KR20090062227A - Method and apparatus for reording of packet in a mobile communication system - Google Patents

Abstract

An apparatus and a method for reordering a packet in a mobile communication system are provided to prevent an error of the sequence rearrangement of a receiving device by stopping the transmission of the currently processed packet by the transmitting device. An RLC transmission device receives a RLC PDU transmission request from a lower layer(610). The RLC transmission device comprises the new RLC PDU and transmits the new RLC PDU to the lower layer(615). The serial number of the new RLC PDU is compared with the serial number of an upper part of the HARQ(Hybrid Automatic Retransmission Request) transmission window(620). The HARQ transmission window is moved(625). The transmission of the RLC PDU of the lower serial number than the serial number of the lower part of the HARQ transmission window is stopped(630).

Description

Packet reordering method and device in mobile communication system {METHOD AND APPARATUS FOR REORDING OF PACKET IN A MOBILE COMMUNICATION SYSTEM}

The present invention relates to an apparatus and a method for reordering the order of packets in a mobile communication system, and more particularly, to a method and an apparatus for reordering the order of packets in a mobile communication system supporting the HARQ scheme.

In general, mobile communication systems have been developed to provide voice services while ensuring user activity, but are gradually expanding to not only voice but also data services, and are now developed to the extent that they can provide high-speed data services. However, in the mobile communication system in which a service is currently provided, a shortage of resources and users demand faster services, and thus, a more advanced mobile communication system is required.

In response to these demands, one of the systems being developed as a next-generation mobile communication system, a specification work for Long Term Evolution (LTE) in 3GPP is in progress. LTE is a technology that implements high-speed packet-based communication with a transmission rate of up to 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.

1 is a diagram illustrating a protocol structure of an LTE system. Hereinafter, a packet input to a specific protocol layer device is called a SDU (Service Data Unit), and a packet output from a specific protocol layer device is called a PDU (Protocol Data Unit). For example, a packet input to an RLC device is an RLC SDU, and a packet output from an RLC device is an RLC PDU.

The PDCPs 105 and 140 perform an operation such as IP header compression / restore, and the RLCs 110 and 135 perform an ARQ operation after reconfiguring the PDCP PDU to an appropriate size. The MAC layer 120 is connected to several RLC devices configured in one terminal and performs an operation of multiplexing the RLC PDUs to the MAC PDU and demultiplexing the RLC PDUs from the MAC PDU. In the protocol layer device, an appropriate header is added as needed. For example, the RLC device adds an RLC header including a serial number to the RLC SDU, and the MAC device includes a MAC header including an RLC device identifier and the like in the MAC SDU. Add.

The physical layers 120 and 125 channel-code, modulate MAC PDUs into OFDM symbols and transmit them to the radio channel 123, or demodulate and channel decode the OFDM symbols received through the radio channel 123 and transmit them to a higher layer. Do the operation. The physical layers 120 and 125 also perform a hybrid automatic retransmission request (HARQ) operation on the MAC PDU. HARQ is a technique of performing retransmission in the physical layer and soft combining a retransmitted packet and an original packet. This has the advantage of reusing without wasting already used transmission resources and energy. HARQ is performed in units of MAC PDUs, and after transmitting the MAC PDU, the transmitting device receives HARQ feedback information on the MAC PDU through a predetermined physical channel. The MAC PDU is retransmitted or a new MAC PDU is transmitted as indicated by the feedback information. Upon receiving the MAC PDU, the receiving device decodes the MAC PDU through a predetermined process and checks whether an error occurs through a CRC operation. As a result of checking whether an error has occurred, if an error occurs, retransmission is requested through a predetermined physical channel, and if an error does not occur, the MAC PDU is transmitted to a higher layer. HARQ transmission and reception is performed through the HARQ transmission apparatus and the HARQ receiving apparatus called HARQ process, the terminal and the base station maximizes the transmission efficiency by driving several HARQ processes at the same time. For example, when a UE and a base station having n HARQ processes transmit a MAC PDU in an arbitrary HARQ process, another MAC PDU is transmitted through another HARQ process even before receiving feedback information on the MAC PDU. As described above, since multiple MAC PDUs are simultaneously processed through a plurality of HARQ processes, a reversal phenomenon inevitably occurs in the HARQ operation. The reversal order is a phenomenon in which the first MAC PDU transmitted succeeds later than the MAC PDU transmitted at a later time while undergoing more retransmission. Therefore, since the radio protocol must deliver the upper layer data to the upper layer in the same order as the upper layer, the radio protocol must rearrange the order of MAC PDUs in which the reversed order occurs.

In a conventional mobile communication system such as High Speed Downlink Packet Access (HSDPA) or High Speed Uplink Packet Access (HSUPA), the sequence reordering is performed at the MAC layer using a serial number called a Transmission Sequence Number (TSN). Is performed in the RLC layer using an RLC serial number called an RLC sequence number, and the size of the RLC SN is 5 bits or 10 bits, depending on the operation mode. In general, the minimum size of a serial number required for reordering is determined by the number of HARQ processes available at the same time and the maximum number of HARQ retransmissions. In WCDMA, a 6-bit TSN, that is, 64 serial numbers are used for order reordering. In LTE and WCDMA, the number of HARQ processes and the maximum number of HARQ retransmissions are almost the same.

2 is a diagram illustrating a general HARQ order rearrangement operation. HARQ order reordering is typically performed by a full window. In brief, the HARQ order rearrangement window 215 is composed of a predetermined window size 220, a window top 205, and a window bottom 210, and the HARQ transmission window bottom 210 is the serial number of the HARQ transmission window top. Is a serial number corresponding to an integer obtained by subtracting the order reordering window size, and the upper part of the HARQ transmission window 205 is the highest serial number of the serial numbers of the RLC PDU in which HARQ transmission is completed.

When the HARQ sequence rearrangement apparatus receives a packet having a serial number higher than the current upper serial number, the HARQ sequence rearrangement apparatus updates the upper serial number of the HARQ sequence rearrangement window to the higher serial number and moves the HARQ sequence rearrangement window accordingly.

Packets placed in the serial number region 230 lower than the HARQ order reordering window due to the movement of the HARQ order reordering window are regarded as having completed HARQ order reordering. For this operation, the HARQ sequence rearrangement apparatus should determine whether the serial number of the received packet is higher than the upper serial number of the HARQ sequence rearrangement window, which is generally set by setting the size of the HARQ sequence rearrangement window to half of the entire serial number size. It is simply implemented. That is, the serial number belonging to the HARQ order reordering window is a serial number lower than the upper serial number of the window, and the serial number not belonging to the HARQ order reordering window is a serial number higher than the upper serial number of the window. For example, assuming a 5-bit serial number, the total size of the serial number is 32 and the size of the HARQ order reordering window is 16. If at any point the top serial number of the HARQ sequence rearrangement window is 30 and the bottom serial number is 15, the serial numbers between 15 and 30 are the serial numbers within the HARQ sequence rearrangement window, and the serial numbers between 31 and 14 are the HARQ sequence rearrangements. The serial number outside the window. As shown in the operation of the HARQ order reordering window, if HARQ transmission and reception of the packet having the serial number [x + 16] succeeds and HARQ transmission and reception of the packet having the serial number x succeeds, a problem occurs in the HARQ order reordering operation.

That is, since the HARQ sequence rearrangement apparatus moves the upper portion of the window to the serial number [x + 16], when a packet having the serial number x is delivered later, the sequence rearrangement apparatus converts the serial number x to a serial number higher than [x + 16]. Recognize and move the window. A specific example will be described with reference to FIG. 3.

3 is a view for explaining a malfunction of the HARQ order rearrangement. When the upper serial number of the window is 15 (310) and the lower serial number is 0 (305), the packet 315 of serial number 1 and the packet 320 of serial number 18 are being processed in HARQ. If at any point in time the packet with serial number 18 is successfully processed, the sequence reordering device moves the top of the sequence reordering window to the serial number 18, and consequently, the packet with serial number 1 is located outside the sequence reordering window. If at any point in time a packet with serial number 1 has been successfully received and delivered to the sequence reordering device, the sequence reordering device may misinterpret the serial number 1 as serial number 1 325 of the next recurring cycle and associate the sequence reordering window with it. Malfunction to move in accordance with. As a result, the order of many packets ranging from serial numbers 3 to 17, which have not yet been reordered, is mistaken for reordering, and the packets in HARQ processing at that time among the packets within the serial number range are not reordered. Problems with processing occur.

The present invention proposes a method and apparatus for proactively preventing failure of order reordering due to a limited size RLC SN.

According to an embodiment of the present invention, when the transmission apparatus successfully transmits a packet in which a transmission device may malfunction due to a mistake of a serial number, if the packet is successfully transmitted, the serial number if the transmission is successfully performed later in the HARQ process Stop transmission of HARQ packets containing packets that may cause misunderstanding and discard them.

According to another embodiment of the present invention, when the transmission of the RLC PDU corresponding to the upper serial number of the HARQ transmission window starts, the transmitting device immediately returns a MAC PDU containing an RLC PDU having a serial number lower than the lower serial number of the HARQ transmission window. Provide a method for disposal.

According to another embodiment of the present invention, the first reception time information and the relative distance are used to determine the relationship between the arbitrary serial number and the serial number of the upper part of the order rearrangement window.

The present invention relates to a method and apparatus for resolving an order inversion caused by an HARQ operation. When a predetermined condition is satisfied, the present invention stops the transmission of a packet currently being processed by a transmitting device, thereby preventing occurrence of an order rearrangement malfunction of a receiving device. have.

Hereinafter, with reference to the accompanying drawings will be described in detail the operating principle of the embodiment of the present invention. In the following description of the present invention, detailed descriptions of well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention. 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.

According to the first embodiment of the present invention, when a transmitting device transmits a packet in which a malfunction may occur due to a mistake of a serial number, if the packet is successfully transmitted, the packet is transmitted if the packet is successfully transmitted later among HARQ processes. The transmission of the HARQ packet containing the packet which may cause a number misinterpretation is stopped and discarded.

The transmission apparatus according to the first embodiment of the present invention has a HARQ transmission window, and the HARQ transmission window is configured as follows. For reference, in the following description, it is assumed that the HARQ transmission window and the HARQ order rearrangement window operate based on an RLC sequence number (SN) and are provided in each of the RLC transmitting apparatus and the RLC receiving apparatus.

When the RLC transmitting apparatus receives a request for transmitting the RLC PDU from the lower layer, the RLC transmitter configures a new RLC PDU, assigns a serial number to the RLC PDU, and delivers the serial number to the lower layer. If any RLC PDU is successfully transmitted at the HARQ level, and an RLC PDU having a serial number smaller than the subtracted size of the HARQ transmission window from the serial number of the successfully transmitted RLC PDU is still transmitting at the HARQ level, Successful transmission of RLC PDUs with small serial numbers leads to malfunctions in HARQ order reordering. Therefore, the RLC transmitting apparatus controls the lower layer apparatus to stop the transmission of the RLC PDU satisfying the above condition if any RLC PDU is successfully transmitted by the HARQ transmitting apparatus.

4 is a diagram illustrating a structure of a HARQ transmission window, and FIG. 5 is a diagram illustrating a transmission operation according to a first embodiment of the present invention.

4 and 5, the size of the HARQ transmission window is 16, the lower serial number of the HARQ transmission window is 1 (515), the upper serial number of the HARQ transmission window is 16 (530). In this situation the transmission of the RLC PDU with serial number 18 is initiated. That is, the RLC PDU having the serial number set to 18 is delivered to the lower layer, and the lower layer starts the HARQ transmission by storing the RLC PDU in an arbitrary MAC PDU. If the RLC PDU [18] is successfully transmitted, that is, if a HARQ ACK is received for the MAC PDU containing the RLC PDU [18], the RLC transmitting apparatus moves the HARQ transmission window accordingly and changes the lower serial number to 3. Update with At this time, the RLC transmitting apparatus stops the transmission of the RLC PDU, that is, the RLC PDU [1], which is located outside the newly updated HARQ transmission window among the RLC PDUs currently being processed for HARQ, and receives the MAC PDU containing the RLC PDU. Control the lower layer to discard.

The fact that any RLC PDU is in the HARQ process means that the MAC PDU containing the RLC PDU is stored in the HARQ process, and the HARQ ACK for the MAC PDU has not yet been received. As described above, by successfully discarding a packet that incorrectly shifts the HARQ order reordering window when the HARQ transmission packet is successfully transmitted, HARQ order reordering is possible with a limited serial number of 5 bits.

6 illustrates an operation of a transmitter according to a first embodiment of the present invention.

Through the call setup process, the transmitting apparatus recognizes the size of the HARQ transmission window. This process is illustrated in step 605 of FIG. Since the size of the HARQ transmission window is the same as the size of the HARQ order reordering window, if the RLC transmitting apparatus recognizes the size of the HARQ transmission window, step 605 may be omitted. As described above, when the size of the transmission window recognizes the size of the HARQ order reordering window, the RLC transmitting apparatus initializes the upper serial number of the HARQ transmission window to 0 in step 610.

After completing the above procedure, the RLC transmitting apparatus performs an RLC PDU transmission procedure according to a conventional procedure. For example, when the lower layer requests to deliver the RLC PDU, the lower layer composes the RLC PDU according to the requested size and gives the RLC PDU a monotonically increasing serial number by 1 to deliver it to the lower layer, for example, the MAC layer. . The MAC layer multiplexes the RLC PDUs into MAC PDUs and inputs them to the transmitting HARQ process. The MAC PDU is transmitted to a receiving HARQ process through a predetermined HARQ process. The transmitting HARQ process determines that the MAC PDU is successfully transmitted when receiving the HARQ ACK for the MAC PDU. Alternatively, upon receiving HARQ NACK for the MAC PDU, HARQ retransmission of the MAC PDU is performed through a predetermined procedure, and the HARQ retransmission is continued until HARQ ACK is received or until it is limited by a predetermined maximum number of retransmissions. .

In the process of performing the normal RLC PDU transmission process, if it is recognized that the transmission of any RLC PDU is completed, that is, if the HARQ ACK for the MAC PDU containing the RLC PDU is received (615), the RLC transmitting apparatus 620 Proceed to step 1 and check whether the top of the HARQ transmission window needs to be updated. That is, the RLC transmitting apparatus compares the serial number of the completed RLC PDU with the upper serial number of the HARQ transmission window, and proceeds to step 625 when the serial number of the completed RLC PDU is larger than the upper serial number of the window. Waiting for the transmission of another RLC PDU is completed, and when the transmission of another RLC PDU is completed, the process returns to step 615.

In step 625, the transmitting device moves the HARQ transmission window and checks whether an RLC PDU having a serial number lower than the lower serial number of the newly updated HARQ transmission window is currently being processed in the HARQ process. In other words, after subtracting the HARQ transmission window size from the serial number of the transmitted RLC PDU, it is checked whether an RLC PDU having a serial number lower than an integer plus 1 is being processed in the HARQ process at the present time. If the RLC PDU of the serial number lower than the integer is being processed in the HARQ process, the flow proceeds to step 630. If the RLC PDU having a serial number lower than the integer is not being processed in the HARQ process, the transmitting apparatus waits until the transmission of another RLC PDU is completed and returns to step 615 when the transmission of another RLC PDU is completed. In operation 630, the transmitting apparatus flushes the HARQ process in which the MAC PDU containing the RLC PDU having a serial number lower than an integer after processing the subtracted window size from the serial number of the completed RLC PDU is being processed. That is, the operation of the HARQ process is stopped and the stored MAC PDU is discarded. The transmitting device that has completed the operation waits until the transmission of another RLC PDU is completed, and then returns to step 615 when the transmission of another RLC PDU is completed.

7 is a diagram illustrating an operation of a transmitting apparatus according to a second embodiment of the present invention.

In the second embodiment of the present invention, when the transmission of the RLC PDU corresponding to the upper serial number of the HARQ transmission window starts, the transmitting device immediately receives the MAC PDU containing the RLC PDU having a serial number lower than the lower serial number of the HARQ transmission window. Suggest how to dispose of

Through the call setup process, the RLC transmitting apparatus recognizes the size of the HARQ transmission window in step 705. Since the size of the HARQ transmission window is the same as that of the HARQ order reordering window, step 705 may be omitted if the RLC transmitting apparatus already knows the size of the HARQ transmission window. In the second embodiment, the upper serial number of the HARQ transmission window is the highest serial number among the serial numbers of the RLC PDUs being processed in the HARQ process at any present time, and the RLC serial number monotonously increases during the RLC PDU transmission. In consideration, the upper serial number of the HARQ transmission window is the serial number of the RLC PDU most recently delivered to the HARQ process.

In step 710, the RLC transmitting apparatus initializes the upper serial number of the HARQ transmission window to zero. After completing the above procedure, the RLC transmitting apparatus performs an RLC PDU transmission procedure according to a conventional procedure. That is, when the lower layer delivers the RLC PDU and notifies the size of the RLC PDU, the lower layer configures the RLC PDU according to the requested size and gives the RLC PDU a monotonically increasing serial number by 1 to give the lower layer, eg For example, the method transmits the MAC layer (715). After transmitting the RLC PDU to the lower layer, the RLC transmitting apparatus updates the upper serial number of the HARQ transmission window with the serial number of the delivered RLC PDU.

In step 720, the transmitting apparatus checks whether an RLC PDU having a serial number lower than a lower serial number of the newly updated HARQ transmission window is being processed in the HARQ process at the present time. That is, the MAC PDU storing the RLC PDU having a serial number lower than an integer added by 1 after subtracting the HARQ transmission window size from the serial number of the RLC PDU delivered to the lower layer in step 715 is stored for HARQ retransmission to the HARQ process at the present time. It is checked whether HARQ ACK for the MAC PDU has been received. If the condition is satisfied, the process proceeds to step 725. If the condition is not satisfied, the process waits until a new RLC PDU is configured and delivered to a lower layer, and then returns to step 715 when a new RLC PDU is delivered to a lower layer. In operation 725, the transmitting device discards the MAC PDU containing the RLC PDU having a lower serial number than the lower serial number of the HARQ transmission window in the HARQ process, waits until a new RLC PDU is configured and delivered to a lower layer, and then a new RLC PDU. Is passed to the lower layer, the process returns to step 715.

A third embodiment of the present invention provides a method and apparatus for increasing the HARQ order reordering window size of a receiving device to twice the normal size. For example, a method and apparatus for achieving HARQ order reordering performance equal to a 6 bit serial number using a 5 bit serial number is presented. When the serial number used for HARQ order reordering is k bits, the size of the HARQ order reordering window is usually 2k / 2. By setting the size of the HARQ order reordering window to half of the entire area of the serial number, the receiving device can determine whether the serial number of a packet received at any point in time is a serial number in the order reordering window or an external serial number of the order reordering window. It determines whether the received serial number is higher than the serial number at the top of the reordering window. For example, when a serial number is 5 bits, a HARQ order reordering window has a size of 16, a window top serial number of 15, and a window bottom serial number of 0, a packet having a serial number of 20 is received. It is clear that the serial number is located outside of. On the other hand, if the size of the HARQ sequence rearrangement window is set to 2k, which is the same as the entire area of the serial number, it is not known whether any serial number received at any time is a serial number in the HARQ sequence rearrangement window or a serial number outside the sequence rearrangement window. . Referring to FIG. 8, when the serial number is 5 bits, the size of the HARQ order reordering window is 32, the upper serial number of the window is 31, and the lower serial number of the window is 0, a packet of a serial number, for example, 3 When receiving the serial number may be a serial number 825 located in the HARQ order reordering window, it may be determined that the serial number 830 located outside the upper serial number of the HARQ order reordering window. In this way, if the size of the HARQ order reordering window is increased to twice the normal size, it is necessary to determine whether an arbitrary serial number is a serial number in the HARQ order reordering window through a separate mechanism. In the third embodiment of the present invention, the first reception time information and the relative distance are used to determine the relationship between the arbitrary serial number and the serial number at the top of the order rearrangement window.

An initial reception time of an RLC PDU means a time when HARQ is transmitted for the first MAC PDU in which the RLC PDU is stored. The HARQ transmission is performed through a physical downlink control channel (PDCCH) and a physical downlink shared channel (PDSCH). The PDCCH is a channel through which control information related to MAC PDU transmission is transmitted, and the PDSCH is a channel through which the MAC PDU is transmitted. Through the PDCCH, information such as transmission resources, MAC PDU size, transmission format, HARQ transmission number (RSN, Retransmission Sequence Number), HARQ process identifier, etc. are transmitted. When the terminal receives the control information through the PDCCH, the terminal performs a predetermined operation such as processing the MAC PDU of the size indicated through the indicated transmission resource and the transmission format and storing the MAC PDU in the indicated HARQ process. The HARQ transmission number is information indicating the number of HARQ transmissions of the corresponding MAC PDU transmission. The first reception time point refers to a point in time at which the PQCH indicated by the HARQ transmission number is indicated as the initial transmission. Since the UE may not receive the PDCCH, if the UE does not receive the PDCCH indicated by the HARQ transmission number as the initial transmission, and then successfully receives the MAC PDU through HARQ retransmission, the UE may determine the MAC PDU. The first reception point is unknown.

Given the time of first reception of any two packets, it is possible to clearly identify the prognostic relationship between the two packets. For example, a packet having an initial reception time t1 has a lower serial number since it occurred earlier than a packet having an initial reception time t1 + t2. By using the fact, a receiving apparatus that receives an arbitrary packet grasps the posterior relationship between the packet and the reference packet by comparing the initial reception time of the packet with the initial reception time of any reference packet, and accordingly the It is determined whether the serial number of the received packet is a serial number in the HARQ order rearrangement window or a serial number outside the window. If the initial reception time of the received packet is unknown, the receiving apparatus measures the relative distance between the serial number of the received packet and the serial number of the reference packet, and determines the position of the received packet as the position where the relative distance is short. do. That is, the receiving device compares the difference between the two serial numbers when the serial number of the received packet is lower than the reference serial number and compares the difference between the two serial numbers when the serial number of the received packet is higher than the reference serial number. Select the case with small difference value.

An operation of a third embodiment according to the present invention will be described with reference to FIG. 9.

At any point in time, the serial number is 5 bits, the HARQ order rearrangement window size is 32 (920), the upper window serial number is 22 (905), the lower window serial number is 9 (910), and the initial reception time of the upper window serial number. When 100 (905), it is assumed that the PDU [28] is received at the terminal. If the initial reception time of the PDU [28] is 50, the serial number of the PDU should be lower than the upper serial number of the window, so that the receiving device places the PDU in the HARQ order reordering window. Thereafter, if a PDU [31] whose initial reception time is unknown at any point in time is received, the receiving device compares the relative distance between the PDU [31] and the upper serial number of the sequence rearrangement window, which is a reference serial number, in both directions. do. If the received PDU [31] is located in the order reordering window, the distance between the serial number of the PDU and the top serial number of the order reordering window is MOD [22-31, 32] = 23. On the other hand, if the PDU [31] is located outside the order reordering window, the distance between the serial number 31 of the received PDU and the top serial number 22 of the order reordering window is MOD [31-22, 32] = 9. The receiving device adopts the case where the PDU [31], which is a case of short distance, is located outside the order reordering window. That is, it is determined that the serial number 31 is higher than the upper serial number of the reordering window, and takes necessary actions such as moving the upper serial number of the window to 31.

10 is an operation of a receiving apparatus according to a third embodiment of the present invention.

In step 1005, the receiving device initializes the HARQ order reordering window. The receiving apparatus sets the upper serial number of the HARQ order reordering window to 0 and initializes the reference initial reception time to the earliest possible time, for example, the time of initializing the window. The reference initial time point is a time point when the PDU of the uppermost serial number is first received.

When receiving the RLC PDU for the first time in step 1010, the receiver proceeds to step 1015 and updates the serial number of the first received RLC PDU to the upper serial number of the HARQ order reordering window, and confirms the first reception time of the first received RLC PDU. Update to the time of the first reference reception. Since the upper serial number of the HARQ window has been updated, the receiving device moves the HARQ order rearrangement window accordingly. If the first reception time of the first received RLC PDU is unknown, the reception apparatus sets the reference initial reception time to 'unknown'.

If the RLC PDU is received in step 1020, the receiving device proceeds to step 1025 and checks whether both the initial reception time and the reference initial reception time of the received RLC PDU are known, and if both values are known, in step 1030, If at least one of the two values is unknown, go to step 1035. Proceeding to step 1030, it is possible to determine whether the serial number of the received packet is higher or lower than the upper serial number of the window by comparing the initial reception time of the received packet with the reference initial reception time. In step 1030, the receiving apparatus checks whether the first reception time of the received packet is later than the reference initial reception time, and if so, proceeds to step 1040 and, if not, to step 1050. Proceeding to step 1040 means that the received packet occurred later than the packet corresponding to the upper serial number of the window, so the serial number of the received packet is higher than the upper serial number of the window. Therefore, the receiving device places the received packet outside the HARQ order reordering window. That is, the serial number of the received packet is regarded as a serial number higher than the upper serial number of the HARQ order reordering window, and placed in the position indicated by the serial number. Since the upper serial number of the HARQ order reordering window has been updated to a new value, the receiving device moves the HARQ order reordering window in step 1045 and updates the reference initial reception time point to the first reception time of the received packet. It then takes some actions according to the movement of the HARQ order reordering window and waits until a new RLC PDU arrives. If the initial reception time of the received packet is earlier than the reference initial reception time, the reception device proceeds to step 1050. In step 1050, the receiving apparatus determines that the serial number of the received packet is located in the HARQ order reordering window, and stores the received packet at a position indicated by the serial number in the HARQ order reordering window. It then takes some actions by storing the new packet in the HARQ order reordering window and waits until a new RLC PDU arrives. If at least one of the initial reception time and the reference initial reception time of the packet received in step 1025 is not known, the reception apparatus proceeds to step 1035. Proceeding to step 1035 means that it is not possible to determine whether the received packet should be located in the HARQ order reordering window or outside the HARQ order reordering window by comparing the first reception time. In step 1035, the receiving device checks whether an RLC PDU having the same serial number as that of the received packet is already stored in the HARQ order reordering window. If the RLC PDU having the same serial number already exists in the HARQ order reordering window, the received RLC PDU is an RLC PDU located outside the HARQ order reordering window, so the receiving apparatus proceeds to step 1040 to order the RLC PDUs. It is located in an area higher than the upper serial number of the reordering window, and takes a series of operations such as updating the upper serial number of the HARQ order reordering window. If a packet having the same serial number as the received packet is not stored in the HARQ order reordering window, the position of the received packet may be inside or outside the HARQ order reordering window. Therefore, the receiver proceeds to step 1055 and compares the serial number of the received packet with the upper serial number of the HARQ order reordering window, and determines whether the received serial number of the received packet is higher than the upper serial number of the HARQ order reordering window. The process is performed by comparing D_R and D_F, and D_R and D_F are calculated through Equation 1 below.

D_R = MOD (SN_reference-SN_received, 2k), D_R = MOD (SN_received-SN_reference, 2k)

The SN_received is the serial number of the received packet, and the SN_reference is the upper serial number of the HARQ order reordering window.

If D_R is greater than D_F in step 1055, that is, if the distance when the received packet is located in the HARQ order reordering window is greater than the distance when the received packet is located in front of the HARQ order reordering window, the received packet is This means that it should be located in front of the HARQ order reordering window. Therefore, the process proceeds to step 1040 to update a serial number of the upper part of the HARQ order reordering window.

If D_F is greater than D_R, that is, if the distance when the received packet is located in front of the HARQ order reordering window is greater than the distance when the received packet is located in the HARQ order reordering window, then the received packet is placed in HARQ order. Since it means that it should be located in the reordering window, the process proceeds to step 1050 to perform a series of operations such as placing the received RLC PDU where the received serial number is located in the HARQ order reordering window. After the upper serial number of the HARQ order rearrangement window is updated, the process of discarding the MAC PDU containing the RLC PDU having a serial number lower than the lower serial number of the HARQ transmission window is the same as the method of FIGS. 6 and 7.

11 is a structure of a transmitter according to an embodiment of the present invention.

The transmitting apparatus is composed of a plurality of RLC transmitting apparatuses 1105 and 1110, a MAC multiplexing apparatus 1115, an HARQ transmitting process 1120, and a physical layer transmitting apparatus 1125.

The RLC transmitting apparatus constructs an RLC PDU and delivers it to the MAC PDU. The RLC transmitting apparatus assigns an RLC serial number monotonically increasing by 1 to the RLC PDU. The RLC transmitter receives notification of HARQ transmission success of the RLC PDU from the MAC multiplexer. If the RLC transmitting apparatus has a HARQ transmission window, the upper serial number of the HARQ transmission window is updated, and the RLC PDU of the lower serial number is being processed in the HARQ transmission process at the time, flush the HARQ process being processed by the RLC PDU. Notify the MAC multiplexer.

The MAC multiplexer multiplexes the RLC PDUs transmitted by the RLC transmitting apparatus into MAC PDUs, and inputs the MAC PDUs into the HARQ process. If the MAC PDU input to the HARQ process is successfully transmitted, the related RLC transmitting apparatus is notified. When the MAC multiplexer notifies the RLC transmitting apparatus to discard the MAC PDU in which the specific RLC PDU is stored, the MAC multiplexer controls the HARQ process to discard the data stored in the HARQ transmission process that the MAC PDU is processing.

The HARQ transmission process is a set of HARQ process transmission buffers and stores MAC PDUs for which HARQ transmission is not completed.

The physical layer transmitting apparatus processes data stored in the HARQ process in a predetermined manner and transmits the data through a wireless channel.

12 is a structure of a receiving apparatus according to an embodiment of the present invention.

The receiving apparatus includes a plurality of RLC receiving apparatuses 1205 and 1210, a MAC demultiplexing apparatus 1215, an HARQ receiving process 1220, and a physical layer receiving apparatus 1225.

The RLC receiver is a device that receives and processes the RLC PDU delivered by the MAC demultiplexer. The RLC receiving apparatus includes a HARQ order reordering window, receives an RLC PDU and an RLC PDU first reception time from a MAC demultiplexing device, compares a reference initial reception time and an initial reception time of the received RLC PDU, and receives the received time. It determines whether the RLC PDU is a PDU in the HARQ order reordering window or a window outside the window, and performs a necessary operation according to the determination. For example, if it is determined that an RLC PDU outside the window is received, the HARQ order reordering window is moved so that the serial number of the new RLC PDU becomes the upper serial number, and the order reordering of the RLC PDUs located in the outer region of the window is completed. To be considered.

The MAC demultiplexer demultiplexes MAC PDUs successfully received in the HARQ process into RLC PDUs, and delivers them to the appropriate RLC device. At this time, the first reception time of the RLC PDUs is transmitted together.

The HARQ reception process is a set of HARQ process reception buffers and stores MAC PDUs for which HARQ reception is not completed.

The physical layer receiving apparatus receives data through a wireless channel in a predetermined manner and transmits the data to the HARQ process.

1 is a diagram illustrating a protocol structure of LTE

2 is a diagram illustrating a general HARQ order reordering operation

3 is a view for explaining a malfunction of HARQ order rearrangement;

4 is a diagram illustrating a structure of a HARQ transmission window.

5 is a diagram illustrating a transmission operation according to the first embodiment of the present invention.

6 is a flowchart illustrating a transmission operation according to the first embodiment of the present invention.

7 is a flowchart illustrating a transmission operation according to the second embodiment of the present invention.

8 is a diagram when the size of the HARQ order reordering window is set to twice the normal size;

9 is a diagram illustrating an order reordering operation according to a third embodiment of the present invention.

10 is a view for explaining the operation of the receiving apparatus according to the third embodiment of the present invention;

11 is a structure of a transmitter according to an embodiment of the present invention

12 is a structure of a receiving apparatus according to an embodiment of the present invention

Claims (4)

In the packet data rearrangement method of a mobile communication system supporting a complex automatic retransmission request (HARQ), Receiving, by the RLC transmitting apparatus, an RLC PDU transmission request from a lower layer, transmitting, by the RLC transmitting apparatus, a new RLC PDU to the lower layer; Comparing the serial number of the transmitted new RLC PDU with the serial number of the upper part of the HARQ transmission window, moving the HARQ transmission window, Stopping the transmission procedure by an RLC PDU having a serial number lower than a lower serial number of the shifted HARQ transmission window. In the packet data rearrangement method of a mobile communication system supporting a complex automatic retransmission request (HARQ), Receiving, by the HARQ receiving apparatus, the first MAC PDU in which the RLC PDU is stored; Receiving, by the HARQ receiving apparatus, any second MAC PDU; Comparing the time points at which the two packets are received, and if the second MAC PDU is higher than the upper serial number of the HARQ transmission window, updating the serial number of the upper HARQ transmission window with the serial number of the second MAC PDU. Reordering packet data in a communication system. The method of claim 2, If the reception time of the second MAC PDU is unknown, Assuming that the received second MAC PDU is inside the HARQ transmission window, measuring a relative distance from the upper serial number of the HARQ transmission window; Assuming that the received second MAC PDU is outside of the HARQ transmission window, measuring a relative distance from the upper serial number of the HARQ transmission window; And determining that the second MAC PDU is higher than the upper serial number of the HARQ transmission window when the relative distance is assumed to be external. The method of claim 2, When the serial number used in the packet data rearrangement method is n bits, the size of the HARQ transmission window is 2n bits.

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