CN101379747A - Method and apparatus for selecting multiple transport formats and transmitting multiple transport blocks simultaneously with multiple H-ARQ processes - Google Patents
Method and apparatus for selecting multiple transport formats and transmitting multiple transport blocks simultaneously with multiple H-ARQ processes Download PDFInfo
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Abstract
A method and apparatus for selecting multiple transport formats and transmitting multiple transport blocks (TBs) in a transmission time interval simultaneously with, multiple hybrid automatic repeat request (H-ARQ) processes in a wireless communication system are disclosed. Available physical resources and H-ARQ processes associated with the available physical resources are identified and channel quality of each of the available physical resources is determined. Quality of service (QoS) requirements of higher layer data to be transmitted are determined. The higher layer data is mapped to at least two H-ARQ processes. Physical transmission and H-ARQ configurations to support QoS requirements of the higher layer data mapped to each H-ARQ process are determined. TBs are generated from the mapped higher layer data in accordance with the physical transmission and H-ARQ configurations of each H-ARQ process, respectively. The TBs are transmitted via the H-ARQ processes simultaneously.
Description
Technical field
The present invention relates to wireless communication system.More specifically, the present invention relates to a kind of multiple transport formats and use automatic repetitive requests of polyhybird (H-AQR) in wireless communication system, selected and handle the method and apparatus that in Transmission Time Interval (TTI), sends many transmission blocks (TB) simultaneously.
Background technology
The purpose that the high-speed packet of evolution inserts the Long Term Evolution (LTE) of (HSPA+) and general land wireless access (UTRA) and universal terrestrial access network (UTRAN) is to develop a kind of Radio Access Network, is used for high data rate, the low power system capacity and the covering of hiding and optimizing grouping and improving.In order to realize these targets, considering the evolution of wave point and radio network frame.In HSPA+, air interface technologies will be still based on code division multiple access (CDMA), but has more effective physical layer architecture, and described physical layer architecture comprises independent channel coding (distinguishing to some extent with channel quality) and multiple-input and multiple-output (MIMO).In LTE, OFDM (OFDMA) and frequency division multiple access (FDMA) are proposed as air interface technologies, to be respectively applied for down link and up link.
Adopted H-ARQ by several wireless communication standards that comprise third generation partnership program (3GPP) and 3GPP2.Except automatic repetitive requests (ARQ) function of Radio Link control (RLC) layer, H-ARQ can improve throughput, compensates the link adaptation mistake, and provides effective transmission speed by channel.By with the H-ARQ function setting at Node-B, rather than in the radio network controller (RNC), can obviously reduce by (being affirmative acknowledgement (ACK) or negative response (NACK)) the caused delay of H-ARQ feedback.The soft bit of subscriber equipment (UE) receiver original transmitted capable of being combined and the soft bit that retransmits subsequently are to realize higher bLock error rate (BLER) performance.Can implement Chase merging or increasing property redundancy.
Insert the asynchronous H-ARQ of use in (HSDPA) in high-speed downlink packet, insert in High Speed Uplink Packet and use synchronous H-ARQ in (HSUPA).In HSDPA and HSUPA, for the transmission assigned radio resource is based on the encoding amount of a CQI (CQI) feedback at certain frequency band.Not distinct in channelization code.Therefore, one H-ARQ is handled distribution from a plurality of dedicated channel MAC (MAC-d) stream multiplexed a HSDPA medium access control (MAC-hs) stream or a HSUPA medium access control (MAC-e/es) stream, and a Cyclic Redundancy Check is attached to a transmission block.
The new physical layer attribute of introducing in HSPA+ comprises MIMO and different channelization code.The new physical layer attribute of introducing in LTE comprises MIMO and different subcarriers (centralized or distributed).By introducing these new physical layer attributes, should change the performance and transformat combination (TFC) selection course of traditional independent H-ARQ scheme.In traditional independent H-ARQ scheme, once only activate a H-ARQ and handle, and in each TTI, need to determine the only TFC of a transmission data block.Tradition TFC selection course does not have the function that the TFC more than a data block that is used for many H-ARQ processing is selected.
Summary of the invention
The present invention relates to a kind of method and apparatus that in wireless communication system, uses many H-ARQ to handle in TTI, to select multiple transport formats and send many TB.Determine the channel quality of available physical resources and each this available physical resources, and the identification H-ARQ related with this available physical resources handles.Determine service quality (QoS) demand of high level data stream waiting for transmission.Described high level data stream is mapped at least two H-ARQ and handles.Determine physical transfer parameter and H-ARQ configuration, map to the QoS demand of the high level data stream of each H-ARQ processing with support.Physical transfer parameter and the H-ARQ configuration of handling according to each H-ARQ given birth to TB from the high level data miscarriage of mapping respectively.Send TB simultaneously via the H-ARQ processing.
Description of drawings
Provide and in conjunction with the accompanying drawings and by the description of the embodiment understood, the present invention will obtain more detailed understanding by following mode by example, wherein:
Fig. 1 is the block diagram of the equipment of configuration according to the present invention; With
Fig. 2 many H-ARQ used according to the invention handle the flow chart that transmits the method for many TB in TTI simultaneously.
Embodiment
When hereinafter quoting, term " wireless transmitter/receiver unit " (WTRU) includes but not limited to subscriber equipment (UE), mobile radio station, fixing or moving user unit, beep-pager, portable phone, PDA(Personal Digital Assistant), computer or any other type of user device that can move in wireless environment.When hereinafter quoting, term " base station " includes but not limited to Node-B (eNB), site controller, the access point (AP) of Node-B, evolution or any other type docking facilities that can move in wireless environment.
The present invention is applicable to any wireless communication system, includes but not limited to LTE, OFDM, MIMO or the OFDM/MIMO of Wideband Code Division Multiple Access (WCDMA) (WCDMA), CDMA2000, HSPA+, 3GPP system.
Feature of the present invention can join in the integrated circuit (IC), perhaps can be configured in the circuit that comprises a plurality of interconnecting members.
Different antenna space wave beam or channelization code can experience different channel qualities, and described channel quality can be fed back by CQI to be represented.Identical adaptive modulation and coding (AMC) can be used for all subcarriers, spatial beams or channelization code, and they are to have the independently quality of subcarrier, spatial beams or channelization code respectively.Replacedly, channel condition can be used to different AMC are used for different subcarriers, spatial beams or channelization code, with the maximization performance.
When use depended on the AMC of subcarrier, spatial beams or channelization code, according to the present invention, each data block of distributing to each subcarrier, spatial beams or channelization code was related with a CRC.Otherwise, when error of transmission,, need be retransmitted so be assigned to the whole group of different subcarriers, spatial beams or channelization code because whole group is related with single CRC.To waste valuable Radio Resource for the re-transmission of each data block that has correctly received.Because each antenna can be in different channel conditions, so when using MIMO, adopt identical condition.Therefore, according to the present invention,, independent CRC is added into each transmission data block when handling by each H-ARQ when using multidimensional H-ARQ to handle with one or more subcarriers, channelization code, transmitting antenna (or spatial beams) response.In traditional independent H-ARQ scheme, once only activate a H-ARQ and handle, and in each TTI, need to determine the only TFC of a transmission data block.Tradition TFC selection course does not have selects function with the QoS demand of suitable support high level data stream to being used for the TFC more than a data block that many H-ARQ handle.
Fig. 1 is that many H-ARQ used according to the invention handle the block diagram that sends the equipment 100 of many transmission blocks (TB) in Transmission Time Interval (TTI) simultaneously.This equipment 100 can be WTRU, Node-B or any other communicator.This equipment 100 comprises that a plurality of H-ARQ handle 102a-102n, a plurality of multiplexed and link adaptation processor 104a-104n and controller 106.Each is multiplexed related with link adaptation processor 104a-104n and a H-ARQ processing 102a-102n.Each multiplexed and link adaptation processor 104a-104n receive physical resource configuration (being that subcarrier is distributed or centralized, a MIMO antenna configurations etc.) and the CQI related with these physical resources.
It is related with the particular group physical resource that each available H-ARQ handles 102a-102n.Dynamically definite physical resource is handled the related of 102a-102n with H-ARQ, perhaps can dispose this association semi-staticly.Network entity (for example eNB scheduler) determines to distribute how many physical resources.When selecting TFC by multiplexed and link adaptation processor 104a-104n at every turn, when perhaps each this H-ARQ handles 102a-102n and produces H-ARQ for specific T B and retransmit, but dynamic reallocation and the related physical resource of specific H-ARQ processing.Can carry out the reallocation of physical resource based on the CQI of specific physical resource, perhaps can determine the reallocation of physical resource based on predetermined frequency-hopping mode.
Multiplexed and link adaptation processor 104a-104n handle 102a-102n for every group of physical resource with related H-ARQ and independently carry out link adaptation.Each multiplexed and link adaptation processor 104a-104n determines the maximum times of modulation and encoding scheme (MCS), multiplexed TB, transmitted power demand, H-ARQ redundancy versions and each TTI re-transmission.This group transmission information is offered each H-ARQ handle 102a-102n.
Can flow (if implementing MIMO), the independent subcarrier in frequency domain (if implementing OFDMA or FDMA), the independent channel coding in encoding domain (if implementing CDMA), the independent time slot in time domain or above-mentioned combination in any by the separate space in spatial domain and define physical resource.Independently subcarrier can be distributed or centralized.Channelization code is to distribute to the physical resource of different TB independently.In cdma system, can distribute different channelization code, to send a TB or several TB based on each TB required channel condition and data rate.The maximum quantity of the TB that can send is less than or equal to the maximum quantity of available channelization code.But, can use several H-ARQ to handle and send several TB simultaneously via different physical resources when several separate spatial flow, subcarrier or channelization code time spent.For example, if two spatial flows are available in 2 * 2MIMO system, then can use two independent H-ARQ to handle and send two TB simultaneously via two spatial flows.
Different physical resource (being different subcarrier, antenna space wave beam, channelization code or time slots) can experience different channel qualities.Determine the quality of each physical resource by one or more CQI measurements.CQI can feed back from communication counterpart, perhaps can obtain based on the channel reciprocity.Also can represent CQI by the MCS and/or the maximum transport block size of permission.
Available physical resources is the amount that is used for independently spatial flow, subcarrier, channelization code and the time slot of transfer of data in can be during certain.Available physical resources for a WTRU depends on a plurality of factors, for example the quantity of the Node-B WTRU that need support in a sub-district, the data rate that need support from the QoS level (for example priority, potentiality, fairness and buffering state) of the channel condition of the interference level of other sub-district, WTRU, service that WTRU need support, WTRU etc.
According to the present invention, many H-ARQ handle 102a-102n and move simultaneously and concurrently.102a-102n can be in order successfully to transmit the re-transmission of adopting varying number owing to the H-ARQ processing, and owing to the data flow that maps to H-ARQ processing 102a-102n can have the definite varying number that retransmits or the QoS demand of different TTI size, if differ from one another the step so H-ARQ handles, then certain H-ARQ may be disabled.In arbitrary TTI, the H-ARQ of any amount processing can become available.According to the present invention, in common TTI, become available with one group of related physical resource more than a H-ARQ processing.By controller 106 coordinate H-ARQ handle and physical resource between association.
Replacedly; also can by based on data flow QoS demand with distribute to the related CQI of physical resource group that each H-ARQ handles, the high level data stream 108a-108m that will can divide into groups according to the QoS demand and different H-ARQ processing 102a-102n shine upon and realize the error protection that do not wait.For example, CQI can illustrate one group of physical resource be better than other the group physical resource.High level data stream with higher QoS demand can map to and the better related H-ARQ processing of physical resource.The QoS demand, grouping size, the H-ARQ capacity that flow based on high level data wait definite quantity that will map to the high level data stream of specific H-ARQ processing.In case determine to use specific H-ARQ to handle each high level data stream of transmission, come multiplexed these data flow by the multiplexed and link adaptation processor 104a-104n that is used for different H-ARQ processing.
Each multiplexed and link adaptation processor 104a-104n receives input (for example the buffer capacity of the CQI of the physical resource of Fen Peiing, maps data streams etc.), and definite physical transfer parameter and H-ARQ configuration, to support to handle the QoS demand of the high level data stream 108a-108m of mapping with each H-ARQ.Described physical transfer parameter comprises: through-put power, modulation and encoding scheme, TTI size, transmission block size and wave beam form pattern, sub-carrier allocation, MIMO antenna configurations etc.The H-ARQ configuration parameter comprises: H-ARQ sign, the maximum times that retransmits, redundancy versions (RV), CRC size etc.Multiplexed and link adaptation processor 104a-104n offer related H-ARQ with the H-ARQ parameter and handle 102a-102n.
Multiplexed all physical resources that can adopt identical MCS, transmission block size, TTI size and/or transmitted power to have nothing to do to quality with physical resource with link adaptation processor 104a-104n.Replacedly, multiplexed and link adaptation processor 104a-104n can adopt different MCS, transmission block size, TTI size and/or based on the channel condition transmitted power to different physical resources, so that maximizing performance.
When AMC that uses the dependence physical resource and H-ARQ operation, preferably, that each data block of distributing to each physical resource is related with single CRC.By this scheme, the whole group that is distributed to different physical resources does not need to be retransmitted when error of transmission, because each transmission block is related with single CRC, and handles 102a-102n by single H-ARQ and handles.
Then, multiplexed and link adaptation processor 104a-104n is selecting suitable TFC (be that TB size, TB group size, TTI are big or small, modulation and encoding scheme (MCS), through-put power, antenna beam, sub-carrier allocation, CRC size, redundancy versions (RV) and map to the data block etc. of Radio Resource) the high level data stream 112a-112m generation TB from distributing afterwards based on CQI and physical transfer parameter to TB.One or more high level data streams can be multiplexed into a TB.Single CRC is added into each TB, is used for independent error detection and H-ARQ and handles.Each TB is provided to the H-ARQ processing 102a-102n that distributes with related transmission parameter.Then, handle 102a-102n via the H-ARQ that distributes respectively and send TB.
Can use transmission or blind Detecting technology to decode before the transmission parameter the recipient, the parameter that can support many H-ARQ to handle transfer to the recipient with signal.The TB that produces along with being sent to H-ARQ, the transmission parameter of association is handled 102a-102n, to be used for transmission.
Fig. 2 is the flow chart that many H-ARQ used according to the invention handle the method 200 of transmitting many TB in TTI simultaneously.The identification available physical resources with handle the channel quality (step 202) of the related available physical resources of 102a-102n with each H-ARQ.Determine QoS demand and the buffering capacity (step 204) of high level data stream 112a-112m to be sent.It should be noted that the step in method 200 can be carried out with different orders, some step available parallelisms are carried out.For example, step 204 can be used on before the step 202 or synchronously and carries out.
By controller 106 high level data is flowed 112a-112m and map to each H-ARQ processing 102a-102n.Handle 102a-102n for each available H-ARQ and determine physical transfer parameter and H-ARQ configuration, to support to map to the required QoS (step 206) that each H-ARQ handles the high level data stream 112a-112m of 102a-102n.But, be necessary to determine which high level data stream 112a-112m is mapped to different H-ARQ handles when in TTI, having more than a H-ARQ processing time spent for transmission.High level data stream 112a-112m can have or not have similar QoS demand.
When the subclass that flows 112a-112m to all high level datas stream 112a-112m or the high level data of different H-ARQ processing to be mapped needs similar QoS, standardize (promptly in each TTI for the QoS that provides by H-ARQ processing 102a-102n then, regulate transmission parameter (for example MCS, TB size and through-put power) and H-ARQ configuration, selecting TFC, is similar thereby handle the QoS that provides among the 102a-102n at H-ARQ).The QoS that can be implemented between many H-ARQ processing 102a-102n by the link adaptation parameters (for example MCS, TB size, through-put power etc.) that is adjusted between a plurality of H-ARQ processing 102a-102n standardizes.For example, available higher MCS is distributed to the physical resource with better channel quality, and will distribute to physical resource than low MCS with poor channel quality.This can cause the multiplexed data blocks for the different sizes of different H-ARQ processing.
Replacedly, when high level data stream 112a-112m needs different QoS, high level data stream 112a-112m can be mapped to the H-ARQ related with physical resource and handle 102a-102n, and wherein said physical resource has the quality near the QoS demand that is matched with high level data stream 112a-112m.The advantage of using many H-ARQ to handle is its flexibility to multiplexing logic channel or MAC stream, and wherein said MAC stream has the related physical resource of different QoS requirements handle 102a-102n and to(for) different H-ARQ.When certain physics resource representation channel quality was better than other physical resource, the data with higher QoS were mapped to the H-ARQ related with this physical resource and handle.This has improved the use of physical resource, and has maximized throughput of system.Replacedly, or additionally, the maximum times of configurable MCS and/or re-transmission is the QoS demand of matching logic channel or MAC stream closer with distinguishing QoS.
Map to after H-ARQ handles 102a-102n high level data being flowed 112a-112m, undertaken multiplexedly by handling the related high level data stream 112a-112m of 102a-102n, handle the physical transfer parameter of 102a-102n and H-ARQ and dispose to produce and be used for each H-ARQ and handle 102a-102n (step 208) according to being used for each H-ARQ respectively with each H-ARQ.But be used for data multiplex sequential processes or parallel processing that each H-ARQ handles 102a-102n.Then, the H-ARQ processing 102a-102n via association sends TB (step 210) simultaneously.
May or can not successfully receive the TB of transmission the communication party.In subsequent TTI, retransmit the TB of failure.Preferably, the size of the TB of re-transmission remains on the identical size that the communication party carries out soft merging.Re-transmission for the TB that fails has several selections.
Select according to first, retransmit the physical resource that distributes remain unchanged (promptly handling the TB that retransmits failure) via identical physical resource and H-ARQ for the H-ARQ of TB.Transmission parameter and H-ARQ configuration (being TFC) can be changed.Particularly, link adaptation parameters (for example day line options, AMC or transmitted power) can be changed, to maximize the chance that successfully transmits the TB that retransmits.When changing link adaptation parameters, the parameter that changes can be sent to the recipient with signal for the re-transmission of the TB that fails.Selectively, the recipient can adopt the blind Detecting technology, the signaling load of the parameter that is used to change with elimination.
Select according to second, the physical resource that distributes for the H-ARQ of transmission block retransmits can be by dynamically reallocation (promptly retransmitting the TB that fails) in different physical resources and identical H-ARQ processings.The reallocation of physical resource can be based on CQI or based on known frequency-hopping mode.
In another was selected, the H-ARQ of failure transmission can segmentation in many H-ARQ handle, and each independently segmentation send to increase the possibility of successful H-ARQ transmission.Select according to this, the physical resource that is used to retransmit TB is reallocated (promptly handling the TB that sends failure via different H-ARQ).Be used for H-ARQ that TTI formerly sends the TB of failure be treated as available, to be used at subsequent TTI transmission other TB arbitrarily.The quantity of maximum transmit power, subcarrier or channelization code, the quantity of antenna or distribution and recommendation MCS can be reallocated, with the re-transmission of the TB that is used to fail.Preferably, can produce the TFCS subclass of new permission, the physical resource of the TB that is used to fail with reflection changes.New argument can be sent to the recipient with signal, to guarantee successfully reception.Replacedly, can adopt the blind Detecting technology, the signaling load of the parameter that is used to change with elimination the recipient.
Embodiment
1. one kind is used many H-ARQ to handle the method that sends many TB in TTI in wireless communication system.
2. as embodiment 1 described method, comprise the step that identification available physical resources and related H-ARQ handle.
3. as arbitrary described method among the embodiment 1-2, comprise the step of the channel quality measurement that obtains each available physical resources.
4. as arbitrary described method among the embodiment 1-3, comprise at least one high level data stream is mapped to the step that at least two H-ARQ handle.
5. as embodiment 4 described methods, comprise and determine that physical transfer parameter and H-ARQ are configured to support to map to the step of the QoS demand of the high level data stream that each H-ARQ handles.
6. as embodiment 5 described methods, comprise that the physical transfer parameter and the H-ARQ that handle according to each H-ARQ respectively dispose the step of giving birth to TB from the high level data miscarriage of mapping.
7. as embodiment 6 described methods, comprise via H-ARQ and handle the step that sends TB simultaneously.
8. as arbitrary described method among the embodiment 5-7, wherein physical transfer parameter and H-ARQ configuration comprises the TFC that is used for each TB.
9. as arbitrary described method among the embodiment 2-8, wherein communication node comprises a plurality of antennas that are used for MIMO, and discerns available physical resources based on spatial data independently.
10. as arbitrary described method among the embodiment 2-9, wherein discern available physical resources based on the independent frequency subcarrier.
11. as embodiment 10 described methods, wherein said subcarrier is a distributed subcarriers.
12. as embodiment 10 described methods, wherein said subcarrier is centralized subcarrier.
13., wherein discern available physical resources based on channelization code independently as arbitrary described method among the embodiment 2-12.
14., wherein discern available physical resources based on different time slots as arbitrary described method among the embodiment 2-13.
15. as arbitrary described method among the embodiment 2-14, it is related to determine dynamically that wherein physical resource and H-ARQ handle.
16. as arbitrary described method among the embodiment 2-14, configures physical resource and H-ARQ processing is related wherein semi-staticly.
17. it is, further comprising the steps of: as to select to treat that the high level data that sends flows in next TTI, handle thereby only selected high level data stream is mapped to H-ARQ as arbitrary described method among the embodiment 4-16.
18. as embodiment 17 described methods, wherein to the packet allocation life span time on each high level data stream, thus the selection of the grouping that is used to transmit based on the described life span time.
19. as arbitrary described method among the embodiment 5-18, wherein when the QoS demand of high level data stream be similar in, determine physical transfer and H-ARQ configuration, thereby the QoS between available H-ARQ handles is similar.
20. as embodiment 19 described methods, wherein handle the MCS that adopts higher order, handle the MCS that adopts low order for H-ARQ with low channel quality for H-ARQ with high channel quality.
21., wherein, each H-ARQ is handled the maximum times of distributing re-transmission based on the QoS demand of the high level data stream that maps to the H-ARQ processing as arbitrary described method among the embodiment 19-20.
22. as arbitrary described method among the embodiment 5-18, wherein when the QoS demand of high level data stream be in the dissmilarity, each high level data stream is mapped to the H-ARQ related with channel quality handle, described channel quality is near the QoS demand that is matched with high level data stream.
23., in wherein the QoS demand that flows when high level data is dissmilarity, H-ARQ is handled the maximum times of distributing re-transmission based on the QoS demand of the high level data stream that maps to the H-ARQ processing as arbitrary described method among the embodiment 5-18.
24., wherein when the bust this of TB, map to the physical resource that H-ARQ handles and do not change for the re-transmission of TB as arbitrary described method among the embodiment 2-23.
25. as embodiment 24 described methods, wherein physical transfer and H-ARQ are configured to the re-transmission of TB and change.
26. as embodiment 24 described methods, wherein to the TB segmentation, to be used for re-transmission.
27. as arbitrary described method among the embodiment 2-23, wherein when the bust this of TB, the physical resource that maps to TB is that the re-transmission of TB changes.
28. as arbitrary described method among the embodiment 1-27, wherein said wireless communication system is the HSPA+ system.
29. as arbitrary described method among the embodiment 1-27, wherein said wireless communication system is the LTE of 3G wireless communication system.
30., wherein begin to determine available physical resources and related H-ARQ processing on common TTI border as arbitrary described method among the embodiment 2-29.
31. as arbitrary described method among the embodiment 5-30, wherein said physical transfer parameter comprises the MCS that is used for each TB.
32. as embodiment 31 described methods, wherein select to be used for the MCS of each TB, to distinguish the QoS demand of TB.
33., wherein select to be used for the MCS of each TB, thereby the QoS that supports is similar in H-ARQ handles as embodiment 31 described methods.
34. as arbitrary described method among the embodiment 5-33, wherein said physical transfer parameter comprises the transmission block size that is used for each TB.
35., wherein select to be used for the TB size of each TB to distinguish the QoS demand of TB as embodiment 34 described methods.
36., wherein select to be used for the TB size of each TB, thereby the QoS that supports is similar between H-ARQ handles as embodiment 34 described methods.
37. one kind is used many H-ARQ to handle the equipment that sends many TB in TTI in wireless communication system.
38., comprise that a plurality of H-ARQ handle as embodiment 37 described equipment.
39. as embodiment 38 described equipment, comprise controller, being configured to discern available physical resources handles with the H-ARQ related with this available physical resources, based on the QoS demand of the channel quality of each available physical resources and high level data stream at least one high level data stream is mapped at least two H-ARQ and handles, and definite physical transfer parameter and H-ARQ are configured to support to map to the QoS demand of the high level data stream that each H-ARQ handles.
40. as embodiment 39 described equipment, comprise a plurality of multiplexed and link adaptation processors, each multiplexed and link adaptation processor and H-ARQ handle related and are configured to the physical transfer parameter handled according to each H-ARQ and the H-ARQ configuration is covered multiplexed high level data with the link adaptation processor and flowed and produce TB from mapping to.
41. as embodiment 40 described equipment, the TFC of the high level data stream that wherein each is multiplexed and the link adaptation processor is identified for shining upon.
42. as arbitrary described equipment among the embodiment 39-41, wherein said controller is based on discerning available physical resources by the independently spatial data that a plurality of antenna produced that is used for MIMO.
43. as arbitrary described equipment among the embodiment 39-42, wherein said controller is discerned available physical resources based on subcarrier independently.
44. as embodiment 43 described equipment, wherein said subcarrier is a distributed subcarriers.
45. as embodiment 43 described equipment, wherein said subcarrier is centralized subcarrier.
46. as arbitrary described equipment among the embodiment 39-45, wherein said controller is discerned available physical resources based on channelization code independently.
47., wherein discern available physical resources based on different time slots as arbitrary described equipment among the embodiment 39-46.
48. as arbitrary described equipment among the embodiment 39-47, it is related to determine dynamically that wherein physical resource and H-ARQ handle.
49. as arbitrary described equipment among the embodiment 39-47, configures physical resource and H-ARQ processing is related wherein semi-staticly.
50. as arbitrary described equipment among the embodiment 39-49, wherein said controller is configured to: select at least one to treat the high level data stream that in next TTI, sends and only selected high level data stream is mapped to H-ARQ to handle.
51. as embodiment 50 described equipment, wherein to the packet allocation life span time on each high level data stream, thus the grouping that controller is used to transmit based on described life span selection of time.
52. as arbitrary described equipment among the embodiment 39-51, wherein when the QoS demand of high level data stream be similar in, described controller is determined physical transfer and H-ARQ configuration, with the QoS that standardizes between handling at available H-ARQ.
53. as embodiment 52 described equipment, wherein handle the MCS that adopts higher order, handle the MCS that adopts low order for H-ARQ with low channel quality for H-ARQ with high channel quality.
54., wherein, each H-ARQ is handled distribution maximum times retransmission limit based on the QoS demand of the high level data that maps to the H-ARQ processing as embodiment 52 described equipment.
55. as arbitrary described equipment among the embodiment 39-51, wherein when the QoS demand of high level data be in the dissmilarity, controller maps to the H-ARQ related with channel quality with high level data and handles, and described channel quality is near the QoS demand that is matched with high level data stream.
56. as arbitrary described equipment among the embodiment 39-51, wherein when the QoS demand of high level data be in the dissmilarity, based on the QoS demand that maps to the high level data stream that H-ARQ handles H-ARQ is handled and distributes the maximum times retransmission limit.
57. as arbitrary described equipment among the embodiment 39-56, wherein when the bust this of TB, controller is that the re-transmission of TB distributes identical physical resource.
58. as embodiment 57 described equipment, wherein said controller is that the re-transmission of TB changes physical transfer and H-ARQ configuration.
59. as arbitrary described equipment among the embodiment 57-58, wherein said controller is to the TB segmentation, to be used for re-transmission.
60. as arbitrary described equipment among the embodiment 39-56, wherein when the bust this of TB, described controller changes physical resource, to be used for the re-transmission of TB.
61. as arbitrary described equipment among the embodiment 37-60, wherein said wireless communication system is the HSPA+ system.
62. as arbitrary described equipment among the embodiment 37-60, wherein said wireless communication system is the LTE of 3G wireless communication system.
63., wherein begin to determine available physical resources and related H-ARQ processing on common TTI border as arbitrary described equipment among the embodiment 39-62.
64. as arbitrary described equipment among the embodiment 39-63, wherein said physical transfer parameter comprises the MCS that is used for each TB.
65. as embodiment 64 described equipment, wherein select to be used for the MCS of each TB, to distinguish the QoS demand of TB.
66., wherein select to be used for the MCS of each TB, thereby the QoS that supports is similar between H-ARQ handles as embodiment 64 described equipment.
67. as arbitrary described equipment among the embodiment 39-66, wherein said physical transfer parameter comprises the transmission block size that is used for each TB.
68., wherein select to be used for the TB size of each TB to distinguish the QoS demand of TB as embodiment 67 described equipment.
69., wherein select to be used for the TB size of each TB, thereby the QoS that supports is similar between H-ARQ handles as embodiment 67 described equipment.
Though feature of the present invention and element are described with specific combination in preferred embodiment, but each feature or element can be under the situation of other features that do not have described preferred implementation and element use separately, or with or with under the various situations that other features of the present invention and element combine do not use.Method that provides in the present invention or flow chart can be to implement by all-purpose computer or the performed mode that is embedded in computer program, software and firmware in the computer-readable recording medium conscientiously of processor.The example of computer-readable recording medium comprises read-only memory (ROM), random access storage device (RAM), register, buffer storage, semiconductor storage unit, magnetizing mediums (for example internal hard drive and removable dish), magnet-optical medium and light medium (for example CD-ROM dish and digital versatile disc (DVD)).
By example, suitable processor comprises: general processor, application specific processor, conventional processors, digital signal processor (DSP), a plurality of microprocessor, one or more and related microprocessor, controller, microcontroller, application-specific integrated circuit (ASIC) (ASIC), field programmable gate array (FPGA) circuit, any other type integrated circuit (IC) and/or the state machine of DSP nuclear.
Can be used for being implemented in the wireless frequency transceiver that uses in wireless transmission receiving element (WTRU), subscriber equipment (UE), terminal, base station, radio network controller or any main frame with the processor of software context.Can combine with module and use WTRU, and in hardware and/or software, implement, for example camera, video camera module, visual telephone, speakerphone, vibrating device, loud speaker, microphone, TV transceiver, hand-free receiver, keyboard, indigo plant
Module, frequency modulation(FM) (FM) radio-cell, LCD (LCD) display unit, Organic Light Emitting Diode (OLED) display unit, digital music player, media player, video-game player module, Internet-browser and/or any wireless lan (wlan) module.
Claims (60)
1. one kind is used the automatic repetitive requests of polyhybird (H-ARQ) to handle the method that sends many transmission blocks (TB) in Transmission Time Interval (TTI) in wireless communication system, and this method comprises:
The identification available physical resources is handled with related H-ARQ;
Obtain the channel quality measurement of each available physical resources;
At least one high level data stream is mapped at least two H-ARQ to be handled;
Determine that physical transfer parameter and H-ARQ are configured to support to map to the QoS demand of the high level data stream that each H-ARQ handles;
Physical transfer parameter and the H-ARQ configuration of handling according to each H-ARQ given birth to transmission block (TB) from the high level data miscarriage of mapping respectively; And
Send TB simultaneously via the H-ARQ processing.
2. the method for claim 1, wherein physical transfer parameter and H-ARQ configuration comprises the transformat combination (TFC) that is used for each fourth B.
3. the method for claim 1, wherein communication node comprises a plurality of antennas that are used for multiple-input and multiple-output (MIMO), and discerns available physical resources based on spatial data independently.
4. the method for claim 1 is wherein discerned available physical resources based on the independent frequency subcarrier.
5. method as claimed in claim 4, wherein said subcarrier is a distributed subcarriers.
6. method as claimed in claim 4, wherein said subcarrier are centralized subcarriers.
7. the method for claim 1 is wherein discerned available physical resources based on channelization code independently.
8. the method for claim 1 is wherein discerned available physical resources based on different time slots.
9. the method for claim 1 is wherein dynamically determined the related of physical resource and H-ARQ processing.
10. the method for claim 1, wherein semi-staticly configures physical resource and H-ARQ handle related.
11. the method for claim 1 also comprises:
Selection treats that the high level data that sends flows, and handles thereby only selected high level data stream is mapped to H-ARQ in next TTI.
12. method as claimed in claim 11, wherein to the packet allocation life span time on each high level data stream, thus the selection of the grouping that is used to transmit based on the described life span time.
13. the method for claim 1, wherein when the QoS demand of high level data stream be similar in, determine physical transfer and H-ARQ configuration, thereby the QoS between available H-ARQ handles is similar.
14. method as claimed in claim 13 is wherein handled modulation and the encoding scheme (MCS) that adopts higher order for the H-ARQ with high channel quality, handles the MCS that adopts low order for the H-ARQ with low channel quality.
15. method as claimed in claim 13 wherein based on the QoS demand of the high level data stream that maps to the H-ARQ processing, is handled the maximum times of distributing re-transmission to each H-ARQ.
16. the method for claim 1 in wherein the QoS demand that flows when high level data is dissmilarity, maps to the H-ARQ related with channel quality with each high level data stream and handles, described channel quality is near the QoS demand that is matched with high level data stream.
17. the method for claim 1 in wherein the QoS demand that flows when high level data is dissmilarity, is handled the maximum times of distributing re-transmission based on the QoS demand of the high level data stream that maps to the H-ARQ processing to H-ARQ.
18. the method for claim 1 wherein when the bust this of TB, maps to the physical resource that H-ARQ handles and does not change for the re-transmission of TB.
19. method as claimed in claim 18, wherein physical transfer and H-ARQ are configured to the re-transmission of TB and change.
20. method as claimed in claim 18 wherein retransmits being used for the TB segmentation.
21. the method for claim 1, wherein when the bust this of TB, the physical resource that maps to TB is that the re-transmission of TB changes.
22. being the high-speed packet of evolution, the method for claim 1, wherein said wireless communication system insert (HSPA+) system.
23. the method for claim 1, wherein said wireless communication system are the Long Term Evolutions (LTE) of the third generation (3G) wireless communication system.
24. the method for claim 1 wherein begins to determine available physical resources and related H-ARQ processing on common TTI border.
25. the method for claim 1, wherein said physical transfer parameter comprise modulation and the encoding scheme (MCS) that is used for each TB.
26. method as claimed in claim 25, wherein selection is used for the MCS of each TB, to distinguish the QoS demand of TB.
27. method as claimed in claim 25, wherein selection is used for the MCS of each TB, thereby the QoS that supports between H-ARQ handles is similar.
28. the method for claim 1, wherein said physical transfer parameter comprises the transmission block size that is used for each TB.
29. method as claimed in claim 28 wherein selects to be used for the TB size of each TB to distinguish the QoS demand of TB.
30. method as claimed in claim 28, wherein selection is used for the TB size of each TB, thereby the QoS that supports between H-ARQ handles is similar.
31. one kind is used the automatic repetitive requests of polyhybird (H-ARQ) to handle the equipment that sends many transmission blocks (TB) in Transmission Time Interval (TTI) in wireless communication system, this equipment comprises:
A plurality of H-ARQ handle;
Controller, being configured to discern available physical resources handles with the H-ARQ related with this available physical resources, based on service quality (QoS) demand of the channel quality of each available physical resources and high level data stream at least one high level data stream is mapped at least two H-ARQ and handles, and definite physical transfer parameter and H-ARQ are configured to support to map to the QoS demand of the high level data stream that each H-ARQ handles; With
A plurality of multiplexed and link adaptation processors, each multiplexed and link adaptation processor and H-ARQ are handled physical transfer parameter of being associated and being configured to handle according to each H-ARQ and H-ARQ configuration and are flowed and produce TB from mapping to this high level data multiplexed and the link adaptation processor.
32. equipment as claimed in claim 31, the transformat combination (TFC) of the high level data stream that wherein each is multiplexed and the link adaptation processor is identified for shining upon.
33. equipment as claimed in claim 31, wherein said controller is based on discerning available physical resources by the independently spatial data that a plurality of antenna produced that is used for multiple-input and multiple-output (MIMO).
34. equipment as claimed in claim 31, wherein said controller is discerned available physical resources based on subcarrier independently.
35. equipment as claimed in claim 34, wherein said subcarrier is a distributed subcarriers.
36. equipment as claimed in claim 34, wherein said subcarrier are centralized subcarriers.
37. equipment as claimed in claim 31, wherein said controller is discerned available physical resources based on channelization code independently.
38. equipment as claimed in claim 31 is wherein discerned available physical resources based on different time slots.
39. equipment as claimed in claim 31, it is related to determine dynamically that wherein physical resource and H-ARQ handle.
40. equipment as claimed in claim 31, wherein configures physical resource and H-ARQ processing statically is related.
41. equipment as claimed in claim 31, wherein said controller is configured to: select at least one to treat the high level data stream that sends and only selected high level data stream is mapped to H-ARQ to handle in next TTI.
42. equipment as claimed in claim 41, wherein to the packet allocation life span time on each high level data stream, thus the grouping that controller is used to transmit based on described life span selection of time.
43. equipment as claimed in claim 31, wherein when the QoS demand of high level data stream be similar in, described controller is determined physical transfer and H-ARQ configuration, with the QoS that standardizes between handling at available H-ARQ.
44. equipment as claimed in claim 43 is wherein handled modulation and the encoding scheme (MCS) that adopts higher order for the H-ARQ with high channel quality, handles the MCS that adopts low order for the H-ARQ with low channel quality
45. equipment as claimed in claim 43 wherein based on the QoS demand of the high level data that maps to the H-ARQ processing, is handled distribution maximum times retransmission limit to each H-ARQ.
46. equipment as claimed in claim 31, wherein when the QoS demand of high level data be in the dissmilarity, controller maps to the H-ARQ related with channel quality with high level data stream and handles, described channel quality is near the QoS demand that is matched with high level data.
47. equipment as claimed in claim 31, wherein when the QoS demand of high level data be in the dissmilarity, controller is handled H-ARQ based on the QoS demand that maps to the high level data that H-ARQ handles and is distributed the maximum times retransmission limit.
48. equipment as claimed in claim 31, wherein when the bust this of TB, controller is that the re-transmission of TB distributes identical physical resource.
49. being the re-transmission of TB, equipment as claimed in claim 48, wherein said controller changes physical transfer and H-ARQ configuration.
50. equipment as claimed in claim 48, wherein said controller are to the TB segmentation, to be used for re-transmission.
51. equipment as claimed in claim 31, wherein when the bust this of TB, described controller changes physical resource, to be used for the re-transmission of TB.
52. being the high-speed packet of evolution, equipment as claimed in claim 31, wherein said wireless communication system inserts (HSPA+) system.
53. equipment as claimed in claim 31, wherein said wireless communication system are the Long Term Evolutions (LTE) of the third generation (3G) wireless communication system.
54. equipment as claimed in claim 31 wherein begins to determine available physical resources and related H-ARQ processing on common TTI border.
55. equipment as claimed in claim 31, wherein said physical transfer parameter comprise modulation and the encoding scheme (MCS) that is used for each TB.
56. equipment as claimed in claim 55, wherein selection is used for the MCS of each TB, to distinguish the QoS demand of TB.
57. equipment as claimed in claim 55, wherein selection is used for the MCS of each TB, thereby the QoS that supports between H-ARQ handles is similar.
58. equipment as claimed in claim 31, wherein said physical transfer parameter comprises the transmission block size that is used for each TB.
59. equipment as claimed in claim 58 wherein selects to be used for the TB size of each TB to distinguish the QoS demand of TB.
60. equipment as claimed in claim 58, wherein selection is used for the TB size of each TB, thereby the QoS that supports between H-ARQ handles is similar.
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