KR20080080234A - Method and system for implementing h-arq assisted arq operation - Google Patents

Abstract

A method and system for implementing hybrid automatic repeat request (H-ARQ)-assisted automatic repeat request (ARQ) in a wireless communication system are disclosed. When an H-ARQ negative acknowledgement (NACK)-to-positive acknowledgement (ACK) error occurs, the H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator to the H-ARQ transmitter unless a maximum retransmission limit has reached, a maximum time for delivery has expired or a lifespan of the failed packet has expired. The H-ARQ transmitter sends a local NACK to the ARQ transmitter so that the failed packet is recovered at an ARQ level. The H-ARQ receiver sends a local NACK to the ARQ receiver if the H-ARQ receiver does not receive the failed packet before certain conditions occur. The ARQ receiver may send a status report to the ARQ transmitter for recovery of the failed packet.

Description

Method and system for implementing AR-operation support

The present invention relates to a wireless communication system. More specifically, the present invention relates to a method and system for implementing a hybrid automatic repeat request (H-ARQ) supported automatic repeat request (ARQ) of a wireless communication system.

In conventional wireless communication systems such as Wideband Code Division Multiple Access (WCDMA) Release 5/6, high speed data transmission is achieved by high speed downlink packet access (HSDPA) and high speed uplink packet access (HSUPA) techniques. H-ARQ and ARQ are implemented to increase the reliability of data transmission.

1 shows a conventional wireless communication system 100. System 100 includes a user equipment (UE) 110, a Node-B 120, and a radio network controller (RNC) 130. The H-ARQ entity is located at the medium access control (MAC) layer 112 of the UE 110 and the MAC layer 122 of the Node-B 120. The packet is assigned a transmission sequence number (TSN) at the H-ARQ transmitter. The H-ARQ receiver receives the packet and attempts to decode the transmitted packet. If the packet is not decodable, the H-ARQ receiver sends a negative acknowledgment (NACK) back to the H-ARQ transmitter for retransmission of the errored packet. If the packet is decoded correctly, the H-ARQ receiver sends a positive acknowledgment (ACK) to the packet to the H-ARQ transmitter. Upon reception of the NACK, if the number of retransmissions of an errored packet is less than a predetermined maximum limit, the H-ARQ transmitter retransmits the packet, and the allowed transmission time for the errored packet does not expire. Otherwise, if the number of retransmissions of the failed packet is not less than the predetermined maximum limit, the failed packet is discarded and recovered at the ARQ level.

The ARQ entity is located in the radio link control (RLC) layer 114 of the UE 110 and the RLC layer 132 of the RNC 130. The ARQ entity handles the retransmission of an errored packet. The ARQ entity recovers at the H-ARQ level the packets lost due to an error that misrecognizes the negative received response as a positive received response. The ARQ process at the RLC layer is very complicated with many options for performing status reporting.

H-ARQ support when both H-ARQ and ARQ functions are co-located, as in universal mobile telecommunication systems (UMTS) Node-B or long term evolution (LTE) evolved Node-B (e-Node-B) ARQ operation may be considered.

2 shows an example of a proposed H-ARQ supported ARQ operation for a third generation partnership project (3GPP) standard. The transmitter 250 includes an ARQ transmitter 252 and an H-ARQ transmitter 254. Receiver 260 includes an ARQ receiver 262 and an H-ARQ receiver 264. H-ARQ transmitter 254 provides local ACK and local NACK to ARQ transmitter 252.

As shown in FIG. 2, when the H-ARQ transmitter 254 fails H-ARQ transmission (eg, due to a maximum retransmission limit), a local NACK is generated. The ARQ transmitter 252 sends an ARQ protocol data unit (PDU) x to the H-ARQ transmitter 254 (step 202). H-ARQ transmitter 254 sends ARQ PDU x to H-ARQ receiver 264 (step 204). If ARQ PDU x is not decodable, H-ARQ receiver 264 sends a NACK to H-ARQ transmitter 254 (step 206). H-ARQ transmitter 254 retransmits ARQ PDU x to H-ARQ receiver 264 (step 208). If ARQ PDU x is still not decodable, H-ARQ receiver 264 sends another NACK to H-ARQ transmitter 254 (step 210). At this time, it is determined whether the number of retransmissions for the ARQ PDU x has reached the maximum retransmission limit (step 212). H-ARQ transmitter 254 then sends a local NACK for ARQ PDU x to ARQ transmitter 252 (step 214).

Local NACK may also be generated when a NACK-to-ACK error is reported from H-ARQ receiver 264 to H-ARQ transmitter 254. 2, the ARQ transmitter 252 sends an ARQ PDU y to the H-ARQ transmitter 254 (step 216). H-ARQ transmitter 254 sends an ARQ PDU y to H-ARQ receiver 264 (step 218). If ARQ PDU y is not decodable, H-ARQ receiver 264 sends a NACK to H-ARQ transmitter 254 (step 220). However, if the NACK is mistaken for an ACK by the H-ARQ transmitter 254, the H-ARQ transmitter 254 considers the ARQ PDU y successfully transmitted. H-ARQ receiver 264 (eg, when H-ARQ receiver 264 receives a new PDU through the same H-ARQ process while waiting for retransmission of ARQ PDU y) NACK-to-ACK error Is detected (step 222). H-ARQ receiver 264 sends a NACK-to-ACK error indicator to H-ARQ transmitter 254 (step 224). Upon receiving the NACK-to-ACK error indicator, the H-ARQ transmitter 254 sends a local NACK to the ARQ transmitter 252 and the ARQ PDU y is recovered at the ARQ level (step 226).

As shown in FIG. 2, during a predetermined time period, when neither of the two events for the ARQ packet occur, a local ACK is generated. ARQ transmitter 252 sends an ARQ PDU z to H-ARQ transmitter 254 (step 228). H-ARQ transmitter 254 sends an ARQ PDU z to H-ARQ receiver 264 (step 230). If the ARQ PDU z is successfully decoded, the H-ARQ receiver 264 sends the ARQ PDU z to the ARQ receiver 262 (step 232) and sends an ACK to the H-ARQ transmitter 254 (step 234). . For a predetermined period of time, when it is determined that a NACK-to-ACK error was not reported (step 236), the H-ARQ transmitter 254 sends an ACK to the ARQ transmitter 252 (step 238). After receiving the local ACK from H-ARQ transmitter 254, ARQ transmitter 252 will discard the packet from the transmitter buffer.

In the above example of an H-ARQ supported ARQ system, a composite layer 2 (L2) status reporting mechanism is eliminated, assuming only NACK-to-ACK errors are a significant root cause of undetected packet loss. The ARQ transmitter will not be able to recover the packet if the NACK-to-ACK error indicator is lost or if the shared channel is lost due to discontinuous transmission (DTX) / ACK error. Thus, lossless transmission cannot be guaranteed.

The current downlink H-ARQ (Release 5) does not specify the maximum number of retransmissions for a packet. Thus, the H-ARQ transmitter or receiver does not know the maximum number of transmissions for each packet. It is assumed that the ARQ transmitter and the H-ARQ transmitter have the same PDU size. The H-ARQ transmitter informs the ARQ transmitter of the missing segment (not the ARQ PDU). If the ARQ PDU is retransmitted, the H-ARQ transmitter will retransmit the completed packet as well as the missing segment. It is also not clear how to recover the last packet of the H-ARQ transmission.

The present invention relates to a method and system for implementing H-ARQ supported ARQ in a wireless communication system. The H-ARQ receiver determines whether an H-ARQ NACK-to-ACK error has occurred. When an H-ARQ NACK-to-ACK error occurs, the number of retransmissions of the failed packet has not reached the maximum retransmission limit, the maximum time for delivering the failed packet has not expired, and / Or if the lifetime of the errored packet has not expired, the H-ARQ receiver sends an H-ARQ error indicator to the H-ARQ transmitter. The H-ARQ transmitter attempts to recover an errored packet. If the maximum retransmission limit has been reached, the maximum forward time has expired, or the life of a faulty packet has expired, the H-ARQ transmitter sends a local NACK to the ARQ transmitter to recover the failed packet at the ARQ level. Can be. If the H-ARQ receiver does not receive an errored packet before a certain condition occurs, the H-ARQ receiver sends a local NACK to the ARQ receiver. Based on the reception of the local NACK, the ARQ receiver may send a status report to the ARQ transmitter for recovery of the errored packet.

A more detailed understanding of the invention is possible from the following description of the preferred embodiment given by way of example, and can be understood in conjunction with the accompanying drawings of the invention.

1 illustrates a conventional wireless communication system;

2 illustrates an example of an H-ARQ supported ARQ operation proposed for the 3GPP standard; And

3 is a signaling diagram of a process for implementing H-ARQ supported ARQ operation in accordance with the present invention.

Features of the present invention may be incorporated in integrated circuits (ICs) or configured in circuits that include a plurality of interconnect components.

3 is a signaling diagram of a process 400 for implementing H-ARQ supported ARQ operation of a wireless communication system 300 in accordance with the present invention. System 300 includes a transmitter 310 and a receiver 320. Transmitter 310 includes an ARQ transmitter 312 and an H-ARQ transmitter 314. Receiver 320 includes an ARQ receiver 322 and an H-ARQ receiver 324.

In order to support H-ARQ supported ARQ according to the present invention, the following parameters are defined:

T _{error indicator: The} H-ARQ error indication timer is defined as the amount of time the H-ARQ receiver should wait for retransmission of an errored packet before sending the H-ARQ error indicator. For a simple implementation, it is desirable to maintain a constant H-ARQ error indicator timer throughout the system. However, the H-ARQ error indication timer may be adjusted based on quality of service (QoS) requirements. For example, the length of the H-ARQ error indication timer can be linked to scheduling priority.

N _{retransmission} : The maximum number of retransmissions allowed for a packet. The maximum number of retransmissions may vary depending on QoS requirements and may be configured for each service type.

T _forwarding : the maximum forwarding time allowed for successful delivery of a packet after the first transmission. The maximum propagation time may vary according to QoS requirements (eg, block error rate, latency, etc.) and may be configured for each service type.

T _{Synchronous Recovery} : The time at which the H-ARQ receiver expects to receive an errored packet within that period after sending an H-ARQ error indicator in the synchronous H-ARQ.

T _{asynchronous recovery} : The time that an H-ARQ receiver expects to receive an errored packet within that period after sending an H-ARQ error indicator in an asynchronous H-ARQ. The timer may be associated with QoS requirements and may be configured by service type. For example, the length of the timer can be linked to scheduling priority.

W _HARQ : Window in which an errored packet should be received (ie, the number of packets). If an erroneous packet is not received within W _HARQ , the packet is assumed to be lost.

The transmitter 310 and receiver 320 may also be given parameters for the lifetime of the packet (ie, the maximum time at which the packet should be transmitted). Parameters may be provided to the H-ARQ receiver 324 and the H-ARQ transmitter 314 by the central node. If parameters are defined for each service type, parameters may be given to the H-ARQ receiver 324 and the H-ARQ transmitter 314 at the start of the service.

The maximum number of retransmissions of a packet and / or the lifetime of the packet may change dynamically according to QoS requirements. The maximum number of transmissions may be indicated by clearly identifying the number of transmissions in the associated signaling or by clearly identifying the MAC flow associated with the configured maximum number of transmissions. According to the first option, the number of retransmissions per packet is indicated in the associated control signaling for the first transmission. According to the second option, each MAC flow may be associated with a specific number of retransmissions, and by identifying the MAC flow in the associated control signaling for the first transmission, the maximum number of transmissions may be indicated. If the second option is used, the identified MAC flow is interpreted as the maximum number of transmissions configured by the receiver. If a particular H-ARQ process is dedicated to the MAC flow for a set of MAC flows, the maximum number of retransmissions may also be known by the H-ARQ process ID. Alternatively, a flag can be set in the associated signaling to indicate the last transmission.

A process 400 for implementing an H-ARQ supported-ARQ operation in accordance with the present invention is described below with reference to FIG. H-ARQ transmitter 314 transmits the packet to H-ARQ receiver 324 (step 402). If the packet is successfully received, H-ARQ receiver 324 sends the packet to ARQ receiver 322 (not shown in FIG. 3). If the packet is not received successfully, the H-ARQ receiver 324 sends a NACK to the H-ARQ transmitter 314 (step 404). After sending a NACK in step 404, the H-ARQ receiver 324 determines whether an H-ARQ NACK-to-ACK error occurs (step 406). Upon detection of the H-ARQ NACK-to-ACK error, the H-ARQ receiver 324 generates and sends an H-ARQ NACK-to-ACK error indicator to the H-ARQ transmitter 314 (step 408).

In synchronous H-ARQ transmission, the time of H-ARQ retransmission is known to the receiver. If the H-ARQ receiver 324 receives a new packet when retransmission of an errored packet is expected, the H-ARQ receiver 324 determines that an H-ARQ NACK-to-ACK error has occurred, If the generated packet has not been transmitted the maximum number of retransmissions, it sends an H-ARQ NACK-to-ACK error indicator.

In asynchronous H-ARQ transmission, a timer T _{error indicator} is set in the H-ARQ receiver 324 when the maximum number of retransmissions has been reached, and in step 404 the H-ARQ receiver 324 sends a NACK to the H-ARQ transmitter. Send to 314. If timer T has expired, _{an error indicator} to an error occurs, the packet is successfully received before the timer T _{error indicator} is reset to 0, but H-ARQ NACK-to-ACK error indicator is not generated. If the H-ARQ receiver 324 does not successfully receive an errored packet before the timer T _{error indicator} expires, the H-ARQ receiver 324 determines whether an H-ARQ NACK-to-ACK error has occurred. , The number of transmissions of the failed packet has not reached the maximum retransmission limit, the maximum forwarding time (T _forwarding ) for the packet has not expired, and / or the lifetime of the failed packet has not expired. If not, send an H-ARQ NACK-to-ACK error indicator to H-ARQ transmitter 314.

H-ARQ NACK-to-ACK error indicator is sent from H-ARQ receiver 324 to H-ARQ transmitter 314 to signal a H-ARQ NACK-to-ACK mistake in H-ARQ transmitter 314. do. The H-ARQ NACK-to-ACK error indicator is associated with a particular H-ARQ process and a particular packet of that H-ARQ process. The H-ARQ NACK-to-ACK error indicator includes the H-ARQ process identity (ID) and TSN to identify the packet ID in the H-ARQ process.

In synchronous H-ARQ, the H-ARQ process ID because a fixed time relationship between failed transmission and error reporting can be used to associate the H-ARQ NACK-to-ACK error indicator with the H-ARQ process ID and the packet TSN. And TSN can be removed. For example, if there are four synchronous H-ARQ processes, H-ARQ NACK-to-ACK error after time t of receiving a packet with TSN n where an H-ARQ NACK-to-ACK error occurred. An indicator can be sent.

The H-ARQ NACK-to-ACK Error Indicator Packet may be independent of H-ARQ operation. This is accomplished by sending the process identity and time offset (if necessary) to identify the reception time of the received error. Alternatively, after receipt of the received error packet, the H-ARQ NACK-to-ACK error indicator may be sent as a physical layer signal at a fixed time offset.

If more than one packet can be sent from the transmitter 310 to the receiver 320 at the same time, the packets have their own cyclic redundancy check (CRC) and one H-ARQ NACK-to-ACK error indication. It can be used to send a NACK-to-ACK error indication for several packets. Thus, the H-ARQ NACK-to-ACK error indicator may include the H-ARQ process ID, associated packet TSN, and / or timing offset.

The H-ARQ NACK-to-ACK error indicator may have its own CRC, to ensure reliable transmission. This allows MAC or RLC layer signaling for H-ARQ NACK-to-ACK error indication. The H-ARQ NACK-to-ACK Error Indicator Packet may be generated at the H-ARQ level or the ARQ level.

With further reference to FIG. 3, in order to guarantee receipt of the H-ARQ NACK-to-ACK error indicator, the H-ARQ transmitter 314 may send an ACK to the H-ARQ receiver 324 (step 410). The H-ARQ receiver 324 repeatedly sends an H-ARQ NACK-to-ACK error indicator until the H-ARQ receiver 324 receives an ACK from the H-ARQ transmitter 314 or the radio link fails. Can be.

After receiving the H-ARQ NACK-to-ACK error indicator in step 408, the maximum retransmission limit has not been reached, the maximum forwarding time has not expired, and / or the lifetime of the errored packet has not expired. If not, the H-ARQ transmitter 314 attempts to recover from the error at the H-ARQ level by resending the errored packet (step 412). The H-ARQ transmitter 314 sends a local NACK to the ARQ transmitter 312 so that an errored packet can be recovered at the ARQ level (step 414). Preferably, the H-ARQ transmitter 314 may only use the ARQ transmitter (314) when the maximum number of retransmissions has been reached, the maximum delivery time for the transmission of the failed packet has expired, or the lifetime of the failed packet has expired. Send a local NACK).

In the prior art, upon successful delivery of a packet, the H-ARQ receiver 324 sends an ACK to the H-ARQ transmitter 314, and the H-ARQ transmitter 314 sends a local ACK to the ARQ transmitter 312. do. According to the present invention, the H-ARQ transmitter 314 may or may not transmit a local ACK to the ARQ transmitter 312 in such a situation.

After transmitting the H-ARQ NACK-to-ACK error indicator in step 408, the H-ARQ receiver 324 instructs that the H-ARQ receiver 324 prior to at least one of the following conditions in step 416: Determine whether an errored packet was not successfully received:

1) expiration of T _{synchronous recovery} (in synchronous H-ARQ transmission) or T _{asynchronous recovery} (in asynchronous H-ARQ transmission);

2) receiving a new H-ARQ packet having a sequence number that is as large as W _HARQ than the sequence number of the packet in error;

3) the maximum number of retransmissions of an errored packet is reached;

4) expiration of timer T _delivery ; And

5) Expiration of the lifetime of a failed packet.

If at least one of the above conditions occurs, H-ARQ receiver 324 sends a local NACK to ARQ receiver 322 (step 418). Upon receipt of the local NACK, the ARQ receiver 322 may send a status report to the ARQ transmitter 312 for recovery of the errored packet. The mapping between the ARQ PDU and the H-ARQ PDU is not relevant as long as the H-ARQ receiver 324 can identify the ARQ PDU that needs to be recovered.

After receiving the status report from the ARQ receiver 322, the ARQ buffer of the ARQ transmitter 312 may be empty. The status report for the packet in which the error occurred includes information about the successfully received packet. Alternatively, after successfully receiving N consecutive packets or after expiration of the timer, ARQ receiver 322 may send a status report. Alternatively, after transmitting the last packet of the buffer, the ARQ transmitter 312 may poll the ARQ receiver 322. The reason for polling is to prematurely recover from NACK-to-ACK errors at the H-ARQ level for the last packet. The "pole bit for last packet" setting is a configurable parameter for the data flow.

To improve recovery of the last packet in the H-ARQ transmission, after the H-ARQ buffer is empty, a special small packet with the last packet indication may be sent from the H-ARQ transmitter 314. The transmission of a special packet with the last packet indication ensures early recovery of the loss of the last packet at the H-ARQ level. H-ARQ receiver 324 sends a response back to H-ARQ transmitter 314 upon receipt of the particular packet. The response packet may be a new packet generated at the H-ARQ level indicating the last TSN received. Alternatively, the response packet may be sent by using an H-ARQ error indication packet indicating that it is a response to a small packet.

Alternatively, to reduce signaling overhead, a null transmission may be sent after the last data packet of the H-ARQ transmission queue to make an ACK check for the previous transmission.

The null packet contains only control information (ie not payload). After receiving the H-ARQ ACK for the last data packet of the H-ARQ transmission queue, the H-ARQ transmitter 314 transmits a null packet. Once the H-ARQ receiver 324 receives a null packet, the H-ARQ receiver 324 confirms receipt of the last data packet as well as the null packet. If, at the H-ARQ receiver, the last packet was not successfully received, and thus a NACK was sent in response to the last packet, and the maximum number of transmissions was not reached, the reception of a null packet would cause the H-ARQ receiver 324 to NACK. Allow to detect -to-ACK errors.

The transmitter 310 and receiver 320 may be WCDMA in a 3G system, WTRU in CDMA 2000 or LTE, a base station, or any other network entity. "WTRU" is not intended to be limiting, but may be operated in a user equipment (UE), mobile station, fixed subscriber unit or mobile subscriber unit, pager, cellular telephone, personal digital assistant, computer, or any wireless environment. Includes different types of user devices. A "base station" is not intended to be limiting but includes a Node-B, a site controller, an access point, or any other type of interfacing device in a wireless environment.

Example

1. A method for implementing H-ARQ support-ARQ in a wireless communication system comprising a transmitter comprising an H-ARQ transmitter and an ARQ transmitter, and a receiver comprising an H-ARQ receiver and an ARQ receiver.

2. The method of Embodiment 1 includes the H-ARQ receiver determining whether an H-ARQ NACK-to-ACK error has occurred.

3. The method of embodiment 2, wherein the number of retransmissions of an errored packet has not reached the maximum retransmission limit, the maximum time for delivery of an errored packet has not expired, or an errored packet. And if the lifetime of the H-ARQ NACK-to-ACK error occurs, the H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator to the H-ARQ transmitter.

4. The method of any of embodiments 2 and 3, wherein the H-ARQ NACK-to-ACK error indicator is associated with an H-ARQ process ID and an errored packet at the H-ARQ transmitter. .

5. The method of embodiment 4, wherein the H-ARQ NACK-to-ACK error indicator includes an H-ARQ process ID and a transmission sequence number of the packet in error.

6. The method of embodiment 4, wherein the H-ARQ NACK-to-ACK error indicator is sent at a fixed timing offset for the transmission of an errored packet.

7. The method of any of embodiments 3-6, wherein the transmission of the H-ARQ NACK-to-ACK error indicator and the transmission of an errored packet are independent.

8. The method of any of embodiments 3-7, wherein the H-ARQ NACK-to-ACK error indicator is sent via at least one of physical layer signaling, MAC layer signaling, and RLC layer signaling.

9. The method of any of embodiments 3-8, wherein more than one packet is sent simultaneously from an H-ARQ transmitter to an H-ARQ receiver, and the H-ARQ NACK-to-ACK error indicator is greater than one. Indicates an H-ARQ NACK-to-ACK error in a packet.

10. The method of any of embodiments 3-9, wherein the H-ARQ NACK-to-ACK error indicator is sent with a CRC.

11. The method of any of embodiments 3-10, wherein the H-ARQ NACK-to-ACK error indicator is generated by one of an H-ARQ receiver and an ARQ receiver.

12. The method of any of embodiments 3-11, further comprising the H-ARQ transmitter sending an ACK to the H-ARQ receiver upon receipt of the H-ARQ NACK-to-ACK error indicator.

13. The method of embodiment 12 wherein the H-ARQ receiver does not successfully receive an ACK for an H-ARQ NACK-to-ACK error indicator and the radio link between the H-ARQ transmitter and the H-ARQ receiver. If is not failed, the H-ARQ receiver repeatedly transmits an H-ARQ NACK-to-ACK error indicator.

14. The method of any of embodiments 3-13, wherein the H-ARQ receiver performs the same H-ARQ receiver through the same H-ARQ process assigned to the failed packet instead of retransmitting the failed packet. If receiving a new packet, the H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator.

15. The method of any of embodiments 3-14, wherein the H-ARQ receiver does not receive an errored packet until the error indication timer set when the NACK is sent to the H-ARQ transmitter expires. The H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator.

16. The method of any of embodiments 3-15, wherein an error is generated if the maximum retransmission limit has not been reached, the maximum delivery time has not expired, or the lifetime of the failed packet has not expired. The H-ARQ transmitter further retransmits the packet in error until the packet is successfully delivered.

17. The method of embodiment 16, if the maximum retransmission limit has not been reached, the maximum delivery time has not expired, or the lifetime of the failed packet has not expired, then the H-ARQ transmitter has local NACK to the ARQ transmitter. Further comprising the step of transmitting.

18. The method of any of embodiments 3-17, further comprising setting a recovery timer when the H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator.

19. The method of embodiment 18 further includes the H-ARQ receiver sending a local NACK to the ARQ receiver if the H-ARQ receiver does not receive an errored packet before the recovery time expires.

20. The method of embodiment 19 further comprising the ARQ receiver sending a status report to the ARQ transmitter for recovery of the failed packet.

21. The method of any of embodiments 3-20, wherein the H-ARQ receiver is configured until the H-ARQ receiver receives packets having a sequence number greater than a sequence number of the packet in error. If no error packet is received, the H-ARQ receiver further includes sending a local NACK to the ARQ receiver.

22. The method of embodiment 21 further comprising the ARQ receiver sending a status report to the ARQ transmitter for recovery of the failed packet.

23. The method of any of embodiments 3-22, wherein the H-ARQ receiver receives the failed packet until the number of retransmissions of the failed packet reaches a maximum retransmission limit for the failed packet. If not, the H-ARQ receiver further comprises sending a local NACK to the ARQ receiver.

24. The method of embodiment 23 further comprising the ARQ receiver sending a status report to the ARQ transmitter for recovery of the failed packet.

25. The method of any of embodiments 3-24, wherein the H-ARQ receiver does not receive the failed packet until the maximum time for delivery of the failed packet has expired. Further comprises sending a local NACK to an ARQ receiver.

26. The method of embodiment 25 further comprising the ARQ receiver sending a status report to the ARQ transmitter for recovery of the failed packet.

27. The method of any of embodiments 3-26, further comprising sending a status report when the ARQ receiver successfully receives a predetermined number of packets.

28. The method of any of embodiments 3-27, further comprising the ARQ receiver sending a status report when the status report timer expires.

29. The method of any of embodiments 3-28, further comprising the ARQ transmitter requesting a status report from the ARQ receiver, and the ARQ receiver sending a status report from the ARQ transmitter.

30. The method of embodiment 29, after sending the last packet, the ARQ transmitter requests a status report.

31. The method of any of embodiments 3-30, further comprising, after sending the last packet of the buffer, the H-ARQ transmitter sending a small packet having the last packet indication.

32. The method of embodiment 31 wherein the H-ARQ receiver sends a response to the small packet, so that recovery of the last packet is guaranteed by the small packet.

33. The method of any of embodiments 31 and 32, wherein the small packet is null transmission.

34. The method of any of embodiments 31-33, wherein the response to the small packet is sent by using an H-ARQ NACK-to-ACK error indicator.

35. The method of any of embodiments 3-34, wherein the parameters for maximum retransmission limit, maximum time for packet delivery, and packet lifetime are configured by a central control entity.

36. The method of embodiment 35, wherein the parameters are configured when the transmitter is operating.

37. The method of embodiment 35 wherein the parameters are configured at service start.

38. The method of any of embodiments 35-37, wherein the parameters are dynamically configured according to the QoS requirements of the packet.

39. The method of any of embodiments 3-38, wherein the maximum retransmission limit of the packet is indicated by identifying a particular MAC flow associated with a specific maximum retransmission limit of the associated control signaling for the first transmission.

40. The method of any of embodiments 3-38, wherein the maximum retransmission limit of the packet is clearly indicated in the associated control signaling for the first transmission.

41. A wireless communication system implementing H-ARQ support ARQ.

42. The system of embodiment 41 includes a receiver comprising an H-ARQ receiver and an ARQ receiver, wherein the H-ARQ receiver determines whether an H-ARQ NACK-to-ACK error occurs and an error occurs. If the number of retransmissions of a given packet has not reached its maximum retransmission limit, the maximum delivery time of an errored packet has not expired, or the lifetime of the errored packet has not expired, the H-ARQ transmitter is sent a H-ARQ transmitter. And send an ARQ NACK-to-ACK error indicator.

43. The system of embodiment 42 includes a transmitter comprising an H-ARQ transmitter and an ARQ transmitter.

44. The system of any of embodiments 42 and 43, wherein the H-ARQ NACK-to-ACK error indicator is associated with an H-ARQ process ID and an errored packet at the H-ARQ transmitter.

45. The system of any of embodiments 42-44, wherein the H-ARQ NACK-to-ACK error indicator includes an H-ARQ process ID and a transmission sequence number of the packet in error.

46. The system of any of embodiments 42-45, wherein the H-ARQ NACK-to-ACK error indicator is sent at a fixed timing offset for the transmission of an errored packet.

47. The system of any of embodiments 42-46, wherein the transmission of the H-ARQ NACK-to-ACK error indicator and the transmission of an errored packet are independent.

48. The system of any of embodiments 42-47, wherein the H-ARQ NACK-to-ACK error indicator is sent via at least one of physical layer signaling, MAC layer signaling, and RLC layer signaling.

49. The system of any of embodiments 42-48, wherein the H-ARQ transmitter and the H-ARQ receiver are configured to transmit and receive one or more packets simultaneously, wherein the H-ARQ transmitter is H- of the one or more packets. And send an H-ARQ NACK-to-ACK error indicator indicating an ARQ NACK-to-ACK error.

50. The system of any of embodiments 42-49, wherein the H-ARQ NACK-to-ACK error indicator is sent with a CRC.

51. The system of any of embodiments 42-50, wherein the H-ARQ NACK-to-ACK error indicator is generated by one of an H-ARQ receiver and an ARQ receiver.

52. The system of any of embodiments 43-51, wherein the H-ARQ transmitter is configured to send an ACK to the H-ARQ receiver upon receipt of an H-ARQ NACK-to-ACK error indicator.

53. The system of embodiment 52, wherein the H-ARQ receiver repeatedly transmits an H-ARQ NACK-to-ACK error indicator until it successfully receives an ACK for the H-ARQ NACK-to-ACK error indicator. do.

54. The system of any of embodiments 42-53, wherein the H-ARQ receiver receives a new packet through the same H-ARQ process assigned to the failed packet instead of retransmitting the failed packet. , H-ARQ receiver transmits H-ARQ NACK-to-ACK.

55. The system of any of embodiments 42-54, wherein the H-ARQ receiver does not receive an errored packet until the error indication timer set when the NACK is sent to the H-ARQ transmitter expires. The H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator.

56. The system of any of embodiments 43-55, wherein the failed packet is not reached if the maximum retransmission limit has not been reached, the maximum delivery time has not expired, or the lifetime of the failed packet has not expired. The H-ARQ transmitter retransmits the packet in error until it is successfully delivered.

57. The system of any of embodiments 43-56, wherein the failed packet is not reached if the maximum retransmission limit has not been reached, the maximum delivery time has not expired, or the lifetime of the failed packet has not expired. To recover at this ARQ level, the H-ARQ transmitter sends a local NACK to the ARQ transmitter.

58. The system of any of embodiments 42-57, wherein the H-ARQ receiver sets a recovery timer when sending an H-ARQ NACK-to-ACK error indicator and generates an error before the recovery timer expires. If no packet is received, a local NACK is sent to the ARQ receiver.

59. The system of embodiment 58, wherein the ARQ receiver sends a status report to an ARQ transmitter for recovery of the failed packet.

60. The system of any of embodiments 42-59, wherein an error occurs until the H-ARQ receiver receives a packet having a predetermined number greater than the sequence number of the packet in error. If no packet is received, the H-ARQ receiver further includes sending a NACK to the ARQ receiver.

61. The system of embodiment 60, wherein the ARQ receiver sends a status report to an ARQ transmitter for recovery of the failed packet.

62. The system of any of embodiments 42-61, wherein the H-ARQ receiver fails the packet until the number of retransmissions of the failed packet reaches a maximum retransmission limit for the failed packet. If not, the H-ARQ receiver sends a local NACK to the ARQ receiver.

63. The system of embodiment 62, wherein the ARQ receiver sends a status report to an ARQ transmitter for recovery of the failed packet.

64. The system of any of embodiments 42-63, wherein the H-ARQ receiver does not receive the failed packet until the maximum time for delivery of the failed packet has expired. The ARQ receiver sends a local NACK to the ARQ receiver.

65. The system of embodiment 64, wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the failed packet.

66. The system of any of embodiments 42-65, wherein the ARQ receiver sends a status report upon successfully receiving a future determined number of packets.

67. The system of any of embodiments 42-66, wherein the ARQ receiver sends a status report when the status report timer expires.

68. The system of any of embodiments 43-67, wherein the ARQ transmitter requests a status report from an ARQ receiver, and the ARQ receiver sends a status report to an ARQ transmitter.

69. The system of embodiment 68, the ARQ transmitter requests a status report after the transmission of the last packet.

70. The system of any of embodiments 43-69, wherein the H-ARQ transmitter sends a small packet with the last packet indication after transmitting the last packet of the buffer, and the H-ARQ receiver responds to the small packet. By sending, the recovery of the last packet is guaranteed by the small packet.

71. The system of embodiment 70, wherein the small packet is null transmission.

72. The system of any of embodiments 70 and 71, wherein the response to the small packet is sent by using an H-ARQ NACK-to-ACK error indicator.

73. The system of any of embodiments 42-72, wherein the parameter for at least one of the maximum retransmission limit, the maximum time for packet delivery, and the lifetime of the packet is configured by the central control entity.

74. The system of embodiment 73, wherein the parameters are configured when the receiver is operating.

75. The system of embodiment 73, wherein the parameters are configured at start of service.

76. The system of any of embodiments 73-75, wherein the parameters are dynamically configured according to the QoS requirements of the packet.

77. The system of any of embodiments 42-76, wherein the maximum retransmission limit of the packet is indicated by identifying a specific MAC flow associated with a specific maximum retransmission limit of the associated control signaling for the first transmission.

78. The system of any of embodiments 42-76, wherein the maximum retransmission limit of the packet is clearly indicated in the associated control signaling for the first transmission.

79. A receiver implementing the H-ARQ support ARQ.

80. The receiver of embodiment 79 includes an ARQ receiver and an H-ARQ receiver.

81. The receiver of the embodiment of embodiment 80, wherein the H-ARQ receiver determines whether an H-ARQ NACK-to-ACK error occurs and the number of retransmissions of the errored packet reaches a maximum retransmission limit. If the at least one of the maximum time for delivery of the failed packet has expired, and the lifetime of the failed packet has expired, then the H-ARQ receiver has not received the H-ARQ NACK- at the H-ARQ transmitter. and transmit a to-ACK error indicator.

82. The receiver of embodiment 81, wherein the H-ARQ NACK-to-ACK error indicator is associated with an errored packet at the H-ARQ process ID and the H-ARQ transmitter.

83. The receiver of embodiment 81, wherein the H-ARQ NACK-to-ACK error indicator includes an H-ARQ process ID and a transmission sequence number of the packet in error.

84. The receiver of any of embodiments 81-83, wherein the H-ARQ NACK-to-ACK error indicator is sent at a fixed timing offset for the transmission of an errored packet.

85. The receiver of any of embodiments 81-84, wherein the transmission of the H-ARQ NACK-to-ACK error indicator and the transmission of an errored packet are independent.

86. The receiver of any of embodiments 81-85, wherein the H-ARQ NACK-to-ACK error indicator is transmitted via at least one of physical layer signaling, MAC layer signaling, and RLC layer signaling.

87. The receiver of any of embodiments 81-86, wherein the H-ARQ receiver receives more than one packet simultaneously and indicates an H-ARQ NACK-to-ACK error of more than one packet. And send an ARQ NACK-to-ACK error indicator.

88. The receiver of any of embodiments 81-87, wherein the H-ARQ NACK-to-ACK error indicator is sent with a CRC.

89. The receiver of any of embodiments 81-88, wherein the H-ARQ NACK-to-ACK error indicator is generated by one of an H-ARQ receiver and an ARQ receiver.

90. The receiver of any of embodiments 81-89, wherein the H-ARQ receiver receives H-ARQ NACK-to- until it successfully receives an ACK for the H-ARQ NACK-to-ACK error indicator. Send an ACK error indicator repeatedly.

91. The receiver of any of embodiments 81-90, wherein the H-ARQ receiver receives the new packet through the same H-ARQ process assigned to the failed packet, instead of retransmitting the failed packet, Send an H-ARQ NACK-to-ACK error indicator.

92. The receiver of any of embodiments 81-91, wherein the H-ARQ receiver does not receive an errored packet until the error indication timer set when the NACK is sent to the H-ARQ transmitter expires. The H-ARQ receiver sends an H-ARQ NACK-to-ACK error indicator.

93. The receiver of any of embodiments 81-92, wherein the H-ARQ receiver sets a recovery timer when sending an H-ARQ NACK-to-ACK error indicator, and before the recovery timer expires. If the receiver does not receive the packet in error, it sends a local NACK to the ARQ receiver.

94. The receiver of any of embodiments 81-93, wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the failed packet.

95. The receiver of any of embodiments 81-94, wherein the H-ARQ receiver until the H-ARQ receiver receives a packet having a predetermined number greater than the sequence number of the packet in error. If does not receive the packet in error, the H-ARQ receiver further comprises the step of sending a NACK to the ARQ receiver.

96. The receiver of any of embodiments 81-95, wherein the H-ARQ receiver fails the packet until the number of retransmissions of the failed packet reaches a maximum retransmission limit for the failed packet. If not, the H-ARQ receiver sends a local NACK to the ARQ receiver.

97. The receiver of any of embodiments 81-96, wherein the H-ARQ receiver does not receive the errored packet until the maximum time for delivery of the errored packet expires. The ARQ receiver sends a local NACK to the ARQ receiver.

98. The receiver of any of embodiments 81-97, wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the failed packet.

99. The receiver of any of embodiments 81-98, wherein the ARQ receiver sends a status report upon successfully receiving a predetermined number of packets.

100. The receiver of any of embodiments 81-99, wherein the ARQ receiver sends a status report when the status report timer expires.

101. A transmitter that implements H-ARQ support ARQ.

102. The transmitter of embodiment 101 includes an ARQ transmitter and an H-ARQ transmitter.

103. The transmitter of embodiment 102, wherein the H-ARQ transmitter is configured to receive an H-ARQ NACK-to-ACK error indicator, wherein at least one of an ARQ transmitter and an H-ARQ transmitter is H-ARQ NACK-to- It is configured to recover an errored packet corresponding to the ACK error.

104. The transmitter of embodiment 103, wherein the H-ARQ transmitter is configured to send an ACK to the H-ARQ receiver upon receipt of an H-ARQ NACK-to-ACK error indicator.

105. The transmitter of any of embodiments 103 and 104, if at least one of the maximum retransmission limit has been reached, the maximum forward time has expired, and the lifetime of the failed packet has not expired, The H-ARQ transmitter retransmits the failed packet until the failed packet is successfully delivered.

106. The transmitter of any of embodiments 103-105, wherein the errored packet is ARQ if the maximum retransmission limit has been reached, the maximum forward time has expired, or the lifetime of a faulty packet has expired. To recover at the level, the H-ARQ transmitter sends a local NACK to the ARQ transmitter.

107. The transmitter of any of embodiments 103-106, wherein the ARQ transmitter requests a status report from the ARQ receiver.

108. The transmission of embodiment 107, wherein the ARQ transmitter requests a status report after the transmission of the last packet.

109. The transmitter of any of embodiments 103-108, after sending the last packet of the buffer, the H-ARQ transmitter sends a small packet with the last packet indication, such that recovery of the last packet is caused by the small packet. Guaranteed.

110. The transmitter of embodiment 109, wherein the small packet is null transmission.

111. The transmitter of any of embodiments 109 and 110, wherein the response to the small packet is sent by using an H-ARQ NACK-to-ACK error indicator.

While the features and components of the present invention are described in the preferred embodiments of a particular combination, each feature or component may be used alone without the other features and components of the preferred embodiments, or other features and features of the present invention. It may be used in various combinations with or without the elements. The method or flow chart provided in the present invention may be implemented as computer program, software, or firmware tangibly embedded in a computer-readable storage medium for execution by a general purpose computer or processor. Examples of the computer readable storage medium include magnetic media such as read-only memory (ROM), random access memory (RAM), registers, cache memory, semiconductor memory devices, internal hard disks and removable disks, magneto-optical media, And optical media such as CD-ROM discs and digital video discs (DVDs).

By way of example, suitable processors include, but are not limited to, general purpose processors, special purpose processors, conventional processors, digital signal processors (DSPs), multiple microprocessors, one or more microprocessors associated with DSP cores, controllers, microcontrollers, on demand Application Specific Integrated Circuits (ASICs), field programmable gate array (FPGA) circuits, any other type of integrated circuits (ICs), and / or state machines.

The processor associated with the software may be used to implement a radio frequency transceiver used in a wireless transmit / receive unit (WTRU), user equipment (UE), terminal, base station, radio network controller (RNC), or any host computer. WTRUs include cameras, video camera modules, videophones, speakerphones, vibrators, speakers, microphones, television transceivers, handsfree headsets, keyboards, Bluetooth modules, frequency modulated (FM) radio units, liquid crystal display (LCD) display units, organic It can be used with modules implemented in hardware and / or software, such as light emitting device (OLED) display units, digital music players, video game player modules, internet browsers, and / or any wireless local area network (WLAN) modules.

Claims (103)

A transmitter and a receiver, the transmitter including a hybrid automatic repeat request (H-ARQ) transmitter and an automatic repeat request (ARQ) transmitter, wherein the receiver comprises an H-ARQ receiver and an ARQ In a wireless communication system including a receiver, a method for implementing H-ARQ supported ARQ, Determining, by the H-ARQ receiver, that an error has occurred in which an H-ARQ NACK-to-ACK error is mistaken for an H-ARQ negative reception response; And If at least one of the number of retransmissions of the failed packet has reached the maximum retransmission limit, the maximum time for delivery of the failed packet has expired, and the lifetime of the failed packet has expired, The H-ARQ receiver sending an H-ARQ NACK-to-ACK error indicator to the H-ARQ transmitter when an H-ARQ NACK-to-ACK error occurs; H-ARQ support ARQ implementation method comprising a. The H-ARQ supported ARQ of claim 1, wherein the H-ARQ NACK-to-ACK error indicator is associated with an H-ARQ process identity (ID) and the packet where the error occurred at the H-ARQ transmitter. How to implement. The method of claim 2, wherein the H-ARQ NACK-to-ACK error indicator includes the H-ARQ process ID and the transmission sequence number of the packet in which the error occurred. . 3. The method of claim 2 wherein the H-ARQ NACK-to-ACK error indicator is sent at a fixed timing offset for transmission of the errored packet. 10. The method of claim 1 wherein the transmission of the H-ARQ NACK-to-ACK error indicator and the transmission of the errored packet are independent. The H-ARQ NACK-to-ACK error indicator of claim 1, wherein the H-ARQ NACK-to-ACK error indicator is at least one of physical layer signaling, medium access control (MAC) layer signaling, and radio link control (RLC) layer signaling. H-ARQ supported ARQ implementation method that will be transmitted through one. The H-ARQ NACK-to-ACK error indicator of claim 1, wherein more than one packet is simultaneously transmitted from the H-ARQ transmitter to the H-ARQ receiver. H-ARQ supported ARQ implementation method that indicates an -ACK error. The method of claim 1 wherein the H-ARQ NACK-to-ACK error indicator is sent with a cyclic redundancy check (CRC). The method of claim 1 wherein the H-ARQ NACK-to-ACK error indicator is generated by one of the H-ARQ receiver and an ARQ receiver. The method of claim 1, And upon receipt of the H-ARQ NACK-to-ACK error indicator, the H-ARQ transmitter further sending an ACK to the H-ARQ receiver. The method of claim 10, If the H-ARQ receiver does not successfully receive the ACK for the H-ARQ NACK-to-ACK error indicator and the radio link between the H-ARQ transmitter and the H-ARQ does not fail, the H An ARQ receiver repeatedly transmitting the H-ARQ NACK-to-ACK error indicator. The method of claim 1, If the H-ARQ receiver receives a new packet through the same H-ARQ process assigned for the failed packet instead of retransmitting the failed packet, the H-ARQ receiver receives the H-ARQ NACK-. and transmitting an to-ACK error indicator. The method of claim 1, If the H-ARQ receiver does not receive the packet in error until the error indication timer set when a NACK is sent to the H-ARQ transmitter expires, the H-ARQ receiver may receive the H-ARQ NACK-. and transmitting an to-ACK error indicator. The method of claim 1, If at least one of the maximum retransmission limit has been reached, the maximum delivery time has expired, and the lifetime of the failed packet has expired, then the H-ARQ until the failed packet has been successfully delivered. The transmitter retransmitting the errored packet H-ARQ support ARQ implementation method further comprising. The method of claim 14, If the maximum retransmission limit has been reached, the maximum delivery time has expired, or the lifetime of the errored packet has expired, the H-ARQ transmitter is configured to recover the ARQ so that the errored packet is recovered at an ARQ level. H-ARQ support ARQ implementation method further comprising the step of transmitting a local NACK to the transmitter. The method of claim 1, Setting, by the H-ARQ receiver, a recovery timer when transmitting the H-ARQ NACK-to-ACK error indicator; And If the H-ARQ receiver does not receive the errored packet before the recovery timer expires, the H-ARQ receiver further comprises sending a local NACK to the ARQ receiver. Way. The method of claim 16, And sending, by the ARQ receiver, a status report to the ARQ transmitter for recovery of the failed packet. The method of claim 1, If the H-ARQ receiver does not receive the errored packet until the H-ARQ receiver receives a packet having a predetermined number greater than a sequence number of the errored packet. H-ARQ receiver further comprises the step of transmitting a local NACK to the ARQ receiver. The method of claim 18, And sending, by the ARQ receiver, a status report to the ARQ transmitter for recovery of the failed packet. The method of claim 1, If the H-ARQ receiver does not receive the errored packet until the number of retransmissions of the errored packet reaches a maximum retransmission limit for the errored packet, the H-ARQ receiver receives the ARQ. H-ARQ support ARQ implementation method further comprising the step of transmitting a local NACK to the receiver. The method of claim 20, And sending, by the ARQ receiver, a status report to the ARQ transmitter for recovery of the failed packet. The method of claim 1, If the H-ARQ receiver does not receive the errored packet until the maximum time for delivery of the errored packet expires, the H-ARQ receiver sending a local NACK to the ARQ receiver H-ARQ support ARQ implementation method further comprising. The method of claim 20, And sending, by the ARQ receiver, a status report to the ARQ transmitter for recovery of the failed packet. The method of claim 1, And the ARQ receiver further comprises sending a status report upon successful reception of a predetermined number of packets. The method of claim 1, And sending a status report to the ARQ receiver when a status report timer expires. The method of claim 1, The ARQ transmitter requesting a status report from the ARQ receiver; And The ARQ receiver sending a status report to the ARQ transmitter H-ARQ support ARQ implementation method further comprising. 27. The method of claim 26 wherein the ARQ transmitter further comprises requesting the status report after transmission of a last packet. The method of claim 1, After transmitting the last packet of the buffer, the H-ARQ transmitter sends a small packet having a last packet indication; And And the H-ARQ receiver sending a response to the small packet such that the recovery of the last packet is assured by the small packet. 29. The method of claim 28 wherein the small packet is null transmission. 29. The method of claim 28 wherein the response to the small packet is sent by using the H-ARQ NACK-to-ACK error indicator. The method of claim 1 wherein the parameters for the maximum retransmission limit, the maximum time for the packet delivery, and the lifetime of the packet are configured by a central control entity. 32. The method of claim 31 wherein the parameter is configured when the transmitter is operating. 32. The method of claim 31 wherein the parameter is configured at the start of a service. 32. The method of claim 31 wherein the parameter is dynamically configured in accordance with a quality of service (QoS) requirement of a packet. 32. The H-ARQ supported ARQ of claim 31, wherein the maximum retransmission limit of the packet is indicated by identifying a particular medium access control (MAC) flow associated with a specific maximum retransmission limit of the associated control signaling for the first transmission. How to implement. 32. The method of claim 31 wherein the maximum retransmission limit of a packet is clearly indicated in the associated control signaling for the first transmission. A wireless communication system that implements hybrid automatic repeat request (H-ARQ) support automatic repeat request (ARQ), A receiver comprising an H-ARQ receiver and an ARQ receiver, wherein the H-ARQ receiver mistaken for an H-ARQ negative reception response (NACK) as a positive reception response (ACK) (H-ARQ NACK-to-ACK) error. Is determined, the number of retransmissions of an errored packet reaches a maximum retransmission limit, the maximum time for delivery of the errored packet has expired, and the lifetime of the errored packet has expired. A receiver for transmitting an H-ARQ NACK-to-ACK error indicator to the H-ARQ transmitter, if at least one of none has occurred; And A transmitter including the H-ARQ transmitter and an ARQ transmitter Wireless communication system comprising a. 38. The system of claim 37 wherein the H-ARQ NACK-to-ACK error indicator is associated with an H-ARQ process identity (ID) and the errored packet at the H-ARQ transmitter. 39. The system of claim 38 wherein the H-ARQ NACK-to-ACK error indicator includes the H-ARQ process ID and the transmission sequence number of the packet in which the error occurred. 39. The system of claim 38 wherein the H-ARQ NACK-to-ACK error indicator is sent at a fixed timing offset for transmission of the errored packet. 38. The system of claim 37 wherein the transmission of the H-ARQ NACK-to-ACK error indicator and the transmission of the errored packet are independent. 38. The method of claim 37, wherein the H-ARQ NACK-to-ACK error indicator is at least one of physical layer signaling, medium access control (MAC) layer signaling, and radio link control (RLC) layer signaling. Which is transmitted via one. 38. The system of claim 37, wherein the H-ARQ transmitter and the H-ARQ receiver are configured to transmit and receive more than one packet simultaneously, and the H-ARQ receiver receives H-ARQ NACK-to-ACK errors of more than one packet. And transmit the indicating H-ARQ NACK-to-ACK error indicator. 38. The system of claim 37 wherein the H-ARQ NACK-to-ACK error indicator is sent with cyclic redundancy check (CRC). 38. The system of claim 37 wherein the H-ARQ NACK-to-ACK error indicator is generated by one of the H-ARQ receiver and an ARQ receiver. 38. The system of claim 37 wherein the H-ARQ transmitter is configured to send an ACK to the H-ARQ receiver upon receipt of the H-ARQ NACK-to-ACK error indicator. 47. The method of claim 46, wherein the H-ARQ receiver repeatedly transmits the H-ARQ NACK-to-ACK error indicator until it successfully receives the ACK for the H-ARQ NACK-to-ACK error indicator. Wireless communication system. 48. The H-ARQ receiver of claim 47, wherein the H-ARQ receiver receives a new packet through the same H-ARQ process assigned to the failed packet instead of retransmitting the failed packet. And repeatedly transmitting the H-ARQ NACK-to-ACK error indicator. 48. The H-ARQ receiver of claim 47, wherein the H-ARQ receiver does not receive the errored packet until an error indication timer set when a NACK is sent to the H-ARQ transmitter expires. And transmit the H-ARQ NACK-to-ACK error indicator. 48. The method of claim 47, wherein if the maximum retransmission limit has been reached, the maximum delivery time has expired, and the lifetime of the errored packet has not expired, the errored packet has been successfully delivered. Until the H-ARQ transmitter retransmits the errored packet. 51. The method of claim 50, wherein if the maximum retransmission limit has been reached, the maximum delivery time has expired, or the lifetime of the errored packet has expired, the errored packet is recovered at an ARQ level. The ARQ transmitter sends a local NACK to the ARQ transmitter. 48. The method of claim 47, wherein the H-ARQ receiver sets a recovery timer when transmitting the H-ARQ NACK-to-ACK error indicator, and wherein the H-ARQ receiver generates the error before the recovery timer expires. If the packet is not received, the H-ARQ receiver sends a local NACK to the ARQ receiver. 53. The system of claim 52 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 48. The method of claim 47, wherein the H-ARQ receiver causes the error packet until the H-ARQ receiver receives a packet having a sequence number greater than a sequence number of the error packet. If not, the H-ARQ receiver sends a local NACK to the ARQ receiver. 55. The system of claim 54 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 38. The method of claim 37, wherein if the H-ARQ receiver does not receive the errored packet until the number of retransmissions of the errored packet reaches a maximum retransmission limit for the errored packet, Wherein the H-ARQ receiver sends a local NACK to the ARQ receiver. 59. The system of claim 56 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 58. The H-ARQ receiver of claim 57, wherein if the H-ARQ receiver does not receive the errored packet until the maximum time for delivery of the errored packet expires, the H-ARQ receiver sends the ARQ receiver to the ARQ receiver. And transmit a local NACK. 59. The system of claim 56 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 59. The system of claim 56 wherein the ARQ receiver sends a status report upon successful reception of a predetermined number of packets. 38. The system of claim 37 wherein the ARQ receiver sends a status report when a status report timer expires. 38. The system of claim 37 wherein the ARQ transmitter requests a status report from the ARQ receiver and the ARQ receiver sends a status report to the ARQ transmitter. 63. The system of claim 62 wherein the ARQ transmitter requests the status report after transmission of the last packet. 38. The method of claim 37, wherein after transmitting the last packet of the buffer, the H-ARQ transmitter sends a small packet having a last packet indication, and the H-ARQ receiver sends a response to the small packet, thereby transmitting the last packet. Wherein the recovery of the packet is assured by the small packet. 65. The system of claim 64 wherein the small packet is null transmission. 65. The system of claim 64 wherein the response to the small packet is sent by using the H-ARQ NACK-to-ACK error indicator. 38. The system of claim 37 wherein a parameter for at least one of the maximum retransmission limit, the maximum time for packet delivery, and the lifetime of the packet is configured by a central control entity. 68. The system of claim 67 wherein the parameter is configured when the receiver is operating. 68. The system of claim 67 wherein the parameter is configured at start of service. 68. The system of claim 67 wherein the parameter is dynamically configured according to a quality of service (QoS) requirement of a packet. 68. The system of claim 67 wherein the maximum retransmission limit of the packet is indicated by identifying a particular medium access control (MAC) flow associated with a specific maximum retransmission limit of the associated control signaling for the first transmission. 68. The system of claim 67 wherein the maximum retransmission limit of the packet is clearly indicated in the associated control signaling for the first transmission. A receiver that implements hybrid automatic repeat request (H-ARQ) support automatic repeat request (ARQ). An ARQ receiver; And Determine whether an error (H-ARQ NACK-to-ACK) that misidentifies the H-ARQ negative acknowledgment (NACK) as a positive acknowledgment (ACK) occurs; If at least one of the number of retransmissions of the failed packet has reached its maximum retransmission limit, the maximum time for delivery of the failed packet has expired, and the lifetime of the failed packet has expired, H-ARQ receiver sending H-ARQ NACK-to-ACK error indicator to H-ARQ transmitter H-ARQ support ARQ implementation receiver comprising a. 74. The H-ARQ support of claim 73, wherein the H-ARQ NACK-to-ACK error indicator is associated with an H-ARQ process identity (ID) and the errored packet at the H-ARQ transmitter. ARQ implementation receiver. 75. The receiver of claim 74 wherein the H-ARQ NACK-to-ACK error indicator comprises the H-ARQ process ID and the transmission sequence number of the packet in error. 75. The receiver of claim 74 wherein the H-ARQ NACK-to-ACK error indicator is transmitted at a fixed timing offset for transmission of the errored packet. 74. The receiver of claim 73 wherein the transmission of the H-ARQ NACK-to-ACK error indicator and the transmission of the errored packet are independent. 74. The method of claim 73, wherein the H-ARQ NACK-to-ACK error indicator is at least one of physical layer signaling, medium access control (MAC) layer signaling, and radio link control (RLC) layer signaling. H-ARQ supported ARQ implementation receiver that is transmitted over one. 75. The H-ARQ NACK-to-ACK error of claim 73, wherein the H-ARQ receiver is configured to receive more than one packet at the same time, indicating the H-ARQ NACK-to-ACK error of more than one packet. And an indicator for sending an H-ARQ supported ARQ implementation. 74. The receiver of claim 73 wherein the H-ARQ NACK-to-ACK error indicator is sent with cyclic redundancy check (CRC). 74. The receiver of claim 73 wherein the H-ARQ NACK-to-ACK error indicator is generated by one of the H-ARQ receiver and the ARQ receiver. 74. The method of claim 73, wherein the H-ARQ receiver repeatedly transmits the H-ARQ NACK-to-ACK error indicator until it successfully receives an ACK for the H-ARQ NACK-to-ACK error indicator. H-ARQ supported ARQ implementation receiver. 74. The H-ARQ receiver of claim 73, wherein if the H-ARQ receiver receives a new packet through the same H-ARQ process assigned to the errored packet instead of retransmission of the errored packet, And send the H-ARQ NACK-to-ACK error indicator. 74. The H-ARQ receiver of claim 73, wherein the H-ARQ receiver does not receive the errored packet until the error indication timer set when a NACK is sent to the H-ARQ transmitter expires. And send the H-ARQ NACK-to-ACK error indicator. 74. The method of claim 73, wherein the H-ARQ receiver sets a recovery timer when transmitting the H-ARQ NACK-to-ACK error indicator, and wherein the H-ARQ receiver generates the error before the recovery timer expires. If the packet is not received, the H-ARQ receiver sends a local NACK to the ARQ receiver. 86. The receiver of claim 85 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 74. The packet of claim 73, wherein the H-ARQ receiver causes the error-prone packet until the H-ARQ receiver receives a packet having a sequence number that is larger than a sequence number of the errored packet by a predetermined number. If not, the H-ARQ receiver sends a local NACK to the ARQ receiver. 88. The receiver of claim 87 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 74. The H-ARQ receiver of claim 73, wherein the H-ARQ receiver does not receive the errored packet until the number of retransmissions of the errored packet reaches a maximum retransmission limit for the errored packet. An ARQ receiver sending a local NACK to the ARQ receiver. 90. The receiver of claim 89 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 75. The H-ARQ receiver of claim 73, wherein the H-ARQ receiver does not receive the failed packet until the maximum time for delivery of the failed packet has expired. H-ARQ supported ARQ implementation receiver that transmits a local NACK. 92. The receiver of claim 91 wherein the ARQ receiver sends a status report to the ARQ transmitter for recovery of the errored packet. 75. The receiver of claim 73 wherein the ARQ receiver sends a status report upon successful reception of a predetermined number of packets. 80. The receiver of claim 73 wherein the ARQ receiver sends a status report when a status report timer expires. A transmitter that implements hybrid automatic repeat request (H-ARQ) support automatic repeat request (ARQ). ARQ transmitter; And H-ARQ transmitter configured to receive an error indicator that misidentifies the H-ARQ negative acknowledgment (NACK) as a positive acknowledgment (ACK) (H-ARQ NACK-to-ACK) Wherein the at least one of the ARQ transmitter and the H-ARQ transmitter is configured to recover an errored packet corresponding to the H-ARQ NACK-to-ACK error. The transmitter of claim 95, wherein the H-ARQ transmitter is configured to send an ACK to the H-ARQ receiver upon receipt of the H-ARQ NACK-to-ACK error indicator. 95. The method of claim 95, wherein if at least one of the maximum retransmission limit reached, the maximum delivery time expired, and the lifetime of the failed packet has expired has not occurred, the failed packet will be successfully delivered. Until the H-ARQ transmitter retransmits the errored packet. 97. The method of claim 95, wherein if the maximum retransmission limit has been reached, the maximum delivery time has expired, or the lifetime of the errored packet has expired, the errored packet is recovered at an ARQ level. An ARQ transmitter is to send a local NACK to the ARQ transmitter. 95. The H-ARQ supported ARQ implementation transmitter of claim 95, wherein the ARQ transmitter requests a status report from the ARQ receiver. 97. The transmitter of claim 95 wherein the ARQ transmitter requests the status report after transmission of the last packet. 95. The H-ARQ transmitter of claim 95, after sending the last packet of a buffer, the H-ARQ transmitter sends a small packet with a last packet indication, such that recovery of the last packet is assured by the small packet. ARQ implementation transmitter with ARQ support. 102. The H-ARQ supported ARQ implementation transmitter of claim 101 wherein the small packet is a null transmission. 102. The transmitter of claim 101 wherein the response to the small packet is transmitted by using the H-ARQ NACK-to-ACK error indicator.

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