KR101405495B1 - Apparatus and method for data retrnasmission of asynchronous control message transmission in wireless communication system using relay - Google Patents

Abstract

The present invention relates to an apparatus and method for retransmitting data in a wireless communication system using a multi-hop relaying method, and more particularly, to a method and apparatus for retransmitting data in a wireless communication system using a multi- And transmitting the message to the upper node at a time when the node is not in agreement with the upper node, thereby reducing the retransmission delay time occurring in the synchronous retransmission scheme.

A multi-hop relay method, a relay station, an automatic retransmission request, an asynchronous control message, an ACK / NACK message

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for transmitting an asynchronous control message for data retransmission in a wireless communication system using a relay scheme,

1 is a diagram illustrating a configuration of a wireless communication system using a multi-hop relaying method according to the present invention;

2 is a diagram illustrating a data transmission procedure in a wireless communication system using a multi-hop relay scheme according to an embodiment of the present invention;

FIG. 3 illustrates a procedure for performing ARQ in a synchronous manner in a wireless communication system using a multi-hop relaying method according to an embodiment of the present invention; FIG.

FIG. 4 illustrates a procedure for performing ARQ in a synchronous manner in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention.

FIG. 5 illustrates a procedure for performing ARQ in a synchronous manner in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention; FIG.

FIG. 6 illustrates a procedure for performing ARQ asynchronously in a multi-hop relay wireless communication system according to an embodiment of the present invention;

FIG. 7 illustrates a procedure for performing ARQ asynchronously in a multi-hop relay wireless communication system according to another embodiment of the present invention; FIG.

8 is a diagram illustrating a procedure for performing ARQ asynchronously in a multi-hop relay wireless communication system according to another embodiment of the present invention.

9 is a flowchart illustrating an operation procedure of an RS for performing ARQ asynchronously in a multi-hop relay wireless communication system according to an embodiment of the present invention;

10 is a block diagram of a relay station in a wireless communication system using a multi-hop relaying method according to the present invention.

11 is a diagram illustrating a configuration of a feedback header in a wireless communication system using a multi-hop relay scheme according to an embodiment of the present invention, and FIG.

12 is a diagram illustrating a configuration of a feedback header in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for performing an automatic retransmission request (ARQ) in a wireless communication system, and more particularly to an apparatus and method for performing an ARQ in an asynchronous wireless communication system using a multi- Apparatus and method.

In the wireless communication system, an error may occur in specific data depending on a channel state of a radio resource for transmitting data. Control and recovery techniques for such errors are largely divided into ARQ and FEC (Frame Error Check) techniques. Here, the ARQ scheme is a scheme for requesting retransmission of lost data at a receiving end to a transmitting end. In addition, the FEC technique is a technique for correcting errors of data lost at the receiving end.

When the ARQ scheme is used in the wireless communication system, the receiver decodes the received packet to check if an error has occurred. At this time, if there is no error in the received packet, the receiving end transmits an ACK signal to the transmitting end.

Meanwhile, when an error occurs in the received packet, the receiving end transmits a NACK signal to the transmitting end.

The transmitting end transmits a new packet when an ACK message is received from the receiving end. Meanwhile, when a NACK message is received from the receiving end, the transmitting end retransmits the previous packet to the receiving end.

In recent years, the wireless communication system uses a relay system using a relay station to provide a better wireless channel to a terminal located in an edge or a shadow area of the cell. That is, the wireless communication system using the relay scheme can relay the data transmitted / received between the base station and the terminal by using the relay station to provide a better wireless channel between the base station and the terminal.

Therefore, a wireless communication system using the relaying method needs a method of performing an ARQ using the relay station.

Accordingly, it is an object of the present invention to provide an apparatus and a method for performing an automatic retransmission request in a wireless communication system using a multi-hop relay scheme.

It is another object of the present invention to provide an apparatus and method for asynchronously transmitting a control message for an automatic retransmission request in a wireless communication system using a multi-hop relay scheme.

It is another object of the present invention to provide an apparatus and method for asynchronously transmitting an ACK / NACK message for an automatic retransmission request in a wireless communication system using a multi-hop relay scheme.

According to a first aspect of the present invention, there is provided a method of retransmitting in a relay station of a wireless communication system using a relay scheme, comprising the steps of: checking whether an error has occurred in data received from an upper node; Generating a message indicating whether the message is generated or not; and transmitting the message to the upper node at a time when the message is not promised to the upper node.

According to a second aspect of the present invention, a relay station apparatus of a wireless communication system using a relay scheme includes a receiver for receiving data from an upper node, an inspection unit for checking whether an error has occurred in the received data, And a transmitter for transmitting the message to the upper node at a time when the upper node is not in agreement with the upper node.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Hereinafter, a technique for asynchronously transmitting a control message for an automatic retransmission request (hereinafter referred to as ARQ) in a wireless communication system using a relay scheme will be described. The following description will exemplify an ACK / NACK message among control messages, but the same applies to other control messages.

Hereinafter, a wireless communication system using an Orthogonal Frequency Division Multiplexing Access (Orthogonal Frequency Division Multiplexing Access) system will be described as an example, and the present invention is equally applicable to other multiple access systems.

In the following description, it is assumed that the wireless communication system includes three hops as shown in FIG. However, the present invention can also be applied to a case where the wireless communication system is configured with two hops or multiple hops.

FIG. 1 illustrates a configuration of a wireless communication system using a multi-hop relaying method according to an embodiment of the present invention.

As shown in FIG. 1, in the wireless communication system, the base station 100 provides a service through a direct link to a terminal included in a service area. However, when the terminal 130 is located outside the service area or outside the service area, the base station 100 provides a service to the terminal 130 using a relay link through the relay stations 110 and 120 .

For example, when transmitting data from the BS 100 to the MS 130, the BS 100 transmits data to be transmitted to the MS 130 to the RS 110.

Upon receiving data from the base station 100, the first relay station 110 checks whether the data is erroneous. If there is no error in the data, the RS 120 transmits the data to the RS 120. In this case, if the data includes data to be transmitted to the MS through the RS 1 110, the RS 1 110 transmits the data to the serving MS.

Meanwhile, when an error occurs in the data, the first RS 110 transmits a NACK message for the data to the BS 100.

When the relay station 2 (120) receives data from the first relay station (110), it confirms whether or not the data is erroneous. If there is no error in the data, the terminal 130 transmits the data to the terminal 130.

Meanwhile, when an error occurs in the data, the RS 2 120 transmits a NACK message for the data to the RS 1 (110).

When the MS 130 receives data from the RS 120, the MS 130 determines whether the data error has occurred. If there is no error in the data, the SS 130 transmits an ACK message for the data to the RS 2 120. Meanwhile, if an error occurs in the data, the SS 130 transmits a NACK message for the data to the RS 2 120.

As described above, the relay station and the terminal of the wireless communication system transmit an ACK message or a NACK message to the superordinate node according to whether an error has occurred in the data provided from the superordinate node. At this time, the wireless communication system transmits and receives data and an ACK / NACK message in a basic unit of constant data transmission. In the following description, the wireless communication system assumes that the basic unit of data transmission is one frame. At this time, the frame represents a Transmission Time Interval (TTI) which is a basic physical unit of data transmission. That is, the frame indicates a processing delay time from when one node receives data to confirm an error, and then transmits the data. Although the processing delay time is assumed to be one frame in the following description, a processing delay time of several frames may occur depending on the capabilities of the base station, the relay station and the terminal.

For example, the wireless communication system transmits data and an ACK / NACK message as shown in FIG. 2, it is assumed that data and an ACK / NACK message are transmitted in a synchronous manner in the wireless communication system. That is, the nodes of the wireless communication system promise a time to transmit data and an ACK / NACK message. Therefore, the nodes can recognize the ACK / NACK message for the data according to the time when the ACK / NACK message is received.
FIG. 2 illustrates a data transmission procedure in a wireless communication system using a multi-hop relay scheme according to an embodiment of the present invention.

2, when the base station 200 transmits data to the terminal 230, the base station 200 transmits data to the first relay station 210 during the i-th frame 241 (step 261) ). At this time, the first RS 210 determines whether an error has occurred in the data received from the BS 200. If there is no error in the data, the first relay station 210 transmits the data to the second relay station 220 during the (i + 1) th frame 243 (step 263).

The RS 2 220 checks whether data received from the RS 1 210 has failed. If there is no error in the data, the RS 220 transmits the data to the UE 230 during the (i + 2) th frame 245 (step 265).

When the RS 230 receives data from the RS 220, the MS 230 determines whether the data is erroneous. If there is no error in the data, the terminal 230 transmits an ACK message to the RS 2 in step 267 during the (i + 3) th frame 247.

When the ACK message is received from the SS 230, the RS 2 220 transmits the ACK message to the SS 230 during the (i + 2) -th frame 245 according to the received time information of the ACK message. Lt; RTI ID = 0.0 > ACK < / RTI >

Then, the RS 2 220 transmits the ACK message to the RS 1 210 during the (i + 4) th frame 249 (step 269).

When the ACK message is received from the RS 2 (220), the RS 1 210 transmits the ACK message to the RS 2 (240) during the (i + 1) 220, which is an ACK message.

Thereafter, the RS 1 210 transmits the ACK message to the BS 200 during the (i + 5) th frame 251 (step 271).

When the ACK message is received from the RS 1 210, the BS 200 transmits the ACK message to the RS 1 210 during the i-th frame 241 according to the received time information of the ACK message And confirms that it is an ACK message for data.

As described above, the base station 200, the relay stations 210 and 220, and the terminal 230 of the wireless communication system transmit data and an ACK / NACK message according to a predetermined frame. If an error occurs in the data received by the lower nodes from the upper node, the wireless communication system operates as shown in FIGS. 3, 4 and 5. Here, an upper node (base station or upper relay station) includes frame information for transmitting ACK / NACK messages to lower nodes in the data scheduling information, and transmits the ACK / NACK message to the lower nodes.

FIG. 3 shows a procedure for performing ARQ in a synchronous manner in a wireless communication system using a multi-hop relaying method according to an embodiment of the present invention.

3, when the base station 300 transmits data to the terminal 330, the base station 300 transmits data to the first relay station 310 during the i-th frame 341 (step 361) ).

At this time, the first relay station 310 determines whether an error has occurred in the data provided from the base station 300. If there is an error in the data (step 363), the first RS 310 transmits the ACL / NACK message to the BS 300 in the (i + 5) th frame 351 NACK message to the BS 300 (step 365).

That is, the BS 300 recognizes that the ACK / NACK message for the data transmitted to the first RS 310 during the i-th frame 341 is received during the (i + 5) -th frame 351 . Therefore, the first relay station 310 does not transmit the NACK message for the data from the (i + 1) th frame 343 to the (i + 4) th frame 345, And transmits a NACK message for the data to the BS 300 during a period 351.

The BS 300 transmits a NACK message provided from the RS 1 310 during the (i + 5) th frame 351 to the RS 1 310 during the i-th frame 341 NACK message.

Accordingly, the BS 300 retransmits the data for the NACK message to the first RS 310 during the (i + 6) th frame 353 (step 367).

FIG. 4 illustrates a procedure for performing ARQ in a synchronous manner in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention.

4, when the BS 400 transmits data to the MS 430, the BS 400 transmits data to the RS 1 410 during the i-th frame 441 (step 461) ).

At this time, the RS 1 410 checks whether or not an error has occurred in the data provided from the BS 400. If there is no error in the data, the RS 1 410 transmits the data to the RS 2 420 during the (i + 1) th frame 443 (step 463).

At this time, the RS 2 420 checks whether the data received from the RS 1 410 has an error. If an error occurs in the data (step 465), the RS 2 420 transmits a NACK message for the data for the (i + 4) th frame 449 to the RS 1 410 (step 467 ).

That is, the RS 1 410 transmits an ACK / NACK message for data transmitted to the RS 2 420 during the (i + 4) th frame 443 during the (i + 4) It is recognized as being received. Accordingly, the RS 2 420 does not transmit the NACK message for the data from the (i + 2) th frame 445 to the (i + 3) th frame 447, And transmits a NACK message for the data to the RS 1 (410).

The relay station 1 410 transmits a NACK message received from the RS 2 420 during the (i + 4) th frame 449 to the RS 2 420 during the (i + 1) And confirms that the NACK message is for the transmitted data.

In step 469, the RS 1 410 transmits the NACK message received from the RS 2 420 to the BS 400 during the (i + 5) th frame 451. At this time, the NACK message includes information indicating that an error has occurred in data at the RS 2 420.

The BS 400 transmits a NACK message received from the RS 1 410 during the (i + 5) th frame 451 to the RS 1 410 during the i-th frame 441 NACK message. In addition, the BS 400 checks the information included in the NACK message and confirms that the NACK message is a NACK message for the errored data in the RS 2 420.

Accordingly, the BS 400 transmits scheduling information for retransmitting the data for the NACK message to the first RS 410 during the (i + 6) th frame 453 (step 471).

When the scheduling information is received, the first relay station 410 transmits data on the NACK message received from the second relay station 420 to the relay station 2 420 (i + 7) th frame 455 according to the scheduling information. (Step 473).

FIG. 5 illustrates a procedure for performing ARQ in a synchronous manner in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention.

5, when the BS 500 transmits data to the MS 530, the BS 500 transmits data to the RS 1 510 during the i-th frame 551 (step 561) ).

At this time, the first RS 510 checks whether the data provided from the BS 500 is erroneous. If there is no error in the data, the RS 1 510 transmits the data to the RS 2 520 during the (i + 1) th frame 543 (step 563).

At this time, the RS 2 520 checks whether the data received from the RS 1 510 has an error. If there is no error in the data, the RS 2 520 transmits the data to the UE 530 during the (i + 2) th frame 545 (step 565).

At this time, the MS 530 checks whether the data received from the RS 2 520 has an error. If an error occurs in the data in step 567, the SS 530 transmits a NACK message for the data for the (i + 3) -th frame 547 to the RS 2 520 (step 569) .

The RS 2 520 transmits the NACK message received from the UE 530 during the (i + 3) th frame 545 to the UE 530 during the (i + 2) NACK message for the data.

The RS 2 520 transmits the NACK message received from the SS 530 to the RS 1 510 during the (i + 4) th frame 549 (step 571). At this time, the NACK message includes information indicating that an error has occurred in the data in the AT 530.

The RS 1 510 transmits a NACK message received from the RS 2 520 during the (i + 4) th frame 549 to the RS 2 520 during the (i + 1) And confirms that the NACK message is for the transmitted data. In addition, the RS 1 510 checks the information included in the NACK message and confirms that the NACK message is a NACK message for the data in which the error occurred in the UE 530.

In step 573, the RS 1 510 transmits the NACK message received from the RS 2 520 to the BS 500 during the (i + 5) th frame 551. At this time, the NACK message includes information indicating that an error has occurred in the data in the AT 530.

The BS 500 transmits a NACK message received from the RS 1 510 during the (i + 5) th frame 551 to the RS 1 510 during the i-th frame 541 NACK message. Also, the BS 500 checks the information included in the NACK message and confirms that the NACK message is a NACK message for the data in which the error occurred in the AT 530. [

Accordingly, the BS 500 transmits the scheduling information for retransmitting the data for the NACK message to the first RS 510 during the (i + 6) th frame 553 (step 575).

The RS 1 510 transmits the scheduling information provided from the BS 500 to the RS 2 520 during the (i + 7) th frame 555 (step 577).

When the scheduling information is received, the RS 2 520 transmits data on the NACK message provided from the SS 530 to the SS 530 during the (i + 8) th frame 557 according to the scheduling information (Step 579).

As described above, since the nodes of the wireless communication system send and receive control messages according to predetermined transmission time points, the overhead for the control messages can be reduced. However, when an error occurs in the data provided from the upper node, the lower nodes receiving the data have to wait for transmission of the control message until a predetermined time, so that the delay time for retransmission increases.

Accordingly, the wireless communication system transmits a control message asynchronously as shown in FIG. 6, FIG. 7, and FIG. 8 to reduce the delay time for retransmission.

FIG. 6 illustrates a procedure for asynchronously performing ARQ in a multi-hop relay wireless communication system according to an embodiment of the present invention.

6, when the BS 600 transmits data to the MS 630, the BS 600 transmits data to the RS 610 during the i-th frame 641 (step 661) ).

The RS 1 610 checks whether or not an error has occurred in the data provided from the BS 600. If an error occurs in the data (step 663), the RS 1 610 transmits a NACK message for the data for the (i + 1) -th frame 643 to the BS 600 (step 665) .

At this time, the RS 1 610 transmits a NACK message to the BS 600 at an unspecified point in time. Accordingly, the RS 1 610 transmits additional information about the NACK message together with the Node B 600 so that the Node B 600 can know which node the NACK message is received from and which NACK message it is associated with. Herein, the additional information of the NACK message includes unique identifier information of the RS 1 610 and unique identifier information of the data to indicate which data is the NACK message. If HARQ (Hybrid ARQ) is used, since the nodes can transmit data by dividing the data into several partial data, the additional information for the NACK message should additionally include unique identifier information of the partial data. Further, when transmitting additional information about an ACK message as well as a NACK message at the RS 1 610, each additional information additionally includes information indicating whether the NACK message is additional information of the NACK message or additional information of the ACK message .
For example, when a control message for additional information of a NACK message is configured using the Institute of Electrical and Electronics Engineers (IEEE) 802.16 standard, the additional information may include CID information of the relay station 1 610, Connection IDendifier) and a BSN (Block Sequence Number) indicating a unique number of data.
If HARQ is used, the additional information may be a CID or an RCID (Reduced CID) of the RS 1 610 and an ACID (HARQ Channel ID) indicating a unique number of HARQ data or a unique identifier of the partial data of the ACID And a SPID (Sub Packet ID).
Further, when transmitting additional information about an ACK message as well as a NACK message at the RS 1 610, each additional information additionally includes information indicating whether the NACK message is additional information of the NACK message or additional information of the ACK message .

In another embodiment, the RS 1 610 may configure an ACK / NACK message as shown in FIG. 11 or 12 using a feedback header defined in the IEEE 802.16 standard. 11 and 12 illustrate an ACK / NACK message structure using a frame header defined in the MAC signaling header type II of the IEEE 802.16 standard. Therefore, in order to indicate the MAC signaling header type 2 of the IEEE 802.16 standard, the frame header has a value of 1 for both the HT field and the EC field.

11 illustrates a configuration of a feedback header in a wireless communication system using a multi-hop relaying method according to an embodiment of the present invention.

11, the feedback header includes a feedback type field 1101, a feedback content field 1103, and a feedback type field 1103 when the type field is set to 0 and the CID (CID Inclusion Indication) field is set to 1, A CID field 1105, and a Header CheckSum (HCS) 1107.

The feedback type field 1101 indicates that the feedback content field 1103 includes ACK or NACK information for data composed of a bitmap. At this time, the feedback header may indicate whether the bitmap information included in the feedback content field 1103 is repeated according to the value of the feedback type field 1101. For example, when the value of the type field 1101 is 1100, the feedback content field 1103 includes 16 bits of ACK / NACK information for 16 data. Also, when the value of the type field 1101 is 1101, the feedback content field 1103 includes information in which ACK / NACK information for 8 data is repeated twice using 16 bits.

The feedback content field 1103 is a bitmap composed of 16 bits, and each bit indicates ACK or NACK information for each data. At this time, the bitmap includes ACK / NACK information of data arranged in the order of the DL map.

The CID field 1105 includes identifier information of a node that transmits ACK / NACK information through the feedback content field 1103.

The HCS field 1107 includes information for checking whether the feedback header is erroneous.

FIG. 12 shows a configuration of a feedback header in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention.

12, when the type field is set to 1, the feedback header includes a feedback type field 1201, a repetition type field 1203, a feedback content field 1205, a CID Field 1207 and a Header CheckSum (HCS)

The feedback type field 1201 indicates that the feedback content field 1103 includes ACK or NACK information for data composed of a bitmap.

The repetition type field 1203 indicates repetition information of the bitmap information included in the feedback content field 1205. For example, when the value of the repetition type field 1203 is 00, the feedback content field 1205 includes ACK / NACK information for 16 data using 16 bits. Also, when the value of the repetition type field 1203 is 01, the feedback content field 1205 includes information in which ACK / NACK information for 8 data is repeated twice using 16 bits. Also, when the value of the repetition type field 1203 is 10, the feedback content field 1205 includes information in which ACK / NACK information for 4 pieces of data is repeated 4 times using 16 bits. Also, when the value of the repetition type field 1203 is 11, the feedback content field 1205 includes information in which ACK / NACK information for two pieces of data is repeated eight times using 16 bits.

The feedback content field 1205 is a bitmap composed of 16 bits, and each bit indicates ACK / NACK information for each data. At this time, the bitmap includes ACK / NACK information of data arranged in the order of the DL map.

The CID field 1207 includes identifier information of a node that transmits ACK / NACK information through the feedback content field 1205.

The HCS field 1209 includes information for checking whether the feedback header is erroneous.

As described above, the RS 1 610 may transmit additional information on the NACK signal in the form of a control message or may be transmitted using a separate physical channel.

The BS 600 recognizes that the NACK message is a NACK message for the data transmitted to the RS 1 610 during the i'th frame 641 through the additional information of the NACK message provided from the RS 1 610 do.

Therefore, the BS 600 retransmits the data for the NACK message to the RS 1 610 during the (i + 2) th frame 645 (step 667).

FIG. 7 illustrates a procedure for performing ARQ asynchronously in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention.

7, when the BS 700 transmits data to the MS 730, the BS 700 transmits data to the RS 710 during the i-th frame 741 (step 761) ).

At this time, the RS 1 710 checks whether or not an error has occurred in the data provided from the BS 700. If there is no error in the data, the RS 1 710 transmits the data to the RS 2 720 during the (i + 1) th frame 7473 (step 763).

At this time, the RS 2 720 checks whether the data provided from the RS 1 710 is erroneous. If an error occurs in the data (step 765), the RS 2 720 transmits a NACK message for the data in which the error occurred during the (i + 2) th frame 745 to the RS 710 (Step 767). At this time, the RS 2 720 transmits additional information on the NACK message to the RS 1 710. Herein, the RS 2 720 may configure the additional information in the same form as the additional information configured by the RS 1 610 in FIG. 6.

The relay station 1 710 transmits the NACK message to the relay station 720 through the additional information of the NACK message provided from the relay station 2 720 to the relay station 720 during the (i + 1) NACK message.

In step 769, the RS 1 710 transmits the NACK message received from the RS 2 720 to the BS 700 during the (i + 3) -th frame 747. At this time, the RS 1 710 transmits additional information about the NACK message received from the RS 2 720 to the BS 700.

The BS 700 transmits the NACK message through the additional information of the NACK message provided from the first RS 710 to the RS 710 during the (i + 1) And transmits the NACK message to the UE.

Accordingly, the BS 700 transmits scheduling information for retransmitting the data to the RS 710 during the (i + 4) th frame 749 (step 771).

When the scheduling information is received, the RS 1 710 transmits data for the NACK message provided from the RS 2 720 to the RS 2 720 during the (i + 5) -th frame 751 according to the scheduling information. (Step 773).

FIG. 8 illustrates a procedure for performing ARQ asynchronously in a wireless communication system using a multi-hop relay scheme according to another embodiment of the present invention. As shown in FIG. 8, when the UE requests retransmission of data, the asynchronous retransmission method and the synchronous retransmission method have the same delay time. Therefore, when the UE requests retransmission of data, it is more efficient to use the synchronous retransmission method as shown in FIG. 8 than the asynchronous retransmission method in which additional information is required.

8, when the BS 800 transmits data to the MS 830, the BS 800 transmits data to the RS 810 during the i-th frame 881 (step 861) ).

At this time, the RS 1 810 confirms whether or not an error has occurred in the data provided from the BS 800. If there is no error in the data, the RS 1 810 transmits the data to the RS 2 820 during the (i + 1) th frame 843 (step 863).

At this time, the RS 2 820 confirms whether or not an error has occurred in the data provided from the RS 1 810. If there is no error in the data, the RS 2 820 transmits the data to the SS 830 during the (i + 2) -th frame 848 (step 868).

At this time, the MS 830 confirms whether or not an error has occurred in the data provided from the RS 2 (820). If an error occurs in the data (step 867), the UE 830 transmits a NACK message for the errored data to the RS 2 820 during the (i + 3) -th frame 847 Step 869).

The relay station 2 820 transmits the NACK message received from the terminal 830 during the (i + 3) -th frame 845 to the terminal 830 during the (i + 2) NACK message for the data.

In step 871, the RS 2 820 transmits the NACK message received from the MS 830 to the RS 810 during the (i + 4) th frame 849. At this time, the NACK message includes information indicating that an error has occurred in the data in the SS 830.

The RS 1 810 recognizes that the NACK message provided from the RS 2 820 is a NACK message for data transmitted to the RS 2 820 during the (i + 1) -th frame 843. In addition, the RS # 1 810 recognizes that the NACK message is a NACK message for the errored data in the UE 830 according to the information included in the NACK message.

In step 873, the RS 1 810 transmits the NACK message received from the RS 2 820 to the BS 800 during the (i + 5) th frame 851. At this time, the NACK message includes information indicating that an error has occurred in the data in the SS 830.

The BS 800 recognizes that the NACK message provided from the RS 1 810 is a NACK message for data transmitted to the RS 810 during the i-th frame 841. In addition, the BS 800 recognizes that the NACK message is a NACK message for data in which the error occurred in the UE 830 according to the information included in the NACK message.

Accordingly, the BS 800 transmits the scheduling information for retransmitting the data for the NACK message to the first RS 810 during the (i + 6) th frame 853 (step 875).

The RS 1 810 transmits the scheduling information received from the BS 800 to the RS 2 820 during the (i + 7) th frame 855 (step 877).

The RS 2 820 transmits data for the NACK message received from the MS 830 to the MS 830 during the (i + 8) -th frame 857 upon receiving the scheduling information from the RS 810. (Step 879).

As described above, the lower nodes of the wireless communication system transmit the control message asynchronously to the upper node. That is, the lower nodes transmit control messages to the upper nodes at a time when they are not promised. Accordingly, the lower nodes configure additional information on the control message transmitted to the opposite node, and transmit the control information to the upper node together with the control message. If the lower nodes transmit not only the NACK message but also the ACK message asynchronously, the lower nodes may configure additional information on the ACK message in the same form as the additional information on the NACK message. In this case, the additional information includes information indicating whether the additional information is additional information of the NACK message or additional information of the ACK message.

Hereinafter, an operation method of a relay station when the asynchronous retransmission method is used in the wireless communication system will be described.

FIG. 9 illustrates an operation procedure of an RS for performing ARQ asynchronously in a wireless communication system using a multi-hop relaying method according to an embodiment of the present invention.

Referring to FIG. 9, in step 901, the RS determines whether data is received from an upper node (a BS or an upper RS).

If the data is received, the RS proceeds to step 903 and determines whether or not the data is erroneous. For example, the RS determines whether an error has occurred by using a CRC (Cyclic Redundancy Check) of the data.

If an error occurs in the data, the RS proceeds to step 911 and transmits a NACK message for the errored data to the upper node at a time when it is not agreed with the upper node. Therefore, the RS transmits the NACK message and the additional information about the NACK message to the superordinate node. Here, the additional information includes unique identifier information of the RS and data unique identifier information for indicating which data the NACK message is for. If the HARQ scheme is used, the additional information should additionally include unique identifier information of the partial data.

Thereafter, the RS returns to step 901 and checks whether the error occurred data is retransmitted from the upper node.

On the other hand, if there is no error in the data in step 903, the RS proceeds to step 905 and transmits the data to a lower node (e.g., a lower RS or a terminal).

In step 907, the RS determines whether an ACK message is received from the lower node.

If the NACK message is received from the lower node, the RS proceeds to step 915 and transmits the NACK message provided from the lower node to the upper node. If a NACK message is received from the lower node at an unspecified point in time, the RS can check the lower node that transmitted the NACK message and the errored data information through the additional information on the NACK message. At this time, the RS transmits the NACK message provided from the lower node and the additional information about the NACK message to the upper node.

After transmitting the NACK message to the upper node, the RS proceeds to step 913 and receives the retransmission scheduling information from the upper node.

Thereafter, the RS returns to step 905 and retransmits the error-detected data, which is confirmed through the additional information of the NACK message, to the lower node that has transmitted the NACK message according to the scheduling information. In another embodiment, the RS may transmit the retransmission scheduling information to a lower node that has transmitted the NACK message. That is, when the NACK message provided from the lower node indicates that an error occurs in data of another lower node connected to the lower node, the relay station transmits the retransmission scheduling information to the lower node.

On the other hand, if the ACK message is received from the lower node in step 907, the RS proceeds to step 909 and transmits the ACK message provided to the lower node to the upper node.
Thereafter, the RS terminates the algorithm.

Hereinafter, a block configuration of a relay station for performing an asynchronous retransmission scheme in the wireless communication system will be described.

FIG. 10 shows a block configuration of a relay station in a wireless communication system using a multi-hop relaying method according to the present invention. In the following description, it is assumed that the transmitting unit 1000 and the receiving unit 1020 use different antennas, but the transmitting unit 1000 and the receiving unit 1020 may use one antenna.

10, the RS includes an ARQ control unit 1040, an ARQ state unit 1050, and an ARQ timer 1030 shared by the transmission unit 1000, the reception unit 1020, and the transmission unit 1000 and the reception unit 1020 1060, and a channel estimator 1070.

First, the transmitter 1000 includes a data generator 1001, a channel encoder 1003, a CRC generator 1005, a modulator 1007, an IFFT (Inverse Fast Fourier Transform) calculator 1009, and an RF processor 1011 .

The data generator 1001 collects the data stored in the data queue 1013 and the control message generated by the message generator 1017 in a service data unit (SDU) generator 1015 to generate one data for physical layer transmission do. Here, the message generator 1017 generates an ACK control message if there is no error in the data received through the receiver 1020. On the other hand, when an error occurs in the data, the message generator 1017 generates a NACK message. In addition, the message generator 1017 generates additional information on the NACK message so that the NACK message is received from a node and a NACK message for the data. For example, the message generator 1017 generates additional information including unique identifier information of a relay station and unique identifier information of a data to indicate which data is the NACK message. If the HARQ scheme is used, the message generator 1017 additionally includes unique identifier information of the partial data in the additional information.

The channel encoder 1003 encodes the data supplied from the data generator 1001 according to a modulation level (e.g., an MCS (Modulation and Coding Scheme) level). The CRC generator 1005 generates an error detection code, adds the error detection code to the data received from the channel encoder 1003, and outputs the error detection code.

The modulator 1007 modulates data supplied from the CRC generator 1005 according to a modulation level (e.g., an MCS level) and outputs the modulated data.

The IFFT operator 1009 performs inverse fast Fourier transform on the frequency domain data provided from the modulator 1007 and converts the frequency domain data into a time domain signal.

The RF processor 1011 frequency-up converts the baseband signal received from the IFFT processor 1009 into a radio frequency signal, and outputs it to an upper node and a lower node through an antenna.

The receiver 1020 includes an RF processor 1021, a Fast Fourier Transform (FFT) calculator 1023, a demodulator 1025, a CRC eliminator 1027, a channel decoder 1029, and a data processor 1031 .

The RF processor 1021 frequency downconverts the high frequency signal received through the antenna from the upper node or the lower node to a baseband signal and outputs the baseband signal.

The FFT processor 1023 performs fast Fourier transform on the time domain signal provided from the RF processor 1021 and converts it into a frequency domain signal.

The demodulator 1025 demodulates the signal received from the FFT processor 1023 according to the modulation level. At this time, the demodulator 1025 outputs the demodulated signal to the CRC eliminator 1027 and the channel estimator 1070.

The CRC eliminator 1027 checks the error detection code of the signal supplied from the demodulator 1025 to determine whether the signal has an error. At this time, the CRC eliminator 1027 removes the error detection code from the signal provided from the demodulator 1025.

The channel decoder 1029 decodes the error-free signal provided from the CRC eliminator 1027 according to the modulation level and outputs the error-free signal.

The SDU processor 1035 of the data processing unit 1031 separates data and control messages from the physical layer signal provided from the channel decoder 1029. Thereafter, the SDU processor 1035 provides the data to the second data queue 1037 and stores the data, and the control message is provided to the message processor 1033 for decoding. Here, the first data queue 1013 and the second data queue 1027 may be the same data queue.

The message processor 1033 notifies the ARQ controller 1040 of the reception of the NACK control message when the NACK control message is received from the lower node. Also, the message processor 1033 determines which node the lower node that transmitted the NACK control message is using and the NACK control message is the NACK control message for which data, using the additional information of the NACK control message received from the lower node Check.

The ARQ state unit 1050 manages the ARQ state for the retransmitted data. The ARQ timer 1060 manages a life time for retransmission of the RS.

The ARQ controller 1040 controls the overall operation of the ARQ of the relay station in cooperation with the ARQ state unit 1050 and the ARQ timer 1543. At this time, the ARQ controller 1040 controls the retransmission by communicating with the data generator 1001, the channel encoder 1003, and the CRC generator 1005 of the transmitter 1000. For example, when a retransmission request is received from the lower node through the receiving unit 1020, the ARQ controller 1040 controls the transmitting unit 1000 to transmit the retransmission request signal to an upper node. In addition, when retransmission scheduling information is received from the upper node, the ARQ controller 1040 codes data provided from the upper node stored in the data queue 1013 according to a channel state, inserts an error detection code, To be retransmitted to the child node requesting retransmission.

The ARQ controller 1040 controls the retransmission by communicating with the data processor 1031, the channel decoder 1029 and the CRC eliminator 1027 of the receiver 1020. For example, when an error occurs in the received data in the CRC eliminator 1027, the ARQ controller 1040 controls the message generator 1017 to generate a NACK control message for transmission to the base station.

Also, the ARQ controller 1040 terminates the retransmission procedure when the ARQ timer 1060 receives the valid timeout message during the retransmission procedure.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the illustrated embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

As described above, there is an advantage in that the retransmission delay time occurring in the synchronous retransmission scheme can be reduced by performing retransmission asynchronously in a wireless communication system using a multi-hop relay scheme.

Claims (30)

A retransmission method in a relay station of a wireless communication system using a relay scheme, Determining whether an error has occurred in data received from an upper node, Generating a message indicating whether an error occurs in the data; And transmitting the message to the upper node at a time when the node is not in agreement with the upper node, Wherein the generating of the message generates a message indicating whether an error occurs in the data composed of a control message or a header, and the header includes at least one of ACK information and at least one error And NACK information for at least one of the generated data. delete The method according to claim 1, The process of generating the message includes: In the case of generating a message configured in the form of a control message, an ACK type control message including an ACK message for data for which no error has occurred and additional information for the ACK message, a NACK message for data in which an error occurs, And generating a NACK type control message including additional information for the NACK type control message. The method according to claim 1, Wherein the control message includes at least one of unique identifier information of the relay station, unique identifier information of data indicating occurrence of an error, and unique identifier information of the partial data when the data is partial data. The method according to claim 1, Wherein the control message includes at least one of Connection Identifier (CID) information of the RS and Block Sequence Number (BSN) of data indicating whether an error has occurred. The method according to claim 1, Wherein the control message includes at least one of a connection identifier or an RCID (Reduced CID) of the relay station, an ACID (HARQ Channel ID) of data indicating whether an error has occurred, or a SPID (Sub Packet ID) of partial data of the ACID, ≪ / RTI > delete The method according to claim 1, Wherein the header includes at least one of identifier information of the relay station, error occurrence information on at least one data provided from the upper node, repetition of the error occurrence information, and repetition frequency information Lt; / RTI > 9. The method of claim 8, Wherein the header comprises information on whether or not an error has occurred with respect to data provided from the superordinate node, in a form of a bitmap. 10. The method of claim 9, Wherein the header includes a bitmap indicating whether an error occurs in the data according to a sequence of data included in the DL map provided from the superordinate node. The method according to claim 1, Wherein the upper node is a base station or a higher relay station. The method according to claim 1, Transmitting the data to a lower node when an error does not occur in data received from the upper node; And transmitting the ACK message to the upper node when an ACK message is received from the lower node. 13. The method of claim 12, And transmitting the ACK message to the superordinate node, And transmitting the ACK message to the upper node at an agreed time point. 13. The method of claim 12, Checking data for the NACK message when at least one of a NACK message and additional information for the NACK message is received from the lower node; Transmitting at least one of a NACK message for the confirmed data and additional information for the NACK message to the upper node; Further comprising the step of retransmitting the confirmed data to the lower node according to the scheduling information when the retransmission scheduling information is received from the upper node or transmitting the scheduling information to the lower node. 13. The method of claim 12, And the lower node is a lower relay station or a terminal. A relay station apparatus of a wireless communication system using a relay scheme, A receiving unit for receiving data from an upper node, An examining unit for examining whether or not an error has occurred in the received data; A message generator for generating a message including information on whether or not the data is erroneous, And a transmitter for transmitting the message to the superordinate node at a time point not promised to the superordinate node, The message generator generates a message including whether the data is erroneous in the form of a control message or a header, and generates ACK information for at least one data in which no error occurred and at least one data And generates the header-type message including the NACK information. delete 17. The method of claim 16, When the message is configured in the form of a control message, the message generator generates an ACK type control message including an ACK message for data for which no error has occurred, additional information for the ACK message, or a NACK And a NACK type control message including a message and additional information for the NACK message. 17. The method of claim 16, Wherein the message generator generates a message in the form of a control message including at least one of unique identifier information of the relay station, unique identifier information of data indicating occurrence of an error, and unique identifier information of the partial data when the data is partial data, Lt; / RTI > 17. The method of claim 16, Wherein the message generator generates a message in the form of a control message including at least one of Connection Identifier (CID) information of the relay station and BSN (Block Sequence Number) information of data indicating whether an error has occurred Device. 17. The method of claim 16, Wherein the message generation unit is configured to generate the RSID of the relay station based on a connection identifier or an RCID (Reduced CID) of the relay station, an ACID (HARQ Channel ID) of data indicating whether an error has occurred or a SPID (Sub Packet ID) of partial data of the ACID, Wherein the message is a control message in the form of a control message. delete 17. The method of claim 16, The message generation unit may include a header format including at least one of the identifier information of the relay station, the error occurrence information on at least one data provided from the upper node, the repeat occurrence information of the error occurrence information, Lt; RTI ID = 0.0 > message. ≪ / RTI > 17. The method of claim 16, Wherein the message generator generates a header-type message including bitmap information on error occurrence / non-occurrence of data provided from the upper node. 25. The method of claim 24, Wherein the message generator generates a header-type message including a bitmap indicating whether an error occurs in the data according to the order of the data included in the downlink map provided from the upper node. 17. The method of claim 16, Wherein the transmission unit transmits the data to a lower node when an error does not occur in the data provided from the upper node. 27. The method of claim 26, And the lower node is a lower relay station or a terminal. 17. The method of claim 16, Wherein the upper node is a base station or a higher relay station. delete delete

Images