KR20010111637A - Apparatus and Method for Selective Repeat Automatic Repeat reQuest in Wireless Data Transmission System - Google Patents

Abstract

The present invention relates to a wireless data transmission system, and more particularly, to an apparatus and method for managing a Selective Repeat Automatic Repeat reQuest. In the wireless data transmission system according to the present invention, the selective repetitive automatic retransmission request (ARQ) management device is a data communication system for requesting the transmission device to retransmit data frames that are not received by the receiving device. A reception data storage for receiving, a reception time checking apparatus for determining whether at least one or more data frames requested from the retransmission request are received within a predetermined time, and at least one or more data frames not received by inspecting the reception data storage And a control unit for requesting a retransmission of the data transmission apparatus, storing the retransmitted data frame in the reception data storage unit, and requesting the retransmission of the unreceived data again. A receiving method of a data communication system for requesting a transmitting apparatus to retransmit a data frame that has not been received by such a configuration, the method comprising: a first step of storing received data frames in order of receiving the received data; And a second step of requesting the transmitting apparatus to retransmit at least one or more data frames, and a third step of determining whether all of the requested one or more data frames have been received within a predetermined time. Thus, the number of NAK retransmission timers that are unnecessarily maintained and managed to waste system resources can be greatly reduced.

Description

Apparatus and Method for Selective Repeat Automatic Repeat reQuest in Wireless Data Transmission System}

The present invention relates to a wireless data transmission system, and more particularly, to an apparatus and method for managing a Selective Repeat Automatic Repeat reQuest.

In general, Selective Repeat Automatic Repeat reQuest (hereinafter referred to as Selective Repeat ARQ) method is a method of requesting retransmission only for data frames that have not been successfully transmitted to the receiving end. -More efficient than Go ARQ or Go-Back-N.

In addition, since the receiving end waits for retransmission of an error data frame and arranges it according to the frame number, it needs to have a large buffer to store all data frames arriving between them, and a complicated logic circuit for arranging the frame order is required. .

This selective repetitive ARQ scheme is used in the Radio Link Protocol (hereinafter referred to as RLP) in IS-95 or code division multiple access 2000 (cdma2000) systems that support wireless data transmission services. It is explained.

The structure of a transmitter / receiver for the selective iterative ARQ scheme according to the prior art is shown in FIG.

Referring to FIG. 1, data transmitted from the transmitter 101 are sequentially stored in the received data storage 105 in frame units.

Frame-based data stored in the received data storage unit 105 is required to retransmit the data by a selective repeat automatic retransmission request (ARQ) scheme for the frames that were not successfully received under the control of the controller 103.

A negative acknowledgment (NAK) is transmitted from the receiving end 102 to the transmitting end 101 for the lost frame that was not successfully transmitted by the selective repetitive automatic retransmission request (ARQ) scheme. For each NAK, each NAK retransmission timer is activated.

Also, each NAK stop timer for each frame that has not been transmitted after a certain time is activated.

The negative acknowledgment (NAK) retransmission timer and the negative acknowledgment (NAK) interrupt timer are provided in the reception time checking apparatus 104 and are controlled by the controller 103.

The operation principle of the selective iterative ARQ scheme according to the prior art is shown in FIG.

The transmitting end transmits the frames in order according to the serial number of the frame, and the receiving end expects to receive frames sequentially according to the serial number.

Therefore, as shown in FIG. 2, the transmitting end sequentially transmits a frame having a frame number of zero. However, since frame 2 is not received, the receiving end receives frame 3 after receiving frame 1. This means that frame 2 is lost during transmission, so the receiver sends a negative response (NAK # 2) for frame 2. Receiving a negative response (NAK # 2) for this frame 2, the transmitting end retransmits frame 2.

In general, the receiving end drives a negative acknowledgment (NAK) retransmission timer when a negative acknowledgment (NAK # j) for the j-th frame is transmitted.

The NAK retransmission timer increments in frames or time units and expires when this value reaches a certain threshold.

If the requested jth frame does not arrive until the NAK retransmission timer expires, the receiver retransmits a negative response (NAK # j) for the jth frame. After retransmitting the NAK frame, it restarts the NAK retransmission timer and waits for the frame to be received.

According to this principle, a negative acknowledgment (NAK) retransmission timer management scheme according to the prior art is shown in FIG. 3.

Referring to FIG. 3, when data is received at the receiving end (S10), the receiving end determines whether retransmission of an arbitrary frame #j (j is a frame number) is necessary (S11).

If the frame #j is received, the frame #j is stored in the buffer (S12).

However, if frame #j is not received and needs to be retransmitted, a negative acknowledgment (NAK # j) for the frame j is transmitted to the transmitting end, and at the same time, a negative acknowledgment (NAK) retransmission timer is driven. This NAK retransmission timer is driven for each frame requiring retransmission.

This negative acknowledgment (NAK) and the retransmission timer for this negative acknowledgment (NAK) are repeatedly performed for any frame or time unit (S15).

When the transmission frequency i of the NACK transmitted every arbitrary frame or time unit is equal to or greater than the reference number N _th , the NAK interrupt timer is driven (S16), and again. The reception of a random frame #j is checked until the NACK abort timer expires (S17).

If any frame #j is not received even after the NAK abort timer expires, the receiver sends this fact to the higher layer.

However, in this selective repeat ARQ scheme, continuous frames may be simultaneously lost when the radio channel is in poor condition.

As shown in FIG. 4, when frame 8 is received due to a problem on the channel after receiving frame 1, the receiver thinks that frames 2 to 7 are lost during transmission, and a negative response requesting retransmission of these frames. Send (NAK).

At this time, six NAK retransmission timers are simultaneously driven and expire at the same time.

This separate management of timers that are started and expired at the same time causes a waste of system resources.

Accordingly, an object of the present invention has been made in view of the above-mentioned problems of the prior art, and it is possible to stop one NAK retransmission timer or one NAK for multiple NAKs. An object of the present invention is to provide an apparatus and method for managing a Selective Repeat Automatic Repeat reQuest in a wireless data communication system that provides an efficient system resource only by using a timer.

According to an apparatus feature of the present invention for achieving the above object, in a data communication system for requesting a transmitting apparatus to retransmit a data frame not received by a receiving apparatus, receiving data storage for receiving an ordered data frame And a reception time confirmation device for determining whether all of the at least one data frame requested from the retransmission request have been received within a predetermined time, and retransmission of at least one data frame not received by inspecting the reception data storage unit. And a control unit for storing the requested and retransmitted data frame in the received data storage unit and requesting the retransmitted data not received again.

Preferably, the reception time confirmation apparatus is composed of one timer for checking a predetermined time from a retransmission request time and a determination device for checking reception of a frame for which retransmission is requested within the predetermined time.

A receiving method of a data communication system for requesting a transmitting apparatus to retransmit a data frame that has not been received by such a configuration, the method comprising: a first step of storing received data frames in order of receiving the received data; And a second step of requesting the transmitting apparatus to retransmit at least one or more data frames, and a third step of determining whether all of the requested one or more data frames have been received within a predetermined time.

Preferably, when all data is not received in the third step, the first step and the third step are repeated, and the time measurement of the third step is performed by one timer.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram of a transmitting / receiving apparatus for a selective repetitive automatic retransmission request (ARQ) according to the prior art.

2 is a diagram illustrating the principle of a selective repeat automatic retransmission request (ARQ) method according to the prior art.

3 is a flowchart illustrating a negative acknowledgment (NAK) retransmission timer management scheme according to the prior art.

4 is a diagram illustrating a structure of a receiving end buffer for managing a negative acknowledgment (NAK) retransmission timer according to the related art.

5 is a diagram illustrating the principle of an optional repeated automatic retransmission request (ARQ) method in accordance with the present invention.

6 is a block diagram of a transmitting and receiving apparatus for an optional repeated automatic retransmission request (ARQ) according to the present invention.

* Description of the symbols for the main parts of the drawings *

201: transmitting end

202: receiving end

203: control unit

204: reception time confirmation device

205: reception data storage unit

206: negative response retransmission timer

207: Abort Stop Timer

208: Discrimination Device

The present invention proposes an apparatus and method for selectively repeating ARQ management by providing only one negative acknowledgment (NAK) retransmission timer for a plurality of simultaneous negative acknowledgments (NAKs).

In addition, the present invention proposes an apparatus and method for selectively repeating ARQ management by providing only one negative response (NAK) stop timer for a plurality of simultaneous negative responses (NAK).

A NAK list is constructed to use one NAK retransmission timer or NAK interrupt timer for the plurality of NACs that have occurred simultaneously.

In the NAK list, the serial number of the frame for which retransmission is requested, and the states of the NAK retransmission timer and the NAK stop timer are recorded, and when the requested frame is received, it is deleted from the list.

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

5 is a diagram illustrating the principle of an optional repeated automatic retransmission request (ARQ) method according to the present invention.

Referring to FIG. 5, when frames 0 and 1 arrive at the receiver, and the channel environment of the receiver is deteriorated and frames 8 are received, the receiver is 2, 3, 4, 5, 6, 7 It is determined that frame has been lost.

Therefore, the receiver sends respective negative responses (NAK # 2, # 3, # 4, # 5, # 6, # 7) for the lost frames, and at the same time, each negative response (NAK # 2). One negative response (NAK) retransmission timer is started for #, # 3, # 4, # 5, # 6, and # 7.

If only 3, 5 frames arrive before the NAK retransmission timer expires, NAK for frames 2, 4, 6 and 7 after expiration of the NAK retransmission timer Retransmit, and at the same time restart the NAK retransmission timer. In this case, it is managed by one NAK retransmission timer.

Retransmission of the negative acknowledgment (NAK) for the lost frames is repeated a certain number (N _th ) every frame or time unit.

For the frames that have not been received after the predetermined number of times N _th , a negative acknowledgment (NAK) is finally transmitted to the transmitting end, and at the same time, a negative acknowledgment (NAK) stop timer is driven. In this case, one NAK abort timer is driven for the plurality of lost frames.

Like the NAK retransmission timer, the NAK stop timer is incremented by frame or time unit and one NAK stop timer for a plurality of frames is driven.

Even after the NAK stop timer expires, frames not received are notified to the upper layer, and the arrived frames are stored in the received data storage.

Frames for which retransmission is requested through the negative acknowledgment (NAK) are managed by a negative acknowledgment (NAK) list.

In the NAK list, the serial number of the frame for which retransmission is requested, and the states of the NAK retransmission timer and the NAK stop timer are recorded, and when the requested frame is received, it is deleted from the list.

The NAK list is configured as shown in Table 1 below.

Timer Identifier Serial number of the frame where the NAK was sent 001 Ox300 Ox301 Ox303 ... ...

According to the above principle, a block diagram of a transmitter and receiver for an optional repeated automatic retransmission request (ARQ) according to the present invention is shown in FIG.

Referring to FIG. 6, a configuration of a transmitting / receiving end for an optional repetitive automatic retransmission request (ARQ) includes a transmitting end 201 for transmitting data, a receiving end 202 for receiving the data, and a transmission from the transmitting end 201. A reception data storage unit 205 for storing the received data in units of frames, and a controller 203 for checking a frame number stored in the reception data storage unit 205 and controlling a retransmission request for a frame that has not been successfully received. And a timer driving for a negative response (NAK) to the retransmission request of the controller, and a reception time checking device 204 for checking a data frame received within a predetermined time of the timer.

The reception time checking apparatus 204 may include one negative acknowledgment (NAK) retransmission timer 206 for one or more frames that have not been received, and one negative response for one or more frames that have not been received after a predetermined time. NAK interrupt timer 207, and a discrimination apparatus 208 for checking a data frame received within a predetermined time of the NAK retransmission timer 205 and NAK interrupt timer 206. .

Accordingly, when data is received at the receiving end 202, the receiving end 202 determines whether retransmission of a plurality of frames #j, #k, # ... (where j and k are frame numbers) is necessary.

If the plurality of frames #j, #k, # ... are received, the frames #j, #k, # ... are stored in the received data storage unit 205 in frame units. .

However, if frames #j and #k are not received among the plurality of frames (#j, #k, # ...) and need retransmission, a negative response to the frames j and K (NAK # j) is required. NAK # k is transmitted to the transmitter 202, and at the same time, one NAK retransmission timer 206 for the plurality of frames is driven.

Such a negative acknowledgment NAK and the retransmission timer 206 for this negative acknowledgment NAK are repeated every arbitrary frame or time unit.

When the frames #j and #k lost within the frame or time unit of the NACK retransmission timer 206 are received, the received frame is stored in the reception data storage unit 205.

However, if the reception of any of the frames #j, #k is not received during the frame or time unit of the NAK retransmission timer 206, these frames (frames #j, #k) are negative. (NAK) Listed.

The frames included in the NAK list are retransmitted to the NAK, and at the same time, one NAK retransmission timer 206 is driven.

It is checked whether the corresponding frame of the negative acknowledgment (NAK) transmitted from the receiving end 202 is received until the retransmission timer 206 expires.

If the corresponding frame of the negative acknowledgment NAK has not been received, the receiving end 202 retransmits the negative acknowledgment NAK again. At this time, when checking the number of times of retransmission (i) that is, the retransmission number of times (i) a reference number (N _th) of a negative acknowledgment (NAK) negative acknowledgment (NAK) retransmission timer of a negative acknowledgment (NAK) in which the transmission ( Instead, the NAK abort timer 207 is driven.

Like the NAK retransmission timer 206, the NAK stop timer 207 is incremented by frame or time unit and one NAK stop timer 207 for a plurality of frames is stored. Driven.

Even after the NAK abort timer 207 expires, frames not received are notified to the upper layer, and the received frames are stored in the reception data storage unit 205.

The determination device 208 determines whether data frames are received within a predetermined period of the NAK retransmission timer 206 or the NAK stop timer 207.

As described above, the present invention can significantly reduce the number of NAK retransmission timers that are unnecessarily maintained and managed to waste system resources.

In particular, it is more efficient in the case of continuous frame loss that can occur in a wireless environment, the complexity does not increase compared to the conventional method.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the examples, but should be defined by the claims.

Claims (5)

A data communication system for requesting a transmitting device to retransmit a data frame not received at a receiving device, A reception data storage unit for receiving an ordered data frame; A reception time checking apparatus for determining whether at least one data frame has been received within a predetermined time from a retransmission request time point; And a controller for inspecting the received data storage unit to request retransmission of at least one or more unreceived data frames to the transmitter, storing the retransmitted data frames in the received data storage unit, and requesting retransmission of unreceived data. Optional repeat automatic retransmission request management apparatus in a wireless data communication system, characterized in that made. The apparatus of claim 1, wherein the reception time confirmation apparatus comprises one timer for checking a predetermined time from a retransmission request time point and a determination device for checking reception of a frame for which retransmission is requested within the predetermined time. An apparatus for managing selective repetitive automatic retransmissions in a communication system. A receiving apparatus of a data communication system for requesting a transmitting apparatus to retransmit a data frame which has not been received, Storing a received data frame in an ordered sequence; Checking the received data and requesting a transmitting device to retransmit at least one or more unreceived data frames; And a third step of determining whether all of the at least one data frame requested within a predetermined time period have been received. 4. The method of claim 3, wherein if the data is not received in the third step, repeating the first step and the third step. 4. The method of claim 3, wherein the time measurement of the third step is performed by one timer.