KR20080003682A - Method and apparatus for quickly transmitting packet by adjusting timing of retransmission of HARV in mobile communication system - Google Patents

Abstract

The present invention relates to a method and apparatus for quickly transmitting a packet by adjusting a HARQ retransmission timing in a mobile communication system, wherein the terminal transmits a buffer status report to a resource allocated from a base station and a determined retransmission timing (HARQ). RTT) process of receiving length information, and if it is determined that the short HARQ RTT by checking the length of the determined HARQ RTT, and transmits the HARQ packet using the resources allocated by the base station, the time distance (T_feedback) of the short feedback information Receiving a feedback signal from the base station after elapsed), if the received feedback signal is NACK, retransmitting a HARQ packet after a short HARQ RTT time elapses, and then receiving the received feedback signal. And retransmitting the HARQ packet until ACK.

Description

METHOD AND APPARATUS FOR PACKET TRANSMIT BY HARQ RETRANSMISSION TIMING CONTROLLING IN A MOBILE COMMUNICATION SYSTEM}

1 is a diagram illustrating the structure of an LTE system.

2 is a diagram illustrating a message transmission and reception procedure according to the prior art.

3 shows the effect of a long HARQ RTT and a short HARQ RTT on message transmission.

4 is a diagram illustrating a message transmission and reception procedure according to a first embodiment of the present invention.

5 is a flowchart showing the operation of the terminal of the first preferred embodiment of the present invention.

6 is a diagram illustrating a message transmission and reception procedure according to a second preferred embodiment of the present invention.

7 is a flowchart illustrating an operation of a terminal according to a second preferred embodiment of the present invention.

8 is a diagram illustrating a message transmission and reception procedure according to a third embodiment of the present invention.

9 is a flowchart illustrating an operation of a terminal according to a third embodiment of the present invention.

10 is a flowchart illustrating an operation of determining, by a terminal, retransmission timing according to a third embodiment of the present invention.

11 is a diagram illustrating a reverse transmission structure of a terminal according to an embodiment of the present invention.

12 is a diagram illustrating a reverse reception structure of a base station according to a preferred embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile communication system using HARQ, and more particularly, to a method and apparatus for quickly processing a packet by shortly adjusting a retransmission timing of a packet requiring rapid processing.

Long Term Evolution (LTE) is under discussion at 3GPP, which is responsible for UMTS standardization. LTE is a technology that implements high-speed packet-based communication of about 100 Mbps, aiming for commercialization in 2010. To this end, various methods are discussed. For example, the network structure can be simplified to reduce the number of nodes located on the communication path, or the wireless protocols can be as close to the wireless channel as possible. As a result, the structure of LTE is expected to change from the existing four-node structure to a two-node or three-node structure.

1 is a diagram illustrating the structure of an LTE system.

Referring to FIG. 1, it may be simplified to a two node structure of an Evolved Node B (ENB) 105 and an Evolved Gateway GPRS Serving Node (EGGSN) 110.

The ENB 105 is a node corresponding to an existing Node B and is connected to a user equipment (UE) 100 through a wireless channel. Unlike the existing Node B, ENB plays a more complex role. In LTE, all user traffic, including real-time services such as VoIP, will be serviced via a shared channel, which means that a device is needed to collect and schedule situation information of UEs 100, and ENB 105 Is responsible for the scheduling.

Similar to HSDPA (High Speed Downlink Packet Access) or EDCH (Enhanced Dedicated Channel), LTE performs hybrid automatic repeat reQuest (hereinafter referred to as HARQ) between ENB 105 and UE 100. LTE is expected to use Orthogonal Frequency Division Multiplexing (OFDM) as a wireless access technology in the 20 MHz bandwidth to achieve transmission rates up to 100 Mbps. In addition, an adaptive modulation & coding (AMC) scheme that determines a modulation scheme and a channel coding rate according to the channel state of the terminal will be applied.

The HARQ is a technique of increasing reception success rate by soft combining with retransmitted data without discarding previously received data.

HARQ is used to increase transmission efficiency in high-speed packet communication such as HSDPA and EDCH, and LTE also uses HARQ between a terminal and a base station.

The HARQ is divided into synchronous and asynchronous HARQ based on the transmission timing of the retransmitted packet.

In synchronous HARQ, the retransmission timing of packets is constant. Therefore, the transmitting side must execute retransmission for any packet at a predetermined point in time. Therefore no special packet identifier is needed.

In asynchronous HARQ, the retransmission timing of packets is not constant. Therefore, when retransmitting any packet, the transmitting side should transmit a packet identifier (also referred to as HARQ processor identifier) indicating which packet should be soft combined with the retransmitted packet. In general, synchronous HARQ is used in the reverse direction, and asynchronous HARQ is used in the forward direction.

In the synchronous HARQ system, the retransmission timing is determined based on the encoding delay and decoding delay of the largest packet, the ACK / NACK transmission delay for the packet, and the like.

In LTE with 20 MHz bandwidth, the largest packet size is expected to reach 50000 bits (0.5 msec TTI). Therefore, the processing time for the maximum packet up to 50000 bits will be an important factor in determining the retransmission timing in the system. The retransmission timing is also called HARQ Round Trip Time (RTT).

When any packet is transmitted through HARQ, the packet is typically retransmitted several times at the HARQ level. Therefore, the HARQ RTT is closely related to the transmission delay of the packet. In other words. The shorter the HARQ RTT, the greater the probability that the transmission delay will be shorter.

In general, a small size control message is exchanged first before full data transmission and reception. Since the control message is transmitted / received in a request / response format, new data is not generated until one control message is processed.

For this reason, control messages generally need to be processed quickly, regardless of their kind. That is, since the response message to the control message is not received until the transmission of any control message is completed, the faster the control message is processed, the smaller the call setup delay is. However, it is inefficient to use the conventional HARQ RTT with the handling of the largest packet in the control message transmission.

2 is a diagram illustrating a message transmission and reception procedure according to the prior art.

2 illustrates a problem of the prior art in a general communication flow using a shared channel, and data is first generated at step 215 at an arbitrary terminal 205 that is not transmitting or receiving data at any time. The data may be, for example, a registration message generated after the terminal is powered on, a location update message generated after the terminal moves to a new cell, or may be a control message for setting a control plane.

In step 220, the terminal 205 transmits a buffer status report message indicating that there is data to be transmitted to the base station 210, and the base station 210 allocates resources to the terminal 205 in step 225.

In step 230, the terminal 205 transmits data to the base station 210 using the allocated resource. In step 235, the base station 210 decodes the message and performs a CRC operation. If not, the NACK is transmitted to the terminal 205.

The terminal 205 receiving the NACK retransmits the message to the base station 210 at the time when the message was first transmitted in step 240 by a HARQ RTT.

The base station 210 receives the message in step 245, but since the reception is not completed, the base station 210 transmits a NACK to the terminal 205.

In step 250, the terminal 205 retransmits the message to the base station 210 at the time when HARQ RTT passes again. The message retransmission is repeated until the ACK is received from the base station 210 in step 255.

In the message transmission / reception procedure using the HARQ according to the prior art operating as described above, although the retransmission must be continued until the transmission of the message is completed, a typical HARQ in consideration of the processing of the largest packet for transmission of the control message. By using the RTT, there is a problem that the call setup delay is increased due to the rapid message processing.

Accordingly, the present invention, which was devised to solve the problems of the prior art operating as described above, provides a method and apparatus for quickly transmitting a packet by adjusting a HARQ retransmission timing in a mobile communication system.

The present invention provides a method and apparatus for using a short HARQ RTT instead of a conventional HARQ RTT for small messages exchanged several times in a mobile communication system.

The present invention provides a method and apparatus for notifying a base station of which HARQ RTT to use, in a state in which a terminal and a base station recognize a length of a long HARQ RTT and a short HARQ RTT in a mobile communication system.

The present invention provides a method and apparatus for using a short HARQ RTT when a predetermined condition is satisfied in a state where a terminal and a base station recognize a length of a long HARQ RTT and a short HARQ RTT in a mobile communication system in advance.

The present invention always starts with a short HARQ RTT in a state in which a UE and a base station recognize a length of a long HARQ RTT and a short HARQ RTT in a mobile communication system, and the base station changes the HARQ RTT through separate three-layer signaling. It is to provide a method and apparatus.

According to an embodiment of the present invention, in a method of quickly transmitting a packet by adjusting a HARQ retransmission timing in a mobile communication system, a terminal transmits a buffer status report to allocate resources allocated from a base station and a determined retransmission timing (HARQ RTT) length. Receiving information, and if it is determined that the short HARQ RTT by checking the determined length of the HARQ RTT, the HARQ packet is transmitted using the resources allocated by the base station, the elapsed time (T_feedback) of the short feedback information has elapsed After receiving the feedback signal from the base station, if the received feedback signal is NACK, performing a retransmission of the HARQ packet after a short HARQ RTT time elapsed, and then the received feedback signal is ACK Until a retransmission of the HARQ packet is characterized in that it comprises.

According to another embodiment of the present invention, in a method of transmitting a packet by adjusting a HARQ retransmission timing in a mobile communication system, a terminal transmits a buffer status report to receive an allocated resource from a base station, and the reported buffer status. Determining whether a short retransmission timing (HARQ RTT) use condition is met using a value and an allocated resource; if the short HARQ RTT use condition is met, transmitting a HARQ packet using the allocated resource, and providing short feedback information. Receiving a feedback signal from the base station after a time T_feedback has elapsed; if the received feedback signal is NACK, performing a retransmission of a HARQ packet after a short HARQ RTT time elapses; And then retransmitting the HARQ packet until the received feedback signal is an ACK. It shall be.

In another embodiment of the present invention, a method of transmitting a packet by adjusting the HARQ retransmission timing in a mobile communication system, the terminal transmits a buffer status report to receive the allocated resources from the base station, and the allocated resources Save the default HARQ RTT and T_feedback in the retransmission timing (HARQ RTT) and the time distance (T_feedback) of the feedback information to be used at the same time as sending the first message to enter the connected state to the network radio resource control (RRC) layer. And when a new HARQ RTT and T_feedback are received from the network RRC layer, storing the new HARQ RTT and T_feedback in HARQ RTT and T_feedback to be used, and performing HARQ packet transmission based on the stored HARQ RTT and T_feedback. It characterized in that it comprises a process.

Another embodiment of the present invention, in the apparatus for transmitting a packet by adjusting the HARQ retransmission timing in a mobile communication system, a multiplexing apparatus for multiplexing a packet of a higher layer into a HARQ packet, and performing the transmission and retransmission of the HARQ packet HARQ processor to process the feedback signal received from the base station after the time (T_feedback) of the feedback information at the time when the HARQ processor transmits the packet, if the feedback signal is ACK A feedback signal processor for instructing a HARQ processor to transmit a new HARQ packet, and instructing the HARQ processor to retransmit after a retransmission timing (HARQ RTT) if the feedback signal is NACK, and determining the sizes of the HARQ RTT and T_feedback; The HARQ RTT is transmitted to the HARQ processor, and T_feedback is the feedback signal processing. HARQ RTT / T_feedback control unit for transmitting to the base station, a transceiver for transmitting and receiving a control message and HARQ packet through signaling between the base station and the network radio resource control (RRC) layer, and processes the message received from the base station And a forward control channel processor.

In another embodiment of the present invention, in the apparatus for transmitting a packet by adjusting the HARQ retransmission timing in a mobile communication system, transmitting and receiving a control message and HARQ packet through signaling between the terminal and the network radio resource control (RRC) layer A transceiver, a forward control channel processor for processing a message received from the terminal, a HARQ packet transmitted by the terminal, soft combining and performing a CRC operation to determine whether there is an error, and having an error A HARQ processor storing the packet in a soft buffer, transmitting an HARQ packet without an error to the demultiplexing device, and notifying the feedback signal generator whether there is an error, and a higher layer of higher layer packets stored in the HARQ packet. A demultiplexing apparatus for demultiplexing a packet and a time equal to T_feedback when the HARQ processor receives a packet After the consumption, the feedback signal generator for transmitting a feedback signal to the terminal, and determine the size of the HARQ RTT and T_feedback, the HARQ RTT is transmitted to the HARQ processor, T_feedback HARQ RTT to deliver to the feedback signal processor It includes a / T_feedback control unit.

Hereinafter, the operating principle of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily flow the gist of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

Although the present invention has been described in particular on the basis of LTE application, it can be applied to all mobile communication systems using HARQ without any modification.

The present invention provides a method and apparatus for using a short HARQ RTT instead of a conventional HARQ RTT for small messages exchanged several times before full data transmission and reception, such as a control message.

In a state in which the UE and the base station recognize the lengths of the long HARQ RTT and the short HARQ RTT in advance, a method of notifying the base station of which HARQ RTT to use is presented as an embodiment of the present invention.

In a state in which the UE and the base station recognize the lengths of the long HARQ RTT and the short HARQ RTT in advance, a method of using the short HARQ RTT when a predetermined condition is satisfied is described as a second embodiment of the present invention.

In a state in which the UE and the base station recognize the lengths of the long HARQ RTT and the short HARQ RTT in advance, the method starts with the short HARQ RTT always, and the base station changes the HARQ RTT through separate three-layer signaling. To present.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

3 is a diagram illustrating the effect of a long HARQ RTT and a short HARQ RTT on message transmission.

The transmission delay required for the transmission of a general control message can be expressed as Equation 1 below.

PACKET TRANSMISSION DELAY = TTI  + (NUMBER OF HARQ  TRANSMISSIONS-1) x HARQ RTT  x TTI

In a system in which HARQ RTT is 8, if any packet is initially transmitted through processor 1 305, retransmission of the packet is performed at 310 after 8 TTIs. Assuming that all three retransmissions were required until the packet was successfully transmitted, the packet is completed at 315, so the time taken to transmit the packet in the wireless channel is all 25 TTI. If one TTI is 0.5 msec, this corresponds to 12.5 msec.

As can be seen from Equation 1, a short HARQ RTT can be used to transmit a packet more quickly. For example, in a system having HARQ RTT of 4, since packet transmission is completed in 13 TTIs in the same situation, 6.5 msec is required. Therefore, the effect of reducing the delay of 6 msec occurs. If the HARQ RTT is 2, the packet transmission is completed in 7 TTIs, and thus the improvement effect is further increased, compared to the case where the HARQ RTT is 8. The delay of 9 msec can be reduced.

<First Embodiment>

In one embodiment of the present invention, a base station notifies a terminal of which HARQ RTT and a short HARQ RTT are known in advance, and a base station notifies the terminal which HARQ RTT to use.

4 is a diagram illustrating a message transmission and reception procedure according to a first embodiment of the present invention.

Referring to FIG. 4, data is first generated at an arbitrary terminal 405 that is not transmitting or receiving data at any time in step 415. The data may be, for example, a registration message generated after the terminal is powered on, a location update message generated after the terminal moves to a new cell, or a control message for setting a control plane.

Accordingly, the terminal 405 transmits a buffer status report message indicating that there is data to be transmitted to the base station 410 in step 420, and the base station allocates resources to the terminal 405 in step 425.

At this time, the base station 410 instructs the terminal to use a short HARQ RTT when the following several conditions are satisfied.

-The data to be sent must be processed quickly.

-The amount of data to be transmitted is small enough to take all necessary operations such as packet encoding and decoding within a short HARQ RTT.

In step 430, the terminal 405 transmits data to the base station 410 using the allocated resource. In step 435, the base station 410 decodes the message and performs a CRC operation. At this point, the feedback information is transmitted to the terminal 405.

In the HARQ system, after a predetermined time passes after the HARQ packet is transmitted, feedback information about the packet is transmitted. After that, for convenience of description, the time distance between any HARQ packet and feedback information for the packet is named T_feedback.

The length of the HARQ RTT is closely related to the size of the T_feedback, and in order to have a short HARQ RTT, the T_feedback must also have a small value.

Therefore, the terminal 405 and the base station 410 know in advance the length of the short HARQ RTT and the long HARQ RTT, and the length of T_feedback to be used for the short HARQ RTT and the long HARQ RTT. For convenience of description, the T_feedback applied to the short HARQ RTT is referred to as the short T_feedback, and the T_feedback applied to the long HARQ RTT is referred to as the long T_feedback.

The base station 410 may notify the terminal of the length of the HARQ RTT using the resource allocation information in step 425, or may notify the terminal of the length of the HARQ RTT using other forward control information. In addition, the base station 410 selects the length of the T_feedback according to the length of the HARQ RTT notified to the terminal 405. That is, if the base station instructs 410 to use a short HARQ RTT, the UE 405 transmits feedback information on the HARQ packet at a time point 433 after a short T_feedback when the HARQ packet is received in step 435. do.

The terminal 405 similarly transmits a packet to which a short HARQ RTT is applied, and regards a signal received at a time point as short as T_feedback as a feedback signal for the packet. Thus, if the feedback signal is NACK, the HARQ packet is retransmitted to the base station 410 in step 440, and the base station 410 transmits the feedback information on the HARQ packet to the terminal 443 after T_feedback in step 445. 405).

Thereafter, the terminal 405 checks the feedback information received in step 450 and if it is NACK, retransmits the HARQ packet to the base station 410. The above process is repeated until the feedback signal received from the base station 410 is ACK.

Meanwhile, the terminal 405 transmits a HARQ packet using a short HARQ RTT and a short T_feedback until the base station instructs to use a long HARQ RTT.

5 is a flowchart showing the operation of the terminal of the first preferred embodiment of the present invention.

Referring to FIG. 5, in step 500, the UE recognizes a length of a short HARQ RTT, a length of a short T_feedback, a length of a long HARQ RTT, and a length of a long T_feedback. Of course, such parameters may have unique values for each system, so that it may not be necessary to use separate signaling to recognize the parameters. Alternatively, you can use the previously used values.

In step 505, the length of HARQ RTT is signaled to the UE. In the previous step, the terminal reports the type and amount of data to be transmitted to the base station through the buffer status report, and the base station determines the length of the terminal HARQ RTT based on the information. The HARQ RTT length information may be signaled through a forward common control channel.

In step 510, the UE checks the length of the signaled HARQ RTT, and if the long HARQ RTT is signaled, proceeds to step 515, and if the short HARQ RTT is signaled, proceeds to step 530.

In step 515, the UE transmits a HARQ packet using resources allocated by the base station. In step 520, the UE receives a feedback signal from the base station after a long T_feedback has elapsed.

If the feedback signal received in step 520 is NACK, the terminal performs a retransmission of the HARQ packet by applying a long HARQ RTT in step 525. That is, retransmission of the HARQ packet is performed after a long HARQ RTT time elapses from the transmission time point of the previous HARQ packet.

If the short HARQ RTT is signaled in step 510, the UE transmits a HARQ packet using resources allocated by the base station in step 530, and receives a feedback signal from the base station after a short T_feedback in step 535.

If the feedback signal received in step 535 is NACK, the UE performs retransmission of the HARQ packet by applying a long HARQ RTT in step 540. That is, after a short HARQ RTT time elapses from the transmission time of the previous HARQ packet, the HARQ packet is retransmitted.

Second Embodiment

In the second embodiment of the present invention, a method of saving transmission resources required for RTT length signaling is proposed by allowing the terminal and the base station to implicitly select the RTT length without explicitly signaling the length of the RTT.

6 is a diagram illustrating a message transmission and reception procedure according to a second embodiment of the present invention.

Referring to FIG. 6, data is first generated at an arbitrary terminal 605 that is not transmitting or receiving data at any time in step 615. The data may be, for example, a registration message generated after the terminal is powered on, a location update message generated after the terminal moves to a new cell, or a control message for setting a control plane.

In step 620, the terminal 605 transmits a buffer status report message indicating that there is data to be transmitted to the base station 610, and the base station 610 allocates resources to the terminal 605 in step 625.

In this case, the terminal 605 and the base station 610 determine whether the buffer status and the allocated resources of the terminal 605 meet the short HARQ RTT usage condition.

Short HARQ RTT usage conditions may include, for example, the following.

1. In the buffer status reported by the terminal, only a message to be processed quickly, for example, a control message, is written.

2. The buffer size stored in the terminal is less than or equal to a predetermined reference value.

3. The size of the resource allocated to the terminal is less than a predetermined reference value.

If all three conditions are met, the terminal 605 and the base station 610 use a short HARQ RTT in step 630.

The terminal 605 transmits data to the base station 610 using the allocated resource in step 633. The base station decodes the message and performs a CRC operation in step 635. To send.

In this case, the base station 610 transmits feedback information on the HARQ packet at a time point that is as short as T_feedback 634 when the HARQ packet is received.

The terminal 605 transmits a packet to which a short HARQ RTT is applied in step 633, and considers a signal received at a time point equal to T_feedback as a feedback signal for the packet in step 635. In this case, when the received feedback signal is NACK, the terminal 605 retransmits the packet at a time point shorter by a short HARQ RTT when the HARQ packet is transmitted in step 640.

The terminal 605 and the base station 610 repeat the process until the transmission of the packet is completed. That is, the terminal 605 repeats until it receives the ACK signal for the packet from the base station 610.

Meanwhile, when the new buffer status is reported or the size of the resource allocated to the terminal 605 changes, the terminal 605 and the base station 610 check whether the short HARQ RTT usage condition is met.

7 is a flowchart illustrating an operation of a terminal according to a second preferred embodiment of the present invention.

Referring to FIG. 7, in step 700, the UE recognizes a length of a short HARQ RTT and a length of a short T_feedback, a length of a long HARQ RTT and a length of a long T_feedback, and THRESHOLD_1, THRESHOLD_2, and THRESHOLD_3. Such parameters may have unique values for each system, so that it may not be necessary to use separate signaling to recognize the parameters. Alternatively, you can use the previously used values. The THRESHOLD_1 is a threshold of the buffer size used for determining whether to use a short HARQ RTT, and THRESHOLD_2 is a threshold of an allocated resource size used for determining whether to use a short HARQ RTT. THRESOLD_3 is also a priority threshold used for determining whether to use a short HARQ RTT.

As the short HARQ RTT usage condition, for example, a short HARQ RTT when the size of the reported buffer is smaller than THRESHOLD_1, the size of the allocated resource is smaller than THRESHOLD_2, and the priority of the reported buffer is higher than THRESHOLD_3. Can be used.

In step 703, the terminal reports the buffer status to the base station, and in step 705, the resource to be used by the terminal is signaled from the base station.

In step 710, the UE determines whether the short HARQ RTT usage condition as shown above is met based on the buffer status value reported in step 703 and the allocated resource signaled in step 705.

If the use of the short HARQ RTT is determined, go to step 730, otherwise proceed to step 715.

In step 715, the UE transmits a HARQ packet using resources allocated by the base station. In step 720, the UE receives a feedback signal from the base station after a long T_feedback has elapsed.

If the feedback signal received in step 720 is NACK, the UE performs a retransmission of the HARQ packet by applying a long HARQ RTT in step 725. That is, retransmission of the HARQ packet is performed after a long HARQ RTT time elapses from the transmission time point of the previous HARQ packet.

If the use of the short HARQ RTT is determined in step 710, the UE transmits the HARQ packet using the resources allocated by the base station in step 730, and receives a feedback signal from the base station after the short T_feedback has elapsed in step 735.

If the feedback signal received in step 735 is NACK, the UE performs retransmission of the HARQ packet by applying a short HARQ RTT in step 740. That is, after a short HARQ RTT time elapses from the transmission time of the previous HARQ packet, the HARQ packet is retransmitted.

Third Embodiment

In the third embodiment of the present invention, the HARQ RTT value to be used as a default is determined in advance, and when the base station wants to use a HARQ RTT other than the default value, the base station performs radio resource control (RRC) signaling. It proposes a method of notifying the UE of a new HARQ RTT value and a T_feedback value by using.

8 is a diagram illustrating a message transmission and reception procedure according to a third embodiment of the present invention. Referring to FIG. 8, data is first generated at an arbitrary terminal 805 that is not transmitting or receiving data at any time in step 815. The data may be, for example, a registration message that occurs after the terminal 805 is powered on, a location update message that occurs after the terminal 805 moves to a new cell, or for setting a control plane. It may be a control message.

Accordingly, the terminal 805 transmits a buffer status report message 820 indicating that there is data to be transmitted to the base station 810 in step 820, and the base station 810 transmits resources to the terminal 805 in step 825. Assign.

In this case, since the HARQ RTT value to be used for the terminal 805 is not signaled, the terminal 805 transmits the initial message to the base station 810 by applying the HARQ RTT and T_feedback defined as default values in step 833. do. Since the default HARQ RTT is a value applied to a control message transmitted before the user plane is set, the default HARQ RTT is not defined based on a time required for processing the largest packet, but is defined based on a time required for processing a normal control message.

The first control message is transmitted to the RRC layer 812 of the network, and the network RRC layer 812 generates an appropriate control message according to the content of the control message in step 825 and transmits it to the terminal 805. When the HARQ RTT of the terminal 805 is to be changed to a value other than the default value, the RRC layer 812 of the network includes the HARQ RTT value and the T_feedback value to be changed in the control message.

The terminal 805 performs an appropriate operation based on the contents of the received control message. For example, if the received message is a user plane setting message, the user plane is set by referring to configuration information of the user plane included in the received message.

If the control message includes a new HARQ RTT value and a T_feedback value, the terminal 805 transmits the signaled new HARQ RTT value and the T_feedback instead of the default HARQ RTT and the default T_feedback in transmitting a future packet in step 830. Use a value.

If the RRC layer 812 of the network attempts to change the HARQ RTT value in step 835, the RRC layer 812 includes a new HARQ RTT value and a T_feedback value to be changed in an appropriate control message, and transmits it to the terminal, and the terminal 805 performs step 840. Uses the newly signaled HARQ RTT and T_feedback values.

9 is a flowchart illustrating an operation of a terminal according to a third embodiment of the present invention.

Referring to FIG. 9, the terminal manages variables called CURRENT_T_feedback and CURRENT_HARQ_RTT.

Whenever the HARQ packet is transmitted, the values stored in the variable at the time when the packet is transmitted are used as the T_feedback value and the HARQ_RTT value.

In step 900, the UE transmits a HARQ packet using resources allocated by the base station. In step 905, the UE receives a feedback signal from the base station after a time elapsed by the value stored in CURRENT_T_feedback.

If the feedback signal received in step 905 is NACK, the terminal performs retransmission of the HARQ packet in step 280. At this time, the retransmission time point is a time point in which a time equal to the value stored in the CURRENT_HARQ_RTT has passed from the time point of transmitting the previous HARQ packet.

10 is a flowchart illustrating an operation of determining, by a terminal, a retransmission timing according to a third embodiment of the present invention.

Referring to FIG. 10, the UE manages CURRENT_T_feedback and CURRENT_HARQ_RTT variables. In step 1005, the UE recognizes the lengths of the default HARQ RTT and the default T_feedback. Since such parameters have unique values for each system, there is no need to use separate signaling to recognize the parameters.

In step 1005, the terminal transmits a first message to enter the connected state.

As soon as the UE transmits the message in steps 1015 and 1020, the UE stores a default HARQ RTT and a default T_feedback in CURRENT_HARQ_RTT and CURRENT_T_feedback. Therefore, the default HARQ RTT and the default T_feedback are applied to the transmission of the first message.

After the new HARQ RTT value and the new T_feedback value are signaled in step 1025, the UE updates CURRNET_HARQ_RTT with the newly signaled HARQ RTT value in step 1030 and 1035 with the newly signaled T_feedback value.

After that, when the terminal transitions from the connected state to another state, for example, an idle state in step 1040, the terminal clears the values stored in the CURRENT_HARQ_RTT and CURRENT_T_feedback variables in step 1045.

11 is a diagram illustrating a reverse transmission and reception structure of a terminal according to an embodiment of the present invention. Referring to FIG. 11, a reverse transmission / reception apparatus of a terminal includes a multiplexing apparatus 1105, a HARQ processor 1110, a feedback signal processor 1115, an HARQ RTT / T_feedback controller 1120, a forward control channel processor 1125, and a transceiver 1130.

The multiplexing device 1105 multiplexes a packet of a higher layer into a HARQ packet. The HARQ processor 1110 is responsible for transmitting and retransmitting the HARQ packet, and the feedback signal processor 1115 processes the feedback signal received from the base station after T_feedback takes time when the HARQ processor transmits the packet. . If the feedback signal is ACK, the HARQ processor is instructed to transmit a new HARQ packet. If the feedback signal is NACK, the HARQ processor is instructed to be retransmitted. The size of the T_feedback uses a value delivered by the HARQ RTT / T_feedback controller 1120.

The HARQ RTT / T_feedback controller 1120 determines the sizes of the HARQ RTT and the T_feedback, and transmits the HARQ RTT to the HARQ processor and the T_feedback to the feedback signal processor 1115.

In the first embodiment, the HARQ RTT / T_feedback control unit 1120 receives information from the forward control channel processor 1125 to determine which HARQ RTT of a long HARQ RTT and a short HARQ RTT to be used.

In the second embodiment, the HARQ RTT / T_feedback control unit 1120 determines which HARQ RTT is used between the long HARQ RTT and the short HARQ RTT based on the content of the most recently transmitted buffer status report and the most recently received resource information. do.

In the third embodiment, the HARQ RTT / T_feedback control unit 1120 is informed of which HARQ RTT to use from the RRC layer.

12 is a diagram illustrating a reverse reception structure of a base station according to an embodiment of the present invention.

Referring to FIG. 12, a reverse reception apparatus of a base station includes a demultiplexer 1205, a HARQ processor 1210, a feedback signal generator 1215, an HARQ RTT / T_feedback controller 1220, a forward control channel processor 1225, It consists of a transceiver 1230.

The demultiplexer 1205 demultiplexes the upper layer packets stored in the HARQ packet to the appropriate upper layer. The HARQ processor 1210 soft-combines HARQ packets transmitted by the terminal and performs a CRC operation to determine whether there is an error. The HARQ packet having an error is stored in a soft buffer, and the HARQ packet having no error is transmitted to the demultiplexing device 1205. The feedback signal generator 1215 notifies of the presence of an error. The feedback signal generator 1215 is a device that transmits a feedback signal to the terminal after the time required by T_feedback when the HARQ processor receives the packet. The size of the T_feedback uses a value delivered by the HARQ RTT / T_feedback controller 1220.

The HARQ RTT / T_feedback controller 1220 determines the sizes of the HARQ RTT and the T_feedback, and transmits the HARQ RTT to the HARQ processor and the T_feedback to the feedback signal processor.

In the case of the first embodiment, the HARQ RTT / T_feedback controller 1220 transmits information to the forward control channel processor 1225 to determine which HARQ RTT of a long HARQ RTT and a short HARQ RTT to be used.

In the second embodiment, the HARQ RTT / T_feedback control unit 1220 determines which HARQ RTT is used between a long HARQ RTT and a short HARQ RTT based on the contents of the most recently received buffer status report and the most recently transmitted resource information. .

In the third embodiment, the HARQ RTT / T_feedback controller 1220 is informed of which HARQ RTT to use from the RRC layer.

As described above, in order to quickly transmit an important control message in a synchronous HARQ system, a method of using a variable HARQ RTT has been described.

However, the necessity of quickly transmitting a control message in an asynchronous HARQ system is the same, and this is possible by quickly performing retransmission of the HARQ packet.

In the asynchronous HARQ system, the retransmission time point is not constant and variable, but the retransmission time point is closely related to the time point at which the receiver transmits feedback information. That is, since retransmission cannot be performed until the feedback information is transmitted, it is important to shorten T_feedback in order to quickly retransmit in an asynchronous HARQ system.

Therefore, the methods presented in the embodiments of the present invention are equally applicable to an asynchronous HARQ system. However, in the asynchronous HARQ system, since the HARQ RTT value is variable and the T_feedback value is fixed, only the T_feedback value is adjusted, not both HARQ RTT and T_feedback.

For example, similar to the first embodiment of the present invention, the UE and the base station may recognize the long T_feedback value and the short T_feedback value, and the base station may signal which T_feedback to use for each packet through the forward control channel.

Alternatively, similarly to the second embodiment of the present invention, the UE and the base station recognize the long T_feedback value, the short T_feedback value, and THRESHOLD. You can also use T_feedback.

Alternatively, similar to the third embodiment of the present invention, when the terminal and the base station recognize the default value of the T_feedback, and want to use a T_feedback other than the default value, the new T_feedback value may be signaled by the RRC signaling.

In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

The present invention has the effect of efficiently reducing the transmission delay time due to packet retransmission by adjusting the HARQ retransmission timing to quickly transmit the packet.

Claims (18)

In the method for transmitting a packet by adjusting the HARQ retransmission timing in a mobile communication system, The terminal transmits a buffer status report to receive the resources allocated from the base station and the determined retransmission timing (HARQ RTT) length information; If the determined length of the HARQ RTT is determined to be a short HARQ RTT, the HARQ packet is transmitted by using the resources allocated by the base station, and a feedback signal is received from the base station after a time T_feedback of the short feedback information has elapsed. Receiving process, If the received feedback signal is NACK, retransmitting a HARQ packet after a short HARQ RTT time elapses; And then retransmitting the HARQ packet until the received feedback signal is an ACK. The method of claim 1, wherein the terminal, A method of transmitting a packet by adjusting HARQ retransmission timing, wherein the length of a short HARQ RTT, a length of a short T_feedback, a length of a long HARQ RTT, and a length of a long T_feedback are recognized. The method of claim 1, wherein if it is determined that the long HARQ RTT is determined by checking the determined length of the HARQ RTT, the HARQ packet is transmitted by using the resources allocated by the base station, and the feedback signal is received from the base station after the long T_feedback has elapsed. Process, If the received feedback signal is NACK, performing a retransmission of the HARQ packet after a long HARQ RTT time elapses; And then retransmitting the HARQ packet until the received feedback signal is an ACK. In the method for transmitting a packet by adjusting the HARQ retransmission timing in a mobile communication system, Receiving, by the terminal, an allocated resource from the base station by transmitting a buffer status report; Determining whether the reported buffer state value and the allocated resource meet the short retransmission timing (HARQ RTT) usage condition; If the short HARQ RTT usage condition is met, transmitting a HARQ packet using the allocated resource, receiving a feedback signal from the base station after a time T_feedback of the short feedback information elapses; If the received feedback signal is NACK, retransmitting a HARQ packet after a short HARQ RTT time elapses; And then retransmitting the HARQ packet until the received feedback signal is an ACK. The method of claim 4, wherein the terminal, The length of the short HARQ RTT and the length of the short T_feedback, the length of the long HARQ RTT and the length of the long T_feedback, the threshold of the buffer size used to determine whether to use the short HARQ RTT, and the allocation used to determine whether to use the short HARQ RTT. A method for transmitting a packet by adjusting the HARQ retransmission timing, wherein the resource size threshold value 2 and the priority threshold value 3 used for determining whether to use a short HARQ RTT are recognized. 6. The HARQ according to claim 4 or 5, wherein the HARQ is short when the size of the reported buffer is smaller than the threshold 1, the size of the allocated resource is smaller than the threshold 2, and the priority of the reported buffer is higher than the threshold 3. Method for transmitting a packet by adjusting the HARQ retransmission timing, characterized in that using the RTT. The method of claim 4, further comprising: transmitting a HARQ packet using the allocated resource and receiving a feedback signal from the base station after a long T_feedback when the long HARQ RTT usage condition is met; If the received feedback signal is NACK, performing a retransmission of the HARQ packet after a long HARQ RTT time elapses; And then retransmitting the HARQ packet until the received feedback signal is an ACK. In the method for transmitting a packet by adjusting the HARQ retransmission timing in a mobile communication system, Receiving, by the terminal, an allocated resource from the base station by transmitting a buffer status report; HARQ RTT defaults to the retransmission timing (HARQ RTT) and the time distance (T_feedback) of the feedback information to be used simultaneously with transmitting the first message to enter the connected state using the allocated resource to the network radio resource control (RRC) layer. Storing the T_feedback and When a new HARQ RTT and T_feedback is received from the network RRC layer, storing the new HARQ RTT and T_feedback in the HARQ RTT and T_feedback to be used; And performing a HARQ packet transmission on the basis of the stored HARQ RTT and T_feedback. The method of claim 8, wherein the terminal, The method for transmitting a packet by adjusting the HARQ retransmission timing, wherein the default HARQ RTT and T_feedback are recognized. The method as claimed in claim 8, further comprising the step of deleting information stored in the HARQ RTT and T_feedback to be used when the terminal releases the connected mode. An apparatus for transmitting a packet by adjusting a HARQ retransmission timing in a mobile communication system, A multiplexing device for multiplexing a packet of a higher layer into a HARQ packet, A HARQ processor for transmitting and retransmitting the HARQ packet; The HARQ processor processes the feedback signal received from the base station after a time as much as a time T_feedback of feedback information at the time of transmitting the packet. If the feedback signal is ACK, a new HARQ is transmitted to the HARQ processor. A feedback signal processor for instructing to transmit a packet and instructing the HARQ processor to retransmit after the elapse of HARQ RTT if the feedback signal is NACK; A HARQ RTT / T_feedback controller for determining the size of the HARQ RTT and the T_feedback, transmitting the HARQ RTT to the HARQ processor, and transmitting the T_feedback to the feedback signal processor; A transceiver for transmitting and receiving a control message and a HARQ packet through signaling between the base station and a network radio resource control (RRC) layer; And a forward control channel processing unit for processing a message received from the base station, wherein the HARQ retransmission timing is adjusted. The method of claim 11, wherein the HARQ RTT / T_feedback control unit, The apparatus for transmitting a packet by adjusting the HARQ retransmission timing, characterized by receiving information from the forward control channel processor to determine which HARQ RTT, one of a long HARQ RTT and a short HARQ RTT. The method of claim 11, wherein the HARQ RTT / T_feedback control unit, Based on the contents of the most recently transmitted buffer status report and the most recently received resource information, it is determined whether the HARQ RTT, the long HARQ RTT or the short HARQ RTT, is to be used. Device. The method of claim 11, wherein the HARQ RTT / T_feedback control unit, The apparatus for transmitting a packet by adjusting the HARQ retransmission timing, characterized in that the network RRC layer is informed which HARQ RTT to use. An apparatus for transmitting a packet by adjusting a HARQ retransmission timing in a mobile communication system, A transceiver for transmitting and receiving a control message and a HARQ packet through signaling between a terminal and a network radio resource control (RRC) layer; A forward control channel processor for processing a message received from the terminal; Soft combining HARQ packets transmitted by the terminal and performing a CRC operation to determine whether there is an error, the HARQ packet having an error is stored in a soft buffer, and the HARQ packet without an error is the demultiplexer. A HARQ processor for transmitting a signal to the feedback signal generator and reporting an error to the feedback signal generator; A demultiplexing device for demultiplexing higher layer packets stored in the HARQ packet to a higher layer, A feedback signal generator for transmitting a feedback signal to the terminal after the time required by T_feedback when the HARQ processor receives the packet; The HARQ RTT and T_feedback are determined, the HARQ RTT is transmitted to the HARQ processor, and the T_feedback includes a HARQ RTT / T_feedback control unit for transmitting the feedback signal processor to adjust the HARQ retransmission timing. Device to transmit. The method of claim 15, wherein the HARQ RTT / T_feedback control unit, And transmitting the packet from the forward control channel processor by adjusting the HARQ retransmission timing, wherein the HARQ RTT and the short HARQ RTT are used to determine information on which HARQ RTT to use. The method of claim 15, wherein the HARQ RTT / T_feedback control unit, Based on the contents of the most recently received buffer status report and the most recently transmitted resource information, it is determined whether the HARQ RTT, the long HARQ RTT or the short HARQ RTT, is to be used. Device. The method of claim 15, wherein the HARQ RTT / T_feedback control unit, The apparatus for transmitting a packet by adjusting the HARQ retransmission timing, characterized in that the network RRC layer is informed which HARQ RTT to use.

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