CN103354537A - Device and method for segmented transmission of transmission block - Google Patents

Device and method for segmented transmission of transmission block Download PDF

Info

Publication number
CN103354537A
CN103354537A CN2013102807716A CN201310280771A CN103354537A CN 103354537 A CN103354537 A CN 103354537A CN 2013102807716 A CN2013102807716 A CN 2013102807716A CN 201310280771 A CN201310280771 A CN 201310280771A CN 103354537 A CN103354537 A CN 103354537A
Authority
CN
China
Prior art keywords
segmentation
transmission block
transmission
bit number
symbol
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
CN2013102807716A
Other languages
Chinese (zh)
Other versions
CN103354537B (en
Inventor
李迎阳
张玉建
李小强
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Beijing Samsung Telecommunications Technology Research Co Ltd
Samsung Electronics Co Ltd
Original Assignee
Beijing Samsung Telecommunications Technology Research Co Ltd
Samsung Electronics Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Beijing Samsung Telecommunications Technology Research Co Ltd, Samsung Electronics Co Ltd filed Critical Beijing Samsung Telecommunications Technology Research Co Ltd
Priority to CN201310280771.6A priority Critical patent/CN103354537B/en
Publication of CN103354537A publication Critical patent/CN103354537A/en
Application granted granted Critical
Publication of CN103354537B publication Critical patent/CN103354537B/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Images

Abstract

The invention discloses a device and method for segmented transmission of transmission blocks. The method includes steps of segmenting the transmission blocks and sorting according to bit numbers; determining the amount of physical resource occupied by segments according to the bit numbers of the segments; performing operations such as encoding, rate matching and the like of the transmission blocks; and performing physical resource mapping of the different segments in the monotonic non-decreasing order of the bit numbers of the segments.

Description

The equipment of transmission block segment transmissions and method
The application is the dividing an application of application for a patent for invention 200710143148.0 that is called " equipment of transmission block segment transmissions and method " in the name that on August 6th, 2007 submitted to.
Technical field
The present invention relates to wireless communication system, relate in particular and a kind ofly in wireless communication system, transmission block is carried out equipment and the method for segment transmissions.
Background technology
Now, 3GPP standardization body has set about beginning its existing system standard is carried out long-term evolution (LTE).In the middle of numerous physical layer transmission technology, be the focus of research based on the downlink transfer technology of OFDM (OFDM) with based on the uplink technology of single-carrier frequency division multiple access access (SCFDMA).Two kinds of hardwood structures are arranged: i.e. Class1 frame structure (Type1Frame Structure) and type 2 frame structures (Type2Frame Structure) in LTE.Two kinds of duplex modes of FDD and TDD are arranged in the Class1 frame structure, and only have TDD duplex mode in type 2 frame structures.The below describes prior art and the problem in the current LTE system as an example of LTE Class1 FDD system example, described problem is present in LTE type 2 systems equally.
According to the discussion result of current LTE, Fig. 1 is the downlink frame structure of LTE Class1 FDD, and radio frames (radio frame) time span (101-103) is 10ms; Each frame is divided into a plurality of time slots (slot) (104-107), and present hypothesis is that each radio frames comprises 20 time slots, and the time span of time slot is 0.5ms; Each time slot comprises again a plurality of OFDM symbols.According to present hypothesis, the time span of effective OFDM symbol is about 66.7 μ s in the LTE system.The time span of the CP of OFDM symbol can have two kinds, be general CP (Normal CP, be also referred to as short CP) time span be approximately 4.69 μ s or 5.21 μ s, lengthen CP (Extended CP, be also referred to as long CP) time span be approximately 16.7 μ s, lengthen the CP time slot and be used for many Cell Broadcast CB/multicasts and the very large situation of radius of society, general CP time slot (108) comprises 7 OFDM symbols, lengthens CP time slot (109) and comprises 6 OFDM symbols.According to present discussion result, continuous two time slots consist of subframes (subffame), and Transmission Time Interval (TTI) is 1ms, equal the time span of a subframe.
Fig. 2 is LTE Class1 FDD system uplink frame structure, and is similar with the downlink frame structure, and the time span of its radio frames (201,202,203) is all 10ms mutually with WCDMA; Each frame is subdivided into a plurality of time slots (204-207), and present hypothesis is that each radio frames comprises 20 time slots, and the time span of time slot is 0.5ms; Each time slot comprises again a plurality of SCFDMA symbols.Consistent with the downlink frame structure, the CP of SCFDMA symbol has two kinds of length, i.e. general CP and lengthen CP, and general CP time slot comprises 7 SCFDMA symbols, lengthens the CP time slot and comprises 6 SCFDMA symbols.According to present discussion result, continuous two time slots consist of subframes (subframe), and Transmission Time Interval (TTI) is 1ms, equal the time span of a subframe.
In the discussion of current LTE, corresponding to the sub-hardwood of the clean culture of Class1 frame structure, the downlink reference signal structure during general CP as shown in Figure 3.It should be noted that there are four transmitting antennas the base station in this structure in order to describe comprehensively.When the base station only has an antenna, then at antenna 1, antenna 2, and do not send any reference signal on the running time-frequency resource of antenna 3 employed reference signals.When there are two antennas the base station, then at antenna 2, and do not send any reference signal on the running time-frequency resource of antenna 3 employed reference signals.In this structure, the reference signal between the different antennae adopts the mode of frequency division multiplexing, and namely the reference signal of different antennae is used different running time-frequency resources.The reference signal of every antenna is 1/6 in the density of frequency domain transmission, namely when the reference signal of certain antenna is transmitted, the reference signal of sub-this antenna of carrier transmission is arranged in per six subcarriers of frequency domain in certain OFDM symbol.The reference signal of antenna 0 and antenna 1 is transmitted in the OFDM of each descending time slot symbol 0 and OFDM symbol 4, and the reference signal of antenna 2 and antenna 3 is transmitted in the OFDM of each descending time slot symbol 1.In addition, according to the discussion of present LTE, whether the base station can configure the reference signal of transmitting antenna 2 and antenna 3.
In the discussion of current LTE, the uplink reference signals structure of Class1 frame structure as shown in Figure 4.Example one is the uplink reference signals structure of general CP subframe, and each time slot comprises 7 SCFDMA symbols, is designated as symbol #0~symbol #6, then is positioned at the middle SCFDMA symbol (being symbol #3) of time slot and is used for transmitting uplink reference signal.Example two is the uplink reference signals structures that lengthen the CP subframe, and each time slot comprises 6 SCFDMA symbols, is designated as symbol #0~symbol #5, and then the symbol #3 of the symbol #2 of first time slot and second time slot is used for transmitting uplink reference signal.In above-mentioned uplink reference signals structure, when subscriber equipment simultaneously on a plurality of antennas during transmitted signal, the reference signal of a plurality of antennas adopts the mode of CDM to transmit at the symbol as reference signal of each time slot.
Discussion result according to current LTE, when the bit number of transmission block be worth Z (being that Z equals 6144) greater than certain in LTE thus in the time of need to carrying out segmentation, thereby in order to make receiving terminal carry out the speed that reception ﹠ disposal is accelerated in the parallel decoding operation to each segmentation, rate-matched is that each segmentation is carried out respectively, and when physical resource shines upon, each piecemeal is mapped to a resource in the TTI in the mode of similar TDM, i.e. segmentation only is mapped on a part of symbol of TTI inside.For example, some segmentations are mapped on the symbol of TTI front portion, and other segmentations are mapped on the symbol at TTI rear portion.In LTE, the symbol here descending be the OFDM symbol, up be the SCFDMA symbol.Like this, the recipient needn't wait until that all symbols of whole TTI receive, and after receiving several symbols that comprise a segmentation, just can process this segmentation, and receive simultaneously the symbol of the back of TTI, thereby reach the purpose to each segmentation parallel processing.
This method to a plurality of segmentation parallel processings, an important problem is the problem of channel estimating.For can be as soon as possible to the segmentation processing of decoding, to some segmentation, the recipient can not use all reference signals in the whole TTI to carry out channel estimating, thereby bring certain loss in precision of channel estimation.Specifically, to the segmentation that the symbol in the TTI front portion transmits, the reference signal at this TTI rear portion can not be used for channel estimating, and the number of available reference signal is less, thereby the precision of channel estimating is relatively low; And the segmentation that the symbol at the TTI rear portion is transmitted, all reference signals of this TTI inside may be used to channel estimating, and the number of available reference signal is more, thus the precision of channel estimating is relatively high.According to the analysis to precision of channel estimation, the decoding performance of each segmentation among TTI is different, and for example, the decoding performance that is positioned at the segmentation on the anterior symbol of TTI is relatively poor, and it is better to be positioned at the decoding performance of the segmentation on the symbol of TTI rear portion.
Summary of the invention
The purpose of this invention is to provide and a kind ofly in wireless communication system, transmission block is carried out equipment and the method for segment transmissions.
According to an aspect of of the present present invention, a kind of transmission block segmentation and the method for distributing physical resource comprise the steps:
A) transmission block is carried out segmentation and sort by bit number;
B) determine the number of the physical resource that it takies according to the bit number of segmentation;
C) transmission block is encoded and the operation such as rate-matched;
D) by the order of the bit number monotonic nondecreasing of segmentation the physical resource mapping is carried out in each segmentation.
According to another aspect of the present invention, a kind of method of the transmission block segmentation being carried out the HARQ transmission comprises the steps:
A) transmission block is carried out segmentation, and each segmentation is encoded respectively;
B) to each HARQ transfer of data, determine respectively the physical resource number that each segmentation is mapped to, and rate-matched is carried out in each segmentation;
C) to each HARQ transfer of data, determine that respectively each is fragmented into the mapping order of physical resource, and finish the physical resource mapping.
According to another aspect of the present invention, a kind of up direction comprises the steps: mapping and the transmission method of the segmentation of transmission block
A) subscriber equipment carries out segmentation to transmission block;
B) subscriber equipment is encoded and rate-matched to each segmentation respectively;
C) subscriber equipment is mapped to the segmentation of transmission block on a plurality of SCFDMA symbols that keep at a certain distance away in the TTI.
According to another aspect of the present invention, a kind of equipment to transmission block segmentation and mapping comprises:
A) transmission block segmentation module is used for transmission block is divided into a plurality of segmentations and ordering;
B) coding, rate-matched module are used for to transmission block that segmentation is encoded and the operation such as rate-matched;
C) physical resource mapping block, being used for is each segmentation mapping physical resource in order.
According to another aspect of the present invention, a kind of equipment of separating mapping and segmentation restructuring comprises:
A) transmission block recombination module is used for a plurality of segmentation combinations are obtained transmission block;
B) decoding, rate de-matching module are used for respectively to operations such as each segmentation rate de-matching and decodings;
C) physical resource solution mapping block is used for the signal that solution maps out each segmentation.
According to another aspect of the present invention, a kind of transmitting apparatus that the transmission block segmentation is carried out the HARQ transmission comprises:
A) transmission block segmentation module is used for transmission block is divided into a plurality of segmentations and ordering;
B) coding module is used for to transmission block segmentation and encodes;
C) rate-matched module is used for the number of times according to the HARQ transmission, and rate-matched is carried out in each segmentation;
D) physical resource mapping block is used for the number of times according to the HARQ transmission, is each segmentation mapping physical resource.
E) harq controller is used for control to rate-matched and the physical resource mapping of segmentation.
According to another aspect of the present invention, a kind of receiving equipment that the transmission block segmentation is carried out the HARQ transmission comprises:
A) transmission block recombination module is used for a plurality of segmentation combinations are obtained transmission block;
B) decoder module is used for respectively each segmentation being decoded;
C) rate de-matching module is used for the number of times according to the HARQ transmission, and rate de-matching is carried out in each segmentation;
D) physical resource solution mapping block is used for the number of times according to the HARQ transmission, thereby carries out the signal that the mapping of physical resource solution obtains each segmentation;
E) harq controller is used for control to rate de-matching and the mapping of physical resource solution of segmentation.
According to another aspect of the present invention, the equipment of a kind of up transmission transmission block segmentation comprises:
A) transmission block segmentation module is used for transmission block and carries out segmentation;
B) coding, rate-matched module are used for to transmission block that segmentation is encoded and the operation such as rate-matched;
C) physical resource mapping block is used to each segmentation mapping physical resource.
According to another aspect of the present invention, the equipment of a kind of uplink receiving transmission block segmentation comprises:
A) transmission block recombination module is used for combined section and obtains transmission block;
B) decoding, rate de-matching module are used for respectively to operations such as each segmentation rate de-matching and decodings;
C) physical resource solution mapping block is used for the signal that solution maps out each segmentation.
Description of drawings
Fig. 1 is the downlink frame structure of LTE Class1;
Fig. 2 is the uplink frame structure of LTE Class1;
Downlink reference signal structure when Fig. 3 is general CP;
Uplink reference signals structure when Fig. 4 is general CP;
Fig. 5 is the equipment drawing to transmission block segmentation and mapping;
Fig. 6 is the equipment drawing of separating mapping and segmentation restructuring;
Fig. 7 is the transmitting apparatus figure that the transmission block segmentation is carried out the HARQ transmission;
Fig. 8 is the receiving equipment figure that the transmission block segmentation is carried out the HARQ transmission;
Fig. 9 is the equipment drawing of up transmission transmission block segmentation;
Figure 10 is the equipment drawing of uplink receiving transmission block segmentation;
The schematic diagram of the transmission block segmentation of Figure 11 thing and mapping;
Figure 12 is the schematic diagram 1 that the transmission block segmentation is carried out the HARQ transmission;
Figure 13 is the schematic diagram 2 that the transmission block segmentation is carried out the HARQ transmission;
Figure 14 is the schematic diagram 1 of up direction map transmission piece segmentation;
Figure 15 is the schematic diagram 2 of up direction map transmission piece segmentation;
Figure 16 is up direction carries out the HARQ transmission to the transmission block segmentation schematic diagram.
Embodiment
When the bit number of transmission block is worth Z greater than certain, need to carries out segmentation (segmentation) to transmission block, thereby respectively each segmentation be encoded.In LTE, Z equals 6144, and the mode of coding adopts the Turbo coding.The present invention describes below multiple method to transmission block segmentation and transmission.
Transmission block segmentation and the method for distributing physical resource:
When the bit number of transmission block during greater than Z, transmission block is carried out segmentation, and remember that the number of the segmentation that this transmission block is divided is N SegHere, can be when transmission block be carried out segmentation, the bit number of the segmentation of assurance back is more than or equal to the segmentation of front; Perhaps after segmentation is complete, according to this N SegThe bit number of individual segmentation is to each segmentation ordering, thereby the bit number of the segmentation of assurance back is more than or equal to the segmentation of front.The bit number of note transmission block is B, and remembers that each segmentation is followed successively by S k, its bit number is Here k=0,1 ..., N Seg-1, namely Here,
Figure BDA00003467816800063
Increase or constant with the increase of k.The Resource Unit (RE) of note physical channel adds up to
Figure BDA00003467816800064
In the LTE system, data channel is comprised of a plurality of Resource Block, so
Figure BDA00003467816800065
Equal the summation of the RE number in each Resource Block.
The first determines that the method for the number of the RE that segmentation takies is physical channel
Figure BDA00003467816800066
Individual RE distributes to each segmentation as far as possible uniformly, and, the RE number of the segment assignments that the no more than bit number of the number of the RE of the segment assignments that bit number is fewer is many, this is conducive to remedy the loss of the code rate (coding rate) of the many segmentations of bit number.The RE number of k segment assignments is determined by following formula:
Figure BDA00003467816800067
When a segmentation only is mapped on a part of symbol in the TTI, order according to the bit number monotonic nondecreasing of segmentation is carried out the physical resource mapping to each segmentation, specifically, the fewer segmentation of bit number is mapped on the symbol of front portion of TTI, and the many segmentations of bit number are mapped on the symbol at rear portion of segmentation.For example can shine upon successively segmentation S according to the order that k increases kThis is because the precision of channel estimation of the symbol at TTI rear portion is relatively high, the decoding performance of the segmentation that is conducive to guarantee that bit number is more.
The second determines that the method for the number of the RE that segmentation takies is the bit number according to each segmentation, presses the pro rate physical resource of bit number as much as possible.Like this, the code rate approximately equal of each segmentation, thus coding efficiency is approximate.
The third determines that the method for the number of the RE that segmentation takies is the bit number later according to the coding of each segmentation, presses as much as possible the pro rate physical resource of coded bit number.Similar with second method, this method makes the code rate approximately equal of each segmentation, thereby coding efficiency is approximate.
Because data channel adopts qam mode, the modulation symbol on each RE comprises I and two branch roads of Q, thus another kind of for the method for each segment assignments physical resource is to define the branch road that least resource unit is modulation symbol, such physical channel
Figure BDA00003467816800071
Individual RE comprises
Figure BDA00003467816800072
The resource of individual unit.Said method can expand to handle like this
Figure BDA00003467816800073
The resource of individual unit is distributed to N SegIndividual segmentation.
Be transmitting apparatus figure as shown in Figure 5, transmission block segmentation module (501) and physical resource mapping block (503) are embodiments of the present invention.At first, module (501) is used for transmission block is carried out segmentation, and according to the bit number of segmentation each segmentation is sorted, and the bit number of the segmentation of back is more than or equal to the segmentation of front; Next, module (502) each segmentation is encoded respectively operations such as (such as Turbo coding), rate-matched; Then, the bit of each segmentation is carried out physical resource mapping (503) in order, the segmentation that namely bit number is few is mapped to the front portion of TTI, and the many segmentations of bit number are mapped to the rear portion of TTI.
Be receiving equipment figure as shown in Figure 6, physical resource solution mapping block (603) and transmission block restructuring (601) are embodiments of the present invention.According to method of the present invention, at physical resource solution mapping block (603) thus demapping physical channels is obtained the bit of each segmentation; Next, the bit of each segmentation carried out respectively the operations (602) such as rate de-matching and decoding; And in transmission block restructuring (601) module each segmentation is combined into transmission block; Then judge whether transmission block sends successfully.
At up direction, when subscriber equipment need to send upstream data and upstream control signaling simultaneously, upstream data and upstream control signaling all are to transmit at uplink data channels, so subscriber equipment when transmission block is carried out staged operation, need to be considered the impact of the resource that upstream control signaling takies.
Upstream control signaling can be divided into two types, the first type is that base station and subscriber equipment both sides be sure of the upstream control signaling whether it transmits, for example periodic channel quality indication (CQI), periodic CQI signaling configures by high-level signaling, its reliability is very high, so base station and subscriber equipment are all known the timing of CQI transmission and the resource that takies.The second type is might have probabilistic control signal between base station and the subscriber equipment, for example respond the ACK/NACK of descending HARQ transfer of data, because subscriber equipment might error detection carries out the downlink physical control channel (PDCCH) of descending scheduling, this comprises: the base station has sent carries out the PDCCH of descending scheduling and subscriber equipment does not detect to subscriber equipment, perhaps the base station do not send the PDCCH that carries out descending scheduling of subscriber equipment and the subscriber equipment error detection to the PDCCH that carries out descending scheduling; Like this, subscriber equipment can not be sure of fully whether it needs to send the ACK/NACK control signal.
The RE of the uplink data channels of note base station assigns subscriber equipment adds up to
Figure BDA00003467816800081
The RE number that the upstream control signaling of the first type takies is N C1, the RE number that the upstream control signaling of the second type takies is N C2, and the number of the segmentation of note transmission block division is N Seg
When up direction carried out segmentation to transmission block, if the current upstream control signaling that needs transmission the first type, subscriber equipment was distributed to each segmentation to RE other RE in addition that the upstream control signaling of removing the first type in the uplink data channels takies.This is because the both sides of communication can know reliably whether the upstream control signaling of the first type needs the resource of transmitting and taking, so the both sides of communication can both know reliably that those RE in the uplink data channels are for transmit ascending data.Here, have approximately equalised chnnel coding performance in order to guarantee each segmentation, a kind of method is that subscriber equipment is distributed to each segmentation as far as possible uniformly to RE other RE in addition that the upstream control signaling of removing the first type in the uplink data channels takies.Specifically, according to top method for expressing to parameter, the RE number of k segment assignments is determined by following formula:
Figure BDA00003467816800082
The transmission block segmentation is carried out the method for HARQ transmission:
According to the discussion result among the present LTE, for receiving terminal can be walked abreast thereby the speed that decode operation is accelerated reception ﹠ disposal is carried out in each segmentation of transmission block, rate-matched is that each segmentation is carried out respectively, and when physical resource shines upon, each piecemeal is mapped to a resource in the TTI in the mode of similar TDM, i.e. segmentation only is mapped on a part of symbol of TTI inside.In LTE, the symbol here descending be the OFDM symbol, up be the SCFDMA symbol.Like this, the recipient needn't wait until that all symbols of whole TTI receive, and after receiving several symbols that comprise a segmentation, just can process this segmentation, and receive simultaneously the symbol of the back of TTI, thereby reach the purpose to each segmentation parallel processing.
This method to a plurality of segmentation parallel processings, an important problem is the problem of channel estimating.For can be as soon as possible to the segmentation processing of decoding, to some segmentation, the recipient can not use all reference signals in the whole TTI to carry out channel estimating, thereby bring certain loss in precision of channel estimation.Specifically, to the segmentation that the symbol in the TTI front portion transmits, the reference signal at this TTI rear portion can not be used for channel estimating, and the number of available reference signal is less, thereby the precision of channel estimating is relatively low; And the segmentation that the symbol at the TTI rear portion is transmitted, all reference signals of this TTI inside may be used to channel estimating, and the number of available reference signal is more, thus the precision of channel estimating is relatively high.According to the analysis to precision of channel estimation, in a data transfer, the decoding performance of each segmentation among the TTI is different, for example, the decoding performance that is positioned at the segmentation on the anterior symbol of TTI is relatively poor, and it is better to be positioned at the decoding performance of the segmentation on the symbol of TTI rear portion.
In fact, even do not consider the difference of channel estimating performance that each segmentation parallel processing is caused, the performance of the channel estimating of each segmentation still can be variant, and correspondingly, the decoding performance of each segmentation can be variant.This is because different segmentations is mapped on the interior different symbol of TTI to be transmitted, and the channel estimating performance of the different symbol in the TTI is different.This all is suitable for uplink and downlink transfer.
At up direction, when needs in uplink data channels simultaneously when transmit ascending data and upstream control signaling, the uplink control signaling transmission may cause the decoding performance of each segmentation different.For example, upstream control signaling is in the predefined transmitted over resources of uplink data channels; And to upstream data, come each segment assignments resource for transmission block according to not sending the uplink control signaling situation, but the resource that is taken by upstream control signaling in the ascending resource of each segment assignments can not be used for sending the data of this segmentation, that is to say, the resource that each segmentation is taken is punched and is obtained transmitting the uplink control signaling resource.In addition, if the method for the upstream control signaling (for example CQI) of the division the first type above considering and the upstream control signaling (for example ACK/NACK) of the second type, when the resource of distributing the upstream data segmentation to take, other resources beyond the resource that is taken by the upstream control signaling of the first type in the uplink data channels are distributed to each segmentation; The resource that is taken by the upstream control signaling of the second type in the ascending resource of each segment assignments simultaneously can not be used for sending the data of this segmentation, and the resource that namely each segmentation is taken is punched and obtained transmitting the uplink control signaling resource of the second type.In above-mentioned punch operation, because the position that each segmentation is mapped among the TTI is different, the number of resources that each segmentation is struck off may be different; Perhaps, above-mentioned punch operation may only occur in the part segmentation; Above situation all causes the actual number of resources that takies of each segmentation of up direction different, thereby decoding performance is different.
At down direction, can be by public reference signal be carried out the performance that power ascension improves channel estimating.But because the maximum transmission power of base station is certain, the power that the power ascension of reference signal must cause can be used for transmitting downlink data reduces.At this moment, a kind of solution is that the RE to the some or all of transmitting downlink data on the OFDM symbol at reference signal place punches, and namely these RE are not used in transmitting downlink data, and its transmitted power is 0.Like this, at down direction, if come to be each segment assignments resource according to the situation of the OFDM symbol at reference signal place not being punched, when punch to the OFDM symbol at reference signal place in the base station, the number of resources that each segmentation is struck off may be different, they be that the actual number of resources that takies of each segmentation is different, thereby decoding performance is different.
The number of remembering the segmentation that a transmission block is divided is N, and remembers that each segmentation is followed successively by S 1, S 2... S NBased on HARQ mechanism the transmission of data the time, when HARQ retransmits, the order of transmission of each segmentation of conversion in a TTI, make the decoding performance of segmentation when each time transmitted different, thereby after receiving terminal is carried out the HARQ merging, guarantee the decoding performance equalization of each segmentation, improve the probability that whole transmission block successfully transmits.For example, when the HARQ initial transmission, sequentially send each segmentation according to certain, in general, can be according to ascending order S 1, S 2... S NOrder send each segmentation, like this, S in current transmission 1Decoding performance compare S NDecoding performance poor; When the first time, HARQ retransmitted, the order of transmission of each segmentation of conversion was for example according to descending S N, S N-1... S 1Send each segmentation, like this, S in current the re-transmission 1Decoding performance compare S NDecoding performance good, thereby this twice transmission carried out after HARQ merges segmentation S as the recipient 1And S NDecoding performance reach unanimity, the decoding performance of whole transmission block improves; In follow-up HARQ retransmitted, the order that can take to be different from the front sent each segmentation, the order of transmission of each segmentation of transmission that also can the repeated using front.
When the method for shining upon segmentation is when shining upon successively each segmentation from the TTI starting position, for example from the time, after having shone upon a segmentation, just begin to shine upon next segmentation, like this, when carrying out the HARQ re-transmission, each segmentation of conversion is mapped to the order among the TTI.When the method for shining upon segmentation is that each segmentation of transmission block is divided into multiple group, and shine upon successively the segmentation of each group from the TTI starting position, be that the interior segmentation of each group is multiplexed on the interior identical time location of TTI, like this, when carrying out the HARQ re-transmission, the group of each segmentation of conversion is mapped to the order among the TTI.
The concrete ordering of each segmentation when the present invention does not limit for the first time transmission and re-transmission.Similar with the definition of the redundancy versions (RV) of HARQ, system can several possible segmentations of predefine be mapped to the order of TTI.Like this, when each HARQ transfer of data, adopt predefined a kind of segmentation order of transmission.At this moment, the segmentation order of transmission of actual employing during a certain data transfer can be by the indication of control signal demonstration, and this is similar to the HARQ RV that indicates current employing by control signal.Other information of passing through that the segmentation order of transmission of actual employing during a certain data transfer can imply are indicated: for example, the segmentation order of transmission of employing can be bound with HARQ RV; The segmentation order of transmission that perhaps adopts can be bound with current HARQ the number of transmissions to same piece of data.
Adopt this quadrat method, when HARQ retransmits, change the order of transmission of each segmentation, correspondingly need to determine the number (for example number of RE) of the physical resource that each segmentation takies when initial transmission and each HARQ retransmit.The method of the physical resource number of each segmentation was when the first determined that HARQ retransmits: the invariable number that keeps the physical resource that each segmentation takies when retransmitting.Namely when transmitting for the first time, calculate the physical resource number that a segmentation takies after, in the later each time re-transmission, this segmentation all takies the physical resource of similar number.The number of the physical resource of k segment assignments was when note was transmitted for the first time
Figure BDA00003467816800111
The number of the physical resource of k segment assignments remained when then HARQ retransmitted
Figure BDA00003467816800112
Here k=0,1 ..., N Seg-1.The method of the number of the physical resource that each segmentation took when the second determined that HARQ retransmits is: the number of the physical resource that the location positioning in the physical channel that is mapped to according to segmentation distributes.When transmitting for the first time, remember that the number of the physical resource of k segment assignments is And remember that the position that k segmentation is mapped to physical resource is k resource location, k resource location also just saying physical channel comprises number and is Physical resource, k=0 here, 1 ..., N Seg-1.Fixing resource location from physical channel is to the corresponding relation of this locational physical resource number.When HARQ retransmitted, the mapping order of segmentation changed, and according to the new mapping order of segmentation, determined the physical resource number that segmentation takies.That is, the new mapping order of supposing a segmentation is k, and the physical resource number that it takies is
Be transmitting apparatus figure as shown in Figure 7, harq controller (700), rate matchers (703) and physical resource mapping block (705) are embodiments of the present invention.Module (701) is used for transmission block is carried out segmentation; Module (702) is to each segmentation encode respectively (for example Turbo coding); Next, according to method of the present invention, under the control of harq controller (700), rate-matched (703) is carried out respectively in each segmentation, through other processing (704) such as interweaving, carry out physical resource mapping (705); Here when HARQ retransmitted, harq controller (700) was controlled the bit number of each segmentation rate-matched output, and changed the resource that takies when physical resource shines upon; Notice that the present invention does not limit HARQ and whether other processing (704) between rate-matched (703) and the physical resource mapping (705) controlled.
Be receiving equipment figure as shown in Figure 8, harq controller (700), rate de-matching device (703) and physical resource solution mapping block (705) are embodiments of the present invention.According to method of the present invention, under the control of harq controller (700), receiver carries out physical resource solution mapping (805) thereby obtains the signal of each segmentation, after other processing (804), rate de-matching (803) is carried out respectively in each segmentation; Here when HARQ retransmitted, harq controller (700) control receiver solution on the different physical resources of TTI mapped out the signal of segmentation, and control is carried out rate de-matching to it; Next, the soft bit behind the rate de-matching is carried out HARQ merge, and decode (802); At last, through transmission block restructuring (801) module each segmentation is combined into transmission block; Then judge whether transmission block sends successfully.
Up direction is to the mapping method of the segmentation of transmission block:
At up direction, in order to obtain more accurate channel estimating performance, have to after receiving second reference symbol in the time slot in the base station, just can carry out channel estimating, then begins soft demodulation code operations is carried out in each segmentation.Symmetry according to the sub-frame of uplink structure of LTE system, the position that is data symbol and reference symbol is symmetrical, so from the performance of channel estimating, the channel estimating performance of the symbol (ascending order arrangement) in first time slot of TTI respectively with second time slot in symbol (descending) correspondent equal.The method of the segmentation of the map transmission piece that the present invention proposes both can be used for up local formula frequency division multiplexing (LFDMA) channel, also can be used for up LFDMA+ frequency hopping (hopping) channel.Especially to up LFDMA channel, it is effect to the time diversity of transmitting uplink data that method of the present invention can improve on the basis that does not affect parallel processing and channel estimating performance.
The method that a kind of mapping is fragmented into physical layer is, each SCFDMA symbol in the TTI is divided into groups, and each segmentation is mapped to one group or organize on the SCFDMA symbol more, thereby can obtain the effect of time diversity.Whether the physical resource number that the present invention does not limit every group of SCFDMA symbol equates.Based on this mapping method, the first mapping structure is that other symbols except reference symbol in first time slot are divided into one group of G 1, simultaneously other symbols except reference symbol in second time slot are divided into one group of G 2The second mapping structure is that the symbol in the left side of the reference symbol in two time slots is divided into one group of G 1, simultaneously the symbol on the reference symbol right side in two time slots is divided into one group of G 2In LTE, to the subframe of general CP, every group comprises 6 SCFDMA symbols; To lengthening the subframe of CP, every group comprises 5 SCFDMA symbols.The performance of the data of the base station parallel process user equipment of two kinds of mapping structures is the same, and the channel estimating performance of the symbol in each group of two kinds of mapping structures also is suitable, but the second mapping structure can utilize time diversity to improve the performance of transfer of data.The third mapping structure is that the SCFDMA symbol in the left side of the reference symbol in second time slot is divided into one group of G 1, simultaneously the SCFDMA symbol on the reference symbol right side in second time slot is divided into one group of G 2In LTE, to the subframe of general CP, group G 1Comprise 9 SCFDMA symbols, group G 2Comprise 3 SCFDMA symbols; To lengthening the subframe of CP, group G 1Comprise 8 SCFDMA symbols, group G 2Comprise 2 SCFDMA symbols.It should be noted that above three kinds of mapping structures, the bit that does not limit after the rate-matched of a segmentation can only be at a group (G 1Perhaps G 2) in transmission, according to actual conditions, bit after the rate-matched of one or more segmentation may be arranged simultaneously at two group (G 1And G 2) interior transmission.
When considering that up channel is measured the reference signal (CS-RS) of (Channel Sounding), the some or all of resource of a SCFDMA symbol in the TTI may be divided and is used in transmission CS-RS, thus a resource shrinkage of transmit ascending data in the TTI.At this moment a kind of processing method is the upstream data number of resources minimizing for the group at the SCFDMA symbol place of transmitting CS-RS, and the upstream data number of resources of another group is constant.Another kind of processing method is that the number that still guarantees the upstream data resource in two groups equates.At this moment, there is the resource of the SCFDMA symbol of a transmit ascending data to be divided into two parts, and belongs to respectively different groups, thereby the physical resource number in two groups is equated.Especially, this is divided into two parts and the SCFDMA symbol that belongs to respectively not on the same group is and the symmetrical symbol of SCFDMA symbol that is used for CS-RS.For example, discussion result according to current LTE, the method of a kind of CS-RS of transmission is that CS-RS transmits at last SCFDMA symbol of TTI, with the symmetrical symbol of last SCFDMA symbol of TTI first SCFDMA symbol that is TTI, so can be divided into two parts to first SCFDMA symbol, and belong to respectively different groups.This is divided into two parts and the SCFDMA symbol that belongs to respectively not on the same group also can be last SCFDMA symbol of first time slot of TTI.The present invention does not limit the particular location of this symbol.
The method that another kind of mapping is fragmented into physical layer is that each segmentation is mapped to respectively on two groups of SCFDMA symbols that keep at a certain distance away of TTI.For example, be mapped on a part of SCFDMA symbol of each time slot of TTI.Specifically, first segmentation is mapped to respectively several symbols of first SCFDMA sign-on of second time slot of several symbols of first SCFDMA sign-on of first time slot of TTI and TTI; Second SCFDMA sign-on mapping that segmentation finishes from first segmentation in each time slot respectively; The like, the SCFDMA sign-on mapping that each segmentation finishes from previous segmentation.
Be transmitting apparatus figure as shown in Figure 9, physical resource mapping block (903) is embodiment of the present invention.Module (901) is used for transmission block is carried out segmentation; Module (902) each segmentation is encoded respectively operations such as (such as Turbo coding), rate-matched; Next, according to method of the present invention, the bit of each segmentation is carried out physical resource mapping (903).
Be receiving equipment figure as shown in figure 10, physical resource solution mapping block (1003) is embodiment of the present invention.According to method of the present invention, at physical resource solution mapping block (1003) thus demapping physical channels is obtained the bit of each segmentation; Next, the bit of each segmentation carried out respectively the operations (1002) such as rate de-matching and decoding; And in transmission block restructuring (1001) module each segmentation is combined into transmission block; Then judge whether transmission block sends successfully.
Embodiment
This part has provided six embodiment of this invention, and is too tediously long for fear of the description that makes this patent, in the following description, omitted the detailed description of function that the public is known or device etc.
The first embodiment
A kind of method of transmission block being carried out segmentation of the present invention is described in the present embodiment.Here the maximum of the section of scoring bit number is Z, and in LTE, Z equals 6144.
The bit number of note transmission block is B, is designated as b 0, b 1, b 2..., b B-1, and B>Z, so need to carry out segmentation to transmission block, and suppose that further the number of the filling bit that needs add is Y.Total number of transmission block segmentation is According to the discussion result among the LTE, segmentation can have two kinds of sizes, is designated as respectively K +And K -, note D=K +-K -, size is K -The number of segmentation be
Figure BDA00003467816800142
Size is K +The number of segmentation be C +=C-C -Here, Y=C +K ++ C -K --B.
A kind of method of adding filling bit and segmentation is: the front that Y filling bit added to transmission block; Then, carry out segmentation according to vertical order, tell first C +Individual size is K +Segmentation, then tell C -Individual size is K -Segmentation.Here first size is K +The front portion of segmentation be Y filling bit.Remember r (0≤r<C +) bit of individual segmentation is o R0, o R1, o R2..., , K here rEqual K +Perhaps K -Like this, the front portion of the 0th segmentation is Y filling bit, i.e. o 0k=0, k=0,1,2 ..., Y-1, the bit at its rear portion is o 0k=b K-Y, k=Y, Y+1, Y+2 ..., K +-1; R (1≤r<C +) bit of individual segmentation is
Figure BDA00003467816800152
K=0,1,2 ..., K +-1; R (C +≤ r<C) bit of individual segmentation is
Figure BDA00003467816800153
K=0,1,2 ... K-1.
Another method of adding filling bit and segmentation is: according to vertical order, at first transmission block is told C -Individual size is K -Segmentation; Then Y filling bit added to the front of the remaining bits of transmission block, and tell C according to vertical order +Individual size is K +Segmentation.Like this, r (0≤r<C -) bit of individual segmentation is
Figure BDA00003467816800157
K=0,1,2 ..., K-1; C -Individual segmentation front portion is Y filling bit, namely
Figure BDA00003467816800158
K=0,1,2 ..., Y-1, the bit at its rear portion is
Figure BDA00003467816800159
K=Y, Y+1, Y+2 ..., K +-1; R (C -<r<C) bit of individual segmentation is o rk = b C - · K - + ( r - C - ) · K + - Y + k , k=0,1,2,...,K +-1。
The second embodiment
Describing the present invention in the present embodiment is the method for transmission block segmentation and distribution physical resource.Here the maximum of the section of scoring bit number is Z, and in LTE, Z equals 6144, and the mode of coding adopts the Turbo coding.In Figure 11, omitted after the rate-matched to the operation between the physical resource mapping.
As shown in figure 11, the total number of bits of note transmission block is B, in the transmission block segmentation module it is carried out segmentation.Here, the note transmission block is divided into N segmentation, and remembers that the bit number of each segmentation is followed successively by K i, namely
Figure BDA00003467816800155
Here i=1,2 ..., N-1, and suppose that the bit number of adjacent two segmentations satisfies and K i≤ K I+1The resource of note physical channel adds up to N Tot, the method according to this invention is calculated the number of the physical resource of each segmentation mapping, i.e. and the physical resource number of i segmentation is
Figure BDA00003467816800156
Then, respectively each segmentation is encoded, for example Turbo encodes, and output bit number corresponding to each segmentation is respectively 3K i+ 12.Next, the number according to the physical resource of each segmentation mapping the bit behind the coding is carried out rate-matched, and note output bit once is S iSimple in order to describe, omitted among Figure 11 after the rate-matched to the operation between the physical resource mapping.Then, each segmentation is carried out the physical resource mapping according to index order from small to large from the starting position of TTI.Specifically, the segmentation that index is little is mapped to the front portion of TTI, and the large segmentation of index is mapped to the rear portion of TTI.
The 3rd embodiment
The present invention carries out the HARQ transmission to the transmission block segmentation method is described in the present embodiment.Here be transmitted as example with LTE Class1 system descending, and the hypothesis base station configures 4 transmit antennas.Not general, suppose that here the first two OFDM symbol of descending sub frame is used for transmission downlink physical control channel (PDCCH).Suppose that transmission block is divided into two segmentations, is designated as segmentation #0 and segmentation #1.The index of writing down 14 OFDM symbols in the capable subframe from left to right is #0~#13.
Figure 12 is the schematic diagram of base station map transmission piece segmentation when HARQ transmits.Segmentation mapping graph when example one is initial transmission, segmentation #0 is mapped to the front portion of TTI, namely is mapped on the public reference signal RE in addition of OFDM symbol #2~#7; Segmentation #1 is mapped to the rear portion of TTI, namely is mapped on the public reference signal RE in addition of OFDM symbol #8~#13.Example two is the segmentation mapping graphs when HARQ retransmits for the first time, and segmentation #1 is mapped to the front portion of TTI, namely is mapped on the public reference signal RE in addition of OFDM symbol #2~#7; Segmentation #0 is mapped to the rear portion of TTI, namely is mapped on the public reference signal RE in addition of OFDM symbol #8~#13.When the HARQ number of retransmissions greater than 1 the time, follow-up HARQ retransmits the mapping method that can reuse example one or example two.
Send the method for downlink data according to the base station of Figure 12, subscriber equipment is when receive data, and to initial transmission, the decoding performance of transmission block segmentation #1 is better than transmission block segmentation #0; When retransmitting for the first time, the decoding performance of transmission block segmentation #0 is better than transmission block segmentation #1.After thereby subscriber equipment had been carried out the HARQ merging to the downlink data of twice transmission, the decoding performance of these two segmentations reached unanimity, and this is conducive to improve the reception reliability of transmission block.
The 4th embodiment
The present invention carries out the HARQ transmission to the transmission block segmentation method is described in the present embodiment.Here be transmitted as example with LTE Class1 system descending, and the hypothesis base station configures 4 transmit antennas.Not general, suppose that here the first two OFDM symbol of descending sub frame is used for transmission downlink physical control channel (PDCCH).Suppose that transmission block is divided into four segmentations, is designated as segmentation #0~#3.The order of each segmentation is that schematically the present invention does not limit concrete order of transmission when noting each time transmission among Figure 13.
Figure 13 is the schematic diagram of base station map transmission piece segmentation when HARQ transmits.Segmentation mapping graph when example one is initial transmission, the mapping order of four segmentations in TTI of transmission block is to segmentation #3 from segmentation #0.Example two is the segmentation mapping graphs when once retransmitting, and the mapping order of four segmentations in TTI of transmission block is to segmentation #0 from segmentation #3; Example three is the segmentation mapping graphs when retransmitting for the second time, and the mapping order of four segmentations in TTI of transmission block is (#2, #0, #3, #1); When the HARQ number of retransmissions greater than 2 the time, follow-up HARQ retransmits can use new mapping order, also can reuse the mapping method of example one, example two or example two.
Send the method for downlink data according to the base station of Figure 13, the subscriber equipment downlink data receiving, because the position distribution of public reference signal, the decoding performance of each segmentation difference to some extent all during each transmission, after thereby subscriber equipment has been carried out the HARQ merging to the downlink data of repeatedly transmission, the decoding performance of each segmentation reaches unanimity, and this is conducive to improve the reception reliability of transmission block.
The 5th embodiment
The present invention is described at the mapping method of up direction to the transmission block segmentation in the present embodiment.Take the LTE Class1 as example, to general CP subframe structure, the index of each SCFDMA symbol is #0~#13; And to lengthening the CP subframe structure, the index of each SCFDMA symbol is #0~#11.The below describes this method as an example of up LFDMA channel example.As shown in figure 14, suppose that here the interior physical resource of up TTI is divided into two groups and comes the segmentation of map transmission piece.
Example one is the mapping structure of general CP subframe, and (#0~#2, #7~#9) are divided into one group of G to the SCFDMA symbol in reference symbol (#3 and the #10) left side in two time slots 1(#4~#6, #11~#13) are divided into one group of G to the SCFDMA symbol on reference symbol (#3 and the #10) right side in two time slots 2Here, group G 1With group G 2Be respectively applied to transmit a part of segmentation, and may exist a plurality of segmentations in two groups, to transmit simultaneously.For example, when the number of transmission block segmentation is odd number, can there be a segmentation to need in two groups, to transmit simultaneously.
Example two is the mapping structure that lengthens the CP subframe, and is similar with example one, and (#0~#1, #6~#8) are divided into one group of G to the SCFDMA symbol in reference symbol (#2 and the #9) left side in two time slots 1(#3~#5, #10~#11) are divided into one group of G to the SCFDMA symbol on reference symbol (#2 and the #9) right side in two time slots 2Here, group G 1With group G 2Be respectively applied to transmit a part of segmentation, and may exist a plurality of segmentations in two groups, to transmit simultaneously.For example, when the number of transmission block segmentation is odd number, can there be a segmentation to need in two groups, to transmit simultaneously.
When a SCFDMA symbol of sub-frame of uplink is used for transmission CS-RS, suppose that here last SCFDMA symbol is used for transmission.Example three is the mapping structures to general CP subframe, and when the data symbol to TTI divided into groups, hypothesis allowed two group (G here 1And G 2) in the number of up symbol different.(#0~#2, #7~#9) are divided into one group of G to six SCFDMA symbols in reference symbol (#3 and the #10) left side in two time slots 1(#4~#6, #11~#12) are divided into one group of G to the SCFDMA symbol on reference symbol (#3 and the #10) right side in two time slots 2Here organize G 2Than group G 1Lacked a SCFDMA symbol (#13).Group G 1With group G 2Be respectively applied to transmit a part of segmentation, and may exist a plurality of segmentations in two groups, to transmit simultaneously.
When a SCFDMA symbol of sub-frame of uplink is used for transmission CS-RS, suppose that here last SCFDMA symbol is used for transmission.When the data symbol to TTI divides into groups, make two group (G 1And G 2) number of interior ascending resource equates, example four is the mapping structures to general CP subframe.(resource division of #1, #6~#8) is one group of G for half resource of SCFDMA symbol (#0) and 4 complete S CFDMA symbols 1The resource division of second half resource of SCFDMA symbol (#0) and 4 complete S CFDMA symbols (#3~#5, #10) is one group of G 2, such two group (G 1And G 2) number of interior ascending resource equates.Group G 1With group G 2Be respectively applied to transmit a part of segmentation, and may exist a plurality of segmentations in two groups, to transmit simultaneously.
The 6th embodiment
The present invention is described at the mapping method of up direction to the transmission block segmentation in the present embodiment.Here the general CP subframe structure as an example of the LTE Class1 example is example, and the index of each SCFDMA symbol is #0~#13.Take up LFDMA channel as example, as shown in figure 15, suppose that here each segmentation is mapped to respectively on two groups of SCFDMA symbols that keep at a certain distance away of TTI.Not general, suppose that here transmission block is divided into 3 segmentations.
In example one, first segmentation is mapped to SCFDMA symbol (#0, #1, #7 and #8), and second segmentation is mapped to SCFDMA symbol (#2, #3, #9 and #10), and the 3rd segmentation is mapped to SCFDMA symbol (#4, #5, #11 and #12).Here each segmentation is mapped on two groups of SCFDMA symbols of 5 symbols in interval, so have preferably time diversity effect.
In example two, suppose that last SCFDMA symbol (#13) of TTI is used for transmission CS-RS, and be not used in transmit ascending data, the sum of the SCFDMA symbol of transmit ascending data is 11 like this.The ascending resource number of each segment assignments is greater than 3 symbols, still less than 4 symbols.First segmentation is mapped to the SCFDMA symbol (on the some or all of resource of #0, #1, #6~#8), second segmentation is mapped to SCFDMA symbol (#1, #2, #4, #8, #9 and #11), and the 3rd segmentation is mapped to SCFDMA symbol (#4~#6, #11 and #12).Here each segmentation is mapped to respectively on two groups of SCFDMA symbols of several symbols of interval, so have preferably time diversity effect.
The 7th embodiment
Describe the present invention carries out the HARQ transmission to the transmission block segmentation at up direction method in the present embodiment, suppose that here subscriber equipment sends upstream data and upstream control signaling simultaneously in uplink data channels.Notice that Figure 16 is logic diagram, namely when at the multiplexing a plurality of segmentations of SCFDMA symbol or multiplexing segmentation and upstream control signaling, Figure 16 only expresses these information multiplexings is arrived together, and does not limit concrete multiplexing method.Here suppose that transmission block is divided into four segmentations, be designated as segmentation #0~#3, each segmentation is mapped on two interior time slots of TTI to be transmitted.In Figure 16, suppose that a part of resource of the SCFDMA symbol of the uplink reference signals both sides in each time slot is used for the transmission upstream control signaling.The order of each segmentation is that schematically the present invention does not limit concrete order of transmission when noting each time transmission among Figure 16.
Figure 16 is when up direction HARQ transmits, the schematic diagram of subscriber equipment map transmission piece segmentation.Segmentation mapping graph when example one is initial transmission, the mapping order of four segmentations in TTI of transmission block is to segmentation #3 from segmentation #0.Here, a part of resource of segmentation #1 and segmentation #2 is perforated for the transmission upstream control signaling, and segmentation #0 and segmentation #3 are not perforated, so in the current transmission, the decoding performance of segmentation #0 and segmentation #3 is better than segmentation #1 and segmentation #2.Example two is the segmentation mapping graphs when once retransmitting, and the mapping order of four segmentations in TTI of transmission block is (#2, #3, #0, #1).Here, a part of resource of segmentation #0 and segmentation #3 is perforated for the transmission upstream control signaling, and segmentation #1 and segmentation #2 are not perforated, so in the current transmission, the decoding performance of segmentation #1 and segmentation #2 is better than segmentation #0 and segmentation #3.When the HARQ number of retransmissions greater than 1 the time, follow-up HARQ retransmits can use new mapping order, also can reuse example one or example two mapping methods.
Send the method for upstream data according to the subscriber equipment of Figure 16, the base station receives upstream data, because transmission uplink control signaling impact, the decoding performance of each segmentation difference to some extent all during each transmission, after but the HARQ merging has been carried out to the upstream data of repeatedly transmission in the base station, the decoding performance of each segmentation reaches unanimity, and this is conducive to improve the reception reliability of transmission block.
It should be noted that the schematic diagram of Figure 16 is equally applicable to distinguish the method for the upstream control signaling (for example ACK/NACK) of the upstream control signaling of the first type (for example CQI) and the second type.At this moment, other resources beyond the resource that is taken by the upstream control signaling of the first type in the uplink data channels are distributed to each segmentation as far as possible uniformly.Equally, the segmentation mapping graph when example one is initial transmission, the mapping order of four segmentations in TTI of transmission block is to segmentation #3 from segmentation #0.Here, a part of resource of segmentation #1 and segmentation #2 is perforated for the upstream control signaling of transmission the second type, and segmentation #0 and segmentation #3 are not perforated, so in the current transmission, the decoding performance of segmentation #0 and segmentation #3 is better than segmentation #1 and segmentation #2.Example two is the segmentation mapping graphs when once retransmitting, and the mapping order of four segmentations in TTI of transmission block is (#2, #3, #0, #1).Here, a part of resource of segmentation #0 and segmentation #3 is perforated for the upstream control signaling of transmission the second type, and segmentation #1 and segmentation #2 are not perforated, so in the current transmission, the decoding performance of segmentation #1 and segmentation #2 is better than segmentation #0 and segmentation #3.When the HARQ number of retransmissions greater than 1 the time, follow-up HARQ retransmits can use new mapping order, also can reuse example one or example two mapping methods.
Send the method for upstream data according to the subscriber equipment of Figure 16, the base station receives upstream data, because the uplink control signaling impact of transmission the second type, the decoding performance of each segmentation difference to some extent all during each transmission, after but the HARQ merging has been carried out to the upstream data of repeatedly transmission in the base station, the decoding performance of each segmentation reaches unanimity, and this is conducive to improve the reception reliability of transmission block.

Claims (10)

1. a transmission block segmentation and the method for distributing physical resource comprise step:
A) transmission block is carried out segmentation and sort by bit number;
B) determine the number of the physical resource that it takies according to the bit number of segmentation;
C) transmission block is encoded and rate adaptation operating;
D) by the order of the bit number monotonic nondecreasing of segmentation the physical resource mapping is carried out in each segmentation;
Wherein, at step b) in, the RE number of the segment assignments that the no more than bit number of number of the Resource Unit RE of the segment assignments that bit number is fewer is many.
2. method according to claim 1 is wherein at step b) in, the RE number of k segment assignments is determined by following formula:
3. method according to claim 1, it is characterized in that in steps d) in, the fewer segmentation of bit number is mapped on the symbol of front portion of Transmission Time Interval TTI, and the many segmentations of bit number are mapped on the symbol at rear portion of Transmission Time Interval TTI.
4. method according to claim 1 is characterized in that at step b) in, other RE except the RE that the Class1 control signal takies distribute to transmitting uplink data.
5. method according to claim 4 is characterized in that the RE number of k segment assignments is determined by following formula:
Figure FDA00003467816700012
6. method according to claim 4 is characterized in that, the Class1 control signal comprises channel quality indication (CQI).
7. equipment to transmission block segmentation and mapping comprises:
A) transmission block segmentation module is used for transmission block being divided into a plurality of segmentations and sorting by bit number;
B) coding, rate-matched module are used for to transmission block segmentation and encode and rate adaptation operating, wherein, and the RE number of the segment assignments that the no more than bit number of number of the Resource Unit RE of the segment assignments that bit number is fewer is many;
C) physical resource mapping block is used for by the order of the bit number monotonic nondecreasing of segmentation the physical resource mapping being carried out in each segmentation.
8. separate mapping and to the equipment of transmission block segmentation restructuring, comprising for one kind:
A) transmission block recombination module is used for sorting and combining the segmentation of transmission block and by bit number;
B) decoding, rate de-matching module are used for rate de-matching and decode operation are carried out in the transmission block segmentation, wherein, and the RE number of the segment assignments that the no more than bit number of number of the Resource Unit RE of the segment assignments that bit number is fewer is many;
C) physical resource solution mapping block is used for by the order of the bit number monotonic nondecreasing of segmentation the mapping of physical resource solution being carried out in each segmentation.
9. a transmission block segmentation and the method for distributing physical resource comprise step:
A) transmission block is carried out segmentation and sort by bit number;
B) determine the number of the physical resource that it takies according to the bit number of segmentation;
C) transmission block is encoded and rate adaptation operating;
D) by the order of the bit number monotonic nondecreasing of segmentation the physical resource mapping is carried out in each segmentation;
Wherein, in steps d) in, the fewer segmentation of bit number is mapped on the symbol of front portion of Transmission Time Interval TTI, and the many segmentations of bit number are mapped on the symbol at rear portion of Transmission Time Interval TTI.
10. equipment to transmission block segmentation and mapping comprises:
A) transmission block segmentation module is used for transmission block being divided into a plurality of segmentations and sorting by bit number;
B) coding, rate-matched module are used for to transmission block segmentation and encode and rate adaptation operating;
C) physical resource mapping block, be used for by the order of the bit number monotonic nondecreasing of segmentation the physical resource mapping being carried out in each segmentation, wherein, the fewer segmentation of bit number is mapped on the symbol of front portion of Transmission Time Interval TTI, and the many segmentations of bit number are mapped on the symbol at rear portion of Transmission Time Interval TTI.
CN201310280771.6A 2007-06-14 2007-08-06 The apparatus and method of transmission block segment transmissions Active CN103354537B (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201310280771.6A CN103354537B (en) 2007-06-14 2007-08-06 The apparatus and method of transmission block segment transmissions

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
CN200710126161.5 2007-06-14
CN2007101261615 2007-06-14
CN200710126161 2007-06-14
CN 200710143148 CN101325573B (en) 2007-06-14 2007-08-06 Apparatus and method for subsection transmission of transmission block
CN201310280771.6A CN103354537B (en) 2007-06-14 2007-08-06 The apparatus and method of transmission block segment transmissions

Related Parent Applications (1)

Application Number Title Priority Date Filing Date
CN 200710143148 Division CN101325573B (en) 2007-06-14 2007-08-06 Apparatus and method for subsection transmission of transmission block

Publications (2)

Publication Number Publication Date
CN103354537A true CN103354537A (en) 2013-10-16
CN103354537B CN103354537B (en) 2017-03-29

Family

ID=40188904

Family Applications (2)

Application Number Title Priority Date Filing Date
CN 200710143148 Active CN101325573B (en) 2007-06-14 2007-08-06 Apparatus and method for subsection transmission of transmission block
CN201310280771.6A Active CN103354537B (en) 2007-06-14 2007-08-06 The apparatus and method of transmission block segment transmissions

Family Applications Before (1)

Application Number Title Priority Date Filing Date
CN 200710143148 Active CN101325573B (en) 2007-06-14 2007-08-06 Apparatus and method for subsection transmission of transmission block

Country Status (1)

Country Link
CN (2) CN101325573B (en)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109314849A (en) * 2018-09-14 2019-02-05 北京小米移动软件有限公司 Data transmission method, device, equipment, system and storage medium
CN110677907A (en) * 2014-05-19 2020-01-10 高通股份有限公司 Apparatus and method for simultaneous multiplexing and multiple access for different latency targets with thin control
CN111356151A (en) * 2018-12-24 2020-06-30 深圳市中兴微电子技术有限公司 Data processing method and device and computer readable storage medium
CN112436900A (en) * 2020-10-30 2021-03-02 中国石油天然气集团有限公司 Data transmission method and device
US11832230B2 (en) 2014-05-19 2023-11-28 Qualcomm Incorporated Apparatus and method for inter-band pairing of carriers for time division duplex transmit- and receive-switching and its application to multiplexing of different transmission time
WO2023246525A1 (en) * 2022-06-22 2023-12-28 大唐移动通信设备有限公司 Data transmission method, device and apparatus, and storage medium

Families Citing this family (13)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP2410684B1 (en) 2009-03-16 2019-08-28 Sun Patent Trust Radio receiving apparatus, radio transmitting apparatus and wireless communication method
US8144720B2 (en) * 2009-04-24 2012-03-27 Telefonaktiebolaget L M Ericsson (Publ) Uplink radio resource allocation in the presence of power limited users
CN101699780B (en) * 2009-10-30 2012-12-19 上海华为技术有限公司 Data transmission method, user equipment, base station and data transmission system
CN102065465B (en) * 2009-11-17 2013-11-06 中国移动通信集团公司 Method, system and device for transmitting data
CN102244930B (en) * 2010-05-13 2014-04-30 华为技术有限公司 Method and equipment for distributing resources of amplify-and-forward relay network
CN104106296A (en) * 2013-02-08 2014-10-15 华为技术有限公司 Information sending method, information receiving method and device thereof
US9510350B2 (en) * 2013-09-13 2016-11-29 Telefonaktiebolaget Lm Ericsson (Publ) Reference signal allocation for flexible data lengths
CN106063344B (en) * 2014-07-29 2019-11-29 华为技术有限公司 A kind of data transmission method and user equipment
US10361823B2 (en) 2015-05-15 2019-07-23 Huawei Technologies Co., Ltd. Method and apparatus for transmitting uplink data in licensed-assisted access system
CN106571895B (en) * 2015-10-13 2020-11-20 中兴通讯股份有限公司 Timing method and device for hybrid automatic repeat request
CN107734555B (en) * 2016-08-12 2021-07-30 中国移动通信有限公司研究院 Data receiving and transmitting channel, data transmission method and device
CN107835184A (en) * 2017-11-20 2018-03-23 北京东土军悦科技有限公司 TLV data stage treatment method, device, electronic equipment and storage medium
CN110708758B (en) * 2018-07-10 2022-02-25 华为技术有限公司 Data sending method and device

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN1494248A (en) * 2003-08-29 2004-05-05 上海华龙信息技术开发中心 Physical channel mapping treatment device used in broad band CDMA communication system and base band signal treatment device
US20040141515A1 (en) * 2002-12-10 2004-07-22 Xiao Zhi Yong Method of segmenting a re-ordering buffer of WCDMA HSDPA system and mapping data thereto
CN1879341A (en) * 2003-11-10 2006-12-13 Lg电子株式会社 Signal processing apparatus and method using multi-output mobile communication system
CN1893342A (en) * 2005-07-05 2007-01-10 上海原动力通信科技有限公司 Multi-carrier-wave IISDPA business trans mission channel code processing method and coding apparatus

Family Cites Families (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR101000388B1 (en) * 2003-05-15 2010-12-13 엘지전자 주식회사 mobile communication system, and signaling method of the same

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US20040141515A1 (en) * 2002-12-10 2004-07-22 Xiao Zhi Yong Method of segmenting a re-ordering buffer of WCDMA HSDPA system and mapping data thereto
CN1494248A (en) * 2003-08-29 2004-05-05 上海华龙信息技术开发中心 Physical channel mapping treatment device used in broad band CDMA communication system and base band signal treatment device
CN1879341A (en) * 2003-11-10 2006-12-13 Lg电子株式会社 Signal processing apparatus and method using multi-output mobile communication system
CN1893342A (en) * 2005-07-05 2007-01-10 上海原动力通信科技有限公司 Multi-carrier-wave IISDPA business trans mission channel code processing method and coding apparatus

Cited By (15)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US11432305B2 (en) 2014-05-19 2022-08-30 Qualcomm Incorporated Apparatus and method for synchronous multiplexing and multiple access for different latency targets utilizing thin control
US11452121B2 (en) 2014-05-19 2022-09-20 Qualcomm Incorporated Apparatus and method for synchronous multiplexing and multiple access for different latency targets utilizing thin control
US11832230B2 (en) 2014-05-19 2023-11-28 Qualcomm Incorporated Apparatus and method for inter-band pairing of carriers for time division duplex transmit- and receive-switching and its application to multiplexing of different transmission time
US11503618B2 (en) 2014-05-19 2022-11-15 Qualcomm Incorporated Apparatus and method for synchronous multiplexing and multiple access for different latency targets utilizing thin control
CN110677907B (en) * 2014-05-19 2021-10-29 高通股份有限公司 Apparatus and method for simultaneous multiplexing and multiple access for different latency targets with thin control
US11382109B2 (en) 2014-05-19 2022-07-05 Qualcomm Incorporated Apparatus and method for synchronous multiplexing and multiple access for different latency targets utilizing thin control
CN110677907A (en) * 2014-05-19 2020-01-10 高通股份有限公司 Apparatus and method for simultaneous multiplexing and multiple access for different latency targets with thin control
US11357022B2 (en) 2014-05-19 2022-06-07 Qualcomm Incorporated Apparatus and method for interference mitigation utilizing thin control
CN109314849A (en) * 2018-09-14 2019-02-05 北京小米移动软件有限公司 Data transmission method, device, equipment, system and storage medium
CN109314849B (en) * 2018-09-14 2022-01-11 北京小米移动软件有限公司 Data transmission method, device, equipment, system and storage medium
US11902945B2 (en) 2018-09-14 2024-02-13 Beijing Xiaomi Mobile Software Co., Ltd. Method, device, and system for transmitting data in divided transmission blocks
CN111356151B (en) * 2018-12-24 2022-07-08 深圳市中兴微电子技术有限公司 Data processing method and device and computer readable storage medium
CN111356151A (en) * 2018-12-24 2020-06-30 深圳市中兴微电子技术有限公司 Data processing method and device and computer readable storage medium
CN112436900A (en) * 2020-10-30 2021-03-02 中国石油天然气集团有限公司 Data transmission method and device
WO2023246525A1 (en) * 2022-06-22 2023-12-28 大唐移动通信设备有限公司 Data transmission method, device and apparatus, and storage medium

Also Published As

Publication number Publication date
CN103354537B (en) 2017-03-29
CN101325573B (en) 2013-08-21
CN101325573A (en) 2008-12-17

Similar Documents

Publication Publication Date Title
CN101325573B (en) Apparatus and method for subsection transmission of transmission block
CN1196275C (en) Method and arrangement for iteratively improving a channel estimate
CN107359967B (en) Blind detection method for reducing PDCCH blind detection times based on polarization code
CN101953214B (en) Control channel signaling using code points for indicating the scheduling mode
CN101621364B (en) Automatic retransmission controller and reconfiguration device of retransmission block
CN101563877B (en) Optimal error protection coding for MIMO ACK/NACK/PRE/POST information
CN101388743B (en) Physical channel mapping device and mapping method for OFDM system
CN101662346B (en) Automatic retransmission control method, communication system as well as transmitter and receiver thereof
CN102025472B (en) Base station and terminal
US10972228B2 (en) Base station device, user equipment, wireless communication system, and communication method
CN101765992A (en) Methods and apparatus for rate matching to improve hybrid arq operations
KR20100086994A (en) Mobile communication system, base station device, user device and method
CN102255712B (en) Soft storage allocation method for hybrid automatic repeat request process of long term evolution system
CN101917257A (en) Incremental redundancy transmission in a mimo communication system
JP2008236432A (en) User equipment in mobile communication system, base station apparatus and method
CN102224689A (en) Cqi transmission power control method and apparatus for wireless communication system supporting multi-cell hsdpa
CN102318254A (en) Method for requesting retransmission, method for retransmission and devices thereof
CN101325739A (en) Method for transmitting upstream data and upstream control signaling
CN103378956A (en) Method and device for processing soft cache in TDD system
CN101036333A (en) Wireless packet communication apparatus
CN101674164A (en) Method for feeding back ACK/NACK information
CN109923812B (en) Method and device for dynamic scheduling in user equipment and base station
CN105453469A (en) Communications system, infrastructure equipment and method
CN103297194B (en) Orthogonal frequency-division multiplex singal receiver and method of reseptance
CN101771520A (en) Method and device for sending feedback information

Legal Events

Date Code Title Description
C06 Publication
PB01 Publication
C10 Entry into substantive examination
SE01 Entry into force of request for substantive examination
GR01 Patent grant
GR01 Patent grant