JP2011530259A - Terminal signal transmission method and apparatus in mobile communication system - Google Patents

Abstract

The present invention provides a method and apparatus for determining whether a reverse transmission resource allocation message is for transmission of a new packet or retransmission of an existing packet in consideration of NDI, RV, and HARQ buffer states. provide.
A signal transmission method and apparatus for a terminal in a mobile communication system according to the present invention includes a process of checking whether data is stored in a HARQ buffer, and, if data is stored in the buffer, NDI (New Data Indicator). And a step of retransmitting a MAC PDU by applying an instructed transmission resource and RV (Redundancy Version) when the NDI is not toggled.

Description

  The present invention relates to a method and apparatus for processing a reverse transmission resource assignment message in a mobile communication system, and more particularly, to distinguish between an initial reverse transmission resource assignment message and a retransmission reverse transmission resource assignment message in a mobile communication system. The present invention relates to a method and an apparatus.

  UMTS (Universal Mobile Telecommunication Service) system is based on GSM (Global System for Mobile Communications) and GPRS (General Packet Radio Services) based on GSM (Global Packet Radio Services) and GPRS (General Packet Radio Services). This is a third generation asynchronous mobile communication system using CDMA).

  Currently, in 3GPP (3rd Generation Partnership Project), which is in charge of UMTS standardization, a discussion on LTE (Long Term Evolution) is in progress as a next generation mobile communication system of the UMTS system. LTE is a technology that implements high-speed packet-based communication having a transmission rate of about 100 Mbps at the maximum, and is targeted for commercialization around 2010. For this purpose, various methods have been discussed. For example, a method for simplifying the network structure and reducing the number of nodes located on the communication path, a method for bringing the wireless protocol as close as possible to the wireless channel, etc. Is under discussion.

FIG. 1 is a diagram illustrating a structure of an LTE mobile communication system.
Referring to FIG. 1, a next generation radio access network (Evolved Radio Access Network, hereinafter referred to as E-RAN) 110, 112 is a next generation base station (Evolved Node B, hereinafter, ENB or Node B). 120, 122, 124, 126, 128 and a higher node (Access Gateway) 130, 132. A user terminal (User Equipment, hereinafter referred to as UE) 101 is connected to an Internet Protocol (Internet Protocol, hereinafter referred to as IP) network by E-RANs 110 and 112.

  ENBs 120-128 correspond to existing Node Bs in the UMTS system. The ENB is connected to the UE 101 via a radio channel and performs a more complicated role than the existing Node B. In LTE, since all user traffic including real-time services such as VoIP (Voice over IP) using the Internet protocol is serviced through a shared channel, a device for collectively scheduling UE status information is provided. This is necessary, and this is handled by ENB 120-128. One ENB typically controls multiple cells. In order to realize a transmission rate of up to 100 Mbps, LTE uses an orthogonal frequency division multiplexing (hereinafter referred to as OFDM) as a wireless connection technology with a maximum bandwidth of 20 MHz. In addition, an adaptive modulation & coding (hereinafter referred to as AMC) scheme that determines a modulation scheme and a channel coding rate according to the channel state of the terminal is applied.

FIG. 2 is a diagram illustrating a protocol stack of the LTE system.
As shown in FIG. 2, the radio protocol of the LTE system includes PDCP (Packet Data Convergence Protocol) 205 and 240, RLC (Radio Link Control) 210 and 235, MAC (Medium Access Control) 215 and 230, and physical (PHYsical). It consists of layers 220 and 225. PDCP (Packet Data Convergence Protocol) 205 and 240 are responsible for operations such as IP header compression / decompression, and Radio Link Control (Radio Link Control, hereinafter referred to as RLC) 210 and 235 are PDCP PDUs (Packet Data Unit, Hereinafter, a packet output from the specific protocol layer device is referred to as a PDU of the above protocol) and is reconfigured to an appropriate size to perform an ARQ operation or the like. The MACs 215 and 230 are connected to various RLC layer devices configured in one terminal, and perform operations of multiplexing RLC PDUs into MAC PDUs and demultiplexing RLC PDUs from MAC PDUs. The physical layers 220 and 225 perform channel coding and modulation on the upper layer data and generate OFDM symbols to transmit through the radio channel, or demodulate the OFDM symbols received through the radio channel, perform channel decoding, and transmit to the upper layer. Behave.

  In the LTE mobile communication system, HARQ is applied during transmission of reverse MAC PDU to improve transmission efficiency. In a mobile communication system to which HARQ is applied, a receiving apparatus that fails to receive a MAC PDU transmits HARQNACK to the transmitting apparatus, and the transmitting apparatus retransmits the MAC PDU. The receiving apparatus softly combines the retransmitted MAC PDU with the existing MAC PDU, thereby increasing a transmission / reception success probability.

  In the LTE mobile communication system, transmission resources are allocated through a reverse transmission resource allocation message.

FIG. 3 is a diagram illustrating an example of a reverse transmission resource allocation message.
Referring to the transmission resource assignment message shown in FIG. 3, the transmission resource assignment field 305 is information indicating the amount and position of the transmission resource used by the terminal. In the LTE mobile communication system, a unit transmission resource is a resource block (resource block) having a length of 1 msec and a predetermined bandwidth, and a resource block is allocated through the transmission resource allocation field.

  Modulation / channel coding field 310 is a field that indicates a modulation scheme and channel coding rate applied to data to be transmitted. The above field is 5 bits, and is composed of 29 code points from a code point indicating a combination of QPSK modulation and 0.11 channel coding rate to a code point indicating a combination of 64 QAM modulation and 0.95 channel coding rate. Is done. The remaining three points indicate RV (Redundancy Version). To further explain this, reference is made to Table 1 below.

  Table 1 is disclosed in the 3GPP standard document 36.213V 8.60, and discloses the relationship between the transmission block size (TBS) index according to the MCS level stored in the modulation / channel coding field 310 and RV. Referring to Table 1, when the MCS level is 0 to 28, RV is 0, and there is a corresponding transmission block size (TBS) index. Further, when the MCS level is 29 to 31, the RV is 1 to 3, respectively, and there is no corresponding transmission block size (TBS) index.

  NDI (New Data Indicator) 315 is 1-bit information indicating whether the transmission resource allocation message is related to new transmission or retransmission.

  An example of reverse HARQ operation, reverse transmission resource allocation message and NDI is shown in FIG.

FIG. 4 is a diagram illustrating an example of reverse transmission resource allocation message and NDI.
Referring to FIG. 4, if a terminal receives a reverse transmission resource allocation message at an arbitrary time (405), the terminal transmits a transmission indicated by the reverse transmission resource allocation message after a predetermined T 410 elapses. The MAC PDU is transmitted using the resource 415 and the MCS level. For convenience of explanation, the MAC PDU transmitted through the transmission resource allocated in 405 is named MAC PDU A. The terminal performs the transmission with a predetermined time difference of HARQ RTT 417 until transmission of the MAC PDU A is completed, that is, until a HARQ ACK for the MAC PDU A is received or a predetermined maximum allowable number of retransmissions is reached. Re-transmission is performed using resources (420, 425). Transmission of the MAC PDU A is completed at an arbitrary time, and then a new reverse transmission resource allocation message is transmitted to the terminal at an arbitrary time (430). The NDI of the transmission resource allocation message is instructed to have a value different from the NDI of the previous transmission resource allocation message, and the terminal sees that the NDI has changed, and the reverse transmission resource allocation message received at the time is the new MAC. Recognize that it is a transmission resource allocation message for PDU transmission. The terminal starts transmission of a new MAC PDU, for example, MAC PDU B, using the new transmission resource 435. Similarly, the UE retransmits the MAC PDU using the allocated transmission resource for each predetermined HARQ RTT (440).

  For efficient utilization of transmission resources, the base station can move the currently ongoing MAC PDU transmission to other transmission resources. This is called adaptive retransmission, and the base station instructs the terminal to perform adaptive retransmission by transmitting a reverse transmission resource allocation message having the same NDI to the terminal. For example, if a transmission resource for MAC PDU B transmission is to be moved to another RB at an arbitrary time after 430, the new transmission resource information to be moved is stored, and the MAC PDU B transmission is commanded. The reverse transmission resource allocation message 443 containing NDI 1 which is the same NDI as the NDI of the previous reverse transmission resource allocation message is transmitted to the terminal. If the terminal receives a reverse transmission resource allocation message instructing the same NDI as the previous NDI, the terminal determines that adaptive retransmission is instructed, and uses the newly allocated transmission resource to determine the MAC. PDU B is retransmitted (445, 450).

  Thus, using the NDI to determine whether the reverse transmission resource allocation message is for retransmission of an existing MAC PDU or a new MAC PDU transmission, the terminal is responsible for all reverse transmission resources. Operates under the previous title of successfully receiving an assignment message.

FIG. 5 is a diagram showing a problem of the prior art.
Referring to FIG. 5, the terminal receives a reverse transmission resource allocation message in which NDI is set to 0 at an arbitrary time (505), and the terminal transmits the reverse transmission resource allocation as described with reference to FIG. The MAC PDU is transmitted using the transmission resource 515 indicated by the message and the MCS level, and the MAC PDU is retransmitted using the allocated transmission resource for each predetermined HARQ RTT (520). After completing the transmission of the MAC PDU, the terminal commands the transmission of a new MAC PDU at any time, that is, the transmission resource allocation message whose NDI is changed to 1 is lost (525). There may be a case where a transmission resource allocation message for instructing a new MAC PDU transmission is received, that is, a message 530 in which NDI is changed to 0. In this case, since the NDI of the message 530 is the same as the NDI of the most recently received reverse transmission resource assignment message 505, the terminal may mistake the reverse transmission resource assignment message as a message for adaptive retransmission. it can.

  Accordingly, the present invention provides a method and apparatus for discriminating first reverse transmission resource allocation information from a reverse transmission resource allocation message for retransmission in a mobile communication system.

  Also, the present invention provides a method and apparatus for distinguishing a reverse transmission resource allocation message for new MAC PDU transmission and a reverse transmission resource allocation message for adaptive retransmission when a terminal receives reverse transmission resource allocation information. I will provide a.

  The present invention also provides a method for distinguishing between a reverse transmission resource allocation message for new MAC PDU transmission and a reverse transmission resource allocation message for adaptive retransmission when a base station transmits reverse transmission resource allocation information. Providing equipment.

  To achieve the above object, a signal transmission method of a terminal in a mobile communication system according to the present invention includes receiving a reverse transmission resource allocation message from a base station, and determining whether data is available in a HARQ buffer. If it is determined that the HARQ buffer is empty, a new MAC PDU is generated using information included in the reverse transmission resource allocation message, and the new MAC PDU is transmitted to the base station. Including. In addition, after executing the determining step, the method further includes determining whether an RV (Redundancy Version) value is “0”, and the transmitting step is performed when the RV value is “0”. It is characterized by that. In addition, when the RV value is not “0”, the received reverse transmission resource allocation message is ignored.

  Also, in the mobile communication system according to the present invention, a terminal transmits / receives a base station sPDCCH and traffic through a radio channel, and a PDCCH process for transmitting a reverse transmission resource allocation message received from the transmitter / receiver to a transmission resource controller. The reverse transmission resource allocation message is a new MAC using the NDI (New Data Indicator, NDI) and the RV (Redundancy Version) included in the transmitted reverse transmission resource allocation message. It is a reverse transmission resource allocation message instructing the initial transmission of a PDU, a reverse transmission resource allocation message instructing an adaptive retransmission of an existing MAC PDU, or an adaptive retransmission of a new MAC PDU. A transmission resource control unit for confirming whether the message is a reverse transmission resource allocation message, a HARQ device that performs HARQ operation, and an upper layer device that performs upper layer operation of the RLC device, PDCP device, and MAC multiplexing device It is characterized by that. When the HARQ buffer is empty and the RV value is 0, the transmission resource control unit determines that the reverse transmission resource allocation message is a reverse transmission resource allocation message instructing initial transmission of a new MAC PDU. And determining a size of the MAC PDU to be transmitted using an MCS (Modulation and Coding Scheme) level included in the transmission resource allocation message, constructing a MAC PDU of the determined size, and transmitting the MAC PDU to the HARQ device In this manner, the upper layer apparatus is controlled.

  As described above, the terminal signal transmission method and the apparatus therefor in the mobile communication system according to the present invention have the following effects.

  In the mobile communication system, the above two messages are misidentified so that the reverse transmission resource allocation message for new packet transmission can be distinguished from the reverse transmission resource allocation message for retransmission of existing packets. It is possible to prevent wasteful use of transmission resources.

It is a figure which shows an example of a next-generation mobile communication system structure. It is a figure which shows the protocol stack of a next-generation mobile communication system. It is a figure which shows an example of a reverse transmission resource allocation message. It is the figure explaining the example of a reverse transmission resource allocation message and NDI. It is a figure which shows the problem of a prior art. It is a figure which shows the whole operation | movement by one Example of this invention. FIG. 6 is a diagram illustrating a terminal operation according to an embodiment of the present invention. It is a figure which shows the RV transmission example. It is a figure which shows the example of adaptive retransmission and RV. It is a figure which shows the other terminal operation | movement by one Example of this invention. FIG. 10 is a diagram illustrating still another terminal operation according to an embodiment of the present invention. FIG. 10 is a diagram illustrating still another terminal operation according to an embodiment of the present invention. It is a figure which shows the RV bundle transmission example. It is a figure which shows the whole operation | movement by the other Example of this invention. FIG. 10 is a diagram illustrating a terminal operation according to another embodiment of the present invention. It is a figure which shows the structure of a terminal.

  Conventionally, there are cases where NDI alone cannot distinguish a reverse transmission resource allocation message for new packet transmission and a reverse transmission resource allocation message for retransmission of an existing packet. In the present invention, a method and apparatus for determining whether a reverse transmission resource allocation message is for transmission of a new packet or retransmission of an existing packet in consideration of all NDI, RV, and HARQ buffer states in the present invention Present.

  Although the same NDI is stored as the previous reverse transmission resource allocation message, the reverse transmission resource allocation message instructing a new packet transmission usually occurs after the transmission of the previous packet is completed. In the present invention focusing on the above matters, the terminal calculates the last retransmittable time when the first transmission for an arbitrary HARQ process is instructed, and the MAC PDU transmission when the last retransmittable time elapses. Even if is not successful, the data stored in the HARQ buffer is discarded. Further, when the terminal receives a reverse transmission resource allocation message for an arbitrary HARQ process, if there is no data in the buffer of the HARQ process, that is, the data in which the reverse transmission resource allocation message is stored in the HARQ buffer. If the reverse transmission resource allocation message is received for the first time after being discarded, it is determined that the reverse transmission resource allocation message indicates a new MAC PDU transmission regardless of the value indicated by the NDI of the message.

FIG. 6 is a diagram for explaining the operation of the entire system according to an embodiment of the present invention.
Referring to FIG. 6, if the terminal receives a reverse transmission resource allocation message 605 for an arbitrary HARQ process X instructing transmission of a new packet at an arbitrary time, the terminal performs the above reverse after a predetermined T has elapsed. The MAC PDU is transmitted through the HARQ process X using the transmission resource indicated by the direction transmission resource allocation message (610). If the feedback signal for the transmission is NACK 625, the terminal retransmits the MAC PDU using the same transmission resource when HARQ RTT has elapsed from the previous transmission (615, 620). The terminal can proceed with the retransmission operation as described above up to the maximum number of transmissions. If the HARQ ACK 635 for the MAC PDU transmission is received at an arbitrary time, the terminal stops the retransmission. If the last retransmission time 645 elapses, the MAC PDU stored in the HARQ process X is discarded (640). Thereafter, a reverse transmission resource allocation message 650 for the HARQ process X instructing the terminal to transmit a new MAC PDU is transmitted at an arbitrary time, but assuming that the terminal has not received the message, the terminal moves in the reverse direction. Since no data is transmitted, the base station repeats the process of decoding noise at each predetermined retransmission time point, and when the last retransmission time point elapses, the MAC PDU transmission fails and the HARQ process is completed. Judge. Thereafter, the base station transmits a reverse transmission resource allocation message 655 for the process instructing the terminal to transmit a new MAC PDU at any time, and when the terminal receives the message correctly, the NDI of the message is 0, which is the same as the NDI of the reverse transmission resource allocation message received by the terminal immediately before, so when the terminal refers only to the NDI, the reverse transmission resource allocation message is mistaken as a transmission resource allocation message for retransmission. To do. In the present invention, when receiving a reverse transmission resource allocation message for an arbitrary process, the terminal first checks whether data is stored in the HARQ buffer of the process. If data is stored in the buffer, the NDI is referred to determine whether or not a new MAC PDU transmission instruction is possible. If no data is stored in the buffer, a new MAC PDU transmission is instructed regardless of the NDI value. Judge.

FIG. 7 is a flowchart illustrating a terminal operation according to an embodiment of the present invention.
Referring to FIG. 7, if receiving a reverse transmission resource allocation message for any HARQ process in step 705, the UE proceeds to step 710 and checks the HARQ buffer status of the process. If the HARQ buffer is empty, the terminal determines the reverse transmission resource allocation message as a reverse transmission resource allocation message instructing transmission of a new MAC PDU, and branches to step 715. If data is stored in the HARQ buffer, the process branches to step 730, where it is possible to determine whether the reverse transmission resource allocation message is for new MAC PDU transmission or retransmission by NDI.

  Proceeding to step 715 means that the terminal must transmit a new MAC PDU using the allocated transmission resources. The terminal checks RV in step 715. If RV is 0, it means that the reverse transmission resource allocation message is for initial transmission, not adaptive retransmission of a new MAC PDU, and the terminal branches to step 725. If RV is not 0 and other values, it means that the reverse transmission resource allocation message is for adaptive retransmission of a new MAC PDU, and the UE branches to step 720. Hereinafter, RV will be described in more detail with reference to FIGS. 8 and 9 before proceeding with the description.

FIG. 8 is a diagram illustrating an example of RV transmission.
FIG. 9 is a diagram illustrating an example of adaptive retransmission and RV.
Referring to FIGS. 8 and 9, RV is information indicating what part of the original data is contained in the HARQ retransmission. Transmission resource allocation information and MCS level information are stored in a reverse transmission resource allocation message instructing the initial transmission of a new MAC PDU. The terminal that has received the message determines the size of data to be transmitted through the number of allocated resource blocks and the indicated MCS level, and configures the MAC PDU 805 having the determined size. The MAC PDU is channel-coded according to the indicated MCS level, and the channel-coded data 810 is stored in the HARQ buffer of the HARQ process. The terminal transmits a portion corresponding to the indicated RV in the channel-coded data 810, and retransmission is performed in a predetermined order from the RV. The order of RVs is RV0, RV2, RV3, and RV1, and normally, the terminal starts retransmission from RV0 and performs retransmission while circulating the above order. In the coded data, the parts designated by RV0, RV1, RV2, and RV3 are determined in advance such that, for example, RV0 815 is the frontmost part, RV1 820 is the next part, and the like. Actually, the portion indicated by each RV is generally discontinuous, unlike the portion shown in FIG. In general, the first transmission starts from RV0 815, and then RV2 825, RV3 830, and RV1 820 are transmitted in order as the transmission proceeds. In the fifth transmission, the RV has a cyclical nature of returning to RV0. When adaptive retransmission is performed, RV may be specified in a reverse transmission resource allocation message instructing adaptive retransmission. For example, when receiving a reverse transmission resource allocation message 905 indicating the initial transmission of a new MAC PDU at an arbitrary time, the terminal receives RV0 915 of the MAC PDU to be transmitted through a transmission resource allocated after a predetermined T 910. Is transmitted. Assuming a situation where the MAC PDU is continuously retransmitted, the UE transmits RV2 920 using the same transmission resource when HARQ RTT elapses, and is the same when HARQ RTT elapses. RV3 925 is transmitted using the transmission resources. At this time, if the base station tries to move the retransmission of the terminal to another transmission resource, the terminal sends a reverse transmission resource assignment message 930 containing the same NDI as the reverse transmission resource assignment message for the first transmission. Transmit at a predetermined time. The base station can change the RV order of the terminal by setting the RV of the reverse transmission resource allocation message for adaptive retransmission to a desired value. For example, if the base station indicates the RV of the reverse transmission resource allocation message 930 for adaptive retransmission to 2, the terminal transmits the indicated RV2 935 although the retransmission is in the order of transmitting RV1. Then, until the transmission is completed or the base station indicates a new RV, the RV order is determined based on the indicated RV. That is, RV3 940, RV1 945, and RV0 950 are transmitted thereafter. As described above, the RV of the received reverse transmission resource allocation message is 0. This means that the reverse transmission resource allocation message is not a transmission resource allocation message for adaptive retransmission but a transmission for the first transmission. Means that it is a resource allocation message, the UE proceeds to step 725, configures a new MAC PDU according to the information stored in the reverse transmission resource allocation message, performs channel coding, stores it in the HARQ buffer, and indicates A portion corresponding to the received RV, for example, a portion corresponding to RV0 is transmitted.

  Strictly speaking, a transmission resource allocation message with an RV of 0 may be a transmission resource allocation message for adaptive retransmission. For example, when instructing adaptive retransmission to a terminal that performs the fifth transmission, instructing to use RV0 matches the original RV order, which may be more efficient. However, if the base station allows RV0 to be used for adaptive retransmission, the terminal transmits the reverse transmission resource assignment message for the adaptive retransmission RV0 transmitted at an arbitrary time point for the reverse transmission resource assignment for the first transmission. In the present invention, the base station does not indicate RV0 in adaptive retransmission, since it may occur as a message or vice versa. That is, the base station indicates another RV when the adaptive retransmission reverse transmission resource allocation message should be transmitted at a time corresponding to the RV0 order. This reduces the transmission efficiency, but it is more important to ensure clarity in the protocol.

  Returning to FIG. 7, if RV is not 0 in step 715, the reverse transmission resource allocation message is for adaptive retransmission of a new MAC PDU, and the terminal transmits the first transmission of a new MAC PDU at any time in the past. Means that the reverse transmission resource allocation message for was lost. As described above, HARQ retransmission is limited by the maximum number of transmissions. However, the fact that the terminal has lost the reverse transmission resource allocation message for the first transmission means that the terminal does not know what order the adaptive retransmission is. If the terminal misidentifies the last retransmittable time, it may cause unnecessary interference by transmitting data to a transmission resource that is not its own transmission resource, so the terminal proceeds to step 720 and receives the reception. The reverse transmission resource allocation message is ignored and no data is transmitted.

  If the data is stored in the HARQ buffer in step 710, the terminal proceeds to step 730 and checks the NDI. If the NDI is changed, in other words, if the NDI indicated in the reverse transmission resource allocation message for the most recently received HARQ process is different from the NDI of the newly received reverse transmission resource allocation message, The UE determines the reverse transmission resource assignment message as a reverse transmission resource assignment message for a new MAC PDU transmission, and proceeds to step 735 to discard the data currently stored in the HARQ buffer. In step 715, an appropriate operation is performed according to the RV value. If the NDI is not changed, the reverse transmission resource allocation message is a message instructing adaptive retransmission for an existing MAC PDU, and the UE proceeds to step 740 to apply the indicated transmission resource and RV. Then, the corresponding part of the coded data stored in the HARQ buffer is transmitted to the designated transmission resource.

  FIG. 10 is a diagram illustrating another terminal operation according to an embodiment of the present invention. The above operation is essentially the same as the operation shown in FIG. 7, but simplifies the operation by first examining the RV.

  If the reverse transmission resource allocation message for any HARQ process X is received in step 1005, the UE proceeds to step 1010 and checks whether the RV of the received reverse transmission resource allocation message is zero. If RV is 0, the reverse transmission resource allocation message indicates the first transmission of a new MAC PDU, and the UE proceeds to step 1015 and uses the information stored in the reverse transmission resource allocation message to specify a new transmission. A MAC PDU is configured, channel-coded and stored in the HARQ buffer, and the indicated RV, that is, a portion corresponding to RV0 is transmitted.

  In step 1010, if RV is not 0, the terminal proceeds to step 1020 to determine whether the reverse transmission resource allocation message indicates a new MAC PDU transmission, and the process X HARQ Check the buffer status. If the HARQ buffer is empty, the reverse transmission resource allocation message is a reverse transmission resource allocation message instructing adaptive retransmission of a new MAC PDU. RV is not 0, and the HARQ buffer is free means that the terminal has lost the reverse transmission resource allocation message for the first transmission of a new MAC PDU at any point in the past. Proceeding to step 1025, the received reverse transmission resource allocation message is ignored and no data is transmitted. If the data is stored in the buffer of the HARQ process in step 1020, the terminal proceeds to step 1030 and checks whether the NDI can be changed.

  When the NDI is changed, in other words, when the NDI indicated by the reverse transmission resource allocation message for the most recently received HARQ process is different from the NDI of the newly received reverse transmission resource allocation message. Since the reverse transmission resource allocation message indicates an adaptive retransmission of a new MAC PDU, the process proceeds to step 1025. If the NDI is not changed, the reverse transmission resource allocation message is a message for adaptive retransmission for an existing MAC PDU, and the UE proceeds to step 1035 to apply the indicated transmission resource and RV. The corresponding portion of the coded data stored in the HARQ buffer is transmitted to the designated transmission resource.

  To summarize the present invention, the terminal determines that the reverse transmission resource allocation message is one of the following three, and operates accordingly.

  The first is a reverse transmission resource allocation message instructing the initial transmission of a new MAC PDU: if a reverse transmission resource allocation message with RV set to 0 is received for a HARQ process with an empty HARQ buffer, It is determined that the initial transmission of the MAC PDU is instructed, and the backward data is transmitted based on the normal initial transmission method.

  Second, reverse transmission resource allocation message instructing adaptive retransmission of the MAC PDU currently stored in the HARQ buffer: RDI is not 0 for the HARQ processor in which data is stored in the HARQ buffer, and NDI If a reverse transmission resource allocation message that is not toggled is received, it is determined that the adaptive retransmission of the MAC PDU currently stored in the HARQ buffer is instructed, and the reverse transmission is performed based on a normal adaptive retransmission scheme. Retransmit data.

  Third, a reverse transmission resource allocation message instructing adaptive retransmission of a new MAC PDU: receiving a reverse transmission resource allocation message whose RV is not 0 to a HARQ processor whose data is not stored in the HARQ buffer Or, if a reverse transmission resource allocation message in which RV is not 0 and NDI is changed is received for a HARQ processor in which data is stored in the HARQ buffer, an adaptive retransmission of a new MAC PDU is instructed. The received reverse transmission resource allocation message is ignored, and no data is transmitted.

  FIG. 11 is a diagram illustrating still another terminal operation according to an embodiment of the present invention. In the operation shown in FIG. 11, the terminal first simplifies the operation by examining the NDI.

  If the UE receives a reverse transmission resource allocation message for any HARQ process X in step 1105, the UE proceeds to step 1110, where the NDI of the received reverse transmission resource allocation message and the latest NDI of the HARQ process X are determined. Compare if they are identical. The most recent NDI of any HARQ process may be the NDI of the most recent reverse transmission resource allocation message for that HARQ process.

  If the received NDI increases compared to the most recent NDI, that is, the value is changed, the terminal proceeds to step 1115 and determines that the reverse transmission resource allocation message indicates a new MAC PDU transmission. Then, a new MAC PDU is formed by the information stored in the reverse transmission resource allocation message, channel-coded and stored in the HARQ buffer, and a portion corresponding to the instructed RV is transmitted.

  If the received NDI is the same as the most recent NDI, the terminal proceeds to step 1120 and checks the buffer status of the HARQ process. If the buffer is free, the reverse transmission resource assignment message indicates transmission of a new MAC PDU, and thus the process proceeds to step 1115 to transmit a new MAC PDU. If the received NDI is the same as the most recent NDI and the HARQ process is not free, the UE proceeds to step 1125 and determines that the reverse transmission resource allocation message indicates adaptive retransmission. Then, by applying the indicated transmission resource and RV, the corresponding part of the coded data stored in the HARQ buffer is transmitted to the designated transmission resource.

  FIG. 12 is a diagram illustrating still another terminal operation according to an embodiment of the present invention. In the operation shown in FIG. 12, the terminal first simplifies the operation by checking the NDI, and at the same time, uses the RV instead of the buffer status to indicate the reverse transmission resource allocation message indicating the first transmission and the retransmission. The reverse transmission resource allocation message indicating transmission is classified.

  If the UE receives a reverse transmission resource allocation message for any HARQ process X in step 1205, the UE proceeds to step 1210, where the NDI of the received reverse transmission resource allocation message and the most recent NDI of the HARQ process X are determined. Compare if they are identical.

  If the received NDI increases compared to the most recent NDI, that is, the value is changed, the terminal proceeds to step 1215 and determines that the reverse transmission resource allocation message indicates a new MAC PDU transmission. Then, a new MAC PDU is formed by the information stored in the reverse transmission resource allocation message, channel-coded and stored in the HARQ buffer, and a portion corresponding to the instructed RV is transmitted.

  If the received NDI is the same as the most recent NDI, the terminal proceeds to step 1220 and checks whether the RV of the received reverse transmission resource allocation message is 0. If RV is 0, the reverse transmission resource assignment message indicates transmission of a new MAC PDU, and thus the process proceeds to step 1215 to transmit a new MAC PDU. If the received NDI is the same as the most recent NDI, and RV is not 0 and some other value, the terminal proceeds to step 1225, and the reverse transmission resource allocation message indicates adaptive retransmission. Judging and applying the indicated transmission resource and RV, the corresponding part of the coded data stored in the HARQ buffer is transmitted to the designated transmission resource.

  In another embodiment of the present invention, bundled transmission provides a method and apparatus for interpreting a reverse transmission resource allocation message using NDI, RV and HARQ buffer states.

  Bundle transmission is a technique in which a terminal repeatedly transmits a certain number of times using assigned transmission resources, and is intended to solve the problem of insufficient transmission output of a terminal located at a cell edge. is there. In bundle transmission, the terminal transmits RV0, RV2, RV3, and RV1 at a time using the allocated transmission resources four times in succession. The base station softly combines the data received over the above four times, and then determines whether there is an error and transmits HARQACK or HARQNACK.

FIG. 13 is a diagram illustrating an example of RV bundle transmission.
For example, if a reverse transmission resource allocation message 1305 instructing the initial transmission of a new MAC PDU is received by a terminal for which bundle transmission is set at an arbitrary time, the terminal performs four times after a predetermined T 1310 has elapsed. RV0, RV2, RV3, and RV1 are transmitted to the allocated transmission resources during the TTI (1315). If HARQNACK is received after a predetermined period of time has elapsed, the terminal re-transmits RV0, RV2, RV3, and RV1 using the same transmission resources when HARQ RTT 1320 defined for bundle transmission elapses. Transmit (1325).

  In bundle transmission, the same RV is used for transmission and retransmission in this way. In other words, the same value is used for the RV of the reverse transmission resource allocation message for adaptive retransmission and the RV of the reverse transmission resource allocation message for initial transmission. For example, when the reverse transmission resource allocation message 1330 for adaptive retransmission is transmitted at an arbitrary time, the RV of the message is 0, and the RV of the reverse transmission resource allocation message 1305 for the first transmission is Are the same. In this way, since the same RV is used for adaptive retransmission and initial transmission, the UE simply refers to the NDI and HARQ buffer status to determine whether the reverse transmission resource allocation message is for adaptive retransmission. First, it must be determined whether it is for transmission. As described above, when the reverse transmission resource allocation message for the first transmission is lost, it is impossible to determine whether it is for adaptive retransmission or for the first transmission only by NDI and buffer status. It is. For example, in FIG. 13, if the terminal does not receive the reverse transmission resource allocation message 1305 for initial transmission but receives only the reverse transmission resource allocation message 1330 for adaptive retransmission, the NDI is likely to be toggled. The terminal is likely to misrecognize the reverse transmission resource allocation message 1330 for adaptive retransmission as the first transmission reverse transmission resource allocation message.

  In the present invention, in order to solve the above-described problems, in the case of bundle transmission, the RV information of the reverse transmission resource allocation message does not indicate RV but indicates the number of transmissions.

FIG. 14 is a diagram showing an overall operation according to another embodiment of the present invention.
When the base station sets the RV of the reverse transmission resource allocation message for the first transmission to 0 (1405) and performs adaptive retransmission for the second transmission, the RV of the reverse transmission resource allocation message is Set to 1 (1420), RV of the adaptive retransmission reverse transmission resource allocation message for the third transmission is set to 2 (1430), reverse transmission for adaptive retransmission for the fourth transmission When transmitting the reverse transmission resource allocation message for adaptive retransmission, such as setting the RV of the resource allocation message to 3 (1440), a value that increases the RV of the message by 1 according to the number of transmissions is set.

  The terminal transmits a transmission resource allocation message for adaptive retransmission in a state where the RV of the reverse transmission resource allocation message for the HARQ process for which the HARQ buffer is empty is not 0, that is, without receiving the reverse transmission resource allocation message for the first transmission. Is received, the reverse transmission resource allocation message is ignored.

FIG. 15 is a diagram illustrating a terminal operation according to another embodiment of the present invention.
If the reverse transmission resource allocation message for any HARQ process X is received in step 1505, the UE proceeds to step 1510 and checks whether the RV of the received reverse transmission resource allocation message is zero. If RV is 0, the reverse transmission resource allocation message indicates the initial transmission of a new MAC PDU, and the UE proceeds to step 1505 to check whether it is currently in bundle transmission. The applicability of bundle transmission is set through an upper layer control message. If it is in bundle transmission, the terminal proceeds to step 1517; otherwise, the terminal proceeds to step 1515. In step 1515, the UE configures a new MAC PDU according to the information stored in the reverse transmission resource allocation message, channel-codes and stores it in the HARQ buffer, and transmits the indicated RV, that is, a portion corresponding to RV0 To do. In step 1517, the UE configures a new MAC PDU according to the information stored in the reverse transmission resource allocation message, performs channel coding, and stores it in the HARQ buffer. In addition, portions corresponding to RV0, RV2, RV3, and RV1 are sequentially transmitted through the allocated transmission resources.

  In step 1510, if RV is not 0, the terminal proceeds to step 1520 to determine whether the reverse transmission resource allocation message indicates a new MAC PDU transmission, and the process X HARQ Check the buffer status. If the HARQ buffer is empty, the reverse transmission resource allocation message is a reverse transmission resource allocation message instructing adaptive retransmission of a new MAC PDU. That the HARQ buffer is empty means that the reverse transmission resource allocation message indicating the first transmission of a new MAC PDU is lost after the data of the HARQ buffer is discarded. As described above, HARQ retransmission is limited by the maximum number of transmissions. However, if the terminal loses the reverse transmission resource allocation message for the first transmission, the terminal may know the last retransmittable time without knowing which order the adaptive retransmission is. Can not. If the terminal misidentifies the last retransmittable time, it may cause unnecessary interference by transmitting data to a transmission resource that is not its own transmission resource. Therefore, the terminal proceeds to step 1525 and receives the reception. The reverse transmission resource allocation message is ignored and no data is transmitted. If the data is stored in the buffer of the HARQ process in step 1520, the terminal proceeds to step 1530 and checks whether the NDI can be changed.

  If the NDI is changed, in other words, if the NDI indicated in the reverse transmission resource allocation message for the most recently received HARQ process is different from the NDI of the newly received reverse transmission resource allocation message, The UE determines the reverse transmission resource allocation message as a transmission resource allocation message instructing adaptive retransmission of a new MAC PDU, and proceeds to step 1525. If the NDI is not changed, the reverse transmission resource allocation message is a message for adaptive retransmission for an existing MAC PDU, and the UE proceeds to step 1533 to check whether it is currently in bundle transmission. To do. If the bundle transmission is not in progress, the process proceeds to step 1535 and corresponds to the indicated RV among the coded data RV0, RV2, RV3, and RV1 stored in the HARQ buffer using the indicated transmission resource. The part to be transmitted is transmitted. If the bundle is being transmitted, the UE proceeds to step 1537, ignores the indicated RV, and sequentially transmits the coded data RV0, RV2, RV3, and RV1 stored in the HARQ buffer.

  To briefly summarize another embodiment of the present invention, the terminal determines the reverse transmission resource allocation message as one of the following three, and operates accordingly.

  Reverse transmission resource allocation message indicating initial transmission of a new MAC PDU: If a reverse transmission resource allocation message with RV set to 0 is received for a HARQ process in which the HARQ buffer is free, the first of the new MAC PDU It is determined that the transmission is instructed, and the backward data is transmitted based on a normal initial transmission method.

  Reverse transmission resource allocation message instructing adaptive retransmission of MAC PDU currently stored in HARQ buffer: RV is not 0 and NDI is not changed for HARQ processor with data stored in HARQ buffer If the reverse transmission resource allocation message is received, it is determined that the adaptive retransmission of the MAC PDU currently stored in the HARQ buffer is instructed, and the reverse data is retransmitted based on a normal adaptive retransmission scheme. To transmit. The terminal during bundle transmission ignores the instructed RV and transmits data in a predetermined order, for example, RV0, RV2, RV3, and RV1.

  Reverse transmission resource allocation message instructing adaptive retransmission of a new MAC PDU: A reverse transmission resource allocation message with RV not 0 is received for a HARQ processor in which no data is stored in the HARQ buffer, or the HARQ buffer If the reverse transmission resource allocation message in which the RDI is not 0 and the NDI is changed is received for the HARQ processor in which the data is stored in FIG. 6, the adaptive retransmission of the new MAC PDU is instructed. The received reverse transmission resource allocation message is ignored and no data is transmitted.

FIG. 16 is a block diagram of a terminal device according to an embodiment of the present invention.
The terminal device includes an upper layer device 1605, a HARQ device 1610, a transmission / reception unit 1625, a transmission resource control unit 1620, and a PDCCH processing unit 1630.

  The transmission / reception unit 1625 of the terminal is a device that receives the PDCCH through a wireless channel and transmits / receives other traffic. The transmission / reception unit 1625 decodes a signal received through the PDCCH and transmits the decoded signal to the PDCCH processing unit 1630.

  The PDCCH processing unit 1630 performs a predetermined CRC operation on the decoded signal transmitted by the transmission / reception unit 1625, determines whether there is an error, and transmits a transmission resource allocation message without an error to the transmission resource control unit 1620. The transmission resource control unit 1620 uses the NDI and RV of the transmission resource allocation message transmitted by the PDCCH processing unit 1630 and the state of the HARQ buffer to reversely transmit the transmission resource allocation message indicating the initial transmission of a new MAC PDU. It is determined whether a resource allocation message, a reverse transmission resource allocation message instructing adaptive retransmission of an existing MAC PDU, or a reverse transmission resource allocation message instructing adaptive retransmission of a new MAC PDU To do. If the reverse transmission resource allocation message indicates the initial transmission of a new MAC PDU, the size of the MAC PDU to be transmitted is determined using the number of allocated transmission blocks and the MCS level, and the MAC PDU having the determined size is determined. And the upper layer device is controlled so as to be transmitted to the HARQ processor. When receiving a reverse transmission resource allocation message instructing adaptive retransmission of an existing MAC PDU, the HARQ apparatus 1610 is controlled so that the HARQ process performs adaptive retransmission. If a reverse transmission resource assignment message is received that indicates an adaptive retransmission of a new MAC PDU, the reverse transmission resource assignment message is ignored and no action is taken.

  The upper layer device 1605 is commonly called an RLC device, a PDCP device, a MAC multiplexing device, or the like. The HARQ apparatus 1610 includes a number of HARQ processes, and performs a normal HARQ operation for each HARQ process.

  The embodiments of the present invention disclosed in this specification and the drawings are merely illustrative examples for facilitating the technical contents of the present invention and helping the understanding of the present invention. It is not intended to be limited. It will be apparent to those skilled in the art to which the present invention pertains that other variations based on the technical idea of the present invention can be implemented in addition to the embodiments disclosed herein.

101 UE
110, 112 E-RAN
120, 122, 124, 126, 128 ENB

Claims (12)

A signal transmission method for a terminal in a mobile communication system, comprising:
NDI (New Data Indicator) for indicating whether or not the uplink transmission resource allocation message is for the first transmission, MCS (modulation and coding scheme) index for indicating the modulation order, TBS (transport block size) index And receiving an uplink transmission resource allocation message including RV (redundancy version) from the base station;
Determining whether the HARQ buffer is free;
Transmitting a new media access control protocol data unit (MAC PDU) to the base station based on the uplink transmission resource allocation message when the HARQ buffer is empty. Signal transmission method. Determining whether the RV value is set to 0;
The method of claim 1, further comprising: transmitting a new MAC PDU to the base station when the RV value is set to 0. After the determination step,
Using the MCS index included in the uplink transmission resource allocation message to confirm the transmission block size allocated by the base station;
The method of claim 1, further comprising: transmitting the MAC PDU to the base station when it can be confirmed.   The method of claim 2, wherein when the RV is set to a value other than 0, the uplink transmission resource allocation message is ignored. If the HARQ buffer is not empty, checking whether to toggle a new data indicator (NDI) of the uplink transmission resource allocation message;
The method of claim 1, further comprising: retransmitting the MAC PDU by applying RV and transmission resources indicated by an uplink transmission resource allocation message when the NDI is not toggled. Terminal signal transmission method. If the NDI is toggled, flushing the HARQ buffer;
The method of claim 5, further comprising: determining whether RV of the uplink transmission resource allocation message is set to 0. If the RV is set to 0, transmitting a new MAC PDU to the base station using the transmission resource and MCS level indicated by the uplink transmission resource allocation message;
The method of claim 5, further comprising: ignoring the uplink transmission resource allocation message when the RV is set to a non-zero value. A terminal for transmitting a signal in a mobile communication system,
A transmitting / receiving unit that transmits and receives PDCCH (Physical Downlink Control Channel) and traffic through a wireless channel;
A PDCCH processing unit for extracting an uplink transmission resource allocation message from the PDCCH received by the transceiver unit;
A new MAC based on the HARQ buffer status, new data indicator (NDI), RV (Redundancy Version), or a combination of the HARQ buffer status, NDI and RV included in the uplink transmission resource allocation message. A transmission resource control unit for determining whether to transmit a PDU or a previous MAC PDU;
A HARQ unit that performs HARQ operation;
A terminal including a radio link control (Radio Link Control, RLC) device, a packet data concentration protocol (Packet Data Convergence Protocol, PDCP) device, and an upper layer device that performs an upper layer operation of a MAC multiplexing device. The transmission resource control unit
When the RV is set to 0, it is determined that the uplink transmission resource allocation message indicates transmission of a new MAC PDU, and is transmitted based on the MCS level included in the uplink transmission resource allocation message. 9. The size of a MAC PDU to be determined, controlling the upper layer device to generate a MAC PDU, and controlling the MAC PDU to be transmitted to the HARQ unit. Terminal. The transmission resource control unit
If the HARQ buffer is empty and the RV is set to a non-zero value, it is determined that the uplink transmission resource allocation message indicates an adaptive retransmission of a new MAC PDU, and the uplink transmission resource The terminal according to claim 8, wherein the assignment message is ignored. The transmission resource control unit
If the HARQ buffer is not empty, confirm whether the NDI can be toggled, and if the NDI is not toggled, determine that the uplink transmission resource allocation message indicates an adaptive retransmission of a previous MAC PDU. The terminal of claim 8, wherein the previous MAC PDU is retransmitted using the transmission resource and RV indicated by the uplink transmission resource allocation message. The transmission resource control unit
When the NDI is toggled, the HARQ buffer is flushed, and when the RV is set to 0, a new MAC is transmitted using the transmission resource and MCS level indicated by the uplink transmission resource allocation message. The terminal according to claim 11, wherein when transmitting a PDU to a base station and the RV is set to a non-zero value, the uplink transmission resource allocation message is ignored.

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