AU2012200807A1 - Method and apparatus for forwarding non-consecutive data blocks in enhanced uplink transmissions - Google Patents

Abstract

A method and apparatus for forwarding non-consecutive data blocks in enhanced uplink (EU) transmissions. A wireless transmit/receive unit (WTRU) and one or more Node-Bs include one or more automatic repeat request (ARQ)/hybrid-ARQ (H-ARQ) processes for supporting an enhanced dedicated channel (E-DCH). Data blocks transmitted by the WTRU are re-ordered in a re-ordering entity located in the Node-B(s) or a radio network controller (RNC). Once a missing data block is identified, a data forwarding timer in the Node-B(s) or RNC is initiated and subsequent WTRU transmissions are monitored to determine whether the missing data block has been discarded by the WTRU. Upon recognition of the discard of the missing data block, the non-consecutive data blocks are forwarded to higher layers. Co~ Cdi -~ Co oCD V r LU LU :: o-) I;) mmC CNC) C'4j -j -4 co Co CCo U' 0r --r

Description

pool Section 29 Regulatior 3.2(2) AUSTRALIA Patents Act 1990 ORIGINAL COMPLETE SPECIFICATION STANDARD PATENT Application Number: Lodged: Invention Title: Method and apparatus forwarding non-consecutive data blocks in enhanced uplink transmissions The following statement is a full description of this invention, including the best method of performing it known to us: Pl11AHAU/0710 (0001] METHOD AND APPARATUS FOR FORWARDING NON-CONSECUTIVE DATA BLOCKS IN ENHANCED UPLINK TRANSMISSIONS [0002] FIELD OF INVENTION (0003] The present invention is related to a wireless communication syste-m including a wireless transmit/receive unit (WTRU) at least one Node-B and a radio network controller (RNC). More particularly, the present invention is related to a method and system for forwarding non-consecutive data blocks in enhanced uplink (EU) transmissions. [00041 BACKGROUND (0005] Methods for improving uplink (UlL) coverage, throughput and transmission latency are being investigated in Release 6 (R:6) of the 3rd generation partnership project (3GPP). In order to successfully implement these methods, scheduling and assigning of UL physical resources have been moved from the RNC to the Node-B such that the Node-B can make decisions and manage UL radio resources on a short-term basis more efficiently than the RNC, even if the RNC retains overall control over the Node-B. (0006] One or more independent UL transmissions are processed on an enhanced dedicated channel (E-DCH) between a WTRU and a universal mobile telecommunication system (UMTS) terrestrial radio access network (UTRAN) within a common time interval. One example of this would be a medium access control (MAC) layer hybrid-automatic repeat request (H-ARQ) or a simple MAC layer ARQ operation where each individual transmission may require a different number of retransnissions to be successfully received by the UTRAN, This operation may result in a loss of transmission sequence at the MAC layer. [0007] In-sequence data delivery is required by the radio link control (RLC) layer for proper operation. A re-ordering function is needed to organize the received data blocks according to the sequence generated by the WTRU RLC entity. In the prior art, a data-forwarding timer, (called a T1 timer in high speed -1downlink packet access (JJSDPA)), has been utilized for delivery of non consecutive data blocks to higher layers. The timer is initialized when data blocks which have been correctly received cannot be delivered to the higher layers due to non-sequential reception. When the timer expires, all data blocks in the re-ordering buffer up to the next non-sequentially received data block are forwarded to higher layers. [0008] It is difficult to properly set duration for the data forwarding timer since, even in normal operation, cell congestion occasionally generates relatively long periods between transmissions. In addition, since out-of-sequence delivery to RLC acknowledged mode (AM) may result in unnecessary retransmissions, the worst case delay must be considered in setting the data forwarding timer for proper operation. Since transmission errors are unavoidable, this timer mechanism results in increased and potentially unacceptable latency in perfbrming RLC retransmission procedures, [0009} In order to maintain quality of service (QoS), transmissions should not be unnecessarily delayed in providing sequential delivery. The timer mechanism is not efficient to provide proper QoS. If the duration of the timer is too short, out of sequence transmissions may be incorrectly perceived when only a particular transmission has been delayed, resulting in unnecessary requests for RLG retransmissions or potential release of the channeL If the duration of the timer is too long, detection and recovery of failed transmissions is delayed, resulting in greater difficulty in achieving low transmission latency QoS requirements. Determining the duration of the out of sequence forwarding timer is further complicated by relatively large variances in retransmission scheduling. [00101 SUMMARY (0011) The present invention is related to a method and apparatus for forwarding non-consecutive data blocks in EU transmissions. A WTRU and one or more Node-Bs include one or more ARQ/--ARQ processes for supporting EU transmissions. Data blocks transmitted by the WTRU are re-ordered in a re -2- 3 ordering entity located in the Node-B(s) or an RNC. Once a missing data block is identified, a data forwarding timer in the Node-B(s) or RNC is initiated and subsequent WTRU transmissions are monitored to determine whether the missing data block has been discarded by the WTRU. Upon recognition of the 5 discard of the missing data block, the non-consecutive data blocks are forwarded to higher layers. In an absolute priority scheme, a higher priority data block is always serviced before a lower priority data block, and a data block with the earliest transmission sequence number (TSN) is serviced first within the same priority 10 data blocks. In such a mechanism, the Node-B may recognize that the WTRU has discarded the missing data block if all H-ARQ processes available and active for the WTRU at the Node-B have received successfully either: 1) a new transmission with the same priority and a higher TSN compared to the missing data block; or 2) a new transmission with a lower priority compared to the missing 15 data block. In one aspect the present invention provides a method of receiving enhanced uplink data by a wireless network including a Node-B and a radio network controller (RNC), the method including: receiving enhanced uplink signals using at least one hybrid automatic 20 repeat request (HARQ) entity of a Node-B; sending, by the Node-B using at least one HARQ entity, positive acknowledgement messages or negative acknowledgement messages over a downlink signaling channel in response to the received enhanced uplink signals; recovering protocol data units (PDUs) by the at least one HARO entity of 25 the Node-B from the received uplink signals; forwarding by the Node-B the recovered PDUs to the RNC; wherein the Node-B indicates a subframe number of each of the forwarded PDUs; and storing by the RNC the recovered PDUs in at least one reordering buffer and processing the recovered PDUs in response to sequence numbers of the 30 PDUs and the indicated subframe numbers provided by the Node-B; The method of claim 1 wherein the at least one HARO entity is a component of a medium access control (MAC) entity of the Node-B and the at least one reordering buffer is a component of a MAC entity of the RNC.

3a in another aspect the present invention provides a wireless network for receiving enhanced uplink data, the wireless network including: a Node-B including: circuitry configured to receive enhanced uplink signals using at least one 5 hybrid automatic repeat request (HARO) entity; wherein the circuitry is further configured to send, using the at least one HARO entity, positive acknowledgement messages or negative acknowledgement messages over a downlink signaling channel in response to the received enhanced uplink signals; wherein the circuitry is further configured to recover protocol data units 10 (PDUs) by the at least one HARQ entity from the received uplink signals; wherein the circuitry is further configured to forward the recovered PDUs to a radio network controller (RNC); wherein the Node-B indicates a subframe number of each of the forwarded PDUs; and the RNC including: 15 circuitry configured to store the recovered PDUs in at least one reordering buffer; wherein the circuitry is further configured to process the recovered PDUs in response to sequence numbers of the PDUs and the indicated subframe numbers provided by the Node-B. In a further aspect the present invention provides a Node-B for receiving 20 enhanced uplink data, the Node-B including: circuitry configured to receive enhanced uplink signals using at least one hybrid automatic repeat request (HARQ) entity; wherein the circuitry is further configured to send, using the at least one HARQ entity, positive acknowledgement messages or negative acknowledgement messages over a 25 downlink signaling channel in response to the received enhanced uplink signals; wherein the circuitry is further configured to recover protocol data units (PDUs) by the at least one HARQ entity from the received uplink signals; wherein the circuitry is further configured to forward the recovered PDUs to a radio network controller (RNC); wherein the Node-B indicates a subframe number of 30 each of the forwarded PDUs. In yet another aspect the present invention provides a radio network controller (RNC) for processing received enhanced uplink data, the RNC including: 3b circuitry configured to store recovered protocol data units (PDUs) in at least one reordering buffer forwarded by a Node-B; wherein the circuitry is further configured to process the recovered PDUs in response to sequence numbers of the PDUs and indicated subframe numbers of the PDUs provided by the Node-B. 5 BRIEF DESCRIPTION OF THE DRAWINGS A more detailed understanding of the invention may be had from the following description of a preferred embodiment, given by way of example and to be understood in conjunction with the accompanying drawing wherein: Figure 1A is a block diagram of a wireless communication system including 10 one or more Node-Bs with a data re-ordering entity in accordance with one embodiment of the present invention; Figure 18 is a block diagram of a wireless communication system including an RNC with a data re-ordering entity in accordance with another embodiment of the present invention: 15 Figure 2 is a flow diagram of a process for forwarding non-consecutive data blocks using either of the systems of Figures 1 A and 113; and Figure 3 is a flow diagram of a process for forwarding non-consecutive data blocks using the system of Figure 1 B.

(0019] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0020] Hereafter, the terminology "WTRU" includes but is not limited to a user equipment (UE), a mobile station, a fixed or mobile subscriber unit, a pager, or any other type of device capable of operating in a wireless enviromnent. When referred to hereafter, the terminology "Node-B" includes but is not limited to a base station, a site controller, an access point or any other type of interfacing device in a wireless environment. [0021] The features of the present invention may be incorporated into an integrated circuit (IC) or be configured in a circuit comprising a multitude of interconnecting components. [00221 Figure 1A is a block diagram of a wireless communication system 100 including one or more Node-Bs with a data re-ordering entity 122 in accordance with one embodiment of the present invention. The system 100 includes a WTRU 102, one or more Node-Bs 104 and an RNC 106. The WTRU 102 transmits enhanced dedicated channel (E-DCH) data through an assigned E DCH 142. The Node-B(s) 104 transmits either an acknowledgement (ACK) message or a non-acknowledgement (NACK) message through the DL EU signaling ch annel 144, depending on the success or failure of decoding the data at the Node-B(s) 104 using an H-ARQ or simple ARQ operation, as indicated by ARQ/H-ARQ process 112 and 1.28 in the WTRU 102 and Node-B(s) 104, respectively. [0023] Referring to Figure 1A, new MAC entities 110, 120, 130 for EU transmissions, (i.e., MAC-e entities), are included in each of the WTRU 102, the Node-B(s) 104 and the RNC 106, respectively. The MAC-e entity 120 of the Node-B(s) 104 includes a re-ordering entity 122, data re-ordering buffer 124, a data forwarding timer 126 for in-sequence delivery of the data blocks, respectively. The data transmitted by the WTRU 102 over the B-D CH 142 is re ordered by the re-ordering entity 122 before being forwarded to a higher layer. The re-ordering entity 122 receives data blocks, (MAC-c protocol data units (PDUs), and delivers the MAC-e PDUs with consecutive TSNs to a higher layer. MAC-e PDUs that are not consecutive, (i-e., resulting in a missing data block), -4are not delivered to the higher layer until expiration of the data forwarding timer 126. The re-ordering entity 122 uses the knowledge of the ARQ/H-ARQ process 128 to determine whether the missing data block has been discarded by the WTRU 102 and to forward non-consecutive data blocks to higher layers. [0024] Figure 1B is a block diagram of a wireless communication system 150 including an RNC with a data re-ordering entity 132 operating in accordance with another embodiment of the present invention. The system 150 also includes a WTRU 102, one or more Node-Es 104 and an RNC 106, similar to the system 100 of Figure 1A. However, instead of the Node-B(s) 104 including a re-ordering entity 122, the M4AC-e entity 130 of the RNC 106 includes a re-ordering entity 132, a re-ordering buffer 134 and a data forwarding timer 136 for in-sequence delivery of the data blocks, respectively. Data transmitted by the WTRU 102 over the E-DCH 142 is re-ordered by the re-ordering entity 132 before being forwarded to a higher layer. Via the Node-B(s) 104, the re-ordering entity 132 receives data blocks, (MAC-e protocol data units (PDUs)), and delivers the MAC-e PDUs with consecutive TSNs to a higher layer. MAC-c PDUs that are not consecutive are not delivered to the higher layer until expiration of the data forwarding timer 136. The re-ordering entity 13 uses the knowledge of the ARQ/H-ARQ process 128 in the Node-B(s) 104 to determine whether the missing data block has been discarded by the WTRU 102 and to forward non-consecutive data blocks to higher layers. [0025] The -1-AIQ process assignment mechanism is preferably based on absolute priority of data blocks. After recognizing that a data block of a particular transmission sequence number (TSN) is missing in the re-ordering buffer in the UTRAN, (i.e., either a Node-B or an RNC), the re-ordering entity 122, 132 determines the missing data block is lost if subsequent to detection of the missing data block all ARQ/H-ARQ processes 128 available and active within the Node-B(s) 104 for that WTRU 102 have either: 1) a new transmission initiated for a transmission with the same priority class with a higher sequence number; or 2) a new transmission initiated for a transmission with a lower priority class. In such case, the re-ordaring entity 122, 132 determines that the -5data block is lost at the MAC layer and forwards the non-consecutive data blocks to higher layers. [00261 Figure 2 is a flow diagram of a process 200 for forwarding non consecutive data blocks in accordance with one embodiment of the present invention. The process 200 may be implemented using either the configuration of system 100 of Figure 1A or system 1.50 of Figure 1B. The Node-B(s) 104 maintains a finite number of ARQ/tI-ARQ processes 128 for each WTRU 102. The re-ordering entity 132 in the RNC 106 may not have knowledge about the H ARQ operation in the WTRU 102 and the Node-B(s) 104. Therefore, when the configuration of system 150 shown in Figure 1B is used, the Node-B(si 104 provide necessary information to the RNC 106 for enabling the re-ordering entity 132 to determine whether the WTRU 102 has discarded the missing data block. [0027] The Node-B(s) 104 or RNC 106 receives data blocks from the WTRU 102 and correctly decoded data blocks are rearranged in sequence in a re-ordering buffer 124 of the Node-B(s) 104 or the re-ordering buffer 134 of the RNC 106. When the configuration of system 150 is used, the Node-B(s) 104 forwards the successfully decoded data block to the RNC 106 along with the H-ARQ process ID and/or the frame nurnber when the transmission was received, The frame number may be either the frame when the NDI is received or the frame when the successful transmission occurred, 10028] The re-ordering entity 122 of the Node-B(s) 104 or the re-ordering entity 132 of the RNC 106 recognizes a missing data block utilizing a TSN (step 202). A unique TSN is assigned to each data block by the WTRU 102. Upon recognition of the missing data block, the Node-B(s) 104 initializes the data forwarding timer 126 or the RNC initializes the data forwarding time 136 (step 2041 The re-ordering entity 122 or 132 determines whether the data forwarding timer 126 or 136, respectively, has expired (step 206). If the timer 126 or 136 has expired, the re-ordering entity 122 or 132 forwards non-consecutive data blocks to higher layers (step 210), and a higher layer data recovery procedure is initiated. [0029] If the data forwarding timer 126 or 136 has not expired, the re ordering entity 122 or 132 further determines whether the missing data block - -6has been discarded by the WTRU 102 based on a known H-ARQ process assignment mechanism at the WTRU 102 (step 208). When the RNC 106 determines a discarded data block in step 208, the H-ARQ process may be determined implicitly from the frame number the transmission was received in. Following an out-of-sequence reception based on rules for H-ARQ process assignment and the subsequent assignment of H-ARQ processes, the Node-B(s) 104 or the RNC 106 can determine when the WTRI 102 discarded the particular transmission. 100301 The H-ARQ process assignment mechanism at the WTRU 102 is preferably based on absolute priority of the data blocks, even though other mechanisms may be implemented. In an absolute priority scheme, a higher priority data block is always serviced before a lower priority data block, and a data block with the earliest TSN is serviced. first within the same priority data blocks. In such a mechanism, the Node-B(s) 104 or the RNC 106 may recognize that the WTRU 102 has discarded the missing data block if all ARQ/H-ARQ processes 128 available and active for the WTRU 102 at the Node-B(s) 104 have received successfully either: 1) a new transmission with the same priority and a higher TSN compared to the missing data block; or 2) a new transmission with a lower priority compared to the missing data block. (0031) Alternatively, the Node-B(s) 104 or RNC 106 may recognize that the WTRU 102 has discarded the missing data block if the H-ARQ process which is associated with the lost data has successfully received either: 1) a new transmission with the same priority and a higher TSN compared to the missing data block; or 2) a new transmission with a lower priority compared to the missing data block The H-ARQ process may be known by the time of transmission/reception. The time may be indicated as either a frame or subframe number. [00321 If either condition is met, the Node-B(s) 104 or RNC 106 determines at the MAC layer that the missing data block has been discarded by the WTRU 102. Then, the re-ordering entity 122 or 132 forwards the non-consecutive data blocks to the higher layer without waiting for expiratIon of the data forwarding timer 126 or 136. If neither condition is met, the Node-B(s) 104 or RNC 106 determines that the missing data block has not been discarded, the process 200 proceeds to step 212 to wait for the next TTI or data block, and the process 200 then returns to step 206. [0033} New transmissions may be realized by the Node-B(s) 1.04 by receiving of a new data indicator (NDI), NDI is used to indicate whether a transmission is now data or old data (retransmission). For old data, some kind of combining can be done at the Node-B(s) 104. An NDI may also be represented by an B-ARQ process transmission counter. When the H- ARQ process transmission is set to an initial value, this represents the NDL New transmissions may also be determined by received transmission queue identities (IDs) and the TSN following decoding. [00341 The Node-B(s) 104 may support several re-ordering queues for each WTRU 102, and the out of sequence detection and forwarding logic may operate independently for each re-ordering queue. [0035) In another embodiment, the H-ARQ process assignment mechanism at the WTRU 102 is associated with the lost data block. In an absolute priority scheme, a higher priority data block is always serviced before a lower priority data block, and a data block with the earliest TSN is serviced frst within the same priority data blocks. In such a mechanism, the Node-B(s) 104 may recognize that the WTRU 102 has discarded the missing data block if all ARQ/H ARQ processes 128 available and active for the WTRU 102 at the Node-B(s) 104 have received successfully either: 1) a new transmission with the same priority and a higher TSN compared to the missing data block; or 2) a new transmission with a lower priority compared to the missing data block. [0036] If either condition is met, the Node-B(s) 104 determines at the MAC layer that the missing data block has been discarded by the WTRU 102, then the re-ordering entity 122 forwards the non-consecutive data blocks to the higher layer not waiting for expiration of the data forwarding timer 126. If neither condition is met, the Node-B(s) 104 determines that the missing data block has not been discarded, the process 200 proceeds to step 212 to wait for the next TT -8in the case of the Node-Bs 104 or, in the case of the RNC 106, the next data block. The process 200 returns to step 206 after the next TTI occurs or the next data block is received. [0037] New transmissions may be realized by the Node-B(s) 104 by receiving of a new data indicator (NDI). The NDI may be used to allow for I ARQ chase combining in the Node-B(s) 1.04, New transmissions nay also be determined by received transmission queue identities (IDs) and the TSN following decoding. f0038] Figure 3 is a flow diagram of a process 300 for forwarding non consecutive data blocks in accordance with a third embodiment of the present invention. In this embodiment, the RNC 106 notifies the Node-B(s) 104 that there is a missing data block and the Node-B(s) 104 detects whether the WTRU 102 has discarded the missing data block and reports it to the RNC 106. [00391 A re-ordering entity 132 in the RNC 106 checks whether there is a missing data block in the re-ordering buffer 134 (step 302). If there is no missing data block, the process 300 proceeds to step 312 to wait for the next received data block. If there is a missing data block, the re-ordering entity 132 initializes a data forwarding timer 136 and sends a "start watch" command to the Node-B(s) 104 (step 304). The frame number originally reported by the Node-B(s) 104 when the out-of-sequence data block in the re-ordering buffer 134 is recognized and the priority and sequence number of the missing data block are also included in the "start watch" command. [00401 After receiving the start watch command from the RNC 106, the Node-B(s) 104 checks its current database to check all data blocks subsequent to the frame number indicated by the RNC 106 and monitors subsequent transmissions in order to determine whether the WTRU 102 has discarded the missing data block based on the known H-ARQ process assignment mechanism at the WTRU 102 (step 306). As explained hereinabove, the ARQ/H-ARQ processes 112 are preferably assigned in accordance with an absolute priority scheme. In such case, the Node-B(s) 104 determines whether all ARQ/1--ARQ processes 128 available and active for the WTRU 102 within the Node-B(s) 104 have either 1) a -9new transmission with the same priority but with a higher TSN compared to the missing data block or 2) a new transmission data block with a lower priority compared to the missing data block. [0041] If either condition is met, the Node-B(s) 104 sends a transmission failure message to the re-ordering entity 132 in the RNC 106 via E-DCH frame protocol (step 308). In the transmission failure message, the priority, which indicates the re-ordering queue ID, and sequence number of the data block is also included. The Node-B(s) 104 then stops watching for such an event. If neither condition is met, the process 300 proceeds to step 312 to wait for the next received data block. [00421 Upon receiving the transmission failure message, the re-ordering function in the RNC 106 forwards the non-consecutive data blocks to higher layers before the timer expires (step 310). [0043] Although the features and elements of the present invention are described in the preferred embodiments in particular combinations, each feature or element can be used alone without the other features and elements of the preferred embodiments or in various combinations with or without other features and elements of the present invention. [0044] 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. 0* * -10-

Claims (16)

1. A method of receiving enhanced uplink data by a wireless network including a Node-B and a radio network controller (RNC), the method including: receiving enhanced uplink signals using at least one hybrid automatic 5 repeat request (HARQ) entity of a Node-B; sending, by the Node-B using at least one HARQ entity, positive acknowledgement messages or negative acknowledgement messages over a downlink signaling channel in response to the received enhanced uplink signals; recovering protocol data units (PDUs) by the at least one HARQ entity of 10 the Node-B from the received uplink signals; forwarding by the Node-B the recovered PDUs to the RNC; wherein the Node-B indicates a subframe number of each of the forwarded PDUs; and storing by the RNC the recovered PDUs in at least one reordering buffer and processing the recovered PDUs in response to sequence numbers of the 15 PDUs and the indicated subframe numbers provided by the Node-B;

2. The method of claim 1 wherein the at least one HARQ entity is a component of a medium access control (MAC) entity of the Node-B and the at least one reordering buffer is a component of a MAC entity of the RNC.

3. The method of claim 1 wherein the recovered PDUs are medium access 20 control (MAC) PDUs.

4. A wireless network for receiving enhanced uplink data, the wireless network including: a Node-B including: circuitry configured to receive enhanced uplink signals using at least one 25 hybrid automatic repeat request (HARQ) entity; wherein the circuitry is further configured to send, using the at least one HARQ entity, positive acknowledgement messages or negative acknowledgement messages over a downlink signaling channel in response to the received enhanced uplink signals; wherein the circuitry is further configured to recover protocol data units 30 (PDUs) by the at least one HARQ entity from the received uplink signals; wherein 12 the circuitry is further configured to forward the recovered PDUs to a radio network controller (RNC); wherein the Node-B indicates a subframe number of each of the forwarded PDUs; and the RNC including: 5 circuitry configured to store the recovered PDUs in at least one reordering buffer; wherein the circuitry is further configured to process the recovered PDUs in response to sequence numbers of the PDUs and the indicated subframe numbers provided by the Node-B.

5. The wireless network of claim 4 wherein the at least one HARQ entity is a 10 component of a medium access control (MAC) entity of the a Node-B and the at least one reordering buffer is a component of a MAC entity of the RNC.

6. The wireless network of claim 4 wherein the recovered PDUs are medium access control (MAC) PDUs.

7. The method of claim 1 and substantially as hereinbefore described with 15 reference to the accompanying figures.

8. The wireless network of claim 5 and substantially as herein before described with reference to the accompanying figures.

9. A Node-B for receiving enhanced uplink data, the Node-B including: circuitry configured to receive enhanced uplink signals using at least one 20 hybrid automatic repeat request (HARQ) entity; wherein the circuitry is further configured to send, using the at least one HARQ entity, positive acknowledgement messages or negative acknowledgement messages over a downlink signaling channel in response to the received enhanced uplink signals; wherein the circuitry is further configured to recover protocol data units 25 (PDUs) by the at least one HARQ entity from the received uplink signals; wherein the circuitry is further configured to forward the recovered PDUs to a radio network controller (RNC); wherein the Node-B indicates a subframe number of each of the forwarded PDUs. 13

10. The Node-B of claim 9 wherein the at least one HARQ entity is a component of a medium access control (MAC) entity of the Node-B.

11. The Node-B of claim 9 wherein the recovered PDUs are medium access control (MAC) PDUs. 5

12, A radio network controller (RNC) for processing received enhanced uplink data, the RNC including: circuitry configured to store recovered protocol data units (PDUs) in at least one reordering buffer forwarded by a Node-B; wherein the circuitry is further configured to process the recovered PDUs in response to sequence numbers of 10 the PDUs and indicated subframe numbers of the PDUs provided by the Node-B.

13. The RNC of claim 12 wherein the at least one reordering buffer is a component of a medium access control (MAC) entity of the RNC.

14. The RNC of claim 12 wherein the recovered PDUs are medium access control (MAC) PDUs.

15 15. The Node-B of claim 9 and substantially as hereinbefore described with reference to the accompanying figures.

16. The RNC of claim 12 and substantially as hereinbefore described with reference to the accompanying figures. 20 INTERDIGITAL TECHNOLOGY CORPORATION WATERMARK PATENT & TRADE MARK ATTORNEYS 25 P27884AU01