KR100849143B1 - Method and apparatus for supporting arq transmission in wireless communication - Google Patents

Abstract

A method and an apparatus for supporting ARQ transmission in wireless communication are provided to discriminate a successively received ARQ block and an ARQ block with an error to retransmit only the ARQ block having the error, thereby preventing the deterioration of performance due to unnecessary ARQ block retransmission and improving ARQ and system performance. A method for supporting ARQ(Automatic Repeat reQuest) transmission in wireless communication comprises the following steps of: receiving at least one MAC(Media Access Control) SDU(Service Data Unit) from an upper layer in an MAC layer supporting an ARQ protocol(S400); generating at least one ARQ block(S410); adding error detection information to each of the generated ARQ blocks(S420); and generating an MAC PDU(Packet Data Unit)(S430).

Description

Method and apparatus for supporting ARQ transmission in wireless communication {Method and apparatus for supporting ARQ transmission in wireless communication}

1 schematically illustrates an error control process of a link layer using a general ARQ technique.

2 illustrates a structure of a MAC PDU according to the current standard.

FIG. 3 illustrates a case where a transmission failure for a specific ARQ block occurs in ARQ transmission when the MAC PDU structure of FIG. 2 is used.

4 is a flowchart illustrating a method for supporting ARQ transmission in wireless communication according to the present invention.

5 shows an example of the FSH configuration according to the present invention.

6 shows an example of the PSH configuration according to the present invention.

7 illustrates a case in which transmission failure of a specific ARQ block occurs in ARQ transmission according to the present invention.

8 is a block diagram illustrating a configuration of a first embodiment of an ARQ transmission support apparatus in wireless communication according to the present invention.

9 is a flowchart illustrating a first embodiment of a method for supporting ARQ transmission in wireless communication according to the present invention.

10 is a block diagram illustrating a configuration of a second embodiment of an ARQ transmission support apparatus in wireless communication according to the present invention.

11 is a flowchart illustrating a second embodiment of an ARQ transmission support method in wireless communication according to the present invention.

12 is a block diagram illustrating a configuration of a third embodiment of an ARQ transmission support apparatus in wireless communication according to the present invention.

13 is a flowchart illustrating a third embodiment of a method for supporting ARQ transmission in wireless communication according to the present invention.

14 illustrates a MAC PDU configuration according to the present invention.

15 illustrates a receiving device for supporting ARQ transmission in wireless communication according to the present invention.

16 illustrates a receiving method for supporting ARQ transmission in wireless communication according to the present invention.

The present invention relates to automatic repeat request (ARQ) in wireless communication, and more particularly, to a method and apparatus for supporting ARQ transmission in wireless communication.

In case of broadband wired communication using optical cable, transmission error rate is very low due to the stability of communication medium. However, in the case of wireless communication, due to the characteristics of the medium, not only the error rate is relatively higher than that of the wire, but also the distribution of the error rate is very variable. Therefore, the error control technique is a very important part in broadband wireless communication.

The error control technique in the radio link layer includes a forward error correction (FEC) technique for correcting errors in a wireless channel and an automatic repeat request for retransmission when an error is detected for received data. Automatic Repeat reQuest: This is called 'ARQ').

If an error occurs on the communication line, the receiving side notifies the transmitting side of the error and the transmitting side retransmits the frame in which the error occurred. This method is called ARQ. 1 schematically illustrates an error control process of a link layer using a general ARQ technique.

ARQ improves the performance of wireless communication systems by successfully transmitting received packets under low signal strength. However, although the WiMAX standard includes ARQ mechanisms, the poor MAC protocol for ARQ limits its system performance. 2 shows a structure of a MAC PDU having a (α + β) ARQ block. In the current IEEE 802.16 standard, as shown in FIG. 2, one 32-bit cyclic redundancy check (CRC) ends in a media access control (MAC) packet data unit (PDU) to check the entire (α + β) ARQ block. Is added to the part.

FIG. 3 is a diagram illustrating a case in which transmission failure occurs for a specific ARQ block in ARQ transmission when the MAC PDU structure of FIG. 2 is used, despite ARQ feedback being transmitted in units of blocks in the current IEEE 802.16 standard. As it has only CRC of, the error cannot be checked for each ARQ block, and as shown in FIG. 3, when only one (α + 1) ARQ block has an error, other ARQ blocks successfully received at the receiver are also included. Discarded. Therefore, an ARQ mechanism is needed to avoid performance degradation caused by unnecessary ARQ block retransmission.

It is an object of the present invention to provide a method and apparatus for supporting ARQ transmission in wireless communication, which can improve system performance through an improved ARQ mechanism.

Another object of the present invention is to provide a receiving apparatus and method for supporting ARQ transmission in wireless communication.

In order to achieve the above technical problem, the method for supporting ARQ transmission in wireless communication according to the present invention includes at least one MAC SDU (Service SDU) service from an upper layer in a media access control (MAC) layer supporting an Automatic Repeat ReQuest (ARQ) protocol. Receiving a data unit); Generate at least one ARQ block from the at least one MAC SDU, wherein the ARQ block includes an ARQ block header, an ARQ block payload, and error detection information for the ARQ block payload; Generating a MAC PDU including a block and a MAC PDU including error detection information and a MAC PDU header for the MAC PDU payload; And transmitting the MAC PDU to a receiver through a PHY layer.
The MAC PDU header is a Generic MAC Header (GMH), and the ARQ block header includes a fragmentation subheader (FSH) including information required when a MAC PDU is generated by dividing one or more MAC SDUs into two or more; And a packing subheader (PSH) including necessary information when multiple MAC SDUs are packed into one MAC PDU. The FSH and the PSH preferably include information indicating any one of CRC No CRC, 16-bit CRC (CRC16), and 32-bit CRC (CRC32).

According to an aspect of the present invention, there is provided a method for supporting ARQ transmission in wireless communication, the method including: receiving at least one MAC SDU from an upper layer in a MAC layer supporting an ARQ protocol; Generating the at least one MAC SDU into at least one ARQ block; And generating a MAC PDU by adding a CRC for each ARQ block if the number of ARQ blocks included in the MAC PDU is smaller than a first threshold, and adding a CRC for each ARQ block if the number of ARQ blocks is smaller than a first threshold. It is characterized by including. When the number of the ARQ blocks is greater than a predetermined first threshold and less than the predetermined second threshold, CRC16 is added to the ARQ blocks, and the number of ARQ blocks is greater than the first threshold and the second threshold. When large, it is preferable to generate a MAC PDU by adding CRC32 to the ARQ blocks.

According to an aspect of the present invention, there is provided a method for supporting ARQ transmission in wireless communication, the method including: receiving at least one MAC SDU from an upper layer in a MAC layer supporting an ARQ protocol; Generating the at least one MAC SDU into at least one ARQ block; Generating a MAC PDU by adding a CRC for each ARQ block if the channel state information value is greater than a predetermined first threshold value and adding a CRC for each ARQ block if the channel state information value is larger than the first threshold value. . The channel state information value is set by a channel quality indicator (CQI) when the base station is a transmitting end, and is set to a carrier to interference and noise ratio (CINR) of the measured downlink when the terminal is a transmitting end.

According to an aspect of the present invention, there is provided a method for supporting ARQ transmission in wireless communication, the method including: receiving at least one MAC SDU from an upper layer in a MAC layer supporting an ARQ protocol; Generating the at least one MAC SDU into at least one ARQ block; If the ACK rate for the sum of the received ACK (Non-acknowledgment) and NACK (Non-acknowledgment) is greater than a predetermined first threshold, the CRC is not added for each ARQ block, and if it is less than the first threshold, ARQ Generating a MAC PDU by adding a CRC for each block. An CRQ16 is added to ARQ blocks when the ACK rate is less than a first threshold and greater than a second predetermined threshold, and an ARQ block when the ACK rate is less than the first and second thresholds. It is preferable to generate a MAC PDU by adding CRC32.

In order to achieve the above another technical problem, a reception method for supporting ARQ transmission in wireless communication according to the present invention includes receiving a MAC PDU including a plurality of ARQ blocks from a PHY (physical) layer to receive a CRC of the MAC PDU. Checking; Generating an ACK for all ARQ blocks of the MAC PDU if there is no CRC error, and if there is a CRC error, calculating an HCS (Header Check Sequence) to check whether it is the same as the HCS of GMH; Generating NACK for all ARQ blocks of a MAC PDU if the result of the HCS check is not the same, and checking a CRC for each ARQ block if it is the same; And generating an ACK for the corresponding block if there is no error in the CRC check result for each ARQ block, and generating an NACK for the corresponding block if there is an error.

In order to achieve the above technical problem, an apparatus for supporting ARQ transmission in wireless communication according to the present invention includes: an ARQ block generation unit generating at least one ARQ block from at least one MAC Service Data Unit (SDU); An ARQ block counting unit for calculating the number of ARQ blocks included in the MAC PDU; If the number of the ARQ block is less than a predetermined first threshold value does not add a CRC for each ARQ block, if larger than the first threshold value includes a CRC adder for generating a MAC PDU by adding a CRC for each ARQ block It is done. The CRC adder adds CRC16 to ARQ blocks when the number of ARQ blocks is greater than a first threshold and less than a second threshold, and the number of ARQ blocks is equal to the first threshold and the first threshold. When it is larger than 2 thresholds, it is preferable to generate a MAC PDU by adding CRC32 to ARQ blocks.

In order to achieve the above technical problem, an apparatus for supporting ARQ transmission in wireless communication according to the present invention includes: an ARQ block generation unit generating at least one ARQ block from at least one MAC Service Data Unit (SDU); A channel state information value setting unit for setting a channel state information value; And a CRC adder for generating a MAC PDU by adding a CRC for each ARQ block if the channel state information is greater than a predetermined first threshold and for each ARQ block if the channel state information is larger than the first threshold. It is done. The channel state information value is set to a channel quality indicator (CQI) value when the base station is a transmitting end, and is set to a measured CINR of the downlink when the terminal is a transmitting end.

In order to achieve the above technical problem, an apparatus for supporting ARQ transmission in wireless communication according to the present invention includes: an ARQ block generation unit generating at least one ARQ block from at least one MAC Service Data Unit (SDU); An ACK / NACK rate calculator configured to calculate an ACK rate or a NACK rate for the sum of the ACK and NACK received by the transmitting end; And if the ACK rate calculated by the ACK / NACK rate calculation unit is greater than a first threshold value, do not add a CRC for each ARQ block, and if it is less than the first threshold value, add a CRC for each ARQ block and add a MAC PDU. Characterized in that it comprises a CRC addition to generate. The CRC adding unit adds CRC16 to ARQ blocks when the ACK rate is less than a first threshold and greater than a second predetermined threshold, and the ACK rate is greater than the first threshold and the second threshold. When small, it is desirable to generate a MAC PDU by adding CRC32 to the ARQ blocks.

According to another aspect of the present invention, there is provided a receiver for supporting ARQ transmission in wireless communication, the apparatus including: a PDU CRC check unit for receiving a MAC PDU from a PHY (physical) layer and checking a CRC of the MAC PDU; If there is no CRC error, the PDU CRC check unit generates an ACK for all ARQ blocks of the MAC PUD, and if there is a CRC error, calculates a header check sequence (HCS) and checks whether it is the same as the HCS of GMH. ; An ARQ block CRC check unit for generating a NACK for all ARQ blocks of a MAC PDU if the result of the check of the HCS check unit is not the same, and checking the CRC for each ARQ block if it is the same; And an ACK / NACK generation unit for generating an ACK for the corresponding block if there is no error in the CRC check result for each ARQ block, and generating an NACK for the corresponding block if there is an error.

According to an aspect of the present invention, there is provided a method for supporting ARQ transmission in wireless communication, the method including: receiving at least one MAC SDU from an upper layer in a MAC layer supporting an ARQ protocol; Transmitting a MAC PDU from the MAC layer to a receiver via a PHY layer; And receiving information on at least one successful reception of the MAC PDU from the receiver, wherein the MAC PDU includes a MAC PDU header and at least one ARQ blocks generated from the at least one MAC SDU. And a MAC PDU payload, CRC codes for the MAC PDU header and MAC PDU payload, wherein the ARQ block is configured to include an ARQ block header, an ARQ block payload, and an ARQ block CRC code.

The ARQ block CRC code is generated using the ARQ block header and the ARQ block payload, and the ARQ block header is an FSH or PSH sub header. It is preferable that the length of the ARQ block CRC code is selected according to any one of the number of ARQ blocks, ACK rate, and channel information in the MAC PDU.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments. For reference, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted in the following description.

4 is a flowchart illustrating a method for supporting ARQ transmission in wireless communication according to the present invention. Referring to FIG. 4, in order to generate a MAC service data unit (MAC SDU) as a MAC PDU having an ARQ block, at least one MAC SDU is received from an upper layer in the MAC layer supporting the ARQ protocol (step S400). In operation S410, a plurality of SDUs may be packed into one PDU, or one SDU may be divided into a plurality of ARQ blocks.

Error detection information is added to each of the generated ARQ blocks (step S420) to generate a MAC PDU (step S430). The error detection information is preferably a cyclic redundancy check (CRC).

The MAC PDU includes a Generic MAC Header (GMH), and the ARQ block includes an ARQ block header and an ARQ block payload. The ARQ block header includes a fragmentation subheader (FSH) or a packing subheader (PSH). The FSH is a subheader including information required by a receiver when a MAC PDU is generated by dividing one MAC SDU into at least two or more. In addition, the MAC PSH is a subheader including information required at the receiving end when several MAC SDUs are packed into one MAC PDU. The FSH and the PSH preferably include CRC selection information indicating any one of CRC No CRC, CRC16, and CRC32.

5 shows an example of an FSH configuration according to the present invention. The FSH includes the selective CRC allocation using the reserved bit of the FSH in the IEEE 802.16e-2005 standard to support the selective CRC at the tail of the ARQ block. 6 shows an example of the configuration of the PSH according to the present invention. PSH includes an optional CRC allocation using a reserved bit of the PSH in the IEEE 802.16e-2005 standard to support the selective CRC at the tail of the ARQ block. In this case, FIG. 7 illustrates a case where transmission failure of a specific ARQ block occurs in ARQ transmission according to the present invention. As shown in FIG. 7, CRC check is possible for each ARQ block of the MAC PDU generated through the process of FIG. 4, so that only an ARQ block having an error is retransmitted, and there is no need to retransmit an ARQ block without an error. do.

FIG. 8 is a block diagram illustrating a configuration of a first embodiment of an ARQ transmission support apparatus in a wireless communication system according to the present invention. The ARQ block generator 810, the ARQ block count unit 820, and the CRC adder 830 are illustrated in FIG. )

The ARQ block generator 810 generates at least one ARQ block from at least one MAC Service Data Unit (SDU). The ARQ block count unit 820 calculates the number of ARQ blocks included in the MAC PDU. The CRC adding unit 830 generates a MAC PDU by adding a CRC for each ARQ block when the number of the ARQ blocks is smaller than a first threshold, and adding a CRC for each ARQ block when the number of the ARQ blocks is smaller than the first threshold. do. The CRC adding unit 830 adds CRC16 to ARQ blocks when the number of ARQ blocks is greater than a first threshold and less than a second threshold, and the number of ARQ blocks is the first. When greater than the threshold and the second threshold, CRC32 may be added to the ARQ blocks to generate a MAC PDU.

9 is a flowchart illustrating a first embodiment of a method for generating a MAC PDU for supporting ARQ transmission in wireless communication according to the present invention. Referring to FIG. 9, the MAC layer supporting the ARQ protocol receives at least one MAC SDU from an upper layer (step S900), and generates the at least one ARQ block (step S910). Then, the MAC layer includes the MAC PDU. The number of ARQ blocks is obtained (step S920).

If the number of ARQ blocks is smaller than a predetermined first threshold value (CRC16 ARQ threshold value) (step S930), if the number is small, CRC is not added separately for each ARQ block (step S940). Is greater than the CRC16 ARQ threshold, a CRC is added for each ARQ block to generate a MAC PDU. In more detail, it is checked whether the number of the ARQ blocks is greater than the CRC16 ARQ threshold and the second threshold (CRC32 ARQ threshold) (step S950), and when large, CRC32 is added to the ARQ blocks. In step S960, if the number of the ARQ blocks is greater than the CRC16 ARQ threshold and less than the CRC32 ARQ threshold, the CRC16 is added to the ARQ blocks (step S970). The MAC PDU is generated (step S980). The ARQ block header includes either a fragmentation subheader (FSH) or a packing subheader (PSH) as described above, and the FSH and the PSH are shown in FIGS. 5 and 6. As shown in the drawing, CRC selection information, that is, information indicating any one of no CRC, CRC16, and CRC32 is included by using a selective CRC.

FIG. 10 is a block diagram illustrating a configuration of a second embodiment of an ARQ transmission support apparatus in wireless communication according to the present invention. The ARQ block generation unit 1010, the channel state information value setting unit 1020, and the CRC adding unit 1030 are shown in FIG. )

The ARQ block generation unit 1010 generates at least one ARQ block from at least one MAC Service Data Unit (SDU).

The channel state information value setting unit 1020 sets the channel state information value. For example, when the base station is the transmitting end, the channel quality indicator (CQI) value is set to the channel state information value, and the measurement is performed when the terminal is the transmitting end. Set the downlink CINR as the channel status information value. The CRC adding unit 1030 does not add a CRC for each ARQ block if the set channel state information value is greater than a predetermined first threshold value, and adds a CRC for each ARQ block if it is smaller than the first threshold value, thereby adding a MAC PDU. Create

The CRC adding unit 1030 adds CRC16 to ARQ blocks when the CINR is less than a first threshold and greater than a second predetermined threshold, and the CINR is the first threshold and the second threshold. When the value is smaller than the value, CRC32 may be added to the ARQ blocks to generate a MAC PDU.

11 is a flowchart illustrating a second embodiment of an ARQ transmission support method in wireless communication according to the present invention. Referring to FIG. 11, at least one MAC SDU is received from an upper layer in the MAC layer supporting the ARQ protocol (step S1100), and is generated as at least one ARQ block (step S1110). The channel state information value is then generated. When the base station is a transmitting end, the CQI (Channel Quality Indicator) value is set to the channel state information value, and when the terminal is the transmitting end, the measured downlink CINR is set to the channel state information value. In step S1120, it is checked whether the set channel state information value is larger than a predetermined first threshold value CRC16 CINR (step S1130). Add CRC for the entire ARQ block. If the set CINR is smaller than the CRC16 CINR, it is checked whether it is larger than a predetermined second threshold (CRC32 threshold) (step S1150), and when it is small, CRC32 is added to the ARQ blocks (step S1160). Add CRC16 (step S1170).

When the processing for adding CRC information is completed in steps S1140, S1160, and S1170, a MAC PDU is generated. In step S1180, the ARQ block header is a fragmentation subheader (FSH) or a PSH (as described above). Packing SubHeader), and the FSH and PSH include information indicating any one of No CRC, CRC16, and CRC32 using Selective CRC as shown in FIGS. 5 and 6.

12 is a block diagram illustrating a configuration of a third embodiment of an apparatus for supporting ARQ transmission in wireless communication according to the present invention, and includes an ARQ block generator 1210, an ACK rate calculator 1220, and a CRC adder ( 1230.

The ARQ block generator 1210 generates at least one ARQ block from at least one MAC Service Data Unit (SDU).

The ACK / NACK rate calculator 1220 calculates an ACK / NACK rate indicating a ratio of ACK or NACK to the sum of ACK and NACK received by the transmitter from the receiver. The ACK rate and the NACK rate may be expressed as in Equation 1 and Equation 2.

ACK rate = ARQ_ACK / (ARQ_ACK + ARQ_NACK)

NACK Rate = ARQ_NACK / (ARQ_ACK + ARQ_NACK)

Here, ARQ_ACK represents the number of ACKs that the transmitter receives from the receiver, and ARQ_NACK represents the number of NACKs that the transmitter receives from the receiver.

The CRC adding unit 1230 does not add a CRC for each ARQ block when the ACK rate is greater than a first threshold or the NACK rate is less than a first threshold, and the ACK rate is the first. If it is less than a threshold or the NACK rate is greater than the first threshold, a CRC is added for each ARQ block to generate a MAC PDU. In more detail, the CRC adding unit 1230 may be configured such that the ACK rate is smaller than a first predetermined threshold value, greater than a second predetermined threshold value, or the NACK rate is greater than a first predetermined threshold value. When less than a second threshold of, add CRC16 to ARQ blocks, wherein the ACK rate is less than the first and second thresholds or the NACK rate is greater than the first and second thresholds. When large, CRC32 is added to ARQ blocks to generate MAC PDU.

13 is a flowchart illustrating a third embodiment of an ARQ transmission support method in wireless communication according to the present invention. In FIG. 13, for convenience, the ACK rate is expressed as a reference, but it is also applicable based on the NACK rate. Referring to FIG. 13, the MAC layer supporting the ARQ protocol receives at least one MAC SDU from an upper layer (step S1300), and generates the at least one ARQ block (step S1310). An ACK rate or a NACK rate indicating a ratio of ACK or NACK to a sum of NACK and NACK is calculated. (Step S1320) If the ACK rate is greater than a predetermined first threshold value (CRC16 ACK rate), or the NACK rate is predetermined. If it is smaller than the first threshold value (CRC16 NACK rate), the CRC is added to the entire ARQ block constituting the MAC PDU without adding a CRC for each ARQ block (step S1340). If the ACK rate is less than the CRC16 ACK rate, is greater than a second predetermined threshold (CRC32 ACK rate), or if the NACK rate is greater than the CRC16 NACK rate, is less than a second predetermined threshold value (CRC32 NACK rate) Check (step S1350), if the ACK rate is small or the NACK rate is large, add CRC32 to ARQ blocks. (Step S1360), if the ACK rate is large or the NACK rate is small, add CRC16 to ARQ blocks. In step S1370, when the processing for adding CRC information is completed in steps S1340, S1360, and S1370, a MAC PDU is generated (step S1380). Here, the ARQ block header is FSH as described above. (Fragmentation SubHeader) or any one of PSH (Packing SubHeader), wherein the FSH and PSH is any one of (No CRC), CRC16 and CRC32 using a Selective CRC as shown in Figs. Contains information representing the. Meanwhile, in the above-described embodiments, the CRC added to the ARQ block may be generated for the payload of the ARQ block, or may be generated for both the payload and the ARQ block header of the ARQ block.

The above-described embodiments are expressed as a whole. The MAC layer supporting the ARQ protocol receives at least one MAC SDU from an upper layer, and transmits a MAC PDU to the receiver through the PHY layer. Then, it is a structure for receiving information on whether at least one reception success for the MAC PDU from the receiver. In this case, the MAC PDU includes a payload including a MAC header and at least one ARQ blocks generated from the at least one MAC SDU, and a CRC code for the MAC header and the MAC payload. The ARQ block also includes an ARQ block header, an ARQ block payload and an ARQ block CRC code. Here, the ARQ block CRC code is preferably generated using the ARQ block header and the ARQ block payload, and the ARQ block header includes an FSH or PSH sub header. And, the length of the ARQ block CRC code is preferably selected according to any one of the number of ARQ blocks, ACK rate (channel rate) and channel information in the MAC PDU. The ARQ block CRC code is 16 bits or 32 bits in length.

14 illustrates a MAC PDU configuration according to the present invention. The reason why the optional CRC is useful is that if the statistics ratio of the CINR or the successfully received receiver's ARQ block is high enough, or if the packet size is small enough to predict that there will be no error in the MAC PDU, then the omission of the CRC may result in the required propagation resource. You will save.

In FIG. 14, the second and third MAC PDUs show that bits of the CRC can be flexibly selected according to the received packet size, CQI information, or statistical ratio of successfully received ARQ blocks. The accuracy verification procedure of the optional CRC is the same as that of the method of FIG. If there is no CRC at the end of each ARQ block, a conventional method, that is, a method depending on the CRC32 at the end of the MAC PDU is used. 9, 11, and 13 illustrate a procedure for determining a selective CRC based on the number of ARQ blocks, the CINR, and the ACK rate of the MAC PDU, respectively.

For CINR based on selective CRC, in contrast to base station BS using CQI information reported from terminal MS, the MS uses the measured downlink CINR value for uplink selective CRC determination. This is because there is no CQI information for the uplink. This is assuming that downlink and uplink channels are comparable to a TDD system. Combinations of the three methods described above are also possible. For example, the ACK rate based on the optional CRC and the number of ARQ blocks in the MAC PDU based on the optional CRC may be used together only when the CRC16 ARQ block threshold and the CRC32 ARQ block threshold change according to the ARQ ACK rate.

In order to support the selective CRC at the end of the ARQ block, a reserved bit of a fragmentation subheader (FSH) may be allocated for the selective CRC in the IEEE 802.16e-2005 standard. 5 shows a proposed modification to the FSH. For PSH (Packing SubHeader), 1 byte should be added to the IEEE 802.16e-2005 standard for selective CRC as shown in FIG.

FIG. 15 illustrates a receiving apparatus for supporting ARQ transmission in wireless communication according to the present invention, and includes a PDU CRC check unit 1510, an HCS check unit 1520, an ARQ block CRC check unit 1530, and an ACK / NACK. The generator 1540 is included.

The PDU CRC checker 1510 checks the CRC of the MAC PDU by receiving the MAC PDU from the PHY (physical) layer. The HCS check unit 1520 generates an ACK for all ARQ blocks of the MAC PUD when there is no CRC error as a result of the check of the PDU CRC check unit 1510, and calculates a header check sequence (HCS) if there is a CRC error. Check if it is same as HCS of GMH. The ARQ block CRC checker 1530 generates a NACK for all ARQ blocks of a MAC PDU if the result of the check of the HCS checker 1520 is not the same, and checks the CRC for each ARQ block if it is the same. The ACK / NACK generating unit 1540 generates an ACK for the block if there is no CRC check result for each ARQ block, and generates an NACK for the block if there is an error.

16 illustrates a receiving method for supporting ARQ transmission in wireless communication according to the present invention. Referring to FIG. 16, a MAC PDU is received from a PHY (physical) layer (step S1610), and a CRC of the MAC PDU is checked (step S1620). That is, it is checked whether the CRC32 of the calculated CRC and the MAC PDU are the same.

If there is no CRC error, i.e., if the calculated CRC and the CRC32 of the MAC PDU are the same, an ACK is generated for all ARQ blocks of the MAC PDU (step S1630). If the CRC32 of the MAC PDU is not the same, a header check sequence (HCS) is calculated to check whether it is the same as the GMCS's HCS (step S1540). If the HCS check result is not the same, NACK for all ARQ blocks of the MAC PDU is checked. In step S1650, if it is the same, the CRC is checked for each ARQ block (step S1660).

The accuracy of GMH (Generic MAC Header) is verified using a Header Check Sequence (HCS). The ARQ block header, i.e. the accuracy of the FSH or PSH, and the ARQ block payload are checked using a CRC appended to the end of the ARQ block.

If there is no error in the CRC check result for each ARQ block, that is, if the calculated CRC and the CRC of the ARQ block are the same, an ACK is generated for the corresponding block (step S1670), and if there is an error, an NACK is generated for the corresponding block (S1680). Step) Then, it is checked whether there is an ARQ block that has not yet been CRC checked (step S1690), and steps S1660 to S1680 are performed on all ARQ blocks.

In more detail, the accuracy checking procedure at the receiving end is performed as follows. Verify that the calculated 32-bit CRC value is the same as the CRC32 at the end of the MAC PDU. If the calculated CRC value is equal to CRC32 at the end of the MAC PDU, then all ARQ blocks in the MAC PDU are treated as successfully received. If the calculated CRC value is different from CRC32 at the end of the MAC PDU, verify the GMH using HCS. If the calculated HCS is different from the HCS in the GMH, all ARQ blocks in the MAC PDU are treated as having errors and are discarded. If the calculated HCS is the same as the HCS in the GMH, the CRC at the end of each ARQ block is used to verify each ARQ block.

On the other hand, the present invention described above can also be embodied as computer readable codes on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disks, hard disks, optical data storage devices, and also in the form of carrier waves (e.g., transmission over the Internet). It includes what is implemented. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion. And functional programs, codes and code segments for implementing the present invention can be easily inferred by programmers in the art to which the present invention belongs.

Although the present invention has been described in detail with reference to the preferred embodiments, those skilled in the art to which the present invention pertains can implement the present invention in other specific forms without changing the technical spirit or essential features, The examples are to be understood in all respects as illustrative and not restrictive.

In addition, the scope of the present invention is specified by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalent concepts are included in the scope of the present invention. Should be interpreted as

According to the present invention, by distinguishing a successfully received ARQ block and an error ARQ block to be able to retransmit only an error ARQ block, to prevent the performance degradation caused by unnecessary ARQ block retransmission, ARQ performance and system performance Can improve.

Claims (29)

Receiving at least one MAC Service Data Unit (SDU) from a higher layer in a Media Access Control (MAC) layer supporting an Automatic Repeat reQuest (ARQ) protocol; Generate at least one ARQ block from the at least one MAC SDU, wherein the ARQ block includes an ARQ block header, an ARQ block payload, and error detection information for the ARQ block payload; Generating a MAC PDU including a block and a MAC PDU including error detection information and a MAC PDU header for the MAC PDU payload; And And transmitting the MAC PDU to a receiver through a PHY layer. The method of claim 1, wherein the error detection information is A method of supporting ARQ transmission in wireless communication, characterized in that it is a cyclic redundancy check (CRC). The method of claim 2, The MAC PDU header is a Generic MAC Header (GMH), The ARQ block header is A fragmentation subheader (FSH) including information required when a MAC PDU is generated by dividing one MAC SDU into two or more; And A method for supporting ARQ transmission in wireless communication, comprising any one of PSHs (Packing SubHeaders) including necessary information when packing multiple MAC SDUs into one MAC PDU. The method of claim 3, wherein the FSH and PSH is And information indicating any one of 16-bit CRC (CRC16) and 32-bit CRC (CRC32). Receiving at least one MAC SDU from an upper layer at a MAC layer supporting the ARQ protocol; Generating the at least one MAC SDU into at least one ARQ block; And Generating a MAC PDU by adding a CRC for each ARQ block if the number of ARQ blocks included in the MAC PDU is less than a first threshold, and adding a CRC for each ARQ block if the number of ARQ blocks is smaller than a first threshold. ARQ transmission support method for wireless communication, characterized in that. The method of claim 5, CRC16 is added to ARQ blocks when the number of ARQ blocks is greater than a predetermined first threshold and smaller than a predetermined second threshold,  And generating a MAC PDU by adding CRC32 to the ARQ blocks when the number of the ARQ blocks is greater than the first threshold value and the second threshold value. The method of claim 6, wherein the MAC PDU is With Generic MAC Header and ARQ Block Header The ARQ block header is FSH (Fragmentation SubHeader) including information required when a MAC PDU is divided into at least two to generate a MAC PDU, and a sub containing necessary information when multiple MAC SDUs are packed into one MAC PDU Includes any one of PSH (Packing SubHeader) represented by the header, The FSH and the PSH include information indicating any one of CRC No CRC, CRC16 and CRC32. Receiving at least one MAC SDU from an upper layer at a MAC layer supporting the ARQ protocol; Generating the at least one MAC SDU into at least one ARQ block; And Generating a MAC PDU by adding a CRC for each ARQ block if the channel state information value is greater than a predetermined first threshold value, and adding a CRC for each ARQ block if the channel state information value is larger than the first threshold value. ARQ transmission support method in wireless communication. 9. The method of claim 8, wherein the channel state information value is Support for ARQ transmission in wireless communication, characterized in that the base station is set by the CQI (Channel Quality Indicator), and the terminal is set to the carrier to interference and noise ratio (CINR) of the measured downlink Way. The method of claim 8, Add CRC16 to ARQ blocks when the channel state information is less than a first predetermined threshold and greater than a second predetermined threshold;  And generating a MAC PDU by adding CRC32 to ARQ blocks when the channel state information value is smaller than the first threshold value and the second threshold value. The method of claim 10, wherein the MAC PDU is It has a GMH (Generic MAC Header) and ARQ block header, The ARQ block header is FSH (Fragmentation SubHeader) including the information required when generating a MAC PDU by dividing one MAC SDU into at least two, and PSH including the necessary information when multiple MAC SDUs are packed into one MAC PDU (Packing SubHeader) any one, The FSH and the PSH include information indicating any one of CRC No CRC, CRC16 and CRC32. Receiving at least one MAC SDU from an upper layer at a MAC layer supporting the ARQ protocol; Generating the at least one MAC SDU into at least one ARQ block; And If the ACK rate for the sum of the received ACK (Acknowledgment) and NACK (Non-acknowledgment) is greater than a predetermined first threshold, the CRC is not added for each ARQ block. And generating a MAC PDU by adding a CRC for each block. The method of claim 12, CRC16 in ARQ blocks when the ACK rate is less than the first predetermined threshold and greater than the second predetermined threshold or when the NACK rate is greater than the first predetermined threshold and less than the second predetermined threshold. Add CRC32 to the ARQ blocks when the ACK rate is less than the first and second thresholds or the NACK rate is greater than the first and second thresholds. ARQ transmission support method for wireless communication, characterized in that. The method of claim 13, wherein the MAC PDU is It has a GMH (Generic MAC Header) and ARQ block header, The ARQ block header packs a fragmentation subheader (FSH) represented by a subheader including information required when a MAC PDU is generated by dividing one MAC SDU into at least two, and a MAC PDU is packed into one MAC PDU. One of PSH (Packing SubHeader) represented by a subheader containing necessary information in one case, The FSH and the PSH include information indicating any one of CRC No CRC, CRC16 and CRC32. Checking a CRC of the MAC PDU by receiving a MAC PDU including a plurality of ARQ blocks from a PHY (physical) layer; Generating an ACK for all ARQ blocks of a MAC PDU if there is no CRC error as a result of checking the CRC, and if there is a CRC error, calculating a header check sequence (HCS) to check whether it is the same as the HCS of GMH; Generating a NACK for all ARQ blocks of a MAC PDU if it is not the same as a result of checking the HCS, and checking a CRC for each ARQ block if it is the same; And Generating an ACK for the corresponding block if there is no error as a result of checking the CRC for each ARQ block, and generating an NACK for the corresponding block if there is an error. Way. An ARQ block generation unit generating at least one ARQ block from at least one MAC Service Data Unit (SDU); An ARQ block counting unit for calculating the number of ARQ blocks included in the MAC PDU; And If the number of the ARQ block is less than a predetermined first threshold value does not add a CRC for each ARQ block, if larger than the first threshold value includes a CRC adder for generating a MAC PDU by adding a CRC for each ARQ block ARQ transmission support device for wireless communication. The method of claim 16, wherein the CRC addition portion When the number of the ARQ blocks is greater than a predetermined first threshold and less than the predetermined second threshold, CRC16 is added to the ARQ blocks, and the number of ARQ blocks is greater than the first threshold and the second threshold. When large, adds CRC32 to the ARQ blocks to generate a MAC PDU. An ARQ block generation unit generating at least one ARQ block from at least one MAC Service Data Unit (SDU); A channel state information value setting unit for setting a channel state information value; And If the channel state information value is greater than the first threshold value, and does not add a CRC for each ARQ block, and if it is smaller than the first threshold value, the CRC adder for generating a MAC PDU by adding a CRC for each ARQ block, characterized in that it comprises a ARQ transmission support device for wireless communication. 19. The method of claim 18, wherein the channel state information value is The base station is set to a channel quality indicator (CQI) value when the base station, and the terminal is set to the CINR of the downlink measured when the terminal is a transmitter, ARQ transmission support apparatus in a wireless communication. 19. The method of claim 18, wherein the CRC addition portion When the channel state information is less than the first threshold and greater than the second predetermined threshold, CRC16 is added to ARQ blocks, and the channel state information is greater than the first and second thresholds. The apparatus for supporting ARQ transmission in wireless communication, wherein the MAC PDU is generated by adding CRC32 to the ARQ blocks when small. An ARQ block generation unit generating at least one ARQ block from at least one MAC Service Data Unit (SDU); An ACK / NACK rate calculator configured to calculate an ACK rate or a NACK rate for the sum of the ACK and NACK received by the transmitting end; And If the ACK rate calculated by the ACK / NACK rate calculation unit is larger than a first predetermined threshold value or the NACK rate is smaller than a first predetermined threshold value, the CRC is not added for each ARQ block, and the ACK rate is zero. And a CRC adder configured to generate a MAC PDU by adding a CRC for each ARQ block if it is smaller than one threshold or the NACK rate is larger than a first threshold. The method of claim 21, wherein the CRC addition portion CRC16 is added to ARQ blocks when the ACK rate is less than a first predetermined threshold and greater than a second predetermined threshold or when the NACK rate is greater than a first predetermined threshold and less than a second predetermined threshold. When the ACK rate is less than the first threshold value and the second threshold value, or when the NACK rate is greater than the first threshold value and the second threshold value, CRC32 is added to ARQ blocks to generate a MAC PDU. ARQ transmission support apparatus in wireless communication, characterized in that. A PDU CRC check unit for receiving a MAC PDU from a PHY (physical) layer and checking a CRC of the MAC PDU; If there is no CRC error, the PDU CRC checker generates an ACK for all ARQ blocks of the MAC PUD, and if there is a CRC error, calculates a header check sequence (HCS) to check whether it is the same as the HCS of GMH. Check unit; An ARQ block CRC check unit for generating a NACK for all ARQ blocks of a MAC PDU if the result of the check in the HCS check unit is not the same, and checking the CRC for each ARQ block if it is the same; And Supporting the ARQ transmission in the wireless communication, characterized in that for checking the CRC for each ARQ block, if there is no error generates an ACK for the block, if there is an error ACK / NACK generating unit for generating a NACK for the block Receiver for the. delete delete delete delete delete delete

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