KR20060040244A - Efficient Data Transmission and Receiving Method between Terminal and Base Station in Wireless Communication System, Terminal and Base Station - Google Patents

Abstract

In the wireless access communication system, the BS informs that the DCD count has changed due to the change of the DCD burst profile encodings corresponding to the DIUC even before the MSS receives the DCD message so that the MSS can receive the DL traffic smoothly. This prevents the DL traffic reception delay occurring when the MSS receives DCD burst profile encodings corresponding to the updated DIUC.

Sleep mode, sleep window, listening window

Description

Efficient data transmission and reception method between a terminal and a base station in a wireless communication system and the terminal and the base station TECHNICAL FIELD             

1 is a block diagram illustrating a general broadband wireless communication system;

2 is a diagram illustrating a procedure in which an MSS performs a sleep mode;

3 is a diagram illustrating a case where a conventional MSS receives downlink (DL) traffic;

4 is a diagram illustrating a DL traffic processing operation in a terminal when an MSS indicates that a DCD burst profile encoding corresponding to a DIUC has been changed by a DIUC update indicator;

5 is a diagram illustrating a DL traffic processing operation in a terminal when an MSS indicates that a DCD burst profile encoding corresponding to a DIUC is not changed in a DIUC update indicator;

6 is a block diagram of a base station according to an embodiment of the present invention;

7 illustrates a MOB_TRF_IND message according to an embodiment of the present invention.

8 illustrates a DCD burst profile encoding value in a DCD message.                 

9 is a diagram illustrating an operation in a base station according to an embodiment of the present invention;

10 is a block diagram of a terminal according to an embodiment of the present invention;

11 is a view showing an operation in a terminal according to an embodiment of the present invention.

The present invention relates to an efficient data transmission and reception method between a terminal and a base station in a wireless communication system, and a terminal and a base station.

1 is a diagram illustrating a configuration of a general broadband wireless communication system. Referring to FIG. 1, each MSS 10, 12 is generally mobile and is connected to the backbone network 30 via a base station (BS) 20, 22, respectively. The MSS 10, 12 allows access between the BS 20, 22 and the subscriber. Base stations (20, 22) provide control, management, and connectivity to the MSS (10, 12). In addition, the backbone network 30 is connected to an Authentication and Service Authorization Server (ASA) 40 for authentication and service authentication of the MSS 10 and 12.

On the other hand, reducing power consumption is very important for MSS supporting mobility. One way to reduce the power consumption of the MSS is to adopt a sleep mode. In the sleep mode, the MSS stops all functions other than the real time clock (RTC) and phase locked loop (PLL), such as the transmit function and the receive function. At this point, the PLL is active so that it can be restarted. In the sleep mode, the MSS periodically wakes up to perform searching and ranging or handover of neighbor BSs. Broadband wireless communication systems, such as the IEEE 802.16e system, utilize this sleep mode to reduce the power consumption of the MSS and allow the MSS to make handover decisions more smoothly.

In more detail, the MSS entering the sleep mode experiences a sleep window and a listening window. The MSS may stop transmitting and receiving data during the frame corresponding to the sleep period, reduce its power, and sometimes return to an awake state to perform periodic ranging. I can go. In addition, the MSS entering the listening window must wake up because it needs to decode the TRF-IND (Traffic Indication) message transmitted from the BS and search for the DL traffic. That is, the MSS needs to transition from the sleep mode to the awake state and return to the state where reception is possible.

The BS should deliver the traffic indication to the MSS using the broadcast CID (broadcast) during the listening window for the terminal in the sleep mode managed by the BS. Accordingly, when the BS receives the incoming data for a specific MSS operating in the sleep mode, the BS may reach the listening window of the MSS and buffer the DL traffic until the listening window expires. You can, of course, drop such incoming data. Hereinafter, a procedure in which the MSS performs a sleep mode will be described with reference to FIG. 2.                         

2 is a diagram illustrating a procedure in which an MSS performs a sleep mode.

Referring to FIG. 2, the MSS 10 first transmits a MOB-SLP-REQ message to the BS 20 in step 60 so that it can enter a sleep mode. Upon receiving the MOB-SLP-REQ message, the BS 20 transmits a MOB-SLP-RSP message indicating that the MSS 10 is allowed / denied to enter the sleep mode in step 62. The MSS 10 enters the sleep mode upon receiving the MOB-SLP-RSP message from the BS 20. As described above, the MSS 10 repeatedly experiences the sleep window 70 and the listening window 72 in the sleep mode.

Subsequently, BS 20 adjusts to step 64 according to the listening window 72 of corresponding MSS 10 according to the sleepmode pattern negotiated through the MOB-SLP-REQ / MOB-SLP-RSP message. In step 66, the BS 20 informs that there is a corresponding MSS-related message and DL traffic buffered in the MOB-TRF-IND message. At this time, the BS 20 first transmits the DL-MAP to the MSS 10 before transmitting the MOB-TRF-IND message in the listening window. The DL-MAP describes the reception interval in time of each MSS, and the MSSs can know the time interval for receiving data by this DL-MAP.

When the MSS 10 receives the MOB-TRF-IND message, the MSS 10 sees the MOB-TRF-IND message, and if there is a message and DL traffic related to the MSS 10, the MSS 10 transitions to the awake state and becomes available to receive.

Meanwhile, in the broadband wireless communication system, adaptive modulation and coding (AMC) that adaptively applies modulation and coding techniques according to channel conditions between BSs 20 and 22 and MSSs 10 and 12 in each cell 50 and 52. Adopt the method. Accordingly, when the MSS 10, 12 transmits the channel state information to the BS 20, 22, the BS 20, 22 determines the modulation scheme and the coding scheme according to the channel situation to the MSS 10, 12, respectively. You will be informed. BS 20,22 and MSS 10,12 communicate according to the modulation and coding schemes determined in this way. The MSS 10, 12 processes data according to the modulation scheme and the coding scheme determined by the BS 20, 22. In this modulation scheme and coding scheme, the BS 20,22 informs the MSS 10, 12 through a Downlink Channel Descriptor (DCD) message. The DCD message is information indicating a DL channel status and is a broadcast message including an AMC table and system parameters. Information on modulation schemes and coding schemes is included in the AMC table. Downlink Interval Usage Code (DIUC) is an AMC index indicating modulation scheme and coding scheme.

The BS 20, 22 does not transmit the DCD message every frame, but transmits the MSD 10, 12 aperiodically within a predetermined range. Since the DCD message is changed according to channel conditions, a DCD count value for distinguishing each DCD message exists. The DCD count value is included in the DL-MAP and transmitted to the MSS 10, 12. Accordingly, since the MSS 10 and 12 receive the DL-MAP for each listening window, the MSS 10 and 12 may determine whether the DCD message is changed by looking at the DCD count value. In detail, the MSS 10 and 12 determine that the DCD message is changed when the DCD count value obtained in the previous listening window is different from the DCD count value received in the current listening window. In other words, during the sleep mode operation, the MSS 10 decodes the DL-MAP received from the base station during every listening window and maintains information about the DCD count value. However, the MSS 10, 12 may not know whether the change of this DCD message is caused by updating the DCD burst profile encodings corresponding to the DIUC. In other words, since the DCD burst profile encodings, which are indicators for the UE to operate in the AMC scheme, are set in the DCD message, the DCD count changes when the value is changed. In addition, the DCD count is changed even if a portion of the DCD message other than the DCD burst profile encodings value is changed. Therefore, the MSS 10, 12 may not know what part of the DCD message has changed until it receives a new DCD message.

In sleep mode, not only continuous DCD message reception is possible, but also due to the aperiodic transmission of the DCD message, it is difficult to match the sleep window and its period. Furthermore, since the transmission is performed after a maximum of 10 seconds in the case of the DCD message, when the DCD count is changed in the sleep window, the terminal entering the awake interval must wait for the transmission of the DCD message from the base station for up to 10 seconds. The prior art terminates the sleep mode and receives DL traffic when there is DL traffic for the UE by the MOB-TRF-IND message. If the DCD / UCD count changes during the sleep window, the UE cannot know what part of the DCD has changed until a new DCD message is received. Therefore, if the UE transitions to the normal mode to receive DL traffic under the assumption that the DCD count has changed, the DCD burst profile encodings value corresponding to the previously used DIUC is not correct. Maybe not. After all, when receiving the DL traffic based on the DCD burst profile encodings value corresponding to the wrong DIUC, the UE will not properly decode the DL traffic, which leads to continuous data loss. Furthermore, since the base station does not respond with ACK / NACK to the traffic received by the terminal, it determines that the transmission has not been properly performed and attempts to retransmit. This not only causes a waste of radio resources on the base station side, but also generates a situation in which power needs to be wasted for the retransmission request of data on the terminal side.

3 is a diagram illustrating a case where a conventional MSS receives DL traffic (downlink traffic).

Referring to FIG. 3, the MSS 10 and 12 first receive a DL-MAP in a listening window and then receive a MOB_TRF_IND message. When the MSS 10, 12 determines that there is DL traffic (downlink traffic) to be received with reference to the MOB_TRF_IND message, the MSS 10, 12 terminates the sleep mode and enters the normal mode to receive the DL traffic. However, if the DCS count value included in the received DL-MAP is different from the DCD count value recognized before the sleep mode, the MSS 10, 12 receives the DL until the MSS 10, 12 acquires the updated DCD message. The traffic cannot be received, resulting in a data loss interval T. If the UE knows in advance that the above-described change factor of the DCD count value is not due to the change of the DCD burst profile encoding value corresponding to the DIUC, the above-described DL traffic transmission delay can be prevented.

Accordingly, the present invention provides a notification that the DCD count value is changed due to the change of the DCD burst profile encodings corresponding to the DIUC so that the UE can receive the DL traffic in advance, so that the UE has the DCD burst corresponding to the updated DIUC. A method for improving the delay of receiving DL traffic to receive profile encodings is provided.

The present invention also provides a method for reducing the loss interval of the received data according to the reception delay of the DCD message in a base station or a mobile terminal of a wireless communication system, and a base station and a terminal therefor.

To this end, in at least one base station communicating with a predetermined terminal in a wireless access communication system according to an embodiment of the present invention, if any one of a modulation method and a coding method of downlink traffic is changed, a DIUC (Downlink Interval Usage) for indicating this Code) includes a MOB_TRF_IND message generating unit for generating a MOB_TRF_IND message, including an update indicator, and a transmitter for transmitting the MOB-TRF-IND message.

In addition, in a wireless access communication system according to an embodiment of the present invention, the terminal communicating with the base station includes a MOB_TRF_IND message including a Downlink Interval Usage Code (DIUC) update indicator indicating that any one of a modulation technique and a coding technique of downlink traffic has been changed. And a FEC code type setting unit configured to set its own FEC code type with reference to the MOB_TRF_IND message.

In the wireless access communication system according to an embodiment of the present invention, a generation unit for generating a MOB_TRF_IND message including a Downlink Interval Usage Code (DIUC) update indicator to indicate that the modulation or coding technique of the downlink traffic has been changed; And a transmitter for transmitting the MOB_TRF_IND message. More preferably, the MOB-TRF_IND message further includes an FEC code type field for indicating a modulation or code type for downlink traffic to be transmitted later. In addition, the embodiment of the present invention further includes a device for receiving the MOB_TRF_IND message to check the Downlink Interval Usage Code (DIUC) update indicator, DL by checking the Downlink Interval Usage Code (DIUC) update indicator of the MOB_TRF_IND message, If it is determined that the modulation or coding technique of the traffic has been changed, the apparatus may further include a device for decoding the DL traffic with reference to the FEC code type field.

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

In an embodiment of the present invention, the MSS is notified of the updated DIUC by notifying that the DCD count has changed due to the change of the DCD burst profile encodings corresponding to the DIUC even before the MSS receives the DCD message so that the MSS can receive DL traffic smoothly. Do not delay receiving DL traffic to receive corresponding DCD burst profile encodings.

Specifically, according to an embodiment of the present invention, the BS includes a DIUC update indicator in the MOB-TRF-IND message to inform the MSS that the DCD count has changed due to a change in the DCD burst profile encodings corresponding to the DIUC. The DIUC update indicator indicates that the Adaptive Modulation and Coding (AMC) table in the DCD message has been changed, that is, the DIUC has been changed. For example, the DIUC update indicator has two values, one of which indicates that the DCD count has been updated by a change in the DCD burst profile encodings value corresponding to the DIUC, and the other value of the DIUC update indicator has a DCD burst whose DCD count corresponds to the DIUC. Indicates no change in relation to the profile encodings value. The BS also includes the modulation and coding scheme information used by the MSS to receive and process downlink traffic in the MOB-TRF-IND message. The modulation scheme and coding scheme information included in the MOB-TRF-IND message are represented by a DIUC-FEC code type pair value according to an embodiment of the present invention. The DIUC-FEC code type pair consists of a DIUC value and an FEC code type value corresponding to the DIUC.

On the other hand, when the MSS receives the DL-MAP and MOB-TRF-IND messages from the BS in the listening window, the MOB-TRF if the DCD count of the received DL-MAP is different from the DCD count of the DL-MAP received in the previous listening window. Refer to DIUC update indicator included in -IND message. If the MSS refers to the DIUC update indicator and the value is set to 1, the MSS determines that the DCD count has been updated by changing the DCD burst profile encoding value corresponding to the DIUC, and the DIUC-FEC code type pair in the MOB-TRF-IND message. Receive DL traffic by referring to the value. That is, the MSS does not receive DL traffic based on the DCD burst profile encodings value corresponding to the previously used DIUC. Instead, the MSS transmits DL traffic transmitted from the base station in the modified MOB-TRF-IND message until the DCD is received again. Received based on DIUC-FEC code type pair value. The BS may begin transmitting to the MSS in order of smallest data size, which may continue until the MSS receives the DCD message. When the MMS receives the DCD message, it receives DL traffic based on the DCD burst profile encodings corresponding to the newly updated DIUC, and then normal data is received.

First, referring to FIGS. 4 and 5, a case in which the MSS receives DL traffic with reference to the DIUC update indicator will be described according to an embodiment of the present invention.

4 is a diagram illustrating a case in which an MSS receives DL traffic when a DIUC update indicator indicates that a DCD burst profile encoding corresponding to a DIUC has been changed according to an embodiment of the present invention. FIG. 5 illustrates a case in which the MSS receives DL traffic when the DIUC update indicator indicates that the DCD burst profile encodings corresponding to the DIUC are not changed according to an embodiment of the present invention.

4 and 5, the MSS receives DL-MAP and MOB_TRF_IND messages for each listening window 1 and listening window 2. The MSS looks at the DCD counter of the received DL-MAP to determine whether the DCD message has changed. 4 and 5, when the MSS determines that the DCD message has changed in the state of receiving the DL-MAP in the listening window 2, the MSS has a DCD count value (DCD count = N) obtained in the listening window 1, which is the previous listening window. The DCD count value (DCD count = N + 1) received in the listening window 2 which is the current listening window is compared. The MSS determines that the DCD message has been changed if the previous DCD count value is different from the current DCD count value, and if it is the same, the MSS determines that the DCD message has not been changed.                     

When the MSS determines that the DCD message has been changed, the MSS determines whether the Adaptive Modulation and Coding (AMC) table in the DCD message has been changed, that is, whether the DCD burst profile encoding value corresponding to the DIUC has been changed by looking at the DIUC update indicator of the MOB_TRF_IND message. do. The DIUC update indicator has two values. In FIG. 4 and FIG. 5, the value 1 indicates that the DCD count is updated by changing the DCD burst profile encodings value corresponding to the DIUC, and the value 0 indicates the DCD burst with the DCD count corresponding to the DIUC. Indicates no change in relation to the profile encodings value.

Meanwhile, the MSS refers to the MOB_TRF_IND message to determine whether there is download traffic that it should receive. The MSS may determine that there is data to be downloaded to itself by looking at the traffic indication bit of the MOB_TRF_IND message. When the MSS determines that there is data to be downloaded, the MSS terminates the sleep mode, transitions to the normal mode, and receives the corresponding download traffic from the BS.

In this case, when the MSS determines that the DIUC of the DCD message is changed by performing the operation as stated above, the MSS receives the download traffic based on the DIUC-FEC code type pair value in the MOB-TRF-IND message. That is, the MSS does not receive DL traffic based on the DCD burst profile encodings value corresponding to the previously used DIUC, and modifies the DL traffic transmitted from the base station until the DCD message is received again. Received based on DIUC-FEC code type pair value. The base station sets the DIUC-FEC code type pair value included in the MOB-TRF-IND message based on the DCD burst profile encodings in the most recently transmitted DCD message. After receiving the DCD message, the MMS receives DL traffic based on the DCD burst profile encodings corresponding to the newly updated DIUC, and then normal data is received.

Referring to FIG. 4, the MSS receives the download traffic based on the DIUC-FEC code type pair value in the MOB-TRF-IND message in the section indicated by a, and is newly updated in the section indicated by b after receiving the DCD message. DL traffic is received based on the DCD burst profile encodings corresponding to the DIUC. Of course, when the MSS receives the DCD message in the listening window 2, the DLS may receive DL traffic based on the DCD burst profile encoding value corresponding to the DIUC currently received regardless of the DIUC update indicator value.

The MSS receives the download traffic based on the DCD burst profile encoding value of the previously received DCD message when the DCD count is updated when the download traffic is received, but the DCD count is not related to the DIUC according to the DIUC update indicator. .

Referring to FIG. 5, the MSS receives download traffic based on a DCD burst profile encoding value of a previously received DCD message in the period indicated by c and newly updated DIUC in the period indicated by d after receiving the DCD message. DL traffic is received based on the corresponding DCD burst profile encodings. When the MSS receives the DCD message in the listening window 2, the DLS may receive DL traffic based on the DCD burst profile encoding value corresponding to the currently received DIUC regardless of the DIUC update indicator value. Next, the configuration and operation of the base station according to the embodiment of the present invention will be described.                     

6 is a block diagram of a base station according to an embodiment of the present invention. Referring to FIG. 6, a base station 600 according to an embodiment of the present invention includes a DL-MAP generator 620, a MOB-TRF-IND message generator 630, and a transmitter 64.

The base station 600 receives the channel state information from the terminal to adaptively determine the modulation technique and the coding technique, and transmits the determined modulation technique and the coding technique to the terminal through the DCD message. In this case, the base station 600 describes modulation and coding technique information through DCD burst profile encodings of the DCD message.

When the DCD message is generated, the MOB-TRF-IND message generator 630 of the base station 600 determines whether the DIUC burst profile encodings corresponding to the DIUC, which is a table index indicating a modulation scheme and a coding scheme, are changed in the AMC table of the DCD message. To judge. The MOB-TRF-IND message generator 630 may indicate that the DCD count has changed due to a change in the DCD burst profile encodings corresponding to the DIUC when the DCD burst profile encodings corresponding to the DIUC have been changed. Include the DIUC update indicator in the IND message. The DIUC update indicator has two values. One of the two values indicates that the DIUC count has been updated by changing the DCD burst profile encodings corresponding to the DIUC, and the other value indicates that the DIUC count has not been changed with respect to the DCD burst profile encodings corresponding to the DIUC.

The MOB_TRF_IND message generator 630 generates a MOB_TRF_IND message including a DIUC update indicator. In addition, the MOB_TRF_IND message generator 630 includes the modulation scheme and code scheme information for downlink traffic to be transmitted in the MOB_TRF_IND message. The modulation scheme and coding scheme information included in the MOB-TRF-IND message is a DIUC-FEC code type pair consisting of a DIUC value and an FEC code type value corresponding to the DIUC. FIG. 7 illustrates a MOB_TRF_IND message and FIG. 8 illustrates DCD burst profile encodings in a DCD message.

Referring to FIG. 7, the MOB_TRF_IND message according to an embodiment of the present invention includes a DIUC update indicator field 670. In the embodiment of FIG. 7, the DIUC update indicator is 1 bit and indicates that the DCD count has been updated by a DCD burst profile encodings change corresponding to the DIUC or that the DCD count is not updated by a DCD burst profile encodings change corresponding to the DIUC. In addition, the MOB_TRF_IND message according to an embodiment of the present invention is a DIUC-FEC code type pair field 674 for indicating a modulation or code type for downlink traffic to be transmitted later, and whether each terminal has downlink traffic or not. Including a field 676 to inform.

A total of 9 bits of the DIUC-FEC code type pair value 674 indicates a DIUC value from the Most Significant Bit (MSB) to 4 bits, and the remaining lower 5 bits indicate an FEC code type corresponding to the DIUC. For example, in case of 001000010, the FEC code type corresponding to DIUC No. 2 is changed to FEC code type No. 2 (16-QAM (CC) 1/2) as shown in FIG. 7. At this time, the DIUC value and the corresponding FEC code type value are set based on DCD burst profile encodings in the DCD message most recently transmitted by the base station.

In addition, the MOB_TRF_IND message includes a value indicating how many FEC code types associated with the DIUC to be used by the UE have changed. This is N_DIUC_updates value 676 in FIG. 7.

For example, if the terminal receives a DCD message with DCD count = N at the last frame of the listening window, goes to sleep window, wakes up at the first frame of the next listening window and sees the DCD count as N + 1. Assume that

If the base station transmits a DCD message corresponding to DCD count = N + 1 because the FEC code type associated with the DIUC has been changed when the DCD count = N + 1 is compared with the case where the DCD count = N (DIUC update indicator = 1), follow the steps below.

First, the base station 600 checks how many FEC code types related to the DIUC used by the terminal in the sleep mode have changed. For example, if a total of 11 DIUCs are assigned to the UEs in the sleep mode, 7 DIUCs and 3 of them are changed compared to the case where DCD count = N, N_DIUC_updates becomes 3. Here, the total number of DIUCs can be used by all terminals, and the number of DIUCs to be used by terminals in sleep mode is limited to a value smaller than the total number of DIUCs because terminals performing sleep mode operations are a subset of all terminals. will be. In addition, the number of DIUCs that can be used by all terminals can be changed. Therefore, it is apparent that the present invention is not limited to this specific DIUC number value.

If the N_DIUC_updates value 672 is 3, the FEC code type for each DIUC in the DCD message corresponding to DCD count N + 1 for the DCD message corresponding to DCD count N is changed as shown in Table 1 below. do.

Before change after change DCD count N DCD count N + 1 DIUC 1 FEC code type 1 (QPSK (CC) 3/4) DIUC 3 FEC code type 5 (64-QAM (CC) 3/4) DIUC 6 FEC code type 7 (QPSK (BTC) 3/4) DIUC 1 FEC code type 2 (16-QAM (CC) 1/2) DIUC 3 FEC code type 4 (64-QAM (CC) 2/3) DIUC 6 FEC code type 8 (16-QAM (BTC) 3/5)

The MOB-TRF-IND message generator 630 of the base station 600 adds a message field to the MOB-TRF-IND message as follows.

N_DIUC_updates 3

for (i = 0; i <3; i ++) {

DIUC 1 FEC code type 2 (16-QAM (CC) 1/2) 000100010

DIUC 3 FEC code type 4 (64-QAM (CC) 2/3) 001 100 100

DIUC 6 FEC code type 8 (16-QAM (BTC) 3/5) 01 100 1000

The MOB_TRF_IND message generation unit 630 includes information 676 indicating whether there is downlink traffic in each terminal in the MOB_TRF_IND message.

The DL_MAP generation unit 620 generates a DL_MAP including the DCD message count value. As mentioned above, the DCD count value identifies each DCD message. Thus, when the DCD message changes, the DCD count value also changes. The DL_MAP generation unit 620 receives the DCD count value whenever a DCD message is generated. The DL_MAP 620 generator 620 generates a DL_MAP including the provided DCD count value and provides the DL_MAP to the transmitter 640.                     

Then, since the base station 600 does not transmit the DCD message until the terminal enters the normal mode and receives the DL traffic, the base station 600 starts transmitting to the MSS in order of decreasing data size, which is the MSS. Lasts until a DCD message is received.

On the other hand, the configuration of the base station according to the embodiment of the present invention described above can be changed by those skilled in the art. For example, the DL-MAP generator 620 and the MOB_TRF_IND message generator 630 may be implemented as one component having these functions. Alternatively, each component of the base station according to the embodiment of the present invention may be divided into functional blocks for performing an operation. Therefore, the present invention is not limited by the base station configuration according to the above-described embodiment.

Next, the operation of the base station according to the embodiment of the present invention will be described.

9 is a diagram illustrating an operation in a base station according to an embodiment of the present invention. In the following description, the base station 600 is described as interworking with one terminal, but those skilled in the art will understand that the interworking with a plurality of terminals.

Referring to FIG. 8, when a predetermined terminal is in a sleep mode, the base station 600 buffers traffic transmitted to the terminal without transmitting and receiving data with the terminal. In the sleep mode, the sleep window and the listening window are alternately present. The base station 600 determines whether it is a sleep window in step 680. In the sleep mode of the sleep mode, the base station 600 determines whether the contents corresponding to the DIUC, which is a table index indicating a modulation scheme and a coding scheme, are changed in the AMC table of the DCD message in step 682. If the DCD burst profile encodings value corresponding to the DIUC has changed, the MOB_TRF_IND message generator 630 sets the DIUC update indicator to indicate that the DCD count has changed due to the change of the DCD burst profile encodings corresponding to the DIUC in step 684. Create a MOB_TRF_IND message that includes a DIUC update indicator. At this time, the MOB_TRF_IND message generation unit 630 determines how many DIUC-FEC code type pair values, which are modulation or code type information for downlink traffic to be transmitted later, in the MOB_TRF_IND message and how many FEC code types related to the DIUC to be used by the UE are changed. Includes N_DIUC_updates value, which is information indicating. Of course, the MOB_TRF_IND message generator 630 includes information indicating whether there is downlink traffic in each terminal in the MOB_TRF_IND message.

Subsequently, the base station 600 determines whether a listening window has been reached in step 686. If the listening window arrives, the base station 600 proceeds to step 688 and transmits DL-MAP and MOB_TRF_IND messages to the terminal through the transmitter 640.

Next, the configuration and operation of the terminal according to an embodiment of the present invention will be described.

10 is a block diagram of a terminal according to an embodiment of the present invention. Referring to FIG. 10, the terminal 700 according to the embodiment of the present invention includes a transceiver 710, a DIUC change determination unit 720, and an FEC code type setting unit 730. The terminal 700 transmits channel state information to the base station 600 through a transmitter (not shown). The terminal 700 alternately repeats the sleep window and the listening window in the sleep mode.

Referring to FIG. 10, the terminal 700 receives a DL-MAP and a MOB-TRF-IND message from the BS through a transceiver 710 in a listening window. Then, the DIUC change determination unit 720 of the terminal 700 determines whether the DCD count of the received DL-MAP is different from the DCD count of the DL-MAP received in the previous listening window, and in other cases, the DCD count value is changed. . If the DCD count value is changed, the DIUC change determination unit 720 determines whether the DCD count is updated by changing the DCD burst profile encodings value corresponding to the DIUC, referring to the DIUC update indicator included in the MOB-TRF-IND message. do. If the DCD count is updated by the change of the DCD burst profile encodings corresponding to the DIUC, the FEC code type setting unit 730 sets its FEC code type according to the FEC code type in the MOB-TRF-IND message.

Specifically, the FEC code type setting unit 730 sets its FEC code type by referring to the N_DIUC_updates value and the DIUC-FEC code type pair value of the MOB-TRF-IND message. For example, when the DCD message is changed as shown in Table 1, the FEC code type setting unit 730 refers to the N_DIUC_updates value and the DIUC-FEC code type pair value of the MOB-TRF-IND message, and the FEC for the DIUC 1,3,6. If it is determined that the code type has changed, it does not apply the FEC code type corresponding to the DIUC in the previously received DCD message (where the previous is the listening window with DCD count = N). The FEC code type for 6 applies.

If the FEC code type setting unit 730 receives a new DCD message, the FEC code type setting unit 730 sets its FEC code type according to the DCD burst profile encodings corresponding to the DIUC. When the terminal 700 determines that there is DL traffic to be received with reference to the MOB_TRF_IND message, the terminal 700 enters a normal mode and receives DL traffic based on the configured FEC code type.

When the terminal 700 determines that the modulation or coding technique of DL traffic is changed by checking a downlink interval usage code (DIUC) update indicator of the MOB_TRF_IND message, the apparatus for decoding DL traffic by referring to the FEC code type field (Not shown).

On the other hand, the configuration of the terminal according to the embodiment of the present invention described above can be changed by those skilled in the art. For example, the DIUC change determination unit 720 and the FEC code type setting unit 730 receive a MOB_TRF_IND message and inspect the downlink interval usage code (DIUC) update indicator and DL traffic according to the FEC code type according to the inspection result. It can be replaced by a device that decodes. Therefore, the present invention is not limited by the terminal configuration according to the above-described embodiment.

11 is a diagram illustrating an operation in a terminal according to another embodiment of the present invention. Referring to FIG. 11, when the terminal 700 receives the DL-MAP and MOB-TRF-IND messages in a listening window in the sleep mode, the terminal 700 determines whether the DCD count of the DL-MAP has changed in step 810. At the same time, the terminal 700 determines whether there is download traffic to be transmitted to itself by referring to the MOB_TRF_IND message, that is, whether the traffic indicator is positive. If there is no change of the DCD counter and the traffic indicator indicates negative (00), the terminal 700 proceeds to step 820 to maintain a sleep state after ending the listening window. If there is no change of the DCD counter and the traffic indicator indicates a positive value (01), the terminal 700 proceeds to step 830 to end the listening window and enter the normal mode. Subsequently, the terminal 700 receives DL traffic based on the DCD burst profile encoding value of the DCD message previously received in step 831, that is, the FEC code type of DIUC already known or set.

If the DCD counter has changed and the traffic indicator indicates negative, the terminal 700 proceeds to step 840 to end the listening window and maintains an awake state at step 842. The terminal 700 waits for the reception of the new DCD message in step 844. If the DCD message is received, the terminal 700 proceeds to step 846 to maintain a sleep state. Since the terminal 700 knows that the DCD message has been changed through the DCD counter, the terminal 700 maintains an awake state until the DCD message is received even in the sleep mode.

Lastly, if the DC 700 has changed the DCD counter and the traffic indicator indicates a positive value, the terminal 700 proceeds to step 850 in which the DCD count corresponds to the DIUC by referring to the DIUC update indicator included in the MOB-TRF-IND message. Determines whether the DCD burst profile encodings have been updated.

Subsequently, if the DCD count is updated by changing the DCD burst profile encodings value corresponding to the DIUC, the terminal 700 selects its FEC code type according to the DIUC-FEC code type pair value in the MOS-TRF-IND message in step 852. Set it. Subsequently, the terminal 700 terminates the listening window in step 854 and enters a normal mode. Subsequently, the terminal 700 receives DL traffic with the corresponding FEC code type in step 856.

 Here, the FEC code type is the FEC code type signaled by MOB-TRF-IND when DIUC update indicator = 1, and the FEC code type that is mapped to the corresponding DIUC previously known when DIUC update indicator = 0.

Subsequently, the terminal 700 determines whether to receive a DCD message from the base station in step 858. In case of receiving the DCD message, the terminal 700 proceeds to step 860 and sets its FEC code type according to the DCD burst profile encodings value corresponding to the DIUC in the received DCD message. The terminal 700 receives DL traffic based on the FEC code type set in step 862.

In the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

As described above, according to the present invention, the base station can minimize data loss caused by the base station transmitting data to the terminal while waiting for the DCD message, and can eliminate the retransmission procedure caused by the terminal not receiving the data correctly. It reduces DL traffic buffering overhead and improves the efficiency of radio resource usage of the terminal.

In addition, according to the present invention, the DCD count is updated due to the change of the DCD burst profile encodings value corresponding to the DIUC and the FEC code type is informed in advance, thereby inducing smooth DL traffic reception. In addition, when the DCD count is updated by changing a value other than the DCD burst profile encodings value corresponding to DIUC, DL traffic can be normally received using the DCD burst profile encodings value corresponding to the previously known DIUC. Furthermore, unnecessary power consumption that occurs because the terminal performs a request for retransmission of unreceived data is prevented.

 Therefore, the present invention generally has an effect in that the terminal smoothly performs the AMC operation related to data reception in the sleep state and thereby maximizes the efficiency of radio resources.

Claims (35)

In at least one base station for communicating with a predetermined terminal in a wireless access communication system, A MOB_TRF_IND message generation unit for generating a MOB_TRF_IND message, including a downlink interval usage code (DIUC) update indicator to indicate if any one of modulation and coding techniques of downlink traffic is changed; And a transmitter for transmitting the MOB-TRF-IND message. The apparatus of claim 1, further comprising a DL-MAP generation unit for generating a DL-MAP including a DCD count value for identifying a DCD message describing a modulation technique and a coding technique of the downlink traffic. The method according to claim 1 or 2, wherein the MOB_TRF_IND message generator determines whether the DCD burst profile encodings value corresponding to DIUC, which is a table index indicating a modulation scheme and a coding scheme, in the DCD message is changed. And determining which one of the coding techniques is changed. 3. The DIUC update indicator according to claim 2, wherein the DIUC update indicator is a value indicating that the DCD count has been updated by a change of DCD burst profile encodings corresponding to the DIUC, and wherein the DCD count is changed in association with a DCD burst profile encodings corresponding to the DIUC. Device having another value indicating that it is not. The method of claim 3, wherein if the base station does not transmit the DCD message until the terminal enters the normal mode and receives the DL traffic, the base station starts transmitting to the terminal in order of decreasing data size, so that the terminal transmits the DCD message. And persists until received. The apparatus of claim 1, wherein the MOB_TRF_IND message generator includes modulation and code scheme information for downlink traffic to be transmitted in the MOB_TRF_IND message. 7. The apparatus of claim 6, wherein the modulation scheme and code scheme information for downlink traffic to be transmitted are indicated by a DIUC-FEC code type pair consisting of a DIUC value and an FEC code type value corresponding to the DIUC. 7. The apparatus of claim 6, wherein the DIUC-FEC code type pair consists of 9 bits, and the 9 bits comprise an upper 4 bits representing a DIUC and a lower 5 bits representing an FEC code type corresponding to the DIUC. The apparatus of any one of claims 1 to 8, wherein the MOB_TRF_IND message generating unit includes a value N_DIUC_updates indicating how many FEC code types associated with a DIUC to be used by the terminal is changed in the MOB_TRF_IND message. The apparatus of claim 9, wherein the terminal demodulates downlink traffic transmitted according to the changed DIUC and the corresponding FEC code type by receiving the MOB_TRF_IND message. In at least one base station for communicating with a predetermined terminal in a wireless access communication system, Generating a MOB_TRF_IND message, including a Downlink Interval Usage Code (DIUC) update indicator to indicate if one of the modulation and coding techniques of the downlink traffic has changed; Transmitting the MOB-TRF-IND message. 12. The method of claim 11, further comprising generating a DL-MAP including a DCD count value identifying a DCD message describing a modulation technique and a coding technique of the downlink traffic. The method of claim 12, wherein the message generating step Determining whether one of a modulation technique and a coding technique of downlink traffic is changed by determining whether a DCD burst profile encoding value corresponding to DIUC, which is a table index indicating a modulation scheme and a coding scheme, is changed in the DCD message. Characterized in that. The method of claim 12, wherein the DIUC update indicator is a value indicating that the DCD count has been updated by a change of DCD burst profile encodings corresponding to DIUC, and wherein the DCD count is changed in association with DCD burst profile encodings corresponding to DIUC. And having another value indicating that it is not. The method of claim 13, wherein if the terminal does not transmit the DCD message until the terminal enters the normal mode and receives the DL traffic, the terminal starts transmitting to the terminal in order of decreasing data size, and when the terminal receives the DCD message. Method further comprising the step of continuing until. 12. The method of claim 11, wherein generating the message comprises including modulation and code scheme information for downlink traffic to be transmitted in the MOB_TRF_IND message. 17. The method of claim 16, wherein the modulation scheme and code scheme information for downlink traffic to be transmitted are indicated by a DIUC-FEC code type pair value consisting of a DIUC value and an FEC code type value corresponding to the DIUC. 18. The method of claim 17, wherein the DIUC-FEC code type pair consists of 9 bits, and the 9 bits comprise an upper 4 bits representing a DIUC and a lower 5 bits representing an FEC code type corresponding to the DIUC. 12. The method of claim 11, wherein the generating of the message comprises including in the MOB_TRF_IND message a value N_DIUC_updates indicating how many FEC code types associated with the DIUC to be used by the UE have changed. A terminal for communicating with a base station in a wireless access communication system, A transceiver for receiving a MOB_TRF_IND message including a Downlink Interval Usage Code (DIUC) update indicator indicating that any one of a modulation technique and a coding technique of downlink traffic has been changed; And an FEC code type setting unit configured to set its own FEC code type by referring to the MOB_TRF_IND message. 21. The apparatus of claim 20, wherein the transceiver receives a DL-MAP including a DCD count value identifying a DCD message describing a modulation technique and a coding technique of downlink traffic. 22. The method of claim 21, further comprising a DIUC change determination unit for determining whether the DCD count of the received DL-MAP is different from the DCD count of the DL-MAP received in a previous listening window, and in other cases, the DCD count value is changed. Device characterized in that. 22. The apparatus of claim 21, wherein the MOB_TRF_IND message includes modulation scheme and code scheme information for downlink traffic to be transmitted later. 24. The apparatus of claim 23, wherein the MOB_TRF_IND message comprises a DIUC-FEC code type pair including a DIUC value and a FEC code type value corresponding to the DIUC. 25. The apparatus of claim 24, wherein the DIUC-FEC code type pair consists of 9 bits, and the 9 bits comprise an upper 4 bits representing a DIUC and a lower 5 bits representing an FEC code type corresponding to the DIUC. 22. The apparatus of claim 21, wherein the MOB_TRF_IND message includes N_DIUC_updates, which is a value indicating how many FEC code types associated with a DIUC to be used by the UE have changed. The apparatus of claim 24, wherein the FEC code type setting unit sets its own FEC code type by referring to a DIUC-FEC code type pair. A terminal for communicating with a base station in a wireless access communication system, Receiving a MOB_TRF_IND message including a Downlink Interval Usage Code (DIUC) update indicator indicating that either one of a modulation technique and a coding technique of downlink traffic has been changed; Setting its own FEC code type with reference to the MOB_TRF_IND message. 29. The method of claim 28, further comprising receiving a DL-MAP including a DCD count value identifying a DCD message describing a modulation technique and a coding technique of the downlink traffic. 30. The method of claim 29, further comprising determining whether the DCD count of the received DL-MAP is different from the DCD count of the DL-MAP received in a previous listening window and determining that the DCD count value has been changed in other cases. How to. 29. The method of claim 28, wherein the MOB_TRF_IND message includes modulation scheme and code scheme information for downlink traffic to be transmitted later. 29. The method of claim 28, wherein the MOB_TRF_IND message comprises a DIUC-FEC code type pair including a DIUC value and a FEC code type value corresponding to the DIUC. 28. The method of claim 27, wherein the DIUC-FEC code type pair consists of 9 bits, and the 9 bits comprise an upper 4 bits representing a DIUC and a lower 5 bits representing an FEC code type corresponding to the DIUC. 29. The method of claim 28, wherein the MOB_TRF_IND message includes N_DIUC_updates, which is a value indicating how many FEC code types associated with a DIUC to be used by the UE have changed. 33. The method of claim 32, wherein the setting of the FEC code type comprises setting its own FEC code type with reference to the DIUC-FEC code type pair.

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