Abstract:
A medium access control-high speed (MAC-hs) comprises a hybrid automatic repeat request (H-ARQ) device configured to receive data blocks over a wideband-code division multiple access (W-CDMA) high speed-downlink shared channel (HS-DSCH). The H-ARQ device generates an acknowledgement (ACK) or negative acknowledgement (NACK) for each said data block received. Each received data block having a transmission sequence number. The H-ARQ device receives a new transmission instead of a pending retransmission at any time. At least one reordering device has an input configured to receive an output of the H-ARQ device and the at least one reordering device configured to reorder the received data blocks based on each received data block&#39;s transmission sequence number (TSN). Received data blocks are immediately forwarded for processing for higher layers when the received data blocks are received in sequence.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application is a continuation of U.S. patent application Ser. No. 13/892,759, filed May 13, 2013, now issued as U.S. Pat. No. 9,072,115, which is a continuation of U.S. patent application Ser. No. 13/588,775 filed Aug. 17, 2012, now issued as U.S. Pat. No. 8,484,525, which is a continuation of U.S. patent application Ser. No. 12/144,415, filed Jun. 23, 2008, now issued as U.S. Pat. No. 8,271,844, which is a continuation of U.S. patent application Ser. No. 11/365,148, filed Mar. 1, 2006, which issued on Jun. 24, 2008 as U.S. Pat. No. 7,392,452, which is a continuation of U.S. patent application Ser. No. 10/270,822, filed Oct. 15, 2002, which issued on May 20, 2008 as U.S. Pat. No. 7,376,879, which claims priority from U. S. Provisional Patent Application No. 60/343,661, filed Oct. 19, 2001, all of which are incorporated by reference as if fully set forth. 
    
    
     BACKGROUND 
     The present invention is related to MAC architecture in a wireless communication system where Hybrid Automatic Repeat Request (H-ARQ) techniques are applied. 
     A block diagram of the UMTS Terrestrial Radio Access Network (UTRAN) MAC-hs layer architecture is illustrated in  FIG. 1 , and a block diagram of the user equipment (UE) MAC-hs architecture is shown in  FIG. 2 . The UTRAN MAC-hs  30  shown in  FIG. 1  comprises a Transport Format Combination (TFC) selection entity  31 , a scheduling device  32 , a plurality of H-ARQ processors  33   a ,  33   b  and a flow controller  34 . 
     The UE MAC-hs  40  comprises an H-ARQ processor  41 . As will be explained in further detail hereinafter, with reference to both  FIGS. 1 and 2 , the H-ARQ processors  33   a ,  33   b  in the UTRAN MAC-hs  30  and the H-ARQ processor  41  in the UE MAC-hs  40  work together to process blocks of data. 
     The H-ARQ processors  33   a ,  33   b  in the UTRAN MAC-hs  30  handle all of the tasks that are required for H-ARQ to generate transmissions and retransmissions for any transmission that is in error. The H-ARQ processor  41  in the UE MAC-hs  40  is responsible for generating acknowledgements (ACKs) to indicate a successful transmission and negative acknowledgements (NACKs) in the case of failed transmissions. The H-ARQ processors  33   a ,  33   b  and  41  process sequential data streams for each user data flow. Blocks of data received on each user data flow are sequentially assigned to H-ARQ processors  33   a ,  33   b . Each H-ARQ processor  33   a ,  33   b  initiates a transmission, and in the case of an error, the H-ARQ processor  41  requests a retransmission. On subsequent transmissions, the modulation and coding rate may be changed in order to ensure a successful transmission. The H-ARQ processor  41  in the UE MAC-hs  40  may combine the soft information from the original transmission and any subsequent retransmissions. The data to be retransmitted and any new transmissions to the UE are forwarded to the scheduling device  32 . 
     The scheduling device  32 , coupled between the H-ARQ processors  33   a ,  33   b  and the TFC selector  31 , functions as radio resource manager and determines transmission latency in order to support the required QoS. Based on the outputs of the H-ARQ processors  33   a ,  33   b  and the priority of new data being transmitted, the scheduling device  32  forwards the data to the TFC selection entity  31 . 
     The TFC selection entity  31 , coupled to the scheduling device  32 , receives the data to be transmitted and selects an appropriate dynamic transport format for the data to be transmitted. With respect to H-ARQ transmissions and retransmissions, the TFC selection entity  31  determines modulation and coding. 
     Data streams are processed sequentially, and each data block is processed until successful transmission is achieved or the transmission fails and the data is discarded. Retransmissions signaled by the H-ARQ process take precedence over any new data to be transmitted. Each H-ARQ processor  33   a ,  33   b  performs transmissions and retransmissions until the data block transmission is determined successful or failed. Using this scheme, higher priority data transmissions may be delayed while lower priority data retransmissions are processed until success or failure is determined. 
     UE connections require support of several independent traffic control signaling channels. Each of these channels has QoS requirements, which include guaranteed and/or acceptable transmission latency levels. Since the H-ARQ processing is taken into account prior to scheduling, it is not possible for higher priority data to supercede lower priority data retransmissions. Therefore, the transmission latency QoS requirements for high priority data transmissions may not be achievable when low priority data transmissions have been previously assigned to H-ARQ processors  33   a ,  33   b.    
     Since retransmissions are combined with previous transmissions in the H-ARQ process, it is possible that if the first transmissions are sufficiently corrupted, subsequent retransmissions will not achieve successful transmission. In this case since transmissions can not be reinitiated as new transmissions from the scheduling entity  32 , data is discarded. 
     Accordingly, there exists a need for an improved MAC-hs architecture both in the UTRAN and UE that allows for higher priority transmissions to supercede lower priority transmissions and for the ability to reinitiate transmissions at any time. 
     SUMMARY 
     A medium access control-high speed (MAC-hs) comprises a hybrid automatic repeat request (H-ARQ) device configured to receive data blocks over a wideband-code division multiple access (W-CDMA) high speed-downlink shared channel (HS-DSCH). The H-ARQ device generates an acknowledgement (ACK) or negative acknowledgement (NACK) for each said data block received. Each received data block having a transmission sequence number. The H-ARQ device receives a new transmission instead of a pending retransmission at any time. At least one reordering device has an input configured to receive an output of the H-ARQ ARQ device and the at least one reordering device configured to reorder the received data blocks based on each received data block&#39;s transmission sequence number (TSN). Received data blocks are immediately forwarded for processing for higher layers when the received data blocks are received in sequence. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a prior art UTRAN MAC-hs. 
         FIG. 2  is a prior art UE MAC-hs. 
         FIG. 3  is a block diagram of a UTRAN MAC-hs in accordance with the preferred embodiment of the present invention. 
         FIG. 4  is a block diagram of a UE MAC-hs in accordance with the preferred embodiment of the present invention. 
         FIG. 5  is a flow diagram of a procedure for permitting higher priority transmissions to interrupt lower priority transmissions to achieve transmission latency requirements. 
         FIG. 6  is a flow diagram of a procedure to re-initiate failed transmissions to achieve Block Error Rate requirements. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     The preferred embodiments will be described with reference to the drawing figures where like numerals represent like elements throughout. 
       FIG. 3  is a block diagram of the UTRAN MAC-hs  50 , preferably located at Node B  56 , in accordance with the preferred embodiment of the present invention. The UTRAN MAC-hs  50  comprises a TFC selector  51 , a plurality of H-ARQ entities  52   a ,  52   h , a scheduling and prioritization entity  53 , a priority class and TSN setting entity  54  and a flow controller  55 . As will be explained in detail, the components of the UTRAN MAC-hs  50  are coupled together in a novel manner, which facilitates proper scheduling prioritization for greater ability to achieve transmission latency requirements and the ability to reinitiate transmissions at any time to reduce transmission errors within the UTRAN MAC-hs  50  (shown in  FIG. 3 ) and UE MAC-hs  60  (shown in  FIG. 4 ). 
     Similar to the prior art flow controller  34  discussed hereinbefore, the flow controller  55  of the present invention shown in  FIG. 3 , and, coupled to the MAC-c/sh of the RNC (not shown) and the priority class and TSN setting entity  54 , provides a controlled data flow between the Node B  56  and the RNC, taking the transmission capabilities of the air interface into account in a dynamic manner. Although shown in  FIG. 3  as separate components, the functionality of the scheduling and prioritization handling entity  53  (hereinafter, the “scheduling entity  53 ”) and the priority class and TSN setting entity  54  (hereinafter, the “TSN setting entity  54 ”) may be combined into a single entity. 
     TSN setting entity  54  is coupled between the flow controller  55  and the scheduling entity  53 . The TSN setting entity  54  of the present invention sets, for each priority class, a queue identifier and TSN for each new data block being serviced to ensure sequence in delivery of data blocks to higher layers. The TSN is unique to each priority class and queue identity within a high speed downlink shared channel (HS-DSCH), and is incremented for each new data block. Once a queue identifier and the TSN have been set for a new data block, the data block is forwarded to the scheduling entity  53 . 
     The scheduling entity  53  processes data received from the TSN setting entity  54 . The scheduling entity  53  functions as a radio resource manager for the cell, as well as maintaining QoS requirements for the users serviced by the UTRAN MAC-hs  50 . The TSN and priority class identifiers for the data blocks to be transmitted are forwarded to the scheduling entity  53 . 
     In accordance with the present invention, the scheduling entity  53  ensures proper prioritization of transmissions according to data flow QoS latency requirements and allows for reinitiation of failed H-ARQ transmissions that permits the greater ability to achieve QoS Block Error Rate (BLER) requirements. These abilities of the scheduling entity  53  are not possible when H-ARQ processing precedes the scheduling function as in the prior art system of  FIG. 1 . The scheduling entity  53  manages HS-DSCH physical resources between the H-ARQ entities  52   a ,  52   b  and data flows according to their QoS requirements for transmission latency and transport channel BLER requirements. Beside the QoS parameters, the scheduling algorithm used by the scheduling entity  53  may also operate according to, for example, various radio control resource parameters such as the signal-to-interference ratio (SIR), available and rate, speed of the UE, current load of the cell and other factors that are well known to those of skill in the art. The scheduling entity  53  determines the data (associated with a particular UE), and the H-ARQ entities  52   a ,  52   b  that will service the transmission. 
     The transmission assigned to the H-ARQ entities  52   a ,  52   b  is either a new transmission or a retransmission of data that previously was not successfully delivered. Status reports from the previous transmission signaled between the UE H-ARQ entity  61  (shown in  FIG. 4 ) and the UTRAN H-ARQ entities  52   a ,  52   b  (shown in  FIG. 3 ) are relayed to the scheduling entity  53  where it is determined whether a new or retransmission will be serviced. The UTRAN MAC-hs  50  architecture defined by the present invention allows the scheduling entity  53 , at any time, to determine whether or not to permit new transmissions to be initiated on an H-ARQ entity  52   a ,  52   b . New transmissions may be higher priority transmissions that need to supercede lower priority transmissions to achieve QoS transmission latency requirements, or re-initiation of previously failed or interrupted transmissions to achieve QoS transport channel BLER requirements. 
     The algorithm within the scheduling entity  53  schedules data transmissions according to priority class. The UTRAN MAC-hs  50  of the present invention allows lower priority transmissions to be interrupted for the transmission of higher priority transmissions, and provides the ability to reinitiate previously failed or interrupted transmissions at any time. 
     The scheduling entity  53  forwards radio resource scheduling information to the H-ARQs entities  52   a ,  52   b . The scheduling entity  53  directs the H-ARQ entities  52   a ,  52   b  to initiate either a new transmission or a retransmission of a previous unsuccessful transmission by the particular H-ARQ entity  52   a ,  52   b . The data is then forwarded to the TFC selector  51  for transmission. The TFC selector  51 , coupled to the H-ARQ processors  52   a ,  52   b , receives the transmissions and selects an appropriate dynamic transport format parameter for the data to be transmitted to the UE. Although shown in  FIG. 3  as separate components, the functionality of the H-ARQ entities  52   a ,  52   b  and the TFC selector  51  may be combined into a single entity. 
     A block diagram of a UE MAC-hs layer  60  for a UE in accordance with the preferred embodiment of the present invention is illustrated in  FIG. 4 . The UE MAC-hs  60  comprises a plurality of reordering devices  62   a ,  62   b  and an H-ARQ entity  61 . Similar to the H-ARQ processor  41  described hereinbefore with respect to the UTRAN, the UE H-ARQ entity  61  is responsible for handling all the processes for implementing the H-ARQ protocol. Within the UE, the receiving H-ARQ entity  61  combines the soft information from the original transmission and any subsequent retransmissions. 
     Within the H-ARQ protocol layer, individual transmission priority classes and the required sequence of delivery (TSNs) are not known. Accordingly, successful reception transmissions are reordered according to their TSN by the reordering devices  62   a ,  62   b . The reordering devices  62   a ,  62   b  immediately forward for processing in higher layers transmissions following in sequence reception. 
     The MAC-hs process in accordance with the preferred embodiment of the present invention ensures that higher priority transmissions are not delayed by processing of lower priority transmissions. Additionally, transmissions can be reinitiated at any time, thereby reducing the transmission failure rate within the MAC-hs process. This gives the scheduling entity  53  the ability to utilize the input information available to determine the best combination of transmissions to achieve maximum performance of the system, maximum use of the radio network and maintain QoS requirements for transmission latency and BLER. 
     Although the elements or processes of the present invention have been described as discrete hardware components, for example the scheduling entity  53  and the TSN setting entity  54 , these elements will most likely be implemented in one or more software routines or modules. It should be understood that the overall flow and sequence of information between each process is important, not whether the process is implemented separately or together, or in hardware or software. 
     Referring to  FIG. 5 , a method  100  for permitting transmission of higher priority data to interrupt the transmission of lower priority data to achieve transmission latency requirements is shown. The method  100  is for communications between a transmitter  102  (such as at the UTRAN) and a receiver  104  (such as at the UE). The method  100  assumes communication for a particular H-ARQ process, such as between one of the H-ARQ entities  52   a ,  52   b  in the UTRAN and the corresponding H-ARQ entity  61  in the UE. 
     The method  100  commences with the setting of a new data indicator (NDI) for the establishment of a new H-ARQ process (step  103 ). The lower priority data is processed (step  106 ) at the transmitter  102 . As aforementioned at the receiver  104 , a quality check is performed whereby an acknowledgement (ACK) is generated if the transmission is successful (i.e. received without errors) or a non-acknowledgment (NACK) is generated if the transmission is not successful (step  108 ). The ACK or NACK is sent to the transmitter  102 . Steps  106  and  108  are repeated until the transmission is successfully received at the receiver  104 , or higher-priority data arrives at the scheduling entity (step  110 ) that needs to be scheduled to meet QoS transmission latency requirements. 
     If higher priority data needs to be scheduled for transmission to meet transmission latency requirements (step  110 ), lower priority data transmission may be interrupted (step  112 ). The H-ARQ process of transmission of the higher priority data is then commenced (step  114 ). Interruption of the previous data transmission is identified to the receiver  104  by setting of the NDI. At the receiver  104 , a quality check is performed whereby an acknowledgement (ACK) is generated if the transmission is successful or a non-acknowledgment (NACK) is generated if the transmission is not successful (step  116 ). The ACK or NACK is then sent to the transmitter  102 . Steps  114  and  116  are repeated until the higher priority data transmission is successfully received at the receiver  104 . 
     Once the transmission of the higher priority data has been confirmed, the lower priority data transmission may then be reinitiated (step  118 ). The transmission is repeated until the quality check results in an ACK being generated by the receiver  104  (step  120 ). As with the aforementioned H-ARQ process, it may be necessary to retransmit the lower priority data by the transmitter  102  in response to an NACK generated by the receiver  104 . 
     The method  100  of  FIG. 5  is an example of scheduling of an H-ARQ process to achieve desired latency requirements for the data to be transmitted. With the proposed UTRAN MAC architecture  50  in accordance with the present invention, method  100  and other sequences of operation between the transmitter  102  and receiver  104  are also possible to achieve transmission latency requirements. 
     Referring to  FIG. 6 , a method  200  for permitting re-initiation of failed transmissions to achieve Block Error Rate (BLER) requirements is shown. The method  200  is for communications between a transmitter  201  (such as at the UTRAN) and a receiver  203  (such as at the UE). The method  200  assumes communication for any set of H-ARQ processes associated with a UE, such as between one of the H-ARQ entities  52   a ,  52   b  in the UTRAN and the corresponding H-ARQ entity  61  in the UE. 
     The method  200  commences with the processing of data for transmission (step  202 ) at the transmitter  201 . The H-ARQ processing for the data is performed, whereby a quality check is at the receiver  203  is performed (step  204 ) and an ACK or NACK is then sent to the transmitter  201 . Steps  202  and  204  are repeated until the data transmission is successfully received at the receiver  203  or until a retransmission limit or another failure criteria is reached (step  206 ). 
     In the event that a failure criterion has been reached (step  206 ), the UTRAN MAC architecture  50  allows for re-initiation of the failed transmission on the H-ARQ process (steps  212  and  214 ). Re-initiation may be performed after the scheduling of other pending transmissions (steps  208 ,  210 ) or may proceed directly (steps  212 ,  214 ). Accordingly, it is possible subsequent to the transmission or failure of one or more “other” transmissions, these other transmissions may be scheduled (step  208 ) and transmitted by the transmitter  201  and the quality check is performed and ACKs or NACKs are generated and transmitted by the receiver  203  as appropriate (step  210 ). 
     Once the other transmissions have been successfully sent, or the failure criteria has been reached (steps  208 - 210 ), the previously failed transmission may be scheduled for transmission on the H-ARQ process (step  212 ). Re-initiation of the previous data transmission is identified to the receiver  203  by setting of the NDI. Retransmissions of the data are sent and an ACK or a NACK is generated as appropriate (step  214 ). Steps  212  and  214  are repeated until the transmission is successfully received at the receiver  203 , or the retransmission limit or other failure criteria has been reached (step  206 ). The reinitiation of a previously failed transmission can be applied several times to any particular transmission in order to achieve BLER requirements. 
     While the present invention has been described in terms of the preferred embodiment, other variations which are within the scope of the invention as outlined in the claims below will be apparent to those skilled in the art.