CN109586858A - A kind of user that be used to wirelessly communicate, the method and apparatus in base station - Google Patents
A kind of user that be used to wirelessly communicate, the method and apparatus in base station Download PDFInfo
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- CN109586858A CN109586858A CN201710895676.5A CN201710895676A CN109586858A CN 109586858 A CN109586858 A CN 109586858A CN 201710895676 A CN201710895676 A CN 201710895676A CN 109586858 A CN109586858 A CN 109586858A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0053—Allocation of signaling, i.e. of overhead other than pilot signals
- H04L5/0057—Physical resource allocation for CQI
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L5/00—Arrangements affording multiple use of the transmission path
- H04L5/003—Arrangements for allocating sub-channels of the transmission path
- H04L5/0044—Arrangements for allocating sub-channels of the transmission path allocation of payload
Abstract
This application discloses the method and apparatus in a kind of user that be used to wirelessly communicate, base station.User equipment sends the first wireless signal and second wireless singal in the first running time-frequency resource and the second running time-frequency resource respectively.Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First bit block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, and first bit block and second bit block respectively include positive integer bit;First bit block includes the first control information, and whether first bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second bit block includes the second data.The above method allows user equipment to be improved resource utilization according to the radio resource that actual feedback requirements determine that the first control information occupies using the additional data of extra resource transmission.
Description
Technical field
This application involves the transmission method of the wireless signal in wireless communication system and devices, especially support uplink
Control the transmission method and device of the wireless signal in the wireless communication system of information.
Background technique
In the wireless communication system for supporting multi-antenna transmission, UE (User Equipment, user equipment) feeds back CSI
It is a kind of common that (Channel Status Information, channel state information), which carries out multiple antennas processing with assistant base station,
Technology.It is hidden in third generation cooperative partner program (3GPP -3rd GenerationPartner Project) cellular network system
(Implicit) CSI feedback of formula is supported.In traditional LTE (Long Term Evolution, long term evolution) system,
When UE needs to send CSI feedback and upstream data simultaneously on a subframe (sub-frame), CSI feedback can be with
Data are sent on upstream physical layer data channel together.
In 5G system, with the increase of the antenna amount of base station side equipment, the precision of traditional implicit CSI feedback is difficult
To meet the needs of multi-antenna transmission.Therefore, the research of enhancing CSI is proposed in 3GPP R (Release, version) 14.Enhancing
CSI needed for feedback overhead (Overhead) increase significantly, be one accordingly, with respect to the Feedback Design of enhancing CSI and need to solve
Certainly the problem of.
Summary of the invention
Inventors discovered through research that under difficult channel conditions, payload size required for the CSI feedback of enhancing
(payloadsize) it is different, and the variation of this payload size is dynamic.This dynamic payload size changes meeting
Difficulty is caused to the radio resource allocation of uplink, is born since base station cannot be known in advance required for the CSI feedback of enhancing
Size is carried, base station can not reserve sizeable radio resource to CSI feedback.How to solve due to the reserved excessive wireless money in base station
The wasting of resources caused by source, or CSI feedback caused by very few radio resource is reserved as base station can not completely send, it is desirable
It solves the problems, such as.
In view of the above-mentioned problems, this application discloses a solution.It is moved it should be noted that, although the application is initial
Machine is for multiaerial system, and the application is also applied for a single aerial system.In the absence of conflict, the user equipment of the application
In embodiment and embodiment in feature can be applied in base station, vice versa.In the absence of conflict, the application
Feature in embodiment and embodiment can be arbitrarily combined with each other.
This application discloses the methods in the user equipment that be used to wirelessly communicate characterized by comprising
- sends the first wireless signal and second wireless singal in the first running time-frequency resource and the second running time-frequency resource respectively;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First
Bit block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first ratio
Special block and second bit block respectively include positive integer bit;First bit block includes the first control information, described
Whether the first bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second ratio
Special block includes the second data.
As one embodiment, the essence of the above method is, when the number of the first control occupied bit of information
When measuring less, the user equipment can send additional upstream data on first running time-frequency resource, i.e., described first number
According to.This method is advantageous in that, is avoided since the size of first running time-frequency resource is more than to transmit the first control letter
Breath needed for radio resource and caused by the wasting of resources, improve resource utilization.
As one embodiment, the above method is advantageous in that, second data and the first control information are unrelated,
Therefore whether the first control information, which is successfully received, does not interfere with first wireless signal and second wireless communication
Number reception of the target receiver to second data.
As one embodiment, the first control information includes the bit that positive integer is arranged successively.
As one embodiment, first data include the bit that positive integer is arranged successively.
As one embodiment, second data include the bit that positive integer is arranged successively.
As one embodiment, first bit block includes the bit that positive integer is arranged successively.
As one embodiment, second bit block includes the bit that positive integer is arranged successively.
As one embodiment, the resource particle is RE (ResourceElement).
As one embodiment, the resource particle occupies the duration of a multicarrier symbol in time domain, in frequency domain
Occupy the bandwidth of a subcarrier.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is OFDM (OrthogonalFrequency
Division Multiplexing, orthogonal frequency division multiplexing) symbol.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is DFT-S-OFDM (Discrete
Fourier Transform Spread OFDM, discrete fourier change orthogonal frequency division multiplexing) symbol.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is FBMC (Filter Bank Multi
Carrier, filter bank multi-carrier) symbol.
As one embodiment, the second wireless singal is that second bit block successively passes through channel coding
(ChannelCoding), modulation mapper (Modulation Mapper), layer mapper (Layer Mapper), precoding
(Precoding), resource particle mapper (Resource Element Mapper), multicarrier symbol occur
(Generation) output after.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving (Interleaving).
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched (rate matching).
As one embodiment, the second wireless singal is that second bit block successively passes through channel coding, modulation
Mapper, layer mapper, conversion precoder (transform precoder, for generating complex valued signals), precoding, money
Source particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving.
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched.
As one embodiment, first wireless signal is that first bit block successively passes through channel coding, modulation
Mapper, layer mapper, precoding, resource particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving.
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched.
As one embodiment, first wireless signal is that first bit block successively passes through channel coding, modulation
Mapper, layer mapper, conversion precoder, precoding, resource particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving.
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched.
As one embodiment, the first control information is UCI (Uplink Control Information, uplink
Control information).
As one embodiment, the first control information includes { CSI (Channel Status Information, letter
Channel state information), PMI (Precoding Matrix Indicator, pre-coding matrix mark), CQI (Channel
Quality Indicator, channel quality identification), band amplitude coefficient (WidebandAmplitudeCoefficient),
PRI (Relative Power Indicator, relative power instruction), subband range coefficient (Subband Amplitude
Coefficient), subband phase coefficient (Subband Phase Coefficient) } one of or it is a variety of.
As one embodiment, the first control information is to MAC (Medium Access Control, media access control
System) layer is sightless.
As one embodiment, the first control information is generated by physical layer.
As one embodiment, first data and second data belong to the same TB (Transport
Block, transmission block).
As one embodiment, the above method is advantageous in that, first data of additional transmissions and scheduled institute
It states the second data and belongs to the same TB, simplify the processing of the MAC layer.
As one embodiment, first data and second data respectively include in the same TB not on year-on-year basis
It is special.
As one embodiment, first data and second data are identical.
As one embodiment, the above method is advantageous in that, when the number of the first control occupied bit of information
When measuring less, the user equipment can repeat to send scheduled upstream data on first running time-frequency resource, i.e., described
Second data, to improve the transmission reliability of second data.
As one embodiment, first data only include information bit (not including check bit).
As a sub- embodiment of above-described embodiment, the check bit is CRC (Cyclic Redundancy
Check, cyclic redundancy check) bit.
As one embodiment, second data only include information bit (not including check bit).
As a sub- embodiment of above-described embodiment, the check bit is CRC bit.
As one embodiment, the transmission channel for carrying first data is UL-SCH (UpLink Shared
Channel, Uplink Shared Channel).
As one embodiment, the transmission channel for carrying second data is UL-SCH.
As one embodiment, for carrying the transmission channel of first data and for carrying second data
Transmission channel is the same UL-SCH.
As one embodiment, first running time-frequency resource and second running time-frequency resource belong to the same physical layer letter
Road.
As a sub- embodiment of above-described embodiment, the physical layer channel is that upstream physical layer data channel (can
It is used for transmission the up channel of physical layer data).
As a sub- embodiment of above-described embodiment, the physical layer channel is PUSCH (Physical Uplink
Shared CHannel, Physical Uplink Shared Channel).
As a sub- embodiment of above-described embodiment, the physical layer channel be sPUSCH (short PUSCH, it is short
PUSCH)。
As a sub- embodiment of above-described embodiment, the physical layer channel be NR-PUSCH (NewRadio PUSCH,
New wireless PUSCH).
As a sub- embodiment of above-described embodiment, the physical layer channel is NB-PUSCH (NarrowBand
PUSCH, narrowband PUSCH).
As one embodiment, first wireless signal and the second wireless singal are in the same physical layer channel
Transmission.
As a sub- embodiment of above-described embodiment, the physical layer channel is that upstream physical layer data channel (can
For carrying the up channel of physical layer data).
As a sub- embodiment of above-described embodiment, the physical layer channel is PUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is sPUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is NR-PUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is NB-PUSCH.
As one embodiment, if the quantity of the first control occupied bit of information is greater than first threshold, institute
Stating the first bit block not includes first data;If it is described first control the occupied bit of information quantity be less than or
Equal to the first threshold, first bit block includes first data;The first threshold is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
As one embodiment, the quantity for the bit that first data include and the first control information are occupied
The quantity of bit is related.
As one embodiment, the quantity of the first control occupied bit of information is used for determining first number
According to the quantity for the bit for including.
As one embodiment, the quantity for the bit that second data include and the first control information are occupied
The quantity of bit is related.
As one embodiment, the quantity for the resource particle that first running time-frequency resource includes is by the first control information
The maximum quantity for the bit that may be occupied determines.
According to the one aspect of the application characterized by comprising
- generates the first check bit block;
Wherein, first bit block includes first data, and the first check bit block includes positive integer ratio
Spy, the bit in the first data splitting be used to generate the first check bit block, and first data splitting includes described
The bit in bit and second data in first data, first bit block includes first check bit
Block.
As one embodiment, the above method is advantageous in that, when first bit block includes first data,
The target receiver of first wireless signal and the second wireless singal can be judged by the first check bit block
Whether first data and second data are correctly received.
As one embodiment, the first check bit block includes the bit that positive integer is arranged successively.
As one embodiment, first data splitting includes the bit that positive integer is arranged successively.
As one embodiment, the bit in the first check bit block and the first control information is unrelated.
As one embodiment, first data splitting includes all bits and described in first data
All bits in two data.
As one embodiment, first data splitting is cascaded by first data and second data.
As one embodiment, first data splitting is by all bits and second number in first data
All bits in cascade.
As one embodiment, the CRC bit block of first data splitting be used to generate first check bit
Block.
As one embodiment, the first check bit block is passed through by the CRC bit block of first data splitting
It is obtained after scrambling code.
As a sub- embodiment of above-described embodiment, the scrambling code is using the mark of the user equipment as scrambling code sequence
Column.
As one embodiment, the mark of the user equipment is made of 16 bits.
As one embodiment, the mark of the user equipment is distributed by serving cell.
As one embodiment, the mark of the user equipment is C-RNTI (Cell-Radio Network
Temporary Identifier, Cell Radio Network Temporary Identity).
As one embodiment, the first check bit block is the CRC bit block of first data splitting.
As one embodiment, the CRC bit block of given bit block is given bit block by CRC circulation generator polynomial
The output of (cyclic generator polynomial);The given bit block includes positive integer bit.CRC's is specific
Technical detail is saved referring to the 5.1.1 in technical specification (TS-Technical Specification) 36.212.
As a sub- embodiment of above-described embodiment, the bit in the given bit block is sequentially inputted to described
CRC is recycled in generator polynomial, and the output of the CRC circulation generator polynomial is the CRC bit block of the given bit block.
As one embodiment, the multinomial of the CRC bit block composition of bit block and the given bit block is given in GF
(2) generator polynomial can be recycled by CRC on to divide exactly, i.e., the CRC bit block structure of the described given bit block and the given bit block
At deconv with the obtained remainder of CRC circulation generator polynomial be zero.
As one embodiment, any bit given in the CRC bit block of bit block is equal in the given bit block
Positive integer bit sum to 2 modulus.
As one embodiment, the bit that the first check bit block is arranged successively by 8 is formed.
As one embodiment, the bit that the first check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the first check bit block is arranged successively by 24 is formed.
As one embodiment, the method in the user equipment that be used to wirelessly communicate includes:
- generates the 4th check bit block;
Wherein, the 4th check bit block includes positive integer bit, and the bit in first data be used to give birth to
At the 4th check bit block, first bit block includes the 4th check bit block.
As a sub- embodiment of above-described embodiment, the 4th check bit block includes that positive integer is arranged successively
Bit.
As a sub- embodiment of above-described embodiment, first bit block include first data, described first
Check bit block, the 4th check bit block }.
As a sub- embodiment of above-described embodiment, the CRC bit block of first data be used to generate described
Four check bit blocks.
As a sub- embodiment of above-described embodiment, the 4th check bit block is by the CRC of first data
Bit block after scrambling code by obtaining.
As a sub- embodiment of above-described embodiment, the 4th check bit block is the CRC ratio of first data
Special block.
As a sub- embodiment of above-described embodiment, the CRC bit blocks of whole bits in first data by with
In generation the 4th check bit block.
As a sub- embodiment of above-described embodiment, the bit group that the 4th check bit block is arranged successively by 24
At.
As a sub- embodiment of above-described embodiment, the bit group that the 4th check bit block is arranged successively by 16
At.
As a sub- embodiment of above-described embodiment, the bit group that the 4th check bit block is arranged successively by 8
At.
According to the one aspect of the application characterized by comprising
- generates third check bit block;
Wherein, first bit block includes first data, and the third check bit block includes positive integer ratio
Spy, the bit in the second data splitting be used to generate the third check bit block, and second data splitting includes described
The bit in partial bit and second data in first data, first bit block include the third verification ratio
Special block.
As one embodiment, the essence of the above method is, second data splitting can be made to become one completely
Paragraph (segment), simplify the segmentation (segmentation) of the TB constituted to first data and the second data.
As one embodiment, the third check bit block includes the bit that positive integer is arranged successively.
As one embodiment, second data splitting includes the bit that positive integer is arranged successively.
As one embodiment, second data splitting includes partial bit and described in first data
Partial bit in two data.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Partial bit in cascades.
As one embodiment, second data splitting includes partial bit and described in first data
Whole bits in two data.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Whole bits in cascade.
As one embodiment, the CRC bit block of second data splitting be used to generate the third check bit
Block.
As one embodiment, the third check bit block is passed through by the CRC bit block of second data splitting
It is obtained after scrambling code.
As a sub- embodiment of above-described embodiment, the scrambling code is using the mark of the user equipment as scrambling code sequence
Column.
As one embodiment, the third check bit block is the CRC bit block of second data splitting.
As one embodiment, the bit that the third check bit block is arranged successively by 24 is formed.
As one embodiment, the bit that the third check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the third check bit block is arranged successively by 8 is formed.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and equal to bit included by maximum code block (Code Block) quantity.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to maximum code block length (maximum code block size).
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 8448.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 6144.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 3840.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 2560.
As one embodiment, the method in the user equipment that be used to wirelessly communicate includes:
- generates the 4th check bit block;
Wherein, the 4th check bit block includes positive integer bit, and the bit in the first remaining data be used to give birth to
At the 4th check bit block, first remaining data includes in first data and except second data splitting
Bit, first bit block includes the 4th check bit block.
As a sub- embodiment of above-described embodiment, first remaining data includes the ratio that positive integer is arranged successively
It is special.
As a sub- embodiment of above-described embodiment, first remaining data is by first data and described
Bit composition except two data splittings.
As a sub- embodiment of above-described embodiment, the 4th check bit block includes that positive integer is arranged successively
Bit.
As a sub- embodiment of above-described embodiment, the CRC bit block of first remaining data be used to generate institute
State the 4th check bit block.
As a sub- embodiment of above-described embodiment, the 4th check bit block is by first remaining data
CRC bit block after scrambling code by obtaining.
As a sub- embodiment of above-described embodiment, the 4th check bit block is first remaining data
CRC bit block.
As a sub- embodiment of above-described embodiment, the bit group that the 4th check bit block is arranged successively by 24
At.
As a sub- embodiment of above-described embodiment, the bit group that the 4th check bit block is arranged successively by 16
At.
As a sub- embodiment of above-described embodiment, the bit group that the 4th check bit block is arranged successively by 8
At.
As a sub- embodiment of above-described embodiment, first bit block include first data, described first
Check bit block, the third check bit block, the 4th check bit block }.
As one embodiment, in the quantity of the bit in first remaining data and the 4th check bit block
The quantity of bit and less than or equal to bit included by maximum code block (Code Block) quantity.
As one embodiment, in the quantity of the bit in first remaining data and the 4th check bit block
The quantity of bit and be less than or equal to maximum code block length (maximum code block size).
According to the one aspect of the application characterized by comprising
- generates the second check bit block;
Wherein, the second check bit block includes positive integer bit, and second bit block includes second school
Bit block is tested, the bit in second data be used to generate the second check bit block, the second check bit block
It is unrelated with the bit in first data.
As one embodiment, the above method is advantageous in that, when first bit block does not include first data
When or the first control information when not being correctly received, first wireless signal and the second wireless singal
Target receiver still is able to judge whether the second wireless singal is correctly received.
As one embodiment, the second check bit block includes the bit that positive integer is arranged successively.
As one embodiment, all bits in second data be used to generate the second check bit block.
As one embodiment, the CRC bit block of all bits in second data be used to generate described second
Check bit block.
As one embodiment, the second check bit block is the CRC ratio by all bits in second data
Special block after scrambling code by obtaining.
As one embodiment, the second check bit block is the CRC bit of all bits in second data
Block.
As one embodiment, the partial bit in second data be used to generate the second check bit block.
As one embodiment, the CRC bit block of the partial bit in second data be used to generate described second
Check bit block.
As one embodiment, the second check bit block is the CRC ratio by the partial bit in second data
Special block after scrambling code by obtaining.
As one embodiment, the second check bit block is the CRC bit of the partial bit in second data
Block.
As one embodiment, the bit that the second check bit block is arranged successively by 24 is formed.
As one embodiment, the bit that the second check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the second check bit block is arranged successively by 8 is formed.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to maximum code block (Code Block) included by bit quantity positive integer times.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to the positive integer times of maximum code block length (maximum code block size).
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 8448.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 6144.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 3840.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 2560.
According to the one aspect of the application characterized by comprising
- executes at least the latter in the first channel coding and second channel coding;
Wherein, the input of first channel coding includes the bit in first data, first channel coding
Output be used to generate the first wireless subsignal, first wireless signal includes the described first wireless subsignal;Described
The input of two channel codings is second bit block, and it is wireless that the output of the second channel coding be used to generate described second
Signal.
As one embodiment, the input of first channel coding includes the bit in the first check bit block.
As one embodiment, the input of first channel coding includes the bit in the third check bit block.
As one embodiment, the input of first channel coding includes the bit in the 4th check bit block.
As one embodiment, the input of first channel coding includes { whole bits in first data, institute
State whole bits in the first check bit block, whole bits in the third check bit block, the 4th check bit
Whole bits in block }.
As one embodiment, the input of first channel coding includes { whole bits in first data, institute
State whole bits in the first check bit block, whole bits in the 4th check bit block }.
As one embodiment, the input of first channel coding is first bit block.
As a sub- embodiment of above-described embodiment, first wireless signal is the described first wireless subsignal.
As one embodiment, first channel coding is based on polar code (polarization code).
As a sub- embodiment of above-described embodiment, the input of first channel coding includes the first control letter
Bit in breath.
As one embodiment, first channel coding be based on LDPC (Low Density Parity Check, it is low close
Spend even-odd check) code.
As a sub- embodiment of above-described embodiment, the input of first channel coding does not include first control
Bit in information.
As one embodiment, first channel coding is based on Turbo code.
As one embodiment, first channel coding is based on convolutional code.
As one embodiment, first channel coding includes interweaving (Interleaving).
As one embodiment, first channel coding includes rate-matched (rate matching).
As one embodiment, the first wireless subsignal is that the output of first channel coding is successively passed through
Modulation mapper (Modulation Mapper), layer mapper (Layer Mapper), precoding (Precoding), resource grains
Output after (Generation) occurs for sub- mapper (Resource Element Mapper), multicarrier symbol.
As one embodiment, the first wireless subsignal is that the output of first channel coding is successively passed through
Modulation mapper, layer mapper, conversion precoder (transform precoder, for generating complex valued signals) prelist
Code, resource particle mapper, the output after multicarrier symbol generation.
As one embodiment, the second channel coding is based on LDPC code.
As one embodiment, the second channel coding is based on Turbo code.
As one embodiment, the second channel coding is based on convolutional code.
As one embodiment, the second channel coding includes interweaving (Interleaving).
As one embodiment, the second channel coding includes rate-matched (rate matching).
As one embodiment, the input of the second channel coding includes the bit in the second check bit block.
As one embodiment, the input of the second channel coding includes { whole bits in second data, institute
State whole bits in the second check bit block }.
As one embodiment, the second wireless singal is the output of the second channel coding successively through toning
Mapper (Modulation Mapper) processed, layer mapper (Layer Mapper), precoding (Precoding), resource particle
Output after (Generation) occurs for mapper (Resource Element Mapper), multicarrier symbol.
As one embodiment, the second wireless singal is the output of the second channel coding successively through toning
Mapper processed, layer mapper, conversion precoder (transform precoder, for generating complex valued signals), precoding,
Resource particle mapper, the output after multicarrier symbol generation.
As one embodiment, the method in the user equipment that be used to wirelessly communicate includes:
- executes third channel coding;
Wherein, the input of the third channel coding includes the bit in the first control information, the third channel
The output of coding be used to generate the second wireless subsignal;First wireless signal includes the described second wireless subsignal.
As a sub- embodiment of above-described embodiment, first channel coding and second channel coding are based on
LDPC code, the third channel coding are based on Polar code.
As a sub- embodiment of above-described embodiment, the input of the third channel coding includes the first control letter
The CRC bit block of breath.
As a sub- embodiment of above-described embodiment, first wireless signal include the described first wireless subsignal and
The second wireless subsignal.
As a sub- embodiment of above-described embodiment, the second wireless subsignal is the third channel coding
Output successively pass through modulation mapper (Modulation Mapper), layer mapper (Layer Mapper), precoding
(Precoding), resource particle mapper (Resource Element Mapper), multicarrier symbol occur
(Generation) output after.
As a sub- embodiment of above-described embodiment, the second wireless subsignal is the third channel coding
Output successively pass through modulation mapper, layer mapper, conversion precoder (transform precoder, it is multiple for generating
Numerical signal), precoding, resource particle mapper, the output after multicarrier symbol generation.
According to the one aspect of the application characterized by comprising
- sends third wireless signal in third running time-frequency resource;
Wherein, the third running time-frequency resource includes positive integer resource particle;The third wireless signal includes the second control
Information processed, the quantity of the first control occupied bit of information and second control are information-related.
As one embodiment, the second control information is used for determining the first control occupied bit of information
Quantity.
As one embodiment, the second control information indicates the number of the first control occupied bit of information
Amount.
As one embodiment, the second control information includes the bit that positive integer is arranged successively.
As one embodiment, the method in the user equipment that be used to wirelessly communicate includes:
- executes the 4th channel coding;
Wherein, the input of the 4th channel coding includes the bit in the second control information;4th channel
The output of coding be used to generate third wireless signal.
As a sub- embodiment of above-described embodiment, the 4th channel coding is based on Polar code.
As a sub- embodiment of above-described embodiment, the input of the 4th channel coding includes the second control letter
The CRC bit block of breath.
As a sub- embodiment of above-described embodiment, the third wireless signal is the 4th channel coding
Output successively passes through modulation mapper (Modulation Mapper), layer mapper (Layer Mapper), precoding
(Precoding), resource particle mapper (Resource Element Mapper), multicarrier symbol occur
(Generation) output after.
As a sub- embodiment of above-described embodiment, the third wireless signal is the 4th channel coding
Modulation mapper, layer mapper, conversion precoder (transform precoder, for generating plural number are successively passed through in output
Value signal), precoding, resource particle mapper, the output after multicarrier symbol generation.
As one embodiment, the third wireless signal (can be used for transmission physics in upstream physical layer data channel
The up channel of layer data) on transmit.
As a sub- embodiment of above-described embodiment, the upstream physical layer data channel is PUSCH.
As a sub- embodiment of above-described embodiment, the upstream physical layer data channel is sPUSCH.
As a sub- embodiment of above-described embodiment, the upstream physical layer data channel is NR-PUSCH.
As a sub- embodiment of above-described embodiment, the upstream physical layer data channel is NB-PUSCH.
As one embodiment, first wireless signal, the second wireless singal and the third wireless signal exist
It is transmitted in the same physical layer channel.
As one embodiment, first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource are all
Belong to a physical layer channel.
As one embodiment, the second control information includes UCI.
As one embodiment, the second control information includes { CSI, RI (RankIndicator, order mark), CRI
(Channel-state information reference signals Resource Indicator, channel state information
Reference signal resource mark), PMI, non-zero band amplitude coefficient number, CQI, band amplitude coefficient
(WidebandAmplitudeCoefficient), PRI (Relative Power Indicator, relative power instruction) } in
It is one or more.
As one embodiment, the second control information includes RI and CQI.
As one embodiment, the second control information is sightless to MAC layer.
As one embodiment, the second control information is generated by physical layer.
As one embodiment, the third running time-frequency resource includes positive integer resource particle.
As a sub- embodiment of above-described embodiment, the resource particle is RE.
As a sub- embodiment of above-described embodiment, the resource particle occupies holding for a multicarrier symbol in time domain
The continuous time occupies the bandwidth of a subcarrier in frequency domain.
According to the one aspect of the application characterized by comprising
- receives the second signaling;
Wherein, second signaling is used for determining { whether first data are correctly received, and second data are
No to be correctly received, whether the bit in partial bit and second data in first data is correctly received, institute
At least one of whether another part bit stated in the first data is correctly received }.
As one embodiment, the above method is advantageous in that, allows the user equipment to first data and institute
It states the second data to be retransmitted respectively, improve resource utilization.
As one embodiment, { whether second data splitting is correctly received, and first is surplus for the second signaling instruction
Remainder according to whether be correctly received, first remaining data include in first data and second data splitting it
Outer bit.
As one embodiment, the above method is advantageous in that, allows the user equipment to second data splitting
It is retransmitted, is improved resource utilization respectively with first remaining data.
As one embodiment, second signaling indicates whether second data splitting is correctly received.
As one embodiment, second signaling indicates whether the first remaining data is correctly received, and described first is surplus
Remainder is according to including the bit in first data and except second data splitting.
As one embodiment, { whether first data are correctly received, second number for the second signaling instruction
According to whether being correctly received }.
As one embodiment, second signaling indicates whether first data are correctly received.
As one embodiment, second signaling indicates whether second data are correctly received.
As one embodiment, second signaling is physical layer signaling.
As one embodiment, second signaling is in PHICH (Physical Hybrid-automatic repeat-
Request Indicator CHannel, physical hybrid automatic repeat request indicator channel) on transmit.
According to the one aspect of the application characterized by comprising
- receives the first signaling;
Wherein, first signaling includes the first running time-frequency resource set and the first configuration information, first running time-frequency resource
Set includes positive integer resource particle;First running time-frequency resource and second running time-frequency resource belong to first time-frequency
Resource collection, position of the resource particle included by first running time-frequency resource in the first running time-frequency resource set and described
First signaling is unrelated;First configuration information includes { modulation coding scheme, the configuration information of demodulated reference signal, redundancy version
At least one of this, new data instruction };First configuration information be suitable for the first wireless subsignal, described second
Wireless signal } at least the latter.
As one embodiment, first configuration information is suitable for { the first wireless subsignal, described second is wireless
Signal }, first bit block includes first data.
As one embodiment, first configuration information is suitable for the second wireless singal, first bit block
It does not include first data.
As one embodiment, first signaling indicates that the first running time-frequency resource set and described first matches confidence
Breath.
As one embodiment, the modulation coding scheme in first configuration information refers to MCS (Modulation and
Coding Scheme)。
As one embodiment, the configuration information of the demodulated reference signal in first configuration information refers to DMRS
The configuration information of (DeModulation Reference Signals).
As a sub- embodiment of above-described embodiment, the configuration information of the DMRS include occupied time-domain resource,
Occupied frequency domain resource, occupied code domain resource, cyclic shift amount (cyclic shift), OCC (Orthogonal
Cover Code, orthogonal mask) } one of or it is a variety of.
As one embodiment, the redundancy versions in first configuration information refer to RV (Redundancy
Version)。
As one embodiment, the new data instruction in first configuration information refers to NDI (New Data
Indicator)。
As one embodiment, the quantity of resource particle included by first running time-frequency resource and first signaling without
It closes.
As one embodiment, the third running time-frequency resource belongs to the first running time-frequency resource set.
As one embodiment, resource particle included by the third running time-frequency resource is in the first running time-frequency resource set
In position and first signaling it is unrelated.
As one embodiment, first configuration information is not suitable for the described second wireless subsignal.
As one embodiment, first configuration information is not suitable for the third wireless signal.
As one embodiment, first signaling is physical layer signaling.
As one embodiment, first signaling is dynamic signaling.
As one embodiment, first signaling is that the dynamic signaling of (UpLink Grant) is authorized for uplink.
As one embodiment, first signaling includes DCI (Downlink Control Information, downlink
Control information).
As one embodiment, first signaling includes UpLink GrantDCI.
As one embodiment, { time-domain resource that second signaling occupies, the frequency domain money that second signaling occupies
Source, the code domain resource that second signaling occupies } and the time-domain resource that the first running time-frequency resource set occupies, described first
The frequency domain resource that running time-frequency resource set occupies, the configuration information of the DMRS in the configuration information } at least one of correlation.
As one embodiment, { time-domain resource that the first running time-frequency resource set occupies, the first running time-frequency resource collection
Close the frequency domain resource occupied, the configuration information of the DMRS in the configuration information } at least one of be used for determining { described the
The time-domain resource that two signalings occupy, the frequency domain resource that second signaling occupies, the code domain resource that second signaling occupies }.
As one embodiment, first signaling (is simply possible to use in carrying physical layer in down physical layer control channel
The down channel of signaling) on transmit.
As a sub- embodiment of above-described embodiment, the down physical layer control channel is PDCCH (Physical
DownlinkControl CHannel, Physical Downlink Control Channel).
As a sub- embodiment of above-described embodiment, the down physical layer control channel is sPDCCH (short
PDCCH, short PDCCH).
As a sub- embodiment of above-described embodiment, the down physical layer control channel is NR-PDCCH (New
Radio PDCCH, new wireless PDCCH).
As a sub- embodiment of above-described embodiment, the down physical layer control channel is NB-PDCCH
(NarrowBand PDCCH, narrowband PDCCH).
This application discloses the methods in the base station that be used to wirelessly communicate characterized by comprising
- receives the first wireless signal and second wireless singal in the first running time-frequency resource and the second running time-frequency resource respectively;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First
Bit block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first ratio
Special block and second bit block respectively include positive integer bit;First bit block includes the first control information, described
Whether the first bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second ratio
Special block includes the second data.
As one embodiment, the quantity of the first control occupied bit of information is by the base station for determining institute
State whether the first bit block includes first data.
As one embodiment, the quantity of the first control occupied bit of information is by the base station for determining institute
State the quantity for the bit that the first data include.
As one embodiment, the quantity of the first control occupied bit of information is by the base station for determining institute
State the quantity for the bit that the second data include.
As one embodiment, the first control information is UCI.
As one embodiment, first data and second data belong to the same TB (Transport
Block, transmission block).
As one embodiment, first data and second data respectively include in the same TB not on year-on-year basis
It is special.
According to the one aspect of the application characterized by comprising
- restores the first check bit block;
Wherein, first bit block includes first data, and the first check bit block includes positive integer ratio
Spy, the bit in the first data splitting be used to generate the first check bit block, and first data splitting includes described
The bit in bit and second data in first data, first bit block includes first check bit
Block.
As one embodiment, the CRC bit block of first data splitting be used to generate first check bit
Block.
As one embodiment, the base station judges first number of combinations according to the first check bit block of recovery
According to whether being correctly received.
As one embodiment, the first verification ratio is restored in the base station from first wireless signal received
Special block, and determine whether decoding is correct according to the first check bit block of recovery.Described the is judged if decoding is correct
One data splitting is correctly received;Otherwise judge that first data splitting is not correctly received.
As one embodiment, the first verification ratio is restored in the base station from first wireless signal received
Special block restores from first wireless signal received and in the second wireless singal first data splitting, and right
First data splitting of the first check bit block and recovery that restore carries out CRC check whether just to determine decoding
Really.Judge that first data splitting is correctly received if decoding is correct;Otherwise judge that first data splitting does not have
It is correctly received.
As one embodiment, the first verification ratio is restored in the base station from first wireless signal received
Special block restores from first wireless signal received and in the second wireless singal first data splitting.If
The multinomial that the first check bit block of first data splitting and recovery that restore is constituted can be by CRC on GF (2)
Circulation generator polynomial divides exactly, and the base station judges that first data splitting is correctly received;Otherwise judge described first group
Data are closed not to be correctly received.
As one embodiment, the method in the base station that be used to wirelessly communicate includes:
- restores the 4th check bit block;
Wherein, the 4th check bit block includes positive integer bit, and the bit in first data be used to give birth to
At the 4th check bit block, first bit block includes the 4th check bit block.
As a sub- embodiment of above-described embodiment, the base station judges according to the 4th check bit block of recovery
Whether first data are correctly received.
As a sub- embodiment of above-described embodiment, first bit block include first data, described first
Check bit block, the 4th check bit block }.
As a sub- embodiment of above-described embodiment, the base station is restored from first wireless signal received
The 4th check bit block, and determine whether decoding is correct according to the 4th check bit block of recovery.If decoding is just
It is true then judge that first data are correctly received;Otherwise judge that first data are not correctly received.
According to the one aspect of the application characterized by comprising
- restores third check bit block;
Wherein, first bit block includes first data, and the third check bit block includes positive integer ratio
Spy, the bit in the second data splitting be used to generate the third check bit block, and second data splitting includes described
The bit in partial bit and second data in first data, first bit block include the third verification ratio
Special block.
As one embodiment, the CRC bit block of second data splitting be used to generate the third check bit
Block.
As one embodiment, the base station judges second number of combinations according to the third check bit block of recovery
According to whether being correctly received.
As one embodiment, the third verification ratio is restored in the base station from first wireless signal received
Special block, and determine whether decoding is correct according to the third check bit block of recovery.Described the is judged if decoding is correct
Two data splittings are correctly received;Otherwise judge that second data splitting is not correctly received.
As one embodiment, the third verification ratio is restored in the base station from first wireless signal received
Special block restores from first wireless signal received and in the second wireless singal second data splitting, and right
Second data splitting of the third check bit block and recovery that restore carries out CRC check whether just to determine decoding
Really.Judge that second data splitting is correctly received if decoding is correct;Otherwise judge that second data splitting does not have
It is correctly received.
As one embodiment, the third verification ratio is restored in the base station from first wireless signal received
Special block restores from first wireless signal received and in the second wireless singal second data splitting.If
The multinomial that the third check bit block of second data splitting and recovery that restore is constituted can be by CRC on GF (2)
Circulation generator polynomial divides exactly, and the base station judges that second data splitting is correctly received;Otherwise judge described second group
Data are closed not to be correctly received.
As one embodiment, the method in the base station that be used to wirelessly communicate includes:
- restores the 4th check bit block;
Wherein, the 4th check bit block includes positive integer bit, and the bit in the first remaining data be used to give birth to
At the 4th check bit block, first remaining data includes in first data and except second data splitting
Bit, first bit block includes the 4th check bit block.
As a sub- embodiment of above-described embodiment, the base station judges according to the 4th check bit block of recovery
Whether first remaining data is correctly received.
As a sub- embodiment of above-described embodiment, first bit block include first data, described first
Check bit block, the third check bit block, the 4th check bit block }.
As a sub- embodiment of above-described embodiment, the base station is restored from first wireless signal received
The 4th check bit block, and determine whether decoding is correct according to the 4th check bit block of recovery.If decoding is just
It is true then judge that first remaining data is correctly received;Otherwise judge that first remaining data is not correctly received.
According to the one aspect of the application characterized by comprising
- restores the second check bit block;
Wherein, the second check bit block includes positive integer bit, and second bit block includes second school
Bit block is tested, the bit in second data be used to generate the second check bit block, the second check bit block
It is unrelated with the bit in first data.
As one embodiment, the CRC bit block of second data be used to generate the second check bit block.
As one embodiment, the base station judges that second data are according to the second check bit block of recovery
It is no to be correctly received.
As one embodiment, the second verification ratio is restored in the base station from the second wireless singal received
Special block, and determine whether decoding is correct according to the second check bit block of recovery.Described the is judged if decoding is correct
Two data are correctly received;Otherwise judge that second data are not correctly received.
As one embodiment, the second verification ratio is restored in the base station from the second wireless singal received
Special block and second data, and the second check bit block to recovery and second data of recovery carry out the school CRC
Test to determine whether decoding is correct.Judge that second data are correctly received if decoding is correct;Otherwise judge described
Two data are not correctly received.
As one embodiment, the second verification ratio is restored in the base station from the second wireless singal received
Special block and second data.If the second check bit block of second data and recovery restored is constituted multinomial
Formula can recycle generator polynomial by CRC on GF (2) and divide exactly, and the base station judges that second data are correctly received;Otherwise
Judge that second data are not correctly received.
According to the one aspect of the application characterized by comprising
- executes at least the latter in the first channel decoding and second channel decoding;
Wherein, the input of the corresponding channel coding of first channel decoding includes the bit in first data, institute
The output for stating the corresponding channel coding of the first channel decoding be used to generate the first wireless subsignal, the first wireless signal packet
Include the described first wireless subsignal;The input that the second channel decodes corresponding channel coding is second bit block, institute
It states second channel and decodes the output of corresponding channel coding and be used to generate the second wireless singal.
As one embodiment, the first wireless subsignal be used to generate the input of first channel decoding, institute
The output for stating the first channel decoding be used to restore first data.
As one embodiment, the output of first channel decoding be used to restore the first check bit block.
As one embodiment, the output of first channel decoding be used to restore the third check bit block.
As one embodiment, the output of first channel decoding be used to restore the 4th check bit block.
As one embodiment, the input of first channel decoding is the wireless son letter in the base station received described first
Number successively pass through DFT (Discrete Fourier Transform, discrete Fourier transform), multiple antennas detection, constellation demodulation
(DeModulation) it is obtained after.
As one embodiment, the input of first channel decoding is the wireless son letter in the base station received described first
Number successively pass through DFT, balanced, multiple antennas detection obtains after constellation demodulation.
As one embodiment, the input of first channel decoding is the wireless son letter in the base station received described first
It number is obtained after one of { DFT, balanced, multiple antennas detection, constellation demodulation } or a variety of.
As one embodiment, the input of the corresponding channel coding of first channel decoding is first bit block,
The output of first channel decoding be used to restore first bit block.
As a sub- embodiment of above-described embodiment, first wireless signal be used to generate first channel and translate
The input of code.
As one embodiment, the input of first channel decoding is received first wireless signal in the base station
Successively pass through DFT (Discrete Fourier Transform, discrete Fourier transform), multiple antennas detection, constellation demodulation
(DeModulation) it is obtained after.
As one embodiment, the input of first channel decoding is received first wireless signal in the base station
Successively pass through DFT, balanced, multiple antennas detection, constellation demodulation, after obtain.
As one embodiment, the input of first channel decoding is received first wireless signal in the base station
It is obtained after one of { DFT, balanced, multiple antennas detection, constellation demodulation } or a variety of.
As one embodiment, the second wireless singal be used to generate the input of the second channel decoding, described
The output of second channel decoding be used to restore second bit block.
As one embodiment, the input of the second channel decoding is the received second wireless singal in the base station
Successively pass through DFT (Discrete Fourier Transform, discrete Fourier transform), multiple antennas detection, constellation demodulation
(DeModulation) it is obtained after.
As one embodiment, the input of first channel decoding is the received second wireless singal in the base station
Successively pass through DFT, balanced, multiple antennas detection obtains after constellation demodulation.
As one embodiment, the input of first channel decoding is the received second wireless singal in the base station
It is obtained after one of { DFT, balanced, multiple antennas detection, constellation demodulation } or a variety of.
As one embodiment, the method in the base station that be used to wirelessly communicate includes:
- executes third channel decoding;
Wherein, the input of the corresponding channel coding of the third channel decoding includes the ratio in the first control information
The output of spy, the corresponding channel coding of the third channel decoding be used to generate the second wireless subsignal;Described first is wireless
Signal includes the described second wireless subsignal.
As a sub- embodiment of above-described embodiment, the second wireless subsignal be used to generate the third channel
The input of decoding, the output of the third channel decoding be used to restore the first control information.
As a sub- embodiment of above-described embodiment, the output of the third channel decoding be used to restore described first
Control the CRC bit block of information.
As a sub- embodiment of above-described embodiment, the input of the third channel decoding is the received institute in the base station
It states the second wireless subsignal and successively passes through DFT (Discrete Fourier Transform, discrete Fourier transform), multiple antennas
Detection obtains after constellation demodulation (DeModulation).
As a sub- embodiment of above-described embodiment, the input of the third channel decoding is the received institute in the base station
It states the second wireless subsignal and successively passes through DFT, balanced, multiple antennas detection obtains after constellation demodulation.
As a sub- embodiment of above-described embodiment, the input of the third channel decoding is the received institute in the base station
State what the second wireless subsignal obtained after one of { DFT, balanced, multiple antennas detection, constellation demodulation } or a variety of.
According to the one aspect of the application characterized by comprising
- receives third wireless signal in third running time-frequency resource;
Wherein, the third running time-frequency resource includes positive integer resource particle;The third wireless signal includes the second control
Information processed, the quantity of the first control occupied bit of information and second control are information-related.
As one embodiment, the method in the base station that be used to wirelessly communicate includes:
- executes the 4th channel decoding;
Wherein, the input of the corresponding channel coding of the 4th channel decoding includes the ratio in the second control information
It is special;The output of the corresponding channel coding of 4th channel decoding be used to generate the third wireless signal.
As a sub- embodiment of above-described embodiment, the third wireless signal be used to generate the 4th channel and translate
The input of code, the output of the 4th channel decoding be used to restore the second control information.
As a sub- embodiment of above-described embodiment, the output of the 4th channel decoding be used to restore described second
Control the CRC bit block of information.
As a sub- embodiment of above-described embodiment, the input of the 4th channel decoding is the received institute in the base station
It states third wireless signal successively to pass through DFT (Discrete Fourier Transform, discrete Fourier transform), multiple antennas inspection
It surveys, is obtained after constellation demodulation (DeModulation).
As a sub- embodiment of above-described embodiment, the input of the 4th channel decoding is the received institute in the base station
It states third wireless signal and successively passes through DFT, balanced, multiple antennas detection obtains after constellation demodulation.
As a sub- embodiment of above-described embodiment, the input of the 4th channel decoding is the received institute in the base station
State what third wireless signal obtained after one of { DFT, balanced, multiple antennas detection, constellation demodulation } or a variety of.
As one embodiment, the second control information includes UCI.
According to the one aspect of the application characterized by comprising
- sends the second signaling;
Wherein, second signaling is used for determining { whether first data are correctly received, and second data are
No to be correctly received, whether the bit in partial bit and second data in first data is correctly received, institute
At least one of whether another part bit stated in the first data is correctly received }.
According to the one aspect of the application characterized by comprising
- sends the first signaling;
Wherein, first signaling includes the first running time-frequency resource set and the first configuration information, first running time-frequency resource
Set includes positive integer resource particle;First running time-frequency resource and second running time-frequency resource belong to first time-frequency
Resource collection, position of the resource particle included by first running time-frequency resource in the first running time-frequency resource set and described
First signaling is unrelated;First configuration information includes { modulation coding scheme, the configuration information of demodulated reference signal, redundancy version
At least one of this, new data instruction };First configuration information be suitable for the first wireless subsignal, described second
Wireless signal } at least the latter.
This application discloses the user equipmenies that be used to wirelessly communicate characterized by comprising
First processing module sends the first wireless signal and second in the first running time-frequency resource and the second running time-frequency resource respectively
Wireless signal;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First
Bit block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first ratio
Special block and second bit block respectively include positive integer bit;First bit block includes the first control information, described
Whether the first bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second ratio
Special block includes the second data.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also generates the first check bit block.Wherein, first bit block includes first data, the first check bit block
Including positive integer bit, the bit in the first data splitting be used to generate the first check bit block, and described first group
Closing data includes the bit in first data and the bit in second data, and first bit block includes described
First check bit block.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also generates the 4th check bit block.Wherein, the 4th check bit block includes positive integer bit, first bit block
Including first data, the bit in first data be used to generate the 4th check bit block, first ratio
Special block includes the 4th check bit block.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also generates third check bit block.Wherein, first bit block includes first data, the third check bit block
Including positive integer bit, the bit in the second data splitting be used to generate the third check bit block, and described second group
Conjunction data include the bit in partial bit and second data in first data, and first bit block includes
The third check bit block.
As a sub- embodiment of above-described embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that,
The first processing module also generates the 4th check bit block.Wherein, the 4th check bit block includes positive integer bit,
Bit in first remaining data be used to generate the 4th check bit block, and first remaining data includes described first
Bit in data and except second data splitting, first bit block include the 4th check bit block.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also generates the second check bit block.Wherein, the second check bit block includes positive integer bit, second bit block
Including the second check bit block, the bit in second data be used to generate the second check bit block, described
Second check bit block is unrelated with the bit in first data.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also executes the first channel coding.Wherein, first bit block includes first data, first channel coding it is defeated
Enter including the bit in first data, the output of first channel coding be used to generate the first wireless subsignal, institute
Stating the first wireless signal includes the described first wireless subsignal.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also executes second channel coding.Wherein, the input of the second channel coding is second bit block, the second channel
The output of coding be used to generate the second wireless singal.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block also executes third channel coding.Wherein, the input of the third channel coding includes the bit in the first control information,
The output of the third channel coding be used to generate the second wireless subsignal;First wireless signal includes second nothing
Line subsignal.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that, the first processing mould
Block sends third wireless signal also in third running time-frequency resource.Wherein, the third running time-frequency resource includes positive integer resource grains
Son;The third wireless signal includes the second control information, the first control quantity of the occupied bit of information and described
Second control is information-related.
As a sub- embodiment of above-described embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that,
The first processing module also executes the 4th channel coding.Wherein, the input of the 4th channel coding includes second control
Bit in information processed;The output of 4th channel coding be used to generate third wireless signal.
As one embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterised by comprising: the first receiver
Module receives the second signaling;
Wherein, second signaling is used for determining { whether first data are correctly received, and second data are
No to be correctly received, whether the bit in partial bit and second data in first data is correctly received, institute
At least one of whether another part bit stated in the first data is correctly received }.
As a sub- embodiment of above-described embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that,
First receiver module also receives the first signaling.Wherein, first signaling includes the first running time-frequency resource set and first
Configuration information, the first running time-frequency resource set include positive integer resource particle;First running time-frequency resource and described second
Running time-frequency resource belongs to the first running time-frequency resource set, and resource particle included by first running time-frequency resource is described first
Position and first signaling in running time-frequency resource set is unrelated;First configuration information includes { modulation coding scheme, demodulation
At least one of the configuration information of reference signal, redundancy versions, new data instruction }.
As a sub- embodiment of above-described embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that,
First configuration information is suitable for { the first wireless subsignal, the second wireless singal }, the first bit block packet
Include first data.
As a sub- embodiment of above-described embodiment, the above-mentioned user equipment that be used to wirelessly communicate is characterized in that,
First configuration information is suitable for the second wireless singal, and first bit block does not include first data.
This application discloses the base station equipments that be used to wirelessly communicate characterized by comprising
Second processing module receives the first wireless signal and second in the first running time-frequency resource and the second running time-frequency resource respectively
Wireless signal;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First
Bit block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first ratio
Special block and second bit block respectively include positive integer bit;First bit block includes the first control information, described
Whether the first bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second ratio
Special block includes the second data.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also restores the first check bit block.Wherein, first bit block includes first data, the first check bit block
Including positive integer bit, the bit in the first data splitting be used to generate the first check bit block, and described first group
Closing data includes the bit in first data and the bit in second data, and first bit block includes described
First check bit block.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also restores the 4th check bit block.Wherein, first bit block includes first data, the 4th check bit block
Including positive integer bit, the bit in first data be used to generate the 4th check bit block, first ratio
Special block includes the 4th check bit block.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also restores third check bit block.Wherein, first bit block includes first data, the third check bit block
Including positive integer bit, the bit in the second data splitting be used to generate the third check bit block, and described second group
Conjunction data include the bit in partial bit and second data in first data, and first bit block includes
The third check bit block.
As a sub- embodiment of above-described embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that,
The Second processing module also restores the 4th check bit block.Wherein, the 4th check bit block includes positive integer bit,
Bit in first remaining data be used to generate the 4th check bit block, and first remaining data includes described first
Bit in data and except second data splitting, first bit block include the 4th check bit block.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also restores the second check bit block.Wherein, the second check bit block includes positive integer bit, second bit block
Including the second check bit block, the bit in second data be used to generate the second check bit block, described
Second check bit block is unrelated with the bit in first data.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also executes the first channel decoding.Wherein, first bit block includes first data, and first channel decoding is corresponding
The input of channel coding include bit in first data, the output of the corresponding channel coding of first channel decoding
It is used to generate the first wireless subsignal, first wireless signal includes the described first wireless subsignal.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also executes second channel decoding.Wherein, it is second bit that the second channel, which decodes the input of corresponding channel coding,
Block, the output that the second channel decodes corresponding channel coding be used to generate the second wireless singal.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block also executes third channel decoding.Wherein, the input of the corresponding channel coding of the third channel decoding includes first control
The output of bit in information processed, the corresponding channel coding of the third channel decoding be used to generate the second wireless subsignal;
First wireless signal includes the described second wireless subsignal.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that, the second processing mould
Block receives third wireless signal also in third running time-frequency resource.Wherein, the third running time-frequency resource includes positive integer resource grains
Son;The third wireless signal includes the second control information, the first control quantity of the occupied bit of information and described
Second control is information-related.
As a sub- embodiment of above-described embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that,
The Second processing module also executes the 4th channel decoding.Wherein, the input of the corresponding channel coding of the 4th channel decoding
Including the bit in the second control information;The output of the corresponding channel coding of 4th channel decoding be used to generate institute
State third wireless signal.
As one embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterised by comprising:
First sender module sends the second signaling;
Wherein, second signaling is used for determining { whether first data are correctly received, and second data are
No to be correctly received, whether the bit in partial bit and second data in first data is correctly received, institute
At least one of whether another part bit stated in the first data is correctly received }.
As a sub- embodiment of above-described embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that,
First sender module also sends the first signaling.Wherein, first signaling includes the first running time-frequency resource set and first
Configuration information, the first running time-frequency resource set include positive integer resource particle;First running time-frequency resource and described second
Running time-frequency resource belongs to the first running time-frequency resource set, and resource particle included by first running time-frequency resource is described first
Position and first signaling in running time-frequency resource set is unrelated;First configuration information includes { modulation coding scheme, demodulation
At least one of the configuration information of reference signal, redundancy versions, new data instruction }.
As a sub- embodiment of above-described embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that,
First configuration information is suitable for { the first wireless subsignal, the second wireless singal }, the first bit block packet
Include first data.
As a sub- embodiment of above-described embodiment, the above-mentioned base station equipment that be used to wirelessly communicate is characterized in that,
First configuration information is suitable for the second wireless singal, and first bit block does not include first data.
It is compared as one embodiment with traditional scheme, the application has following advantage:
When CSI feedback and upstream data are sent on upstream physical layer data channel together, and base station is not known in advance
In the case where the payload size of CSI feedback, if the radio resource that CSI feedback is distributed in base station is more than actual demand, UE can be with
Additional upstream data is sent, on extra radio resource so as to avoid excessive due to the resource distributed to CSI feedback
Caused by the wasting of resources, improve resource utilization.Alternatively, UE can repeat what transmission was scheduled on extra radio resource
Upstream data improves the transmission reliability of upstream data.
Base station can carry out distributing radio resource to CSI feedback according to maximum possible payload size, avoid due to resource
Distribution is insufficient and caused by CSI the case where cannot completely feeding back.
The upstream data of additional transmissions and scheduled upstream data belong to the same TB, simplify the place of the MAC layer
Reason.
The actual loading size of CSI feedback does not influence the transmission of scheduled upstream data, ensure that when base station fails into
In the case that function receives CSI feedback, scheduled upstream data still can receive.
Detailed description of the invention
By reading referring to the detailed description of non-limiting embodiments in the following drawings, other spies of the application
Sign, objects and advantages will become more apparent:
Fig. 1 shows the flow chart of first wireless signal and second wireless singal of one embodiment according to the application;
Fig. 2 shows the schematic diagrames according to the network architecture of one embodiment of the application;
Fig. 3 shows the reality of the radio protocol architecture of the user plane and control plane according to one embodiment of the application
Apply the schematic diagram of example;
Fig. 4 shows the schematic diagram of enode and UE according to one embodiment of the application;
Fig. 5 shows the flow chart of the wireless transmission of one embodiment according to the application;
Fig. 6 shows the flow chart of the wireless transmission of another embodiment according to the application;
Fig. 7 shows first running time-frequency resource of one embodiment according to the application, the second running time-frequency resource, third time-frequency money
Source and the first running time-frequency resource are integrated into the schematic diagram of the resource impact on time-frequency domain;
Fig. 8 shows the first running time-frequency resource of another embodiment according to the application, the second running time-frequency resource, third time-frequency
Resource and the first running time-frequency resource are integrated into the schematic diagram of the resource impact on time-frequency domain;
Fig. 9 shows the signal of the content of the first bit block and the second bit block according to one embodiment of the application
Figure;
Figure 10 shows showing for the content of the first bit block and the second bit block according to another embodiment of the application
It is intended to;
Figure 11 shows showing for the content of the first bit block and the second bit block according to another embodiment of the application
It is intended to;
Figure 12 shows the schematic diagram of the wireless subsignal of generation first according to one embodiment of the application;
Figure 13 shows the schematic diagram of the wireless subsignal of generation first according to another embodiment of the application;
Figure 14 shows the schematic diagram of the first wireless signal of generation according to one embodiment of the application;
Figure 15 shows the schematic diagram of the first wireless signal of generation according to another embodiment of the application;
Figure 16 shows the schematic diagram of the first wireless signal of generation according to another embodiment of the application;
Figure 17 shows the schematic diagrames according to the generation second wireless singal of one embodiment of the application;
Figure 18 shows the schematic diagram of the generation third wireless signal according to one embodiment of the application;
The bit that Figure 19 shows in the given information bit block according to one embodiment of the application be used for generate to
Determine the schematic diagram of check bit block;
The bit that Figure 20 is shown in the given information bit block according to another embodiment of the application be used to generate
The schematic diagram of given check bit block;
Figure 21 shows the schematic diagram of second signaling content of one embodiment according to the application;
Figure 22 shows the structural block diagram for the processing unit in user equipment of one embodiment according to the application;
Figure 23 shows the structural block diagram for the processing unit in base station of one embodiment according to the application.
Embodiment 1
Embodiment 1 illustrates the flow chart of the first wireless signal and second wireless singal, as shown in Fig. 1.
In embodiment 1, the user equipment in the application is distinguished in the first running time-frequency resource and the second running time-frequency resource
Send the first wireless signal and second wireless singal.Wherein, first running time-frequency resource and second running time-frequency resource wrap respectively
Include positive integer resource particle;First bit block and the second bit block are respectively used to generate first wireless signal and described
Second wireless singal, first bit block and second bit block respectively include positive integer bit;First bit
Block includes the first control information, and whether first bit block includes the first data and the first control occupied ratio of information
Special quantity is related;Second bit block includes the second data.
As one embodiment, the first control information includes the bit that positive integer is arranged successively.
As one embodiment, first data include the bit that positive integer is arranged successively.
As one embodiment, second data include the bit that positive integer is arranged successively.
As one embodiment, first bit block includes the bit that positive integer is arranged successively.
As one embodiment, second bit block includes the bit that positive integer is arranged successively.
As one embodiment, the resource particle is RE (ResourceElement).
As one embodiment, the resource particle occupies the duration of a multicarrier symbol in time domain, in frequency domain
Occupy the bandwidth of a subcarrier.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is OFDM symbol.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is DFT-S-OFDM symbol.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is FBMC symbol.
As one embodiment, there is no a resource particle belong to simultaneously first running time-frequency resource and it is described second when
Frequency resource.
As one embodiment, the second wireless singal is that second bit block successively passes through channel coding
(ChannelCoding), modulation mapper (Modulation Mapper), layer mapper (Layer Mapper), precoding
(Precoding), resource particle mapper (Resource Element Mapper), multicarrier symbol occur
(Generation) output after.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving (Interleaving).
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched (rate matching).
As one embodiment, the second wireless singal is that second bit block successively passes through channel coding, modulation
Mapper, layer mapper, conversion precoder (transform precoder, for generating complex valued signals), precoding, money
Source particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving.
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched.
As one embodiment, first wireless signal is that first bit block successively passes through channel coding, modulation
Mapper, layer mapper, precoding, resource particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving.
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched.
As one embodiment, first wireless signal is that first bit block successively passes through channel coding, modulation
Mapper, layer mapper, conversion precoder, precoding, resource particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, the channel coding includes interweaving.
As a sub- embodiment of above-described embodiment, the channel coding includes rate-matched.
As one embodiment, first bit block includes M the first sub-blocks of bits, the M the first sub-blocks of bits
M the first coded-bit sub-blocks are obtained by channel coding respectively, the M the first coded-bit sub-blocks are by multiplexing
(Multiplexing) the first coded blocks of bits is obtained, first coded blocks of bits be used to generate first wireless communication
Number;The M is positive integer, and any first sub-blocks of bits in the M the first sub-blocks of bits includes positive integer bit, described
Any first coded-bit sub-block in M the first coded-bit sub-blocks includes positive integer bit, first coded-bit
Block includes positive integer bit.
As a sub- embodiment of above-described embodiment, first wireless signal be first coded blocks of bits successively
By modulation mapper, layer mapper, precoding, resource particle mapper, the output after multicarrier symbol generation.
As a sub- embodiment of above-described embodiment, first wireless signal be first coded blocks of bits successively
By modulation mapper, layer mapper, conversion precoder, precoding, resource particle mapper, after multicarrier symbol occurs
Output.
As a sub- embodiment of above-described embodiment, first coded blocks of bits is the M the first coded-bits
Made of sub-block cascade.
As a sub- embodiment of above-described embodiment, bit included by the first control information belongs to the M
First sub-blocks of bits in first sub-blocks of bits.
As a sub- embodiment of above-described embodiment, bit included by first data belongs to the M first
First sub-blocks of bits in sub-blocks of bits.
As a sub- embodiment of above-described embodiment, bit included by the first control information and first number
Belong to same first sub-blocks of bits in the M the first sub-blocks of bits according to included bit.
As a sub- embodiment of above-described embodiment, bit included by the first control information and first number
Belong to two the first sub-blocks of bits different in the M the first sub-blocks of bits according to included bit.
As a sub- embodiment of above-described embodiment, the M is equal to 1.
As a sub- embodiment of above-described embodiment, the M is equal to 2.
As a sub- embodiment of above-described embodiment, the M is greater than 2.
As one embodiment, the first control information is UCI.
As one embodiment, the first control information includes { CSI, PMI, CQI, band amplitude coefficient
(WidebandAmplitudeCoefficient), PRI, subband range coefficient (Subband Amplitude
Coefficient), subband phase coefficient (Subband Phase Coefficient) } one of or it is a variety of.
As one embodiment, the first control information is sightless to MAC layer.
As one embodiment, the first control information is generated by physical layer.
As one embodiment, first data and second data belong to the same TB.
As one embodiment, first data and second data respectively include in the same TB not on year-on-year basis
It is special.
As one embodiment, first data and second data are identical.
As one embodiment, first data include physical layer data.
As one embodiment, first data only include information bit (not including check bit).
As a sub- embodiment of above-described embodiment, the check bit is CRC bit.
As a sub- embodiment of above-described embodiment, the check bit is generated by CRC bit.
As a sub- embodiment of above-described embodiment, the check bit is by CRC bit by obtaining after scrambling code.
As one embodiment, second data include physical layer data.
As one embodiment, second data only include information bit (not including check bit).
As a sub- embodiment of above-described embodiment, the check bit is CRC bit.
As a sub- embodiment of above-described embodiment, the check bit is generated by CRC bit.
As a sub- embodiment of above-described embodiment, the check bit is by CRC bit by obtaining after scrambling code.
As one embodiment, the transmission channel for carrying first data is UL-SCH.
As one embodiment, the transmission channel for carrying second data is UL-SCH.
As one embodiment, for carrying the transmission channel of first data and for carrying second data
Transmission channel is the same UL-SCH.
As one embodiment, first running time-frequency resource and second running time-frequency resource belong to the same physical layer letter
Road.
As a sub- embodiment of above-described embodiment, the physical layer channel is that upstream physical layer data channel (can
It is used for transmission the up channel of physical layer data).
As a sub- embodiment of above-described embodiment, the physical layer channel is PUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is sPUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is NR-PUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is NB-PUSCH.
As one embodiment, first wireless signal and the second wireless singal are in the same physical layer channel
Transmission.
As a sub- embodiment of above-described embodiment, the physical layer channel is that upstream physical layer data channel (can
For carrying the up channel of physical layer data).
As a sub- embodiment of above-described embodiment, the physical layer channel is PUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is sPUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is NR-PUSCH.
As a sub- embodiment of above-described embodiment, the physical layer channel is NB-PUSCH.
As one embodiment, if the quantity of the first control occupied bit of information is greater than first threshold, institute
Stating the first bit block not includes first data;If it is described first control the occupied bit of information quantity be less than or
Equal to the first threshold, first bit block includes first data;The first threshold is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
As one embodiment, the quantity for the bit that first data include and the first control information are occupied
The quantity of bit is related.
As one embodiment, the quantity of the first control occupied bit of information is used for determining first number
According to the quantity for the bit for including.
As one embodiment, when the quantity of the first control occupied bit of information is equal to A1, described first
The quantity for the bit that data include is equal to B1;It is described when the quantity of the first control occupied bit of information is equal to A2
The quantity for the bit that first data include is equal to B2;The A1, the B1, the A2 and the B2 are positive integer respectively;It is described
A2 is greater than the A1, and the B2 is not more than the B1.
As one embodiment, the quantity for the bit that second data include and the first control information are occupied
The quantity of bit is related.
As one embodiment, when the quantity of the first control occupied bit of information is greater than first threshold, institute
The quantity for stating the bit that the second data include is equal to C1;When it is described first control the occupied bit of information quantity be less than or
When equal to the first threshold, the quantity for the bit that second data include is equal to C2;The C1 and C2 is just respectively
Integer;The C2 is greater than the C1.The first threshold is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
As one embodiment, the quantity for the resource particle that first running time-frequency resource includes is by the first control information
The maximum quantity for the bit that may be occupied determines.
Embodiment 2
Embodiment 2 illustrates the schematic diagram of the network architecture, as shown in Fig. 2.
Attached drawing 2 illustrates LTE (Long-Term Evolution, long term evolution), LTE-A (Long-Term
Evolution Advanced, enhance long term evolution) and future 5G system the network architecture 200.LTE network framework 200 can claim
For EPS (Evolved Packet System, evolved packet system) 200.EPS 200 may include one or more UE
(User Equipment, user equipment) 201, E-UTRAN-NR (evolution UMTS Terrestrial Radio Access Network network-is new wireless)
202,5G-CN (5G-CoreNetwork, 5G core net)/EPC (Evolved Packet Core, evolution block core) 210,
HSS (Home Subscriber Server, home signature user server) 220 and Internet service 230.Wherein, UMTS pairs
Answer universal mobile telecommunications service (Universal Mobile Telecommunications System).EPS can connect with other
Enter network interconnection, but in order to not show these entity/interfaces simply.As shown in Fig. 2, EPS offer packet-switched services, however institute
The technical staff in category field will be apparent that each conception of species presented through the application, which extends to, provides circuit switched service
Network.E-UTRAN-NR includes NR (NewRadio, new wireless) node B (gNB) 203 and other gNB204.GNB203 provides court
User and control plane protocol terminations to UE201.GNB203 can be connected to other via X2 interface (for example, backhaul)
gNB204.GNB203 is alternatively referred to as base station, base transceiver station, radio base station, radio transceiver, transceiver function, basic
Set of service (BSS), expansion service set (ESS), TRP (transmitting and receiving point) or some other suitable term.GNB203 is
UE201 provides the access point to 5G-CN/EPC210.The example of UE201 includes cellular phone, smart phone, conversation start association
Discuss (SIP) phone, laptop computer, personal digital assistant (PDA), satelline radio, global positioning system, multimedia dress
It sets, video-unit, digital audio-frequency player (for example, MP3 player), camera, game console, unmanned plane, aircraft, narrowband
Physical Network equipment, machine type communication device, land craft, automobile, wearable device or any other like function dress
It sets.Those skilled in the art UE201 can also be known as mobile station, subscriber stations, mobile unit, subscriber unit, radio-cell,
Remote unit, mobile device, wireless device, wireless communication device, remote-control device, mobile subscriber stations, access terminal, movement are eventually
End, wireless terminal, remote terminal, hand-held set, user agent, mobile client, client or some other suitable term.
GNB203 is connected to 5G-CN/EPC210 by S1 interface.5G-CN/EPC210 includes MME 211, other MME214, S-GW
(Service Gateway, gateway) 212 and P-GW (Packet Date Network Gateway, Packet Data Network
Network diagram closes) 213.MME211 is the control node for handling the signaling between UE201 and 5G-CN/EPC210.Generally, MME211
Carrying and connection management are provided.All User IP (Internet Protocal, Internet Protocol) packets are passed by S-GW212
It send, S-GW212 is itself coupled to P-GW213.P-GW213 provides the distribution of UE IP address and other functions.P-GW213 connection
To Internet service 230.Internet service 230 includes that operator corresponds to the Internet protocol service, specifically may include internet, interior
Networking, IMS (IP Multimedia Subsystem, IP multimedia subsystem) and PS streaming service (PSS).
As one embodiment, the UE201 corresponds to the user equipment in the application.
As one embodiment, the gNB203 corresponds to the base station in the application.
Embodiment 3
Embodiment 3 illustrates user plane and controls the schematic diagram of the embodiment of the radio protocol architecture of plane, such as attached drawing 3
It is shown.
Attached drawing 3 is schematic diagram of the explanation for the embodiment of user plane and the radio protocol architecture for controlling plane, attached
Fig. 3 shows the radio protocol architecture for being used for UE and gNB: layer 1, layer 2 and layer 3 with three layers.1 (L1 layers) of layer are lowermost layer and reality
Apply various PHY (physical layer) signal processing function.L1 layers are referred to as PHY301 herein.Layer 2 (L2 layers) 305 PHY301 it
On, and be responsible for passing through link of the PHY301 between UE and gNB.In user plane, L2 layer 305 includes MAC (Medium
Access Control, media access control) sublayer 302, RLC (Radio Link Control, radio link layer control association
View) sublayer 303 and PDCP (Packet Data Convergence Protocol, Packet Data Convergence Protocol) sublayer 304,
These sublayers terminate at the gNB on network side.Although it is not shown, but UE can have several protocol layers on L2 layer 305,
Including terminating at the network layer (for example, IP layers) at the P-GW213 on network side and terminating at the other end of connection (for example, remote
Hold UE, server etc.) at application layer.PDCP sublayer 304 provides the multichannel between different radio carrying and logic channel
Multiplexing.PDCP sublayer 304 also provides the header compressed for upper layer data packet to reduce radio transmitting expense, by encrypting number
Safety is provided according to packet, and the handover to UE provided between gNB is supported.Rlc sublayer 303 provides upper layer data packet
Segmentation and Reassembly dress, lost data packets re-emit and data packet reorder with compensate as caused by HARQ it is unordered
It receives.Media access control sublayer 302 provides the multiplexing between logical AND transport channel.Media access control sublayer 302 is also responsible for distributing between UE
Various radio resources (for example, resource block) in one cell.Media access control sublayer 302 is also responsible for HARQ operation.In control plane
In, the radio protocol architecture for UE and gNB is substantially the same for physical layer 301 and L2 layer 305, but is not used for
Control the header compressed function of plane.Control plane further include in layer 3 (L3 layers) RRC (Radio Resource Control,
Radio resource control) sublayer 306.RRC sublayer 306 be responsible for obtain radio resource (that is, radio bearer) and using gNB with
RRC signaling between UE configures lower layer.
The user equipment of the radio protocol architecture suitable for the application as one embodiment, in attached drawing 3.
The base station of the radio protocol architecture suitable for the application as one embodiment, in attached drawing 3.
As one embodiment, first wireless signal in the application is created on the PHY301.
As one embodiment, the second wireless singal in the application is created on the PHY301.
As one embodiment, the third wireless signal in the application is created on the PHY301.
As a sub- embodiment, first data in the application are created on the media access control sublayer 302.
As a sub- embodiment, first data in the application are created on several associations on the L2 layer 305
Discuss layer.
As a sub- embodiment, second data in the application are created on the media access control sublayer 302.
As a sub- embodiment, second data in the application are created on several associations on the L2 layer 305
Discuss layer.
As one embodiment, the first control information in the application is created on the PHY301.
As one embodiment, the second control information in the application is created on the PHY301.
As one embodiment, first bit block in the application is created on the PHY301.
As one embodiment, second bit block in the application is created on the PHY301.
As one embodiment, first sub-blocks of bits in the application is created on the PHY301.
As one embodiment, second sub-blocks of bits in the application is created on the PHY301.
As one embodiment, the first check bit block in the application is created on the PHY301.
As one embodiment, the second check bit block in the application is created on the PHY301.
As one embodiment, the third check bit block in the application is created on the PHY301.
As one embodiment, the 4th check bit block in the application is created on the PHY301.
As a sub- embodiment, first signaling in the application is created on the PHY301.
As a sub- embodiment, second signaling in the application is created on the PHY301.
Embodiment 4
Embodiment 4 illustrates NR node and the schematic diagram of UE, as shown in Fig. 4.Attached drawing 4 is phase intercommunication within the access network
The block diagram of the UE450 and gNB410 of letter.
GNB410 includes controller/processor 475, and memory 476 receives processor 470, transmited processor 416, channel
Encoder 477, channel decoder 478, emitter/receiver 418 and antenna 420.
UE450 includes controller/processor 459, memory 460, data source 467, transmited processor 468, reception processing
Device 456, channel encoder 457, channel decoder 458, emitter/receiver 454 and antenna 452.
In DL (Downlink, downlink), at gNB, the upper layer data packet from core network be provided to controller/
Processor 475.Controller/processor 475 implements L2 layers of functionality.In DL, controller/processor 475 provides header pressure
Contracting, encryption, packet are segmented and reorder, the multiplexing between logical AND transport channel, and based on the measurement pair of various priority
The radio resource of UE450 is allocated.Controller/processor 475 is also responsible for HARQ operation, lost package re-emits, and
To the signaling of UE450.Transmited processor 416 and channel encoder 477 are implemented at the various signals for L1 layers (that is, physical layer)
Manage function.Channel encoder 477 implements coding and is interleaved to promote the forward error correction (FEC) at UE450.Transmited processor
416 implement based on various modulation schemes (for example, binary phase shift keying (BPSK), quadrature phase shift keying (QPSK), M phase-shift keying (PSK)
(M-PSK), M quadrature amplitude modulation (M-QAM)) signal cluster mapping, and the symbol after encoded and modulated is carried out
Spatial pre-coding/beam shaping processing, generates one or more spatial flows.Transmited processor 416 then reflects each spatial flow
It is mapped to subcarrier, is multiplexed in the time and/or frequency domain with reference signal (for example, pilot tone), and then uses quick Fourier
The physical channel of leaf inverse transformation (IFFT) generation carrying time domain multi-carrier symbols stream.Each transmitter 418 is transmited processor 416
The base band multicarrier symbol circulation chemical conversion RF flow of offer, is subsequently provided different antennae 420.
In DL (Downlink, downlink), at UE450, each receiver 454 receives letter by its respective antenna 452
Number.Each receiver 454 restores the information being modulated on radio-frequency carrier, and RF flow is converted to base band multicarrier symbol stream and is mentioned
It is supplied to and receives processor 456.Receive the various signal processing functions of L1 layers of processor 456 and the implementation of channel decoder 458.It receives
Base band multicarrier symbol stream is transformed into frequency domain from time domain using Fast Fourier Transform (FFT) by processor 456.In frequency domain, object
Reason layer data signal and reference signal are received the demultiplexing of processor 456, and wherein reference signal will be used for channel estimation, physics
Layer data is resumed out the spatial flow using UE450 as destination by multiple antennas detection in receiving processor 456.Each space
Symbol on stream is demodulated and restores in receiving processor 456, and generates soft decision.The subsequent decoding of channel decoder 458 and
Soft decision described in release of an interleave is to restore on the physical channel by the upper layer data of gNB410 transmitting and control signal.Then by upper layer
Data and control signal are provided to controller/processor 459.Controller/processor 459 implements L2 layers of function.Controller/place
Managing device can be associated with the memory 460 of storage program code and data.Memory 460 can be described as computer-readable media.?
In DL, controller/processor 459 provides demultiplexing, package-restructuring dress, decryption, header between conveying and logic channel and decompresses
Contracting, control signal processing are to restore the upper layer data packet from core network.Then upper layer data packet is provided on L2 layers
All protocol layers.Various control signals can also be provided to L3 to be used for L3 processing.Controller/processor 459 is also responsible for making
Error detection is carried out with confirmation (ACK) and/or negative confirmation (NACK) agreement to support HARQ operation.
In UL (Uplink, uplink), at UE450, upper layer data packet is provided to control using data source 467
Device/processor 459.Data source 467 indicates all protocol layers on L2 layers.Similar to the hair at the gNB410 described in DL
Send function, controller/processor 459 implements header compressed, encryption, packet segmentation and again based on the radio resource allocation of gNB410
The L2 layer function of plane is implemented for user plane and is controlled in multiplexing between sequence and logical AND transport channel.Control
Device/processor 459 processed is also responsible for HARQ operation, lost package re-emits, and to the signaling of gNB410.Channel encoder 457
Implement channel coding, modulation and multiple antennas spatial pre-coding/wave beam of the data after coding by the implementation of transmited processor 468
Excipient processing is modulated into multicarrier/single-carrier symbol stream, then provides via transmitter 454 and arrive different antennae 452.Each hair
The baseband symbol stream that transmited processor 468 provides is converted to radio frequency symbol stream first by emitter 454, then provides antenna 452.
The reception function at the UE450 being functionally similar to described in DL in UL (Uplink, uplink), at gNB410
Energy.Each receiver 418 receives radiofrequency signal by its respective antenna 420, and the radiofrequency signal received is converted to base band letter
Number, and baseband signal is provided to reception processor 470.Receive L1 layers of processor 470 and 478 common implementing of channel decoder
Function.Controller/processor 475 implements L2 layer function.Controller/processor 475 can be deposited with storage program code and data
Reservoir 476 is associated.Memory 476 can be described as computer-readable media.In UL, controller/processor 475 provide conveying with
Demultiplexing, package-restructuring dress, decryption, header decompression, control signal processing between logic channel is to restore from UE450's
Upper layer data packet.Upper layer data packet from controller/processor 475 can provide core network.Controller/processor 475
It is also responsible for carrying out error detection using ACK and/or NACK agreement to support HARQ operation.
As one embodiment, the UE450 includes: at least one processor and at least one processor, it is described extremely
A few memory includes computer program code;At least one processor and the computer program code are configured to
It is used together at least one described processor.
As one embodiment, the UE450 includes: a kind of memory for storing computer-readable instruction program, described
The generation when being executed by least one processor of computer-readable instruction program acts, and the movement includes: in this application
First wireless signal in the application, second running time-frequency resource in this application are sent in first running time-frequency resource
The second wireless singal in middle transmission the application is sent in the application in the third running time-frequency resource in this application
The third wireless signal generates the first check bit block in the application, generates second verification in the application
Bit block generates the third check bit block in the application, generates the 4th check bit block in the application, executes
First channel coding in the application executes the second channel coding in the application, executes described in the application
Third channel coding executes the 4th channel coding in the application, receives first signaling in the application, receives this
Second signaling in application.
As one embodiment, the gNB410 includes: at least one processor and at least one processor, it is described extremely
A few memory includes computer program code;At least one processor and the computer program code are configured to
It is used together at least one described processor.
As a sub- embodiment, the gNB410 includes: a kind of memory for storing computer-readable instruction program, institute
It states the generation when being executed by least one processor of computer-readable instruction program to act, the movement includes: in this application
First running time-frequency resource in receive the application in first wireless signal, in this application second time-frequency money
The second wireless singal in the application is received in source, is received in the application in the third running time-frequency resource in this application
The third wireless signal, restore the application in the first check bit block, restore the application in second school
Bit block is tested, the third check bit block in the application is restored, restores the 4th check bit block in the application, holds
First channel decoding in row the application executes the second channel decoding in the application, executes the institute in the application
Third channel decoding is stated, the 4th channel decoding in the application is executed, sends first signaling in the application, is sent
Second signaling in the application.
As one embodiment, the UE450 corresponds to the user equipment in the application.
As one embodiment, the gNB410 corresponds to the base station in the application.
As one embodiment, { antenna 420, the receiver 418, the reception processor 470, the channel
Decoder 478, the controller/processor 475 } at least one of be used to receive first wireless signal;{ the day
Line 452, the transmitter 454, the transmited processor 468, the channel encoder 457, the controller/processor 459 }
At least one of be used to send first wireless signal.
As one embodiment, { antenna 420, the receiver 418, the reception processor 470, the channel
Decoder 478, the controller/processor 475 } at least one of be used to receive the second wireless singal;{ the day
Line 452, the transmitter 454, the transmited processor 468, the channel encoder 457, the controller/processor 459 }
At least one of be used to send the second wireless singal.
As one embodiment, { antenna 420, the receiver 418, the reception processor 470, the channel
Decoder 478, the controller/processor 475 } at least one of be used to receive the third wireless signal;{ the day
Line 452, the transmitter 454, the transmited processor 468, the channel encoder 457, the controller/processor 459 }
At least one of be used to send the third wireless signal.
As one embodiment, { antenna 452, the receiver 454, the reception processor 456, the channel
Decoder 458, the controller/processor 459 } at least one of be used to receive first signaling;{ the antenna
420, the transmitter 418, the transmited processor 416, the channel encoder 477, the controller/processor 475 } in
At least one of be used to send first signaling.
As one embodiment, { antenna 452, the receiver 454, the reception processor 456, the channel
Decoder 458, the controller/processor 459 } at least one of be used to receive second signaling;{ the antenna
420, the transmitter 418, the transmited processor 416, the channel encoder 477, the controller/processor 475 } in
At least one of be used to send second signaling.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Generate the first check bit block;At least one of the reception processor 470 and the channel decoder 478 are used for
Restore the first check bit block.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Generate the second check bit block;At least one of the reception processor 470 and the channel decoder 478 are used for
Restore the second check bit block.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Generate the third check bit block;At least one of the reception processor 470 and the channel decoder 478 are used for
Restore the third check bit block.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Generate the 4th check bit block;At least one of the reception processor 470 and the channel decoder 478 are used for
Restore the 4th check bit block.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Execute first channel coding;At least one of the reception processor 470 and the channel decoder 478 be used to hold
Row first channel decoding.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Execute the second channel coding;At least one of the reception processor 470 and the channel decoder 478 be used to hold
The row second channel decoding.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Execute the third channel coding;At least one of the reception processor 470 and the channel decoder 478 be used to hold
The row third channel decoding.
As one embodiment, at least one of the transmited processor 468 and the channel encoder 457 are used for
Execute the 4th channel coding;At least one of the reception processor 470 and the channel decoder 478 be used to hold
Row the 4th channel decoding.
Embodiment 5
Embodiment 5 illustrates the flow chart of wireless transmission, as shown in Fig. 5.In figure 5, base station N1 is user equipment
The serving cell of U2 maintains base station.In attached drawing 5, the step in box F501 to box F506 is optional respectively, wherein box
Step in F502 and box F504 is existed simultaneously or is not present simultaneously;Step in box F503 and box F505 is deposited simultaneously
Or be simultaneously not present.
For N1, the first signaling is sent in step s101;In step s 11 in the first running time-frequency resource, the second time-frequency money
The first wireless signal, second wireless singal and third wireless signal are received in source and third running time-frequency resource respectively;In step S102
The first channel decoding of middle execution;Restore the first check bit block, third check bit block and the 4th verification ratio in step s 103
Special block;Second channel decoding is executed in step s 12;Restore the second check bit block in step s 13;It is held in step S104
Row third channel decoding;The 4th channel decoding is executed in step S14;The second signaling is sent in step s105.
For U2, the first signaling is received in step s 201;The first check bit block, third school are generated in step S202
Test bit block and the 4th check bit block;The first channel coding is executed in step S203;The second verification is generated in the step s 21
Bit block;Second channel coding is executed in step S22;Third channel coding is executed in step S204;It is held in step S23
The 4th channel coding of row;It is sent respectively in the first running time-frequency resource, the second running time-frequency resource and third running time-frequency resource in step s 24
First wireless signal, second wireless singal and third wireless signal;The second signaling is received in step S205.
In embodiment 5, first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource wrap respectively
Include positive integer resource particle;First bit block and the second bit block are respectively by the U2 for generating first wireless signal
With the second wireless singal, first bit block and second bit block respectively include positive integer bit;Described
One bit block includes the first control information, and whether first bit block includes shared by the first data and the first control information
The quantity of bit is related;Second bit block includes the second data.The third wireless signal includes the second control letter
Breath, the quantity of the first control occupied bit of information and second control are information-related.First check bit
Block, the second check bit block, the third check bit block and the 4th check bit block respectively include positive integer
Bit.Bit in first data splitting is by the U2 for generating the first check bit block, first data splitting
Including the bit in first data and the bit in second data.Second bit block includes second school
Bit block is tested, the bit in second data is by the U2 for generating the second check bit block, second verification
Bit block is unrelated with the bit in first data.Bit in second data splitting is by the U2 for generating the third
Check bit block, second data splitting include the ratio in partial bit and second data in first data
It is special.Bit in first remaining data is by the U2 for generating the 4th check bit block, the first remaining data packet
Include the bit in first data and except second data splitting.The input of first channel coding includes described
Bit in one data, the output of first channel coding is by the U2 for generating the first wireless subsignal.The third
The input of channel coding includes the bit in the first control information, and the output of the third channel coding is used for by the U2
Generate the second wireless subsignal.If first bit block includes first data, first wireless signal includes institute
State in the first wireless subsignal and the second wireless subsignal at least the former;Otherwise first wireless signal includes described
Second wireless subsignal.The input of the second channel coding is second bit block, the output of the second channel coding
By the U2 for generating the second wireless singal.The input of 4th channel coding includes in the second control information
Bit;The output of 4th channel coding is by the U2 for generating third wireless signal.First channel decoding,
The second channel decoding, the third channel decoding, the 4th channel decoding } it is { first channel coding, institute respectively
State second channel coding, the third channel coding, the 4th channel coding } corresponding channel decoding.Second signaling
By the U2 for determine whether first data are correctly received, and whether second data are correctly received, described the
At least one of whether two data splittings are correctly received, and whether first remaining data is correctly received }.Described first
Signaling includes the first running time-frequency resource set and the first configuration information, and the first running time-frequency resource set includes positive integer resource grains
Son;First running time-frequency resource, second running time-frequency resource and the third running time-frequency resource belong to first running time-frequency resource
Gather, position and described first of the resource particle in the first running time-frequency resource set included by first running time-frequency resource
Signaling is unrelated;Position of the resource particle included by the third running time-frequency resource in the first running time-frequency resource set and described
First signaling is unrelated.First configuration information includes { modulation coding scheme, the configuration information of demodulated reference signal, redundancy version
At least one of this, new data instruction };First configuration information is suitable for the described first wireless subsignal and described second
At least the latter in wireless signal.
As one embodiment, first data and second data belong to the same TB.
As one embodiment, first data and second data respectively include in the same TB not on year-on-year basis
It is special.
As one embodiment, for carrying the transmission channel of first data and for carrying second data
Transmission channel is the same UL-SCH.
As one embodiment, first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource are all
Belong to the same physical layer channel.
As one embodiment, first wireless signal, the second wireless singal and the third wireless signal exist
It is transmitted in the same physical layer channel.
As one embodiment, if the quantity of the first control occupied bit of information is greater than first threshold, institute
Stating the first bit block not includes first data;If it is described first control the occupied bit of information quantity be less than or
Equal to the first threshold, first bit block includes first data;The first threshold is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
As one embodiment, the quantity of the first control occupied bit of information is by the N1 for described in determination
Whether the first bit block includes first data.
As one embodiment, first bit block does not include first data, box F502 and side in attached drawing 5
Frame F504 is not present.
As a sub- embodiment of above-described embodiment, first wireless signal is the described second wireless subsignal.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for the second wireless singal.
As a sub- embodiment of above-described embodiment, second signaling is by the U2 for determining second data
Whether it is correctly received.
As one embodiment, first bit block includes first data, box F502 and box in attached drawing 5
F504 exists.
As a sub- embodiment of above-described embodiment, first wireless signal includes the described first wireless subsignal.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for { the described first wireless son letter
Number, the second wireless singal }.
As a sub- embodiment of above-described embodiment, second signaling is by the U2 for determining { first number
Whether according to being correctly received, whether second data are correctly received }.
As a sub- embodiment of above-described embodiment, second signaling is by the U2 for determining { described second group
Close whether data are correctly received, whether first remaining data is correctly received }.
As one embodiment, the quantity for the bit that first data include and the first control information are occupied
The quantity of bit is related.
As one embodiment, the quantity of the first control occupied bit of information is distinguished by the N1 and U2
For determining the quantity of bit that first data include.
As one embodiment, when the quantity of the first control occupied bit of information is equal to A1, described first
The quantity for the bit that data include is equal to B1;It is described when the quantity of the first control occupied bit of information is equal to A2
The quantity for the bit that first data include is equal to B2;The A1, the B1, the A2 and the B2 are positive integer respectively;It is described
A2 is greater than the A1, and the B2 is not more than the B1.
As one embodiment, the quantity of the first control occupied bit of information is by the N1 for described in determination
The quantity for the bit that first data include.
As one embodiment, the quantity for the resource particle that first running time-frequency resource includes is by the first control information
The maximum quantity for the bit that may be occupied determines.
As one embodiment, the bit in the first check bit block and the first control information is unrelated.
As one embodiment, first data splitting includes all bits and described in first data
All bits in two data.
As one embodiment, first data splitting is cascaded by first data and second data.
As one embodiment, the CRC bit block of first data splitting is by the U2 for generating first school
Test bit block.
As one embodiment, the N1 judges first data splitting according to the first check bit block of recovery
Whether it is correctly received.
As one embodiment, any bit given in the CRC bit block of bit block is equal in the given bit block
Positive integer bit sum to 2 modulus.
As one embodiment, first bit block includes first data, and the first check bit block is described
Third check bit block and the 4th check bit block.
As a sub- embodiment of above-described embodiment, box F502 and box F504 in attached drawing 5 exist.
As a sub- embodiment of above-described embodiment, first wireless signal includes the described first wireless subsignal.
As one embodiment, first bit block is by { the first control information, described first controls information
CRC bit block, first data, the first check bit block, the third check bit block, the 4th check bit
Block } composition.
As one embodiment, second data splitting includes partial bit and described in first data
Partial bit in two data.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Partial bit in cascades.
As one embodiment, second data splitting includes partial bit and described in first data
Whole bits in two data.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Whole bits in cascade.
As one embodiment, the CRC bit block of second data splitting is by the U2 for generating the third school
Test bit block.
As one embodiment, the N1 judges second data splitting according to the third check bit block of recovery
Whether it is correctly received.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and equal to bit included by maximum code block (Code Block) quantity.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to maximum code block length (maximum code block size).
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 8448.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 6144.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 3840.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 2560.
As one embodiment, the CRC bit block of first remaining data is by the U2 for generating the 4th school
Test bit block.
As one embodiment, the N1 judges first remaining data according to the 4th check bit block of recovery
Whether it is correctly received.
As one embodiment, the CRC bit block of second data is by the U2 for generating the second verification ratio
Special block.
As one embodiment, whether the N1 judges second data according to the second check bit block of recovery
It is correctly received.
As one embodiment, the input of first channel coding includes { first data, the first verification ratio
Special block, the third check bit block, the 4th check bit block }.
As one embodiment, the first wireless subsignal is by the N1 for generating the defeated of first channel decoding
Enter, the output of first channel decoding is by the N1 for restoring { first data, the first check bit block, institute
State third check bit block, the 4th check bit block }.
As one embodiment, the input of first channel coding does not include the first control information and described first
Control the CRC bit block of information.
As a sub- embodiment of above-described embodiment, box F503 and box F505 in attached drawing 5 exist.
As a sub- embodiment of above-described embodiment, first channel coding is based on LDPC code.
As a sub- embodiment of above-described embodiment, first wireless signal include the described first wireless subsignal and
The second wireless subsignal.
As a sub- embodiment of above-described embodiment, first wireless signal is by the described first wireless subsignal and institute
State the second wireless subsignal composition.
As one embodiment, the input of first channel coding is first bit block.
As a sub- embodiment of above-described embodiment, first wireless signal is the described first wireless subsignal.
As a sub- embodiment of above-described embodiment, box F503 and box F505 in attached drawing 5 are not present.
As a sub- embodiment of above-described embodiment, the input of first channel coding includes { first control
Information, the CRC bit block of the first control information, first data, the first check bit block, the third verification
Bit block, the 4th check bit block }.
As a sub- embodiment of above-described embodiment, first channel coding is based on polar code (polarization code).
As a sub- embodiment of above-described embodiment, the output of first channel decoding is by the N1 for restoring institute
State the first bit block.
As a sub- embodiment of above-described embodiment, first wireless signal is by the N1 for generating described first
The input of channel decoding.
As one embodiment, the input of the second channel coding includes { second data, the second verification ratio
Special block }.
As one embodiment, the second wireless singal is used to generate the defeated of the second channel decoding by the N1
Enter, the output of the second channel decoding is by the N1 for restoring second bit block.
As one embodiment, the second channel coding is based on LDPC code.
As one embodiment, the third channel coding is based on Polar code.
As one embodiment, the input of the third channel coding includes { the first control information, first control
The CRC bit block of information processed }.
As one embodiment, the second wireless subsignal is by the N1 for generating the defeated of the third channel decoding
Enter, by the N1, for restoring, { the first control information, described first controls information for the output of the third channel decoding
CRC bit block }.
As one embodiment, the second control information is by the N1 for determining occupied by the first control information
Bit quantity.
As one embodiment, the second control information indicates the number of the first control occupied bit of information
Amount.
As one embodiment, the 4th channel coding is based on Polar code.
As one embodiment, the input of the 4th channel coding includes { the second control information, second control
The CRC bit block of information processed }.
As one embodiment, the third wireless signal is by the N1 for generating the defeated of the 4th channel decoding
Enter, by the N1, for restoring, { the second control information, described second controls information for the output of the 4th channel decoding
CRC bit block }.
As one embodiment, the first control information includes UCI.
As one embodiment, the first control information includes { CSI, PMI, CQI, band amplitude coefficient
(WidebandAmplitudeCoefficient), PRI, subband range coefficient (Subband Amplitude
Coefficient), subband phase coefficient (Subband Phase Coefficient) } one of or it is a variety of.
As one embodiment, the second control information includes UCI.
As one embodiment, the second control information includes { CSI, RI, CRI, PMI, non-zero band amplitude coefficient
Number, CQI, band amplitude coefficient (WidebandAmplitudeCoefficient), PRI (Relative Power
Indicator, relative power instruction) one of or it is a variety of.
As one embodiment, second signaling is physical layer signaling.
As one embodiment, second signaling is transmitted on PHICH.
As one embodiment, first configuration information is not suitable for the described second wireless subsignal.
As one embodiment, first configuration information is not suitable for the third wireless signal.
As one embodiment, first signaling includes UpLink GrantDCI.
As one embodiment, first signaling (is simply possible to use in carrying physical layer in down physical layer control channel
The down channel of signaling) on transmit.
Embodiment 6
Embodiment 6 illustrates the flow chart of wireless transmission, as shown in Fig. 6.In figure 6, base station N3 is user equipment
The serving cell of U4 maintains base station.In attached drawing 6, the step in box F601 to box F607 is optional respectively, wherein box
Step in F603 and box F605 is existed simultaneously or is not present simultaneously;Step in box F604 and box F606 is deposited simultaneously
Or be simultaneously not present.
For N3, the first signaling is sent in step S301;Third is received in third running time-frequency resource in step s 302
Wireless signal;The 4th channel decoding is executed in step S303;In the first running time-frequency resource and the second running time-frequency resource in step S31
It is middle to receive the first wireless signal and second wireless singal respectively;The first channel decoding is executed in step s 304;In step S305
The first check bit block of middle recovery and the 4th check bit block;Second channel decoding is executed in step s 32;In step S33
Restore the second check bit block;Third channel decoding is executed in step S306;The second signaling is sent in step S307.
For U4, the first signaling is received in step S401;The 4th channel coding is executed in step S402;In step
Third wireless signal is sent in S403 in third running time-frequency resource;The first check bit block and the 4th school are generated in step s 404
Test bit block;The first channel coding is executed in step S405;The second check bit block is generated in step S41;In step S42
Middle execution second channel coding;Third channel coding is executed in step S406;In the first running time-frequency resource and in step S43
The first wireless signal and second wireless singal are sent in two running time-frequency resources respectively;The second signaling is received in step S 407.
In embodiment 6, first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource wrap respectively
Include positive integer resource particle;First bit block and the second bit block are respectively by the U4 for generating first wireless signal
With the second wireless singal, first bit block and second bit block respectively include positive integer bit;Described
One bit block includes the first control information, and whether first bit block includes shared by the first data and the first control information
The quantity of bit is related;Second bit block includes the second data.The third wireless signal includes the second control letter
Breath, the quantity of the first control occupied bit of information and second control are information-related.First check bit
Block, the second check bit block and the 4th check bit block respectively include positive integer bit.In first data splitting
Bit by the U4 for generating the first check bit block, first data splitting includes in first data
Bit in bit and second data.Second bit block includes the second check bit block, second number
Bit in is by the U4 for generating the second check bit block, the second check bit block and first data
In bit it is unrelated.Bit in first data is by the U4 for generating the 4th check bit block.Described first
The input of channel coding includes the bit in first data, and the output of first channel coding is by the U4 for generating
First wireless subsignal.The input of the third channel coding includes the bit in the first control information, the third letter
The output of road coding is by the U4 for generating the second wireless subsignal.If first bit block includes first number
According to, first wireless signal include in the described first wireless subsignal and the second wireless subsignal at least the former;It is no
Then first wireless signal includes the described second wireless subsignal.The input of the second channel coding is second bit
Block, the output of the second channel coding is by the U4 for generating the second wireless singal.4th channel coding
Input includes the bit in the second control information;The output of 4th channel coding by the U4 for generate third without
Line signal.{ first channel decoding, the second channel decoding, the third channel decoding, the 4th channel decoding }
It is that { first channel coding, the second channel coding, the third channel coding, the 4th channel coding } is right respectively
The channel decoding answered.Second signaling by the U4 for determine whether first data are correctly received, described second
Whether data are correctly received } at least the latter.First signaling includes that the first running time-frequency resource set and first match confidence
Breath, the first running time-frequency resource set includes positive integer resource particle;First running time-frequency resource and second time-frequency money
Source belongs to the first running time-frequency resource set, and resource particle included by first running time-frequency resource is provided in first time-frequency
Position and first signaling in the set of source is unrelated.First configuration information includes { modulation coding scheme, demodulation reference letter
Number configuration information, redundancy versions, new data instruction at least one of;First configuration information is suitable for described first
At least the latter in wireless subsignal and the second wireless singal.
As one embodiment, first bit block does not include first data, box F603 and side in attached drawing 6
Frame F605 is not present.
As a sub- embodiment of above-described embodiment, first wireless signal is the described second wireless subsignal.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for the second wireless singal.
As a sub- embodiment of above-described embodiment, second signaling is by the U4 for determining second data
Whether it is correctly received.
As one embodiment, first bit block includes first data, box F603 and box in attached drawing 6
F605 exists.
As a sub- embodiment of above-described embodiment, first wireless signal includes the described first wireless subsignal.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for { the described first wireless son letter
Number, the second wireless singal }.
As a sub- embodiment of above-described embodiment, second signaling is by the U4 for determining { first number
Whether according to being correctly received, whether second data are correctly received }.
As one embodiment, first data and second data belong to the same TB.
As one embodiment, first data and second data are identical.
As one embodiment, the quantity for the bit that second data include and the first control information are occupied
The quantity of bit is related.
As one embodiment, the quantity of the first control occupied bit of information is by the N3 for described in determination
The quantity for the bit that second data include.
As one embodiment, when the quantity of the first control occupied bit of information is greater than first threshold, institute
The quantity for stating the bit that the second data include is equal to C1;When it is described first control the occupied bit of information quantity be less than or
When equal to the first threshold, the quantity for the bit that second data include is equal to C2;The C1 and C2 is just respectively
Integer;The C2 is greater than the C1.The first threshold is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
As one embodiment, the CRC bit block of first data is by the U4 for generating the 4th verification ratio
Special block.
As one embodiment, whether the N3 judges first data according to the 4th check bit block of recovery
It is correctly received.
As one embodiment, first bit block includes { first data, the first check bit block, institute
State the 4th check bit block }.
As a sub- embodiment of above-described embodiment, box F603 and box F605 in attached drawing 6 exist.
As a sub- embodiment of above-described embodiment, first wireless signal includes the described first wireless subsignal.
As one embodiment, the CRC bit block of first data is by the U4 for generating the 4th verification ratio
Special block.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to maximum code block (Code Block) included by bit quantity positive integer times.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to the positive integer times of maximum code block length (maximum code block size).
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 8448.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 6144.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 3840.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 2560.
As one embodiment, the input of first channel coding includes { first data, the first verification ratio
Special block, the 4th check bit block }.
As one embodiment, the first wireless subsignal is by the N3 for generating the defeated of first channel decoding
Enter, the output of first channel decoding is by the N3 for restoring { first data, the first check bit block, institute
State the 4th check bit block }.
As one embodiment, the input of first channel coding does not include the first control information and described first
Control the CRC bit block of information.
As a sub- embodiment of above-described embodiment, box F604 and box F606 in attached drawing 6 exist.
As a sub- embodiment of above-described embodiment, first channel coding is based on LDPC code.
As a sub- embodiment of above-described embodiment, first wireless signal include the described first wireless subsignal and
The second wireless subsignal.
As a sub- embodiment of above-described embodiment, first wireless signal is by the described first wireless subsignal and institute
State the second wireless subsignal composition.
As one embodiment, the input of first channel coding is first bit block.
As a sub- embodiment of above-described embodiment, first wireless signal is the described first wireless subsignal.
As a sub- embodiment of above-described embodiment, box F604 and box F606 in attached drawing 6 are not present.
As a sub- embodiment of above-described embodiment, the input of first channel coding includes { first control
Information, the CRC bit block of the first control information, first data, the first check bit block, the 4th verification
Bit block }.
As a sub- embodiment of above-described embodiment, first channel coding is based on polar code (polarization code).
As a sub- embodiment of above-described embodiment, the output of first channel decoding is by the N3 for restoring institute
State the first bit block.
As a sub- embodiment of above-described embodiment, first wireless signal is by the N3 for generating described first
The input of channel decoding.
As one embodiment, first wireless signal and the second wireless singal are in the same physical layer channel
Transmission.
As one embodiment, first running time-frequency resource and second running time-frequency resource belong to a physical layer letter
Road.
As one embodiment, the third wireless signal (can be used for transmission physics in upstream physical layer data channel
The up channel of layer data) on transmit.
Embodiment 7
Embodiment 7 illustrates the first running time-frequency resource, the second running time-frequency resource, third running time-frequency resource and the first running time-frequency resource set
The schematic diagram of resource impact on time-frequency domain, as shown in Fig. 7.
In embodiment 7, the first running time-frequency resource set, first running time-frequency resource, second running time-frequency resource and
The third running time-frequency resource respectively includes positive integer resource particle.First running time-frequency resource, second running time-frequency resource and
The third running time-frequency resource belongs to the first running time-frequency resource set.The resource particle is RE (ResourceElement).
First wireless signal in the application, the third in the second wireless singal and the application in the application is wireless
Signal is sent on first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource respectively.Described first
Wireless signal includes the first wireless subsignal and the second wireless subsignal, and first data in the application be used to generate institute
The first wireless subsignal is stated, the first control information in the application be used to generate the described second wireless subsignal.
In fig. 7, the square of heavy line frame indicates the first running time-frequency resource set;The grid table of right oblique line filling
Show the resource particle occupied in first running time-frequency resource by the described second wireless subsignal;Described in the grid expression of dot filling
The resource particle occupied in first running time-frequency resource by the described first wireless subsignal;Blank boxes indicate second running time-frequency resource
In resource particle;The grid of left oblique line filling indicates the resource particle in the third running time-frequency resource.
As one embodiment, the resource particle occupies the duration of a multicarrier symbol in time domain, in frequency domain
Occupy the bandwidth of a subcarrier.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is OFDM symbol.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is DFT-S-OFDM symbol.
As a sub- embodiment of above-described embodiment, the multicarrier symbol is FBMC symbol.
As one embodiment, first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource divide
It is not two-by-two mutually orthogonal (not being overlapped).
As one embodiment, the quantity for the resource particle that first running time-frequency resource includes is by the first control information
The maximum quantity for the bit that may be occupied determines.
As one embodiment, resource particle included by first running time-frequency resource is in the first running time-frequency resource set
In position preset and (do not need to configure).
As one embodiment, resource particle included by first running time-frequency resource is in the first running time-frequency resource set
In position be default.
As one embodiment, resource particle included by the third running time-frequency resource is in the first running time-frequency resource set
In position preset and (do not need to configure).
As one embodiment, resource particle included by the third running time-frequency resource is in the first running time-frequency resource set
In position be default.
As one embodiment, the input of first channel coding does not include the first control information.
As one embodiment, first running time-frequency resource is integrated into time domain and occupies 1 time slot (slot).
As one embodiment, first running time-frequency resource is integrated into time domain and occupies 1 subframe (sub-frame).
As one embodiment, first running time-frequency resource is integrated into time domain and occupies 1 millisecond (ms).
As one embodiment, first running time-frequency resource is integrated into time domain and occupies multiple continuous time slots (slot).
As one embodiment, first running time-frequency resource is integrated into time domain and occupies multiple continuous subframe (sub-
frame)。
As one embodiment, first running time-frequency resource is integrated into time domain and occupies multiple continuous multicarrier symbols.
As one embodiment, first running time-frequency resource is integrated into time domain and occupies multiple discontinuous time slots (slot).
As one embodiment, first running time-frequency resource is integrated into time domain and occupies multiple discontinuous subframe (sub-
frame)。
As one embodiment, first running time-frequency resource is integrated into time domain and occupies multiple discontinuous multicarrier symbols.
As one embodiment, first running time-frequency resource is integrated into frequency domain and occupies the continuous subcarrier of positive integer.
Embodiment 8
Embodiment 8 illustrates the first running time-frequency resource, the second running time-frequency resource, third running time-frequency resource and the first running time-frequency resource set
The schematic diagram of resource impact on time-frequency domain, as shown in Fig. 8.
In embodiment 8, the first running time-frequency resource set, first running time-frequency resource, second running time-frequency resource and
The third running time-frequency resource respectively includes positive integer resource particle.First running time-frequency resource, second running time-frequency resource and
The third running time-frequency resource belongs to the first running time-frequency resource set.The resource particle is RE (ResourceElement).
First wireless signal in the application, the third in the second wireless singal and the application in the application is wireless
Signal is sent on first running time-frequency resource, second running time-frequency resource and the third running time-frequency resource respectively.In the application
First bit block be used to generate first wireless signal, first bit block includes the first control information, institute
State whether the first bit block includes that the first data are related with the first control quantity of the occupied bit of information.
In attached drawing 8, the square of heavy line frame indicates the first running time-frequency resource set;The grid table of right oblique line filling
Show the resource particle in first running time-frequency resource;Blank boxes indicate the resource particle in second running time-frequency resource;It is left oblique
The grid of line filling indicates the resource particle in the third running time-frequency resource.
As one embodiment, first bit block does not include first data, it is described first control information by with
In the generation first wireless subsignal.
As a sub- embodiment of above-described embodiment, the input of the third channel coding in the application includes described
Bit in first control information, the output of the third channel coding be used to generate the first wireless signal.
As one embodiment, first bit block includes first data, the first control information and described
First data be used to generate the described first wireless subsignal jointly.
As a sub- embodiment of above-described embodiment, the input of first channel coding in the application includes described
Bit in bit in first data and the first control information, the output of first channel coding be used to generate the
One wireless signal.
As one embodiment, first running time-frequency resource is integrated into frequency domain and occupies the discontinuous subcarrier of positive integer.
Embodiment 9
Embodiment 9 illustrates the schematic diagram of the content of the first bit block and the second bit block, as shown in Fig. 9.
In embodiment 9, first bit block includes { the first control information, the CRC bit of the first control information
Block, the first data, the first check bit block, third check bit block, the 4th check bit block };Second bit block includes
Second data and the second check bit block.The CRC bit block of first data splitting be used to generate the first check bit block,
First data splitting includes whole bits in first data and whole bits in second data.It is described
The CRC bit block of second data be used to generate the second check bit block.The CRC bit block of second data splitting is used for
The third check bit block is generated, second data splitting includes partial bit and described in first data
Whole bits in two data.The CRC bit block of first remaining data be used to generate the 4th check bit block, and described
One remaining data includes the bit in first data and except second data splitting.
In attached drawing 9, the square of left oblique line filling indicates the portion for belonging to second data splitting in first data
Point;If connected between bit block A and bit block B by curve with the arrow, this indicates that the bit in the bit block A is used for
Generate the bit in the bit block B.Wherein the bit block A can be { the first control information, in first data
Belong to the part of second data splitting, first remaining data, second data } in any one;The ratio
Special block B can be { the CRC bit block of the first control information, the first check bit block, second check bit
Block, the third check bit block, the 4th check bit block } in any one.
As one embodiment, first bit block and second bit block respectively include positive integer and are arranged successively
Bit.
As one embodiment, the first control information includes the bit that positive integer is arranged successively.
As one embodiment, first data include the bit that positive integer is arranged successively.
As one embodiment, second data include the bit that positive integer is arranged successively.
As one embodiment, first data splitting includes the bit that positive integer is arranged successively.
As one embodiment, second data splitting includes the bit that positive integer is arranged successively.
As one embodiment, the first check bit block includes the bit that positive integer is arranged successively.
As one embodiment, the second check bit block includes the bit that positive integer is arranged successively.
As one embodiment, the third check bit block includes the bit that positive integer is arranged successively.
As one embodiment, the 4th check bit block includes the bit that positive integer is arranged successively.
As one embodiment, first data only include information bit (not including CRC bit).
As one embodiment, second data only include information bit (not including CRC bit).
As one embodiment, first data splitting is by all bits and second number in first data
All bits in cascade.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Whole bits in cascade.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and equal to bit included by maximum code block (Code Block) quantity.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 8448.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 6144.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 3840.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 2560.
As one embodiment, in the quantity of the bit in first remaining data and the 4th check bit block
The quantity of bit and less than or equal to bit included by maximum code block (Code Block) quantity.
As one embodiment, the first check bit block is the CRC bit block of first data splitting.
As one embodiment, the first check bit block is passed through by the CRC bit block of first data splitting
It is obtained after scrambling code.
As one embodiment, the bit that the first check bit block is arranged successively by 8 is formed.
As one embodiment, the bit that the first check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the first check bit block is arranged successively by 24 is formed.
As one embodiment, the second check bit block is the CRC bit of all bits in second data
Block.
As one embodiment, the second check bit block is the CRC ratio by all bits in second data
Special block after scrambling code by obtaining.
As one embodiment, the bit that the second check bit block is arranged successively by 24 is formed.
As one embodiment, the bit that the second check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the second check bit block is arranged successively by 8 is formed.
As one embodiment, the third check bit block is the CRC bit block of second data splitting.
As one embodiment, the third check bit block is passed through by the CRC bit block of second data splitting
It is obtained after scrambling code.
As one embodiment, the bit that the third check bit block is arranged successively by 24 is formed.
As one embodiment, the bit that the third check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the third check bit block is arranged successively by 8 is formed.
As one embodiment, the 4th check bit block is the CRC bit block of first remaining data.
As one embodiment, the 4th check bit block is passed through by the CRC bit block of first remaining data
It is obtained after scrambling code.
As one embodiment, the bit that the 4th check bit block is arranged successively by 24 is formed.
As one embodiment, the bit that the 4th check bit block is arranged successively by 16 is formed.
As one embodiment, the bit that the 4th check bit block is arranged successively by 8 is formed.
As one embodiment, the CRC bit block of given bit block is given bit block by CRC circulation generator polynomial
The output of (cyclic generator polynomial);The given bit block includes positive integer bit.CRC's is specific
Technical detail is saved referring to the 5.1.1 in technical specification (TS-Technical Specification) 36.212.
As a sub- embodiment of above-described embodiment, the bit in the given bit block is sequentially inputted to described
CRC is recycled in generator polynomial, and the output of the CRC circulation generator polynomial is the CRC bit block of the given bit block.
As one embodiment, any bit given in the CRC bit block of bit block is equal in the given bit block
Positive integer bit sum to 2 modulus.
Embodiment 10
Embodiment 10 illustrates the schematic diagram of the content of the first bit block and the second bit block, as shown in Fig. 10.
In embodiment 10, first bit block includes { the first control information, the CRC ratio of the first control information
Special block, the first data, the first check bit block, third check bit block, the 4th check bit block };The second bit block packet
Include the second data and the second check bit block.The CRC bit block of first data splitting be used to generate first check bit
Block, first data splitting include whole bits in first data and whole bits in second data.
The CRC bit block of second data be used to generate the second check bit block.The CRC bit block quilt of second data splitting
For generating the third check bit block, second data splitting includes partial bit and institute in first data
State the partial bit in the second data.The CRC bit block of first remaining data be used to generate the 4th check bit block, institute
Stating the first remaining data includes the bit in first data and except second data splitting.
In fig. 10, the square of left oblique line filling indicates the portion for belonging to second data splitting in first data
Point;The square of right oblique line filling indicates the part for belonging to second data splitting in second data;The side of dot filling
Block indicates the part for belonging to not described second data splitting in second data;If by band between bit block A and bit block B
The curve of arrow connects, this indicates that the bit in the bit block A be used to generate the bit in the bit block B.Wherein institute
Stating bit block A can be that { the first control information, the part of second data splitting, institute are belonged in first data
The first remaining data is stated, the part of second data splitting is belonged in second data, is not belonging in second data
The part of second data splitting } in any one;The bit block B can be { the CRC ratio of the first control information
Special block, the first check bit block, the second check bit block, the third check bit block, the 4th verification ratio
Special block } in any one.
As one embodiment, the part that second data splitting is belonged in second data include positive integer according to
The bit of secondary arrangement.
As one embodiment, the part that second data splitting is not belonging in second data includes positive integer
The bit being arranged successively.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Partial bit in cascades.
Embodiment 11
Embodiment 11 illustrates the schematic diagram of the content of the first bit block and the second bit block, as shown in Fig. 11.
In embodiment 11, first bit block includes { the first control information, the CRC ratio of the first control information
Special block, the first data, the first check bit block, the 4th check bit block };Second bit block includes the second data and second
Check bit block.The CRC bit block of first data splitting be used to generate the first check bit block, first number of combinations
According to including whole bits in first data and whole bits in second data.The CRC of second data
Bit block be used to generate the second check bit block.The CRC bit block of first data be used to generate the described 4th
Check bit block.
In attached drawing 11, if connected between bit block A and bit block B by curve with the arrow, this indicates the bit
Bit in block A be used to generate the bit in the bit block B.Wherein the bit block A can be { the first control letter
Breath, first data, second data in any one;The bit block B can be { the first control information
CRC bit block, the first check bit block, the second check bit block, the 4th check bit block } in it is any
One.
As one embodiment, the 4th check bit block is the CRC bit block of all bits in first data.
As one embodiment, the 4th check bit block is by the CRC bit of all bits in first data
Block after scrambling code by obtaining.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to maximum code block (Code Block) included by bit quantity positive integer times.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to the positive integer times of maximum code block length (maximum code block size).
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 8448.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 6144.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 3840.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 2560.
Embodiment 12
Embodiment 12 illustrates the schematic diagram for generating the first wireless subsignal, as shown in Fig. 12.
In embodiment 12, the output of the first channel coding be used to generate the described first wireless subsignal, and described first
The input of channel coding is made of { the first data, the first check bit block, third check bit block, the 4th check bit block }.
The first wireless subsignal is that modulation mapper is successively passed through in the output of first channel coding, and layer mapper turns
Change precoder, precoding, resource particle mapper, the output after multicarrier symbol generation.Wherein, the behaviour in dashed rectangle
Work is optional.The first check bit block is generated by the CRC bit block of the first data splitting, the first data splitting packet
Include the bit in first data and the bit in second data in the application.The third check bit block by
The CRC bit block of second data splitting generates, second data splitting include partial bit in first data and
Bit in second data.The 4th check bit block is generated by the CRC bit block of the first remaining data, and described first
Remaining data includes the bit in first data and except second data splitting.
As one embodiment, { the first data, the first check bit block, third check bit block, the 4th check bit
Block } in the corresponding channel encoder of first channel coding is sequentially inputted to by bit.
As one embodiment, the input of first channel coding includes { whole bits in first data, institute
State whole bits in the first check bit block, whole bits in the third check bit block, the 4th check bit
Whole bits in block }.
As one embodiment, first channel coding is based on LDPC code.
As one embodiment, first channel coding includes interweaving (Interleaving).
As one embodiment, first channel coding includes rate-matched (rate matching).
As one embodiment, first data splitting is by all bits and second number in first data
All bits in cascade.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Partial bit in cascades.
As one embodiment, second data splitting is counted by the partial bit and described second in first data
Whole bits in cascade.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and equal to bit included by maximum code block (Code Block) quantity.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 8448.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 6144.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 3840.
As one embodiment, in the quantity of the bit in second data splitting and the third check bit block
The quantity of bit and be equal to 2560.
Embodiment 13
Embodiment 13 illustrates the schematic diagram for generating the first wireless subsignal, as shown in Fig. 13.
In embodiment 13, the output of the first channel coding be used to generate the described first wireless subsignal, and described first
The input of channel coding is made of { the first data, the first check bit block, the 4th check bit block }.Described first wireless son letter
It number is that modulation mapper, layer mapper are successively passed through in the output of first channel coding, conversion precoder prelists
Code, resource particle mapper, the output after multicarrier symbol generation.Wherein, the operation in dashed rectangle is optional.It is described
First check bit block is generated by the CRC bit block of the first data splitting, and first data splitting includes first data
In bit and the bit in second data in the application.The 4th check bit block is by first data
CRC bit block generates.
Bit as one embodiment, in the quantity of the bit in second data and the second check bit block
Quantity and be equal to the positive integer times of maximum code block length (maximum code block size).
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 8448.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 6144.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 3840.
As a sub- embodiment of above-described embodiment, the maximum code block length is equal to 2560.
As one embodiment, first channel coding is based on LDPC code.
Embodiment 14
Embodiment 14 illustrates the schematic diagram for generating the first wireless signal, as shown in Fig. 14.
In embodiment 14, the output of the first channel coding be used to generate first wireless signal, first letter
The input of road coding is the first bit block, and first bit block is by { the first control information, the CRC of the first control information
Bit block, the first data, the first check bit block, third check bit block, the 4th check bit block } composition.First nothing
Line signal is that modulation mapper is successively passed through in the output of first channel coding, layer mapper, conversion precoder, in advance
Coding, resource particle mapper, the output after multicarrier symbol generation.Wherein, the operation in dashed rectangle is optional.Institute
It states the first check bit block to be generated by the CRC bit block of the first data splitting, first data splitting includes first number
The bit in second data in bit and the application in.The third check bit block is by the second data splitting
CRC bit block generate, second data splitting includes partial bit and second data in first data
In bit.The 4th check bit block is generated by the CRC bit block of the first remaining data, and first remaining data includes
Bit in first data and except second data splitting.
As one embodiment, first channel coding is based on polar code (polarization code).
As one embodiment, first channel coding includes interweaving (Interleaving).
As one embodiment, first channel coding includes rate-matched (rate matching).
As one embodiment, the quantity of the first control occupied bit of information is greater than first threshold;Described
One threshold value is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
Embodiment 15
Embodiment 15 illustrates the schematic diagram for generating the first wireless signal, as shown in Fig. 15.
In embodiment 15, the output of the first channel coding and third channel coding be used to generate first nothing jointly
Line signal, the input of first channel coding are the first sub-blocks of bits #0, and the output of first channel coding is the first volume
Code sub-blocks of bits #0;The input of the third channel coding is the first sub-blocks of bits #1, and the output of the third channel coding is
First coded-bit sub-block #1.The first sub-blocks of bits #0 and the first sub-blocks of bits #1 constitutes described in the application
One bit block.The first sub-blocks of bits #0 is made of the CRC bit block of the first control information and the first control information;Institute
The first sub-blocks of bits #1 is stated to be made of { the first data, the first check bit block, the 4th check bit block }.The first verification ratio
Special block is generated by the CRC bit block of the first data splitting, first data splitting include the bit in first data with
And the bit in second data in the application.The 4th check bit block by first data CRC bit block
It generates.The first coded-bit sub-block #0 and the first coded-bit sub-block #1 gives birth to after being multiplexed (Multiplexing)
At the first coded blocks of bits.First wireless signal is that first coded blocks of bits successively passes through modulation mapper, and layer reflects
Emitter, conversion precoder, precoding, resource particle mapper, the output after multicarrier symbol generation.Wherein, dotted line side
Operation in frame is optional.
As one embodiment, first channel coding is based on LDPC code.
As one embodiment, first channel coding includes interweaving (Interleaving).
As one embodiment, first channel coding includes rate-matched (rate matching).
As one embodiment, the third channel coding is based on Polar code.
As one embodiment, the third channel coding includes interweaving (Interleaving).
As one embodiment, the third channel coding includes rate-matched (rate matching).
As one embodiment, first coded blocks of bits is by the first coded-bit sub-block #0 and described first
Made of coded-bit sub-block #1 cascade.
As one embodiment, the quantity of the first control occupied bit of information is greater than first threshold;Described
One threshold value is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
Embodiment 16
Embodiment 16 illustrates the schematic diagram for generating the first wireless signal, as shown in Fig. 16.
In embodiment 16, the output of third channel coding be used to generate first wireless signal.The third letter
The input of road coding is the first bit block, and first bit block is controlled the CRC of information by the first control information and described first
Bit block composition.First bit block does not include first data in the application.First wireless signal is described
Modulation mapper is successively passed through in the output of third channel coding, layer mapper, conversion precoder, precoding, and resource particle is reflected
Emitter, the output after multicarrier symbol generation.Wherein, the operation in dashed rectangle is optional.
As one embodiment, the quantity of the first control occupied bit of information is not more than first threshold;It is described
First threshold is greater than 1 positive integer.
As a sub- embodiment of above-described embodiment, the first threshold is configured by high-level signaling.
As one embodiment, the third channel coding is based on Polar code.
As one embodiment, the third channel coding includes interweaving (Interleaving).
As one embodiment, the third channel coding includes rate-matched (rate matching).
Embodiment 17
Embodiment 17 illustrates the schematic diagram for generating second wireless singal, as shown in Fig. 17.
In embodiment 17, the output of second channel coding be used to generate the second wireless singal.Second letter
The input of road coding is the second bit block, and second bit block is made of the second data and the second check bit block.Described
The CRC bit block of two data be used to generate the second check bit block.The second wireless singal is the second channel
Modulation mapper, layer mapper, conversion precoder, precoding, resource particle mapper, overloading are successively passed through in the output of coding
Output after the generation of wave symbol.Wherein, the operation in dashed rectangle is optional.
As one embodiment, the second channel coding is based on LDPC code.
As one embodiment, the second channel coding includes interweaving (Interleaving).
As one embodiment, the second channel coding includes rate-matched (rate matching).
Embodiment 18
Embodiment 18 illustrates the schematic diagram for generating third wireless signal, as shown in Fig. 18.
In embodiment 18, the output of the 4th channel coding be used to generate the third wireless signal.4th letter
The input of road coding is made of the CRC bit block of the second control information and the second control information.The third wireless signal
It is that modulation mapper, layer mapper, conversion precoder, precoding, resource are successively passed through in the output of the 4th channel coding
Particle mapper, the output after multicarrier symbol generation.Wherein, the operation in dashed rectangle is optional.
As one embodiment, the second control information includes the bit that positive integer is arranged successively.
As one embodiment, the 4th channel coding is based on Polar code.
Embodiment 19
Embodiment 19 illustrates the schematic diagram that bit in given information bit block be used to generate given check bit block, such as
Shown in attached drawing 19.
In embodiment 19, the CRC bit block of the given information bit block be used to generate the given check bit
Block.The CRC bit block of the given information bit block is the given information bit block by CRC circulation generator polynomial
Output after (cyclic generator polynomial).For generating the CRC bit block of the given information bit block
The block diagram of circuit is as shown in attached drawing 19.{ the given information bit block, the given check bit block } is { { in the application
The first control information, the CRC bit block of the first control information }, { the second control information in the application, institute
State the CRC bit block of the second control information }, { first data in the application, the 4th check bit in the application
Block }, { second data in the application, the second check bit block in the application }, { described first in the application
Data splitting, the first check bit block in the application }, { second data splitting in the application, in the application
The third check bit block }, { first remaining data in the application, the 4th check bit in the application
Block } } in any pair.
In attached drawing 19, the CRC circulation generator polynomial is expressed as: gLDL+…+g1D+g0, wherein { g0,g1,…,
gLIt is the coefficient that the CRC recycles generator polynomial, the L is bit in the CRC bit block of the given information bit block
Number, the value that the CRC recycles any coefficient in the coefficient of generator polynomial belong to { 0,1 }.Circuit in attached drawing 19 includes L
The shift-register sequence of a shift register composition, a change-over switch, L+1 tap and L exclusive-OR operator.The L
+ 1 tap is located at the both ends of the L shift register, as shown in Fig. 19.The index of the L shift register
It is # { 0,1 ..., L-1 } respectively.The L+1 tap respectively corresponds L+1 coefficient { g of the CRC circulation generator polynomial0,
g1,…,gL}。
Position 1 of the initial position of change-over switch in attached drawing 19 in attached drawing 19, in the given information bit block
Bit is successively input into the shift-register sequence of the L shift register composition, while being sequentially output.When described
After all bits in given information bit block are all input into the shift-register sequence of the L shift register composition,
The position of the change-over switch is switched to the position 2 in attached drawing 19, and starts to be sequentially output in the L shift register
Value, since shift register #L-1.Value in the L shift register of output forms the given information bit block
CRC bit block.
As one embodiment, the given information bit block includes the bit that positive integer is arranged successively.
As one embodiment, the given check bit block includes the L bits being arranged successively, and the L is positive integer.
As one embodiment, the given check bit block is passed through by the CRC bit block of the given information bit block
Scrambling code is crossed to obtain later.
As a sub- embodiment of above-described embodiment, the scrambling code uses the mark of the user equipment in the application
As scrambler sequence.
As one embodiment, the mark of the user equipment is made of 16 bits.
As one embodiment, the mark of the user equipment is distributed by serving cell.
As one embodiment, the mark of the user equipment is C-RNTI.
As one embodiment, the given check bit block is the CRC bit block of the given information bit block.
As one embodiment, the CRC bit block of the given information bit block and the given information bit block is constituted
Multinomial on GF (2) can by the CRC recycle generator polynomial divide exactly, i.e., described 4th bit block and the 4th bit
The deconv that the cyclic redundancy check bits block of block is constituted is zero with the remainder that CRC circulation generator polynomial obtains.CRC
Particular technique details referring in technical specification (TS-Technical Specification) 36.212 5.1.1 save.
As one embodiment, the CRC bit block of the given information bit block and the given information bit block is constituted
Multinomial be: a0DL+A-1+a1DL+A-2+…+aA-1DL+p0DL-1+p1DL-2+…+pL-2D+pL-1, wherein the A is described given
The number for the bit that block of information bits includes;The a0, a1..., aA-1It is the A that the given information bit block includes
A bit;The p0, the p1..., the pL-1It is the L bit that the given check bit block includes.
As one embodiment, the CRC circulation generator polynomial is D24+D23+D18+D17+D14+D11+D10+D7+D6+D5+
D4+D3+D+1。
As one embodiment, the CRC circulation generator polynomial is D24+D23+D6+D5+D+1。
As one embodiment, the CRC circulation generator polynomial is D16+D12+D5+1。
As one embodiment, the CRC circulation generator polynomial is D8+D7+D4+D3+D+1。
As one embodiment, the initial value of the L shift register is all 0.
As one embodiment, the initial value of at least one shift register is not 0 in the L shift register.
As one embodiment, the initial value of the L shift register is preset.
Embodiment 20
Embodiment 20 illustrates the schematic diagram that bit in given information bit block be used to generate given check bit block, such as
Shown in attached drawing 20.
In embodiment 20, the CRC bit block of the given information bit block be used to generate the given check bit
Block.The CRC bit block of the given information bit block is the given information bit block by CRC circulation generator polynomial
Output after (cyclic generator polynomial).For generating the CRC bit block of the given information bit block
The block diagram of circuit is as shown in attached drawing 20.{ the given information bit block, the given check bit block } is { { in the application
The first control information, the CRC bit block of the first control information }, { the second control information in the application, institute
State the CRC bit block of the second control information }, { first data in the application, the 4th check bit in the application
Block }, { second data in the application, the second check bit block in the application }, { described first in the application
Data splitting, the first check bit block in the application }, { second data splitting in the application, in the application
The third check bit block }, { first remaining data in the application, the 4th check bit in the application
Block } } in any pair.
In attached drawing 20, the CRC circulation generator polynomial is expressed as: gLDL+…+g1D+g0, wherein { g0,g1,…,
gLIt is the coefficient that the CRC recycles generator polynomial, the L is bit in the CRC bit block of the given information bit block
Number, the value that the CRC recycles any coefficient in the coefficient of generator polynomial belong to { 0,1 }.Circuit in attached drawing 20 includes L
The shift-register sequence of a shift register composition, two change-over switches, L+1 tap and L exclusive-OR operator.The L
+ 1 tap is located at the both ends of the L shift register, as shown in Fig. 20.The index of the L shift register
It is # { 0,1 ..., L-1 } respectively, the index of described two change-over switches is { 0,1 } # respectively.The L+1 tap respectively corresponds
L+1 coefficient { g of the CRC circulation generator polynomial0,g1,…,gL}。
Position 1 of the initial position of change-over switch #0 in attached drawing 20 in attached drawing 20, in the given information bit block
Bit be successively input into the shift-register sequence of L shift register composition, while being sequentially output.Work as institute
It states after the partial bit in given information bit block is input into the shift-register sequence of L shift register composition,
The position of the change-over switch #0 is switched to the position 2 in attached drawing 20, and is sequentially output in the L shift register and partially moves
Value in bit register, change-over switch #1 are sequentially switched on corresponding position.The change-over switch #0 is then switched back
Position 1 in attached drawing 20, remaining bit continuation is sequentially inputted to the L shift LD in the given information bit block
In the shift-register sequence of device composition, while being sequentially output.The above process is repeated 1 times or repeatedly, until the given letter
All bits in breath bit block are all input into the shift-register sequence of the L shift register composition.Then institute
The position for stating change-over switch #0 is switched to position 2 in attached drawing 20, and is sequentially output whole or portion in the L shift register
Divide the value in shift register, the change-over switch #1 is sequentially switched on corresponding position.The position of the change-over switch #0
Output when setting the position 2 in attached drawing 20 constitutes the CRC bit block of the given information bit block.
Embodiment 21
Embodiment 21 illustrates the schematic diagram of the second signaling content, as shown in Fig. 21.
In embodiment 21, second signaling includes the first domain and the second domain, and first domain is used for determining { this Shen
Please in first data whether be correctly received, whether the first remaining data is correctly received is correctly received } in
At least one of;Second domain is used for determining { whether second data in the application are correctly received, the second combination
At least one of whether data are correctly received is correctly received }.Second data splitting includes first number
The bit in partial bit and second data in;First remaining data includes in first data and institute
State the bit except the second data splitting.
As one embodiment, first domain includes positive integer bit.
As one embodiment, first domain includes 1 bit.
As one embodiment, second domain includes positive integer bit.
As one embodiment, second domain includes 1 bit.
As one embodiment, first domain is used for determining whether first data are correctly received, described
Two domains are used for determining whether second data are correctly received.
As a sub- embodiment of above-described embodiment, the CRC bit block of first data be used to generate the application
In the 4th check bit block.
Institute as a sub- embodiment of above-described embodiment, in the quantity and the application of the bit in second data
State the quantity of the bit in the second check bit block and equal to bit included by maximum code block (Code Block) number
The positive integer times of amount.
As one embodiment, first domain is used for determining whether first remaining data is correctly received, institute
It states the second domain and is used for determining whether second data splitting is correctly received.
As a sub- embodiment of above-described embodiment, the CRC bit block of first remaining data be used to generate this
The 4th check bit block in application.
Third verification as one embodiment, in the quantity and the application of the bit in second data splitting
The quantity of bit in bit block and equal to bit included by maximum code block (Code Block) quantity.
Embodiment 22
Embodiment 22 illustrates the structural block diagram for the processing unit in user equipment, as shown in Fig. 22.In attached drawing
In 22, the processing unit 2200 in user equipment is mainly made of first processing module 2201 and the first receiver module 2202.
In embodiment 22, first processing module 2201 sends respectively in the first running time-frequency resource and the second running time-frequency resource
One wireless signal and second wireless singal;First receiver module 2202 receives signaling No. the second.
In embodiment 22, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource grains
Son;First bit block and the second bit block respectively by the first processing module 2201 for generate first wireless signal and
The second wireless singal, first bit block and second bit block respectively include positive integer bit;Described first
Bit block includes the first control information, and whether first bit block includes occupied by the first data and the first control information
Bit quantity it is related;Second bit block includes the second data.Second signaling is by first receiver module
2202 for determining { whether first data are correctly received, and whether second data are correctly received, first number
Whether the bit in partial bit and second data in is correctly received, another part ratio in first data
At least one of whether spy is correctly received }.
As one embodiment, the first processing module 2201 also generates the first check bit block.Wherein, described first
Bit block includes first data, and the first check bit block includes positive integer bit, the ratio in the first data splitting
For spy by the first processing module 2201 for generating the first check bit block, first data splitting includes described the
The bit in bit and second data in one data, first bit block includes the first check bit block.
As one embodiment, the first processing module 2201 also generates the 4th check bit block.Wherein, the described 4th
Check bit block includes positive integer bit, and first bit block includes first data, the ratio in first data
For spy by the first processing module 2201 for generating the 4th check bit block, first bit block includes the described 4th
Check bit block.
As one embodiment, the first processing module 2201 also generates third check bit block.Wherein, described first
Bit block includes first data, and the third check bit block includes positive integer bit, the ratio in the second data splitting
For spy by the first processing module 2201 for generating the third check bit block, second data splitting includes described the
The bit in partial bit and second data in one data, first bit block includes the third check bit
Block.
As a sub- embodiment of above-described embodiment, the first processing module 2201 also generates the 4th check bit
Block.Wherein, the 4th check bit block includes positive integer bit, and the bit in the first remaining data is handled by described first
For module 2201 for generating the 4th check bit block, first remaining data includes in first data and described the
Bit except two data splittings, first bit block include the 4th check bit block.
As one embodiment, the first processing module 2201 also generates the second check bit block.Wherein, described second
Check bit block includes positive integer bit, and second bit block includes the second check bit block, second data
In bit by the first processing module 2201 for generating the second check bit block, the second check bit block with
Bit in first data is unrelated.
As one embodiment, the first processing module 2201 also executes the first channel coding.Wherein, first ratio
Special block includes first data, and the input of first channel coding includes the bit in first data, and described first
The output of channel coding is by the first processing module 2201 for generating the first wireless subsignal, the first wireless signal packet
Include the described first wireless subsignal.
As one embodiment, the first processing module 2201 also executes second channel coding.Wherein, second letter
The input of road coding is second bit block, and the output of the second channel coding is used for by the first processing module 2201
Generate the second wireless singal.
As one embodiment, the first processing module 2201 also executes third channel coding.Wherein, the third letter
The input of road coding includes the bit in the first control information, and the output of the third channel coding is handled by described first
Module 2201 is for generating the second wireless subsignal;First wireless signal includes the described second wireless subsignal.
As one embodiment, the first processing module 2201 sends third wireless communication also in third running time-frequency resource
Number.Wherein, the third running time-frequency resource includes positive integer resource particle;The third wireless signal includes the second control letter
Breath, the quantity of the first control occupied bit of information and second control are information-related.
As a sub- embodiment of above-described embodiment, the first processing module 2201 also executes the 4th channel coding.
Wherein, the input of the 4th channel coding includes the bit in the second control information;4th channel coding it is defeated
Out by the first processing module 2201 for generating third wireless signal.
As one embodiment, first receiver module 2202 also receives the first signaling.Wherein, first signaling
Including the first running time-frequency resource set and the first configuration information, the first running time-frequency resource set includes positive integer resource particle;
First running time-frequency resource and second running time-frequency resource belong to the first running time-frequency resource set, first running time-frequency resource
Position and first signaling of the included resource particle in the first running time-frequency resource set are unrelated;First configuration
Information include modulation coding scheme, the configuration information of demodulated reference signal, redundancy versions, new data instruction at least it
One.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for { the described first wireless son letter
Number, the second wireless singal }, first bit block includes first data.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for the second wireless singal,
First bit block does not include first data.
As one embodiment, the first processing module 2201 include embodiment 4 in antenna 452, transmitter 454,
Transmited processor 468, channel encoder 457, controller/processor 459, memory 460, data source 467 } at least it
One.
As one embodiment, first receiver module 2202 includes { antenna 452, the receiver in embodiment 4
454, receive processor 456, channel decoder 458, controller/processor 459, memory 460, data source 467 } at least
One of.
Embodiment 23
Embodiment 23 illustrates the structural block diagram for the processing unit in base station, as shown in Fig. 23.In attached drawing 23,
Processing unit 2300 in base station is mainly made of Second processing module 2301 and the first sender module 2302.
In embodiment 23, Second processing module 2301 receives respectively in the first running time-frequency resource and the second running time-frequency resource
One wireless signal and second wireless singal;First sender module 2302 sends the second signaling.
In embodiment 23, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource grains
Son;First bit block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, institute
It states the first bit block and second bit block respectively includes positive integer bit;First bit block includes the first control letter
Whether breath, first bit block include that the first data are related with the first control quantity of the occupied bit of information;Institute
Stating the second bit block includes the second data.Second signaling is used for determining { whether first data are correctly received, institute
State whether the second data are correctly received, the bit in partial bit and second data in first data whether by
At least one of be properly received, whether another part bit in first data is correctly received.
As one embodiment, the Second processing module 2301 also restores the first check bit block.Wherein, described first
Bit block includes first data, and the first check bit block includes positive integer bit, the ratio in the first data splitting
Spy be used to generate the first check bit block, and first data splitting includes bit and institute in first data
The bit in the second data is stated, first bit block includes the first check bit block.
As one embodiment, the Second processing module 2301 also restores the 4th check bit block.Wherein, described first
Bit block includes first data, and the 4th check bit block includes positive integer bit, the ratio in first data
Spy be used to generate the 4th check bit block, and first bit block includes the 4th check bit block.
As one embodiment, the Second processing module 2301 also restores third check bit block.Wherein, described first
Bit block includes first data, and the third check bit block includes positive integer bit, the ratio in the second data splitting
Spy be used to generate the third check bit block, second data splitting include the partial bit in first data with
And the bit in second data, first bit block include the third check bit block.
As a sub- embodiment of above-described embodiment, the Second processing module 2301 also restores the 4th check bit
Block.Wherein, the 4th check bit block includes positive integer bit, and the bit in the first remaining data be used to generate described
4th check bit block, first remaining data include the ratio in first data and except second data splitting
Spy, first bit block include the 4th check bit block.
As one embodiment, the Second processing module 2301 also restores the second check bit block.Wherein, described second
Check bit block includes positive integer bit, and second bit block includes the second check bit block, second data
In bit be used to generate the second check bit block, the bit in the second check bit block and first data
It is unrelated.
As one embodiment, the Second processing module 2301 also executes the first channel decoding.Wherein, first ratio
Special block includes first data, and the corresponding channel coding of the first channel decoding is inputted including in first data
The output of bit, the corresponding channel coding of first channel decoding be used to generate the first wireless subsignal, first nothing
Line signal includes the described first wireless subsignal.
As one embodiment, the Second processing module 2301 also executes second channel decoding.Wherein, second letter
The input that road decodes corresponding channel coding is second bit block, and the second channel decodes the defeated of corresponding channel coding
It is used to generate the second wireless singal out.
As one embodiment, the Second processing module 2301 also executes third channel decoding.Wherein, the third letter
The input that road decodes corresponding channel coding includes the bit in the first control information, and the third channel decoding is corresponding
The output of channel coding be used to generate the second wireless subsignal;First wireless signal includes the described second wireless son letter
Number.
As one embodiment, the Second processing module 2301 receives third wireless communication also in third running time-frequency resource
Number.Wherein, the third running time-frequency resource includes positive integer resource particle;The third wireless signal includes the second control letter
Breath, the quantity of the first control occupied bit of information and second control are information-related.
As a sub- embodiment of above-described embodiment, the Second processing module 2301 also executes the 4th channel decoding.
Wherein, the input of the corresponding channel coding of the 4th channel decoding includes the bit in the second control information;Described
The output of the corresponding channel coding of four channel decodings be used to generate the third wireless signal.
As a sub- embodiment of above-described embodiment, first sender module 2302 also sends the first signaling.Its
In, first signaling includes the first running time-frequency resource set and the first configuration information, and the first running time-frequency resource set includes just
Integer resource particle;First running time-frequency resource and second running time-frequency resource belong to the first running time-frequency resource set,
Position and first signaling of the resource particle included by first running time-frequency resource in the first running time-frequency resource set
It is unrelated;First configuration information includes { modulation coding scheme, the configuration information of demodulated reference signal, redundancy versions, new data
At least one of instruction }.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for { the described first wireless son letter
Number, the second wireless singal }, first bit block includes first data.
As a sub- embodiment of above-described embodiment, first configuration information is suitable for the second wireless singal,
First bit block does not include first data.
As one embodiment, the Second processing module 2301 include embodiment 4 in antenna 420, receiver 418,
At least one of receive processor 470, channel decoder 478, controller/processor 475, memory 476 }.
As one embodiment, first sender module 2302 includes { antenna 420, the transmitter in embodiment 4
At least one of 418, transmited processor 416, channel encoder 477, controller/processor 475, memory 476 }.
Those of ordinary skill in the art will appreciate that all or part of the steps in the above method can be referred to by program
Related hardware is enabled to complete, described program can store in computer readable storage medium, such as read-only memory, hard disk or light
Disk etc..Optionally, one or more integrated circuit can be used also to realize in all or part of the steps of above-described embodiment.Phase
It answers, each modular unit in above-described embodiment, can be realized using example, in hardware, it can also be by the form of software function module
It realizes, the application is not limited to the combination of the software and hardware of any particular form.User equipment, terminal and UE packet in the application
Include but be not limited to unmanned plane, the communication module on unmanned plane, telecontrolled aircraft, aircraft, baby plane, mobile phone, tablet computer, pen
Remember this, vehicular communication equipment, wireless sensor, card of surfing Internet, internet-of-things terminal, RFID terminal, NB-IOT terminal, MTC
(Machine Type Communication, machine type communication) terminal, eMTC (enhanced MTC, the MTC of enhancing) is eventually
End, data card, card of surfing Internet, vehicular communication equipment, inexpensive mobile phone, the wireless telecom equipments such as inexpensive tablet computer.The application
In base station or system equipment include but is not limited to macrocell base stations, microcell base station, Home eNodeB, relay base station, gNB
(NR node B), the wireless telecom equipments such as TRP (Transmitter Receiver Point transmits and receives node).
The above, the only preferred embodiment of the application, are not intended to limit the protection scope of the application.It is all
Within spirit herein and principle, any modification made, equivalent replacement, improve etc., it should be included in the protection of the application
Within the scope of.
Claims (20)
1. the method in the user equipment that be used to wirelessly communicate characterized by comprising
- sends the first wireless signal and second wireless singal in the first running time-frequency resource and the second running time-frequency resource respectively;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First bit
Block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first bit block
Positive integer bit is respectively included with second bit block;First bit block include first control information, described first
Whether bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second bit block
Including the second data.
2. the method according to claim 1, wherein including:
- generates the first check bit block;
Wherein, first bit block includes first data, and the first check bit block includes positive integer bit, the
Bit in one data splitting be used to generate the first check bit block, and first data splitting includes first number
The bit in bit and second data in, first bit block includes the first check bit block.
3. method described in any claim according to claim 1 or in 2 characterized by comprising
- generates third check bit block;
Wherein, first bit block includes first data, and the third check bit block includes positive integer bit, the
Bit in two data splittings be used to generate the third check bit block, and second data splitting includes first number
The bit in partial bit and second data in, first bit block includes the third check bit block.
4. according to claim 1 to method described in any claim in 3 characterized by comprising
- generates the second check bit block;
Wherein, the second check bit block includes positive integer bit, and second bit block includes the second verification ratio
Special block, the bit in second data be used to generate the second check bit block, the second check bit block and institute
The bit stated in the first data is unrelated.
5. according to claim 1 to method described in any claim in 4 characterized by comprising
- executes at least the latter in the first channel coding and second channel coding;
Wherein, first channel coding input include first data in bit, first channel coding it is defeated
It is used to generate the first wireless subsignal out, first wireless signal includes the described first wireless subsignal;Second letter
The input of road coding is second bit block, and the output of the second channel coding be used to generate second wireless communication
Number.
6. the method according to claim 1 characterized by comprising
- sends third wireless signal in third running time-frequency resource;
Wherein, the third running time-frequency resource includes positive integer resource particle;The third wireless signal includes the second control letter
Breath, the quantity of the first control occupied bit of information and second control are information-related.
7. according to claim 1 to method described in any claim in 6 characterized by comprising
- receives the second signaling;
Wherein, second signaling be used for determining whether first data are correctly received, and second data whether by
It is properly received, whether the bit in partial bit and second data in first data is correctly received, and described
At least one of whether another part bit in one data is correctly received }.
8. the method according to any claim in claim 5 to 7 characterized by comprising
- receives the first signaling;
Wherein, first signaling includes the first running time-frequency resource set and the first configuration information, the first running time-frequency resource set
Including positive integer resource particle;First running time-frequency resource and second running time-frequency resource belong to first running time-frequency resource
Gather, position and described first of the resource particle in the first running time-frequency resource set included by first running time-frequency resource
Signaling is unrelated;First configuration information include modulation coding scheme, the configuration information of demodulated reference signal, redundancy versions, newly
At least one of data instruction };First configuration information is suitable for { the first wireless subsignal, described second is wireless
Signal } at least the latter.
9. the method in the base station that be used to wirelessly communicate characterized by comprising
- receives the first wireless signal and second wireless singal in the first running time-frequency resource and the second running time-frequency resource respectively;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First bit
Block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first bit block
Positive integer bit is respectively included with second bit block;First bit block include first control information, described first
Whether bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second bit block
Including the second data.
10. according to the method described in claim 9, it is characterised by comprising:
- restores the first check bit block;
Wherein, first bit block includes first data, and the first check bit block includes positive integer bit, the
Bit in one data splitting be used to generate the first check bit block, and first data splitting includes first number
The bit in bit and second data in, first bit block includes the first check bit block.
11. the method according to any claim in claim 9 or 10 characterized by comprising
- restores third check bit block;
Wherein, first bit block includes first data, and the third check bit block includes positive integer bit, the
Bit in two data splittings be used to generate the third check bit block, and second data splitting includes first number
The bit in partial bit and second data in, first bit block includes the third check bit block.
12. the method according to any claim in claim 9 to 11 characterized by comprising
- restores the second check bit block;
Wherein, the second check bit block includes positive integer bit, and second bit block includes the second verification ratio
Special block, the bit in second data be used to generate the second check bit block, the second check bit block and institute
The bit stated in the first data is unrelated.
13. the method according to any claim in claim 9 to 12 characterized by comprising
- executes at least the latter in the first channel decoding and second channel decoding;
Wherein, the input of the corresponding channel coding of first channel decoding includes the bit in first data, and described the
The output of the corresponding channel coding of one channel decoding be used to generate the first wireless subsignal, and first wireless signal includes institute
State the first wireless subsignal;The input that the second channel decodes corresponding channel coding is second bit block, described
The output of the corresponding channel coding of two channel decodings be used to generate the second wireless singal.
14. the method according to any claim in claim 9 to 13 characterized by comprising
- receives third wireless signal in third running time-frequency resource;
Wherein, the third running time-frequency resource includes positive integer resource particle;The third wireless signal includes the second control letter
Breath, the quantity of the first control occupied bit of information and second control are information-related.
15. the method according to any claim in claim 9 to 14 characterized by comprising
- sends the second signaling;
Wherein, second signaling be used for determining whether first data are correctly received, and second data whether by
It is properly received, whether the bit in partial bit and second data in first data is correctly received, and described
At least one of whether another part bit in one data is correctly received }.
16. method described in any claim in 3 to 15 according to claim 1 characterized by comprising
- sends the first signaling;
Wherein, first signaling includes the first running time-frequency resource set and the first configuration information, the first running time-frequency resource set
Including positive integer resource particle;First running time-frequency resource and second running time-frequency resource belong to first running time-frequency resource
Gather, position and described first of the resource particle in the first running time-frequency resource set included by first running time-frequency resource
Signaling is unrelated;First configuration information include modulation coding scheme, the configuration information of demodulated reference signal, redundancy versions, newly
At least one of data instruction };First configuration information is suitable for { the first wireless subsignal, described second is wireless
Signal } at least the latter.
17. being used for the user equipment wirelessly communicated characterized by comprising
First processing module sends the first wireless signal and second wirelessly respectively in the first running time-frequency resource and the second running time-frequency resource
Signal;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First bit
Block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first bit block
Positive integer bit is respectively included with second bit block;First bit block include first control information, described first
Whether bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second bit block
Including the second data.
18. user equipment according to claim 17 characterized by comprising
First receiver module receives the second signaling;
Wherein, second signaling be used for determining whether first data are correctly received, and second data whether by
It is properly received, whether the bit in partial bit and second data in first data is correctly received, and described
At least one of whether another part bit in one data is correctly received }.
19. being used for the base station equipment wirelessly communicated characterized by comprising
Second processing module receives the first wireless signal and second wirelessly respectively in the first running time-frequency resource and the second running time-frequency resource
Signal;
Wherein, first running time-frequency resource and second running time-frequency resource respectively include positive integer resource particle;First bit
Block and the second bit block are respectively used to generate first wireless signal and the second wireless singal, first bit block
Positive integer bit is respectively included with second bit block;First bit block include first control information, described first
Whether bit block includes that the first data are related with the first control quantity of the occupied bit of information;Second bit block
Including the second data.
20. base station equipment according to claim 19 characterized by comprising
First sender module sends the second signaling;
Wherein, second signaling be used for determining whether first data are correctly received, and second data whether by
It is properly received, whether the bit in partial bit and second data in first data is correctly received, and described
At least one of whether another part bit in one data is correctly received }.
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