit, the second type of information bit and the third type of information bit.

S2: Obtaining an encoded bit string by performing polar encoding on the arranged CSI and the information bits of the fourth kind.

For specific examples of the present embodiment, the examples described in the above-described embodiments and preferred examples can be referred to, and descriptions thereof will be omitted in the present embodiment.

Preferably, embodiments of the present disclosure further provide a communication device. This communication device comprises a memory configured to store CSI and a fourth type of information bit, and a coded bit string by performing polar coding on the CSI and the fourth type of information bit. a polar code encoder configured to obtain

The CSI includes first type information bits, second type information bits, and third type information bits. The CSI and the fourth kind of information bits are arranged as follows: the first kind of information bits, the second kind of information bits, the third kind of information bits and the fourth kind of information bits are polar code are arranged in order according to the order of position index values or the order of position index reliability.

Specifically, as shown in FIG. 5, communication device 200 includes encoder 206, decoder 212, and transceiver 214. Transceiver 214 transmits codetext after polar code encoding via a communication channel. Send and/or receive. Encoder 206 includes memory 202 and polar code encoder 204 . Memory 202 is configured to store data (CSI and fourth type information bits) encoded by polar code encoder 204 . The polar code encoder 204 is configured to perform polar coding on the CSI and the fourth type information bits stored in the memory 202 to obtain an encoded bit stream for transmission to another device. It is

For specific examples of this embodiment, the examples described in the above embodiments and preferred examples can be referred to, and the description thereof will be omitted in this embodiment.

Preferably, embodiments of the present disclosure further provide a communication device. This communication device includes a polar code encoder configured to obtain an encoded bit string by performing polar code encoding on CSI and the fourth type of information bits, and a polar code encoder configured to decode the polar code. and a configured polar code decoder.

The CSI includes first type information bits, second type information bits, and third type information bits. The CSI and the fourth kind of information bits are arranged as follows: the first kind of information bits, the second kind of information bits, the third kind of information bits and the fourth kind of information bits are polar code are arranged in order according to the order of position index values or the order of position index reliability.

Specifically, as shown in FIG. 6, communication device 314 includes transceiver 302 , processor 304 , and memory 306 . Transceiver 302 can receive data from communication device 314 and can transmit data to communication device 314 . For example, transceiver 302 can receive and/or transmit information bits between communication device 314 and a CPU. Transceiver (encoder interface) 302 may also output and/or receive polar code text between communication device 314 and another communication device in the network. Memory 306 may include data storage 308 that acts as a local cache for storing received information bits and/or codewords . The memory 306 also includes a polar code encoding module 310 configured to perform encoding according to a polar code encoding method, and a non-transitory computer readable storage medium (e.g., EPROM, eepm, flash memory, hard disk, etc.). ), the non-transitory computer-readable storage medium storing a polar code decoding module 312 configured to decode the codetext of the polar code be able to.

For specific examples of this embodiment, the examples described in the above embodiments and preferred examples can be referred to, and the description thereof will be omitted in this embodiment.

Of course, one of ordinary skill in the art can implement each module or each step of the disclosure described above on a general-purpose computing device. These modules and steps may be integrated on a single computing device or distributed over a network of multiple computing devices. These modules and steps can be implemented in executable program code on a computing device. These modules and steps can be stored in a memory device and executed by a computing device when desired. In some cases, these modules and steps can be performed in a different order than the steps shown or described. Alternatively, these modules and steps may be manufactured as individual integrated circuit modules, or multiple modules and steps may be manufactured as a single integrated circuit module. Thus, the present disclosure is not limited to any specific hardware and software combination.

The above descriptions are merely preferred embodiments of the present disclosure and are not intended to limit the present disclosure. A person skilled in the art can make various changes and modifications to this disclosure. Any modification, equivalent replacement or improvement made within the principles of the present disclosure shall fall within the protection scope of the present disclosure.

INDUSTRIAL APPLICABILITY The present disclosure can improve the BLER performance of the CSI report by applying it to the communication field, and solves the problem of the related technology that the position of various information in the CSI report cannot be arranged rationally. solve.

Claims (7)

A method for encoding channel state information CSI, comprising:
mapping the CSI and parity check bits according to an index within a position index set;
The CSI includes a first type of information bit, a second type of information bit, and a third type of information bit,
The first type of information bits includes CSI-RS resource indicator CRI and rank indicator RI, the second type of information bits are padding bits, and the third type of information bits are precoding matrix indicator PMI. and at least one of a channel quality indicator CQI;
As a positional relationship between the CRI and the RI of the first type of information bits, the position of the CRI is before the position of the RI,
As a positional relationship between the PMI and the CQI of the third type of information bits, the position of the PMI is before the position of the CQI,
The mapping includes mapping the first type information bit, the second type information bit, the third type information bit and the parity check bit to the position index according to the order of the position index from the smallest value to the largest value. including placing in a set,
obtaining an encoded bitstream by performing polar code encoding on the mapped CSI and the parity check bits . an index of the first type of information bit is first determined;
2. The method of claim 1, wherein the first type of positional index is an index having the smallest index number and the same number of information bits of the first type among indices in the positional index set. of the second type of information bits, the third type of information bits and the parity check bits from indices in the position index set excluding the first type of position index determined by the first type of information bits; Determining an index in the position index set includes:
determining an index in the position index set that has the same number of parity-check bits and the largest index number as the index of the parity-check bits ;
indices of the second type of information bits from undetermined indices in the position index set according to the array of values of the position indices and the number of each of the second type of information bits and the third type of information bits; and sequentially determining the indices of the information bits of the third type. An apparatus for encoding channel state information CSI, comprising:
a mapping module configured to map the CSI and parity check bits according to an index in a position index set;
the CSI includes a first type of information bit, a second type of information bit and a third type of information bit;
The first type of information bits includes CSI-RS resource indicator CRI and rank indicator RI, the second type of information bits are padding bits, and the third type of information bits are precoding matrix indicator PMI. and at least one of a channel quality indicator CQI;
As a positional relationship between the CRI and the RI of the first type of information bits, the position of the CRI is before the position of the RI,
As a positional relationship between the PMI and the CQI of the third type of information bits, the position of the PMI is before the position of the CQI,
The mapping includes mapping the first type information bit, the second type information bit, the third type information bit and the parity check bit to the position index according to the order of the position index from the smallest value to the largest value. including placing in a set,
An apparatus comprising an encoding module configured to obtain an encoded bitstream by performing polar code encoding on the mapped CSI and parity check bits . the mapping module is configured to first determine an index of the first type of information bits;
5. The apparatus of claim 4 , wherein the first type of positional index is an index having the smallest index number and the same number of information bits of the first type among indices in the positional index set. of the second type of information bits, the third type of information bits and the parity check bits from indices in the position index set excluding the first type of position index determined by the first type of information bits; Determining an index in the position index set includes:
determining an index in the position index set that has the same number of parity-check bits and the largest index number as the index of the parity-check bits ;
indices of the second type of information bits from undetermined indices in the position index set according to the array of values of the position indices and the number of each of the second type of information bits and the third type of information bits; and sequentially determining indices of the third type of information bits. a storage medium;
a processor;
The storage medium stores a program,
The processor is configured to execute a program,
Apparatus, wherein the program, when executed, performs the method of any one of claims 1 to 3 .

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