KR101350637B1 - Method and system for transmitting/receiving broadcast data in a wireless access system - Google Patents

Abstract

The present invention relates to a method and a system for receiving a broadcast service in a wireless access system, and more particularly, to a method and system for transmitting and receiving broadcast data for receiving a broadcast service in a wireless access system.

The wireless access system for transmitting and receiving broadcast data according to the present invention downlinks map information including an indicator indicating whether a broadcast message including allocation information of the broadcast data exists and a waiting time indicating a location of a next broadcast message. A base station for transmitting in a subframe and a mobile terminal receiving the downlink subframe and receiving the broadcast message when the broadcast message exists in the received downlink subframe based on the indicator. do.

As described above, according to the present invention, a method of reducing the number of demodulated frames in an initial state for receiving a broadcast message can reduce power consumption of the mobile terminal, and in particular, reduces power consumption during frequent broadcast channel switching. Can be reduced.

Broadcast message, MBS, downlink subframe.

Description

Broadcast data transmission / reception method and system in wireless access system {METHOD AND SYSTEM FOR TRANSMITTING / RECEIVING BROADCAST DATA IN A WIRELESS ACCESS SYSTEM}

1 is a diagram illustrating an example of a configuration of a downlink subframe in a wireless access system;

2 is a view showing a method of transmitting and receiving a broadcast message in a conventional wireless access system,

3 is a flowchart illustrating a process of receiving broadcast data in a mobile terminal of a wireless access system according to an embodiment of the present invention;

4 is a diagram illustrating a method for receiving a broadcast message in a mobile terminal according to an embodiment of the present invention.

The present invention relates to a method and system for receiving a broadcast service in a wireless access system, and more particularly, to a method and system for transmitting and receiving broadcast data for receiving a broadcast service in a wireless access system.

A representative example of a wireless access system that provides a broadband packet data service such as a broadcast service is a WiBro / WiMAX system based on IEEE 802.16e, a portable Internet standard (hereinafter, WiBro / WiMAX system). have. The WiBro / WiMAX system has a wider bandwidth of data than a conventional wireless communication technology for voice service, and can perform large data transmission in a short time, and it is possible to efficiently use a channel by sharing all user channels. In addition, the WiBro / WiMAX system guarantees a quality of service (QoS), so that the user may receive different quality services according to the characteristics of the service. In the WiBro / WiMAX system, all users connected to the base station share and use a common channel, and the interval in which each user uses the channel is allocated by the base station in every up and down frame. Channel characteristic information and channel access information should be informed so that they can be used separately.

In the WiBro / WiMAX system, channel information is classified into an uplink channel and a downlink channel, and channel characteristic information including a channel ID and a configuration change count value of each channel is classified into TLV (Type, Length, Defined as Value) to include in the Downlink Channel Descriptor (DCD), Uplink Channel Descriptor (UCD) message to inform all mobile terminals of the uplink and downlink channel characteristic information at regular intervals. In addition, the base station transmits an uplink_map (UpLink_MAP: "UL_MAP") and a downlink_map ("DL_MAP") message including uplink access information and downlink access information at the beginning of each frame. Transmit to all domestic mobile terminals. Hereinafter, for convenience, a broadband wireless communication system including the WiBro / WiMAX system will be collectively described as a wireless access system.

1 is a diagram illustrating an example of a configuration of a downlink subframe in a wireless access system, for example, IEEE 802.16e based wireless access employing an Orthogonal Frequency Division Multiplexing Access (OFDMA) scheme. In the system, a configuration of a downlink subframe that a base station broadcasts to mobile terminals is illustrated.

Referring to each region constituting the subframe of FIG. 1, the preamble 110 is positioned in front of the subframe in FIG. 1. The preamble 110 is used by the mobile terminal to make cell decisions or to synchronize system synchronization. In addition, the subframe includes a frame control header (FCH) 130, a map (MAP) area 150, and a burst area 170.

A DL_MAP message and a UL_MAP message are transmitted through the map area 170 as a message defining the location and use of bursts allocated to DL and UL. The information element constituting the DL_MAP (hereinafter referred to as DL_MAP IE (Information Element)) includes a down interval usage code (Down Interval Usage Code), a CID (connection ID), and position information of a DL burst (subchannel offset, symbol offset, subchannel). Number, symbol number).

MBS data bursts transmitted for the multicast and broadcast service (hereinafter, referred to as MBS ") are transmitted through the burst area 170 of the subframe of FIG. 1. May include an MBS region.

Hereinafter, only a map region 150 including DL_MAP_IE and a burst region 170 including MBS data bursts as broadcast data in the configuration of a downlink subframe of the radio access system will be briefly shown to receive a broadcast service in the radio access system. A method of transmitting and receiving a broadcast message will be described. For convenience of description, a frame including an MBS region will be described as an MBS frame.

2 is a diagram illustrating a method of transmitting and receiving a broadcast message in a conventional wireless access system.

In the conventional wireless access system, the MBS_MAP message, which is a broadcast message, may be received by a plurality of mobile terminals in two ways. First, the mobile terminal checks the MBS_MAP_IE 213 of the DL_MAP 211 message in the initial state of attempting the first MBS connection, receives the MBS_MAP message, and checks the MBS_DATA_IE 219 included in the MBS area in the normal state when the connection is completed. MBS_MAP message can be received.

Hereinafter, a process of receiving a MBS_MAP message for receiving a broadcast service in an initial state and a normal state by receiving the first to third MBS frames 210, 230, and 250 with reference to FIG. 2 will be described.

The mobile terminal receives the first MBS frame 210 for the MBS and attempts an initial MBS connection. Assume that the MBS_MAP message 217 includes the MBS_DATA_IE 219 in the first MBS frame 210. After receiving the first MBS frame 210, the mobile terminal waits for the next MBS frame offset allocated from the MBS_DATA_IE 219 of the first MBS frame to wait for the second MBS frame 230. Receive. It is assumed that the second MBS frame 230 received by the mobile terminal does not include MBS_DATA_IE in the MBS_MAP message 237 in the MBS region 235 and includes the MBS data burst 239 which is broadcast data. In addition, after receiving the second MBS frame 230, the mobile terminal waits for the next MBS frame offset allocated from the MBS_DATA_IE 219 of the first MBS frame to receive the third MBS frame 250. It is assumed that the MBS_MAP message 257 includes the MBS_DATA_IE 259 in the third MBS frame 250 received by the mobile terminal.

In FIG. 2, the MBS_MAP_IE (213, 233, 253) included in the DL_MAP message (211, 231, 251) is a symbol position where the MBS regions 215, 235, 255 start in the MBS frames 210, 230, and 250, and the first of the MBS_MAP message (217, 237, 257). The allocation information I1 can be known. The MBS_MAP messages 217, 237 and 257 are always allocated from the first symbol and the first sub-channel of the MBS regions 215, 235 and 255.

In addition, the MBS_MAP message 217, 237, 257 basically includes as many MBS_DATA_IE 219, 259 as the number of channels (or bursts) serviced. The MBS_DATA_IE (219, 259) is the second allocation of MBS data burst 231 that can be received at the position of [Next MBS burst frame offset + a] so that the mobile terminal can receive the next MBS data burst 231 of the channel. Contains information I2. Here, a is a margin set to stably receive the desired MBS data burst 231, for example, a value of 2 may be set. In addition, when the MBS_DATA_IE (219, 259) receives the third MBS frame 250 including the multicast connection identifier (CID) (referred to as MBS connection, hereinafter " MCID "), that is, the MBS_MAP message 257, for each broadcast channel. The third allocation information I3 indicating the next MBS frame offset is included to indicate whether or not it is possible. The MBS frame offset for receiving the third MBS frame 250 including the MCID is M bits, and the lower M bits of the frame number of the second MBS frame 230 received after the first MBS frame 210. Specifies a frame that is equal to the value.

Therefore, the reception operation of the MBS data burst 235 in the mobile terminal initially parses the MBS_DATA_IE 219 of the MBS_MAP message 217 indicated by the DL_MAP 211 message, and then checks the MCID to determine whether the MBS data burst 235 is received. Decide When receiving the MBS_DATA_IE 219 including the MCID assigned to the mobile terminal, referring to the allocation information (I2) for the MBS data burst 239 allocated to [next MBS burst frame offset + a], the MBS data burst ( 235). Although FIG. 2 has described the MBS operation for receiving one broadcast content, this can be extended to the MBS operation for receiving a plurality of broadcast contents by allocating a plurality of MBS_DATA_IE 219.

Hereinafter, an MBS operation for receiving a plurality of broadcast contents will be described by way of example.

One MCID is assigned per broadcast content, for example, MCID = 0 for A broadcast content, MCID = 1 for B broadcast content, MCID = 2 for C broadcast content, and MCID = 3 for D broadcast content, An MBS operation of receiving a plurality of broadcast contents when the MCIDs allowed for the mobile terminal are all 0, 1, 2, and 3 will be described.

Since the mobile terminal only needs to receive broadcast content desired by the user, only one of all MBS bursts for A / B / C / D is demodulated. If the user wants A broadcast content, only the frame including the MBS data burst with MCID = 0 is required to demodulate the corresponding MBS data burst with reference only to MBS_DATA_IE with MCID = 0.

Assuming that the user receives the MBS operation for receiving A broadcast content, as described above, the mobile terminal receives the first MBS frame 210 in the initial state operation and checks the DL_MAP 211 message including the MBS_MAP_IE 213. do. In the MBS_MAP message 217, when the MBS_DATA_IE 219 including MCID = 0 is analyzed, the first MBS data burst 239 may be received, and then the system enters a steady state operation. In the normal state, as shown in FIG. 2, the third frame 250 after the next MBS frame offset indicating when the third MBS frame 250 including the MCID = 0 is received in the MBS_DATA_IE 219. ) Only when MBS_DATA_IE with MCID = 0 is received and the MBS data burst is received.

Accordingly, demodulation is performed on all frames including the MBS region until the first MCID = 0 MBS_DATA_IE. However, when receiving the MBS_DATA_IE with the first MCID = 0, when the MBS frame including the MCID is received, Since only the frame needs to be demodulated with reference to the MBS frame offset indicating whether it can be received, it may be helpful to save power of the mobile terminal. However, when the user stops receiving the A broadcast content and receives the B broadcast content, in order to receive MBS_DATA_IE having MCID = 1, the user should start the initial state operation again and enter the steady state operation. At this time, the maximum MBS frame amount to be received in order to receive the B broadcast content is the next MBS frame offset included in MBS_DATA_IE having MCID = 1, and DL_MAP and MBS_MAP messages are displayed for the frames. The included MBS frame should be received.

Therefore, the more frequently the user changes the broadcast channel, the longer the time to reach the initial state for receiving the first MBS_DATA_IE increases the power consumption of the mobile terminal.

On the other hand, if the first user receives and manages MBS_DATA_IE for channel broadcast candidates B broadcast content, C broadcast content, and D broadcast content while receiving A broadcast content at all times, the initial state does not stay in the initial state at the time of receiving broadcast content change. It can immediately enter the normal state of receiving B or C or D broadcast content. In this case, however, all MBS_DATA_IEs for A, B, C and D must be managed, thus increasing power consumption.

That is, conventionally, when receiving only one broadcast content, it is advantageous to reduce power consumption. However, when there are a plurality of broadcast channels and frequently switch these broadcast channels, power consumption increases. In addition, although all the MBS areas in the prior art always include the MBS_MAP message, in fact, since the frame receiving the MBS_MAP message and the frame receiving the MBS data burst may be different, there may be a frame having only the MBS data burst in the MBS area. In this case, the MBS_MAP message without the MBS_DATA_IE can be implemented, but it is inefficient by receiving the unnecessary MBS_MAP message without the MBS_DATA_IE. This is inefficient because the mobile terminal in the initial state demodulates the unnecessary MBS_MAP message, which is unnecessary in the initial state as well as the normal state.

The present invention provides a method and system for efficiently transmitting / receiving broadcast data in a wireless access system.

In addition, the present invention provides a method and system that can reduce power consumption and overhead of a mobile terminal when transmitting / receiving broadcast data in a wireless access system.

The method for transmitting broadcast data in a base station of a wireless access system according to the present invention includes an indicator for indicating whether a broadcast message including allocation information of the broadcast data includes a wait time indicating a location of a next broadcast message. Generating map information; and transmitting the generated map information in a downlink subframe.

In addition, the method for receiving broadcast data in a mobile terminal of a wireless access system according to the present invention includes an indicator indicating whether a broadcast message including allocation information of the broadcast data in the initial state of the mobile terminal and the next broadcast message. Receiving a downlink subframe including a reception wait time indicating a location of the signal; and receiving the broadcast message when the broadcast message exists in the received downlink subframe based on the indicator. do.

In addition, the wireless access system for transmitting and receiving broadcast data according to the present invention downlinks map information including an indicator indicating whether a broadcast message including allocation information of the broadcast data exists and a waiting time indicating a location of a next broadcast message. A base station for transmission in a link subframe and a mobile terminal receiving the downlink subframe and receiving the broadcast message when the broadcast message exists in the received downlink subframe based on the indicator. Include.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intention or custom of a user or an operator. Therefore, the definition should be based on the contents throughout this specification.

3 is a flowchart illustrating a process of receiving broadcast data in a mobile terminal of a wireless access system according to an embodiment of the present invention.

According to an embodiment of the present invention, a mobile terminal of a wireless access system receives a broadcast message in three states: initial state, dormant state, and normal state. The initial state is a state of attempting to access an MBS for the first time, the idle state is a state of setting and switching a broadcast channel after the MBS connection, and the normal state of receiving a broadcast message of a broadcast channel set and switched from the idle state. It is a state. When the sync loss occurs in the normal state, the signal is switched to the initial state, and when the broadcast channel is switched, it is switched to the idle state.

The MBS_MAP_IE included in the DL_MAP message according to an embodiment of the present invention includes MBS_MAP_Ind (Indicate) indicating an MBS frame for receiving the MBS_MAP message and Dormant Message Timer (hereinafter referred to as DMT ") information. The MBS_MAP_Ind includes: An indicator indicating whether an MBS_MAP message is present in an MBS frame, and the DMT is a timer that sets a reception waiting time (or the number of frames) for receiving the next MBS_MAP message.

In step 301 of FIG. 3, the mobile terminal is in an initial state of attempting an initial MBS connection to receive a broadcast message. In step 303, the mobile station receives the MBS frame including the DL_MAP message from the base station. In step 305, the mobile station determines whether there is a MBS_MAP_IE indicating a symbol position at which the MBS region starts and MBS_MAP message allocation information in the DL_MAP message. As a result of the determination of the mobile terminal in step 305, if the MBS_MAP_IE is present, the process proceeds to step 307, the transition to the idle state, and if there is no MBS_MAP_IE, the process proceeds to step 303.

In step 309 of FIG. 3, the mobile terminal determines whether the MBS_MAP message is present by checking whether the MBS_MAP_Ind value included in the MBS_MAP_IE is 1. In step 309, if the MBS_MAP_Ind value is 1, the mobile terminal determines that the MBS_MAP message exists in the MBS frame and proceeds to step 313. On the other hand, if the MBS_MAP_Ind value is not 1 in step 309, the mobile terminal determines that the MBS_MAP message does not exist and proceeds to step 311.

In step 311, the mobile station waits to receive the next MBS_MAP message during the configured DMT. The method of setting the DMT is as follows. The next MBS frame offset included in the previously received N MBS_DATA_IE is M bits, and the value is Next_MBS_frame_offset_n (n = 0 to N-1), and the lower M bits of the frame number of the current frame are L. When DMT = min [Next_Mbs_frame_offset_n-L) mod 2 ^ M] for (n = 0 ~ N-1).

As described above, when the mobile terminal is an MBS frame other than MBS_MAP_Ind = 1 in step 309 and 311, the mobile terminal does not include the MBS_MAP message in the MBS region, and thus does not need allocation information for the MBS_MAP message. At this time, the mobile terminal can reduce the overhead for transferring allocation information for the MBS_MAP message, and can reduce power by not performing unnecessary demodulation during the K (greater than or equal to 0 as a DMT value) frame.

In step 313, if the MBS_MAP_Ind is 1, the mobile terminal determines that the MBS frame includes the MAS_MAP message, and after receiving the MBS frame including the MBS_MAP message, analyzes the MBS_DATA_IE included in the MBS_MAP message.

In step 315, if the MCID (my MCID) assigned to the mobile terminal exists in MBS_DATA_IE according to the analysis result, the mobile terminal proceeds to step 317. When the MCID assigned to the mobile terminal does not exist in MBS_DATA_IE, the 311. Proceed to step.

In step 317, the mobile station receives the MBS data burst allocated to [Next MBS Burst Frame Offset + a] of the next MBS frame and transitions to the normal state.

In step 319, the mobile station checks the MBS_MAP message by receiving the next MBS frame after the next MBS frame offset in the normal state. In step 319, the MBS_DATA_IE included in the MBS_MAP message is analyzed. In step 321, when the mobile terminal has an MCID corresponding to the broadcast channel selected by the user of the mobile terminal in the MBS_DATA_IE, the mobile terminal allocates the next MBS data to [next MBS burst frame offset + a] included in MBS_DATA_IE. Receive a burst.

Hereinafter, an example of a method of receiving a broadcast message in a mobile terminal of the above-described wireless access system in FIG. 4 will be briefly described in a downlink subframe.

4 is a diagram illustrating a method for receiving a broadcast message in a mobile terminal according to an embodiment of the present invention.

According to an embodiment of the present invention, after receiving the first MBS frame 410 for MBS, the mobile terminal attempts to access the first MBS. It is assumed that the MBS_MAP_IE 413 included in the DL_MAP 411 message in the first MBS frame 410 includes MBS_MAP_Ind = 1 and MBS_MAP_DMT = A. After receiving the first MBS frame 410, the mobile station identifies a next MBS frame offset of a reception channel allocated from the MBS_DATA_IE 419 of the first MBS frame, and then offsets the received MBS frame offset. Wait for the second MBS frame 430 to receive. It is assumed that the MBS_MAP_IE 433 included in the DL_MAP 413 message in the second frame 430 received by the mobile terminal includes MBS_MAP_Ind = 0 and MBS_MAP_DMT = B. In addition, after receiving the second MBS frame 430, the mobile terminal allocates the MCID of the reception channel allocated from the MBS_DATA_IE 419 of the first MBS frame, waits for the next MBS frame offset I3, and then waits for the third MBS. The frame 450 is received. It is assumed that the MBS_MAP message 457 includes the MBS_DATA_IE 45919 in the third MBS frame 250 received by the mobile terminal.

If the mobile terminal describes the operation of the initial state for receiving the broadcast message in the first frame 410 under the above conditions, first, the mobile terminal receives the first frame 410 including the DL_MAP 411 message from the base station. In the DL_MAP 411 message, it is determined whether the MBS_MAP_IE 413 indicating the symbol position at which the MBS region 415 starts and the first allocation information I1 of the MBS_MAP message 417 exist.

In FIG. 4, since the MBS_MAP_IE 413 is present in the first frame 410, the mobile station transitions to the idle state to perform the selection or switching operation of the broadcast channel, and MBS_MAP_Ind and MBS_MAP_DMT included in the received MBS_MAP_IE 413. Check it. Since the MBS_MAP_Ind value included in the received MBS_MAP_IE 413 is 1, the MS determines that the MBS_MAP message 417 exists in the first frame 410. The DMT receives the next MBS_MAP message after the set A frame (or time). Therefore, the DMT decreases by 1 every frame and the DMT becomes '0' in the frame immediately before MBS_MAP_Ind = 1.

Meanwhile, after confirming that MBS_MAP_Ind = 1, the MS checks the MBS_MAP message 417 in the MAP region of the first frame 410, and analyzes the MBS_DATA_IE 419 included in the checked MBS_MAP message 417. When it is determined that the MCID according to the broadcast channel selected by the user of the mobile terminal exists in the MBS_DATA_IE 419 according to the analysis result, the mobile terminal determines from the MBS_DATA_IE 419 the [MBS Burst Frame Offset + a] receives the MBS data burst 439 allocated to the corresponding position of the second frame 430, and transitions to the normal state. As in the above operation, the mobile terminal can reduce power consumption by checking in advance whether the MBS_MAP message exists in the MBS region based on the MBS_MAP_Ind.

Since the mobile terminal checks the DL_MAP 431 included in the received second MBS frame 430, MBS_MAP_Ind = 0 and MBS_MAP_DMT = B of MBS_MAP_IE 433, MBS_MAP message is included in the MBS region 435 You can see that it is not. In this case, for example, the mobile terminal does not operate for a time for receiving the number of B frames set in the MBS_MAP_DMT. Therefore, according to the present invention, the system overhead 431 I1 can be reduced by not transmitting or receiving the MBS_MAP message not including the MBS_DATA_IE in the MBS region. The overhead reduction may include not transmitting and receiving unnecessary MBS_MAP messages and not transmitting unnecessary MBS_MAP message information to MBS_MAP_IE in DL_MAP messages.

In addition, the mobile terminal receives the third MBS frame 450 by waiting for the next MBS frame offset I3 after the MCID allocated from the MBS_DATA_IE 419 of the first MBS frame is allocated. The MBS_DATA_IE 459 is analyzed in the MBS_MAP message 457 included in the third frame 450. If there is an MCID (my MCID) assigned to the mobile terminal in the MBS_DATA_IE 459 according to the analysis result, the mobile terminal is allocated to the position of [Next MBS frame offset + a] included in MBS_DATA_IE. Then receive the MBS data burst.

As described above, the present invention provides a method of reducing the number of demodulated frames in an initial state to receive a broadcast message, thereby reducing power consumption of the mobile terminal, and in particular, reducing power consumption during frequent channel switching. Can be.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, according to the present invention, a method of reducing the number of demodulated frames in an initial state for receiving a broadcast message can reduce power consumption of the mobile terminal, and in particular, reduces power consumption during frequent broadcast channel switching. May decrease.

In addition, the present invention can reduce the power consumption of the mobile terminal by checking in advance whether the MBS_MAP message exists in the MBS area.

In addition, the present invention can reduce the system overhead by not transmitting and receiving MBS_MAP messages that do not include MBS_DATA_IE in the MBS area.

Claims (8)

In the method of transmitting broadcast data in the base station of the radio access system, Generating map information including an indicator indicating whether a broadcast message including allocation information of the broadcast data exists and a waiting time indicating a location of a next broadcast message; And transmitting the generated map information in a downlink subframe. The method of claim 1, The process of transmitting the downlink subframe Broadcast data transmission method comprising the step of performing in the wireless access system based on IEEE 802.16e which is a portable Internet standard. In the method for receiving broadcast data in a mobile terminal of a wireless access system, Receiving a downlink subframe including an indicator indicating whether a broadcast message including allocation information of the broadcast data exists in an initial state of the mobile terminal and a reception waiting time indicating a location of a next broadcast message; And receiving the broadcast message when the broadcast message exists in the received downlink subframe based on the indicator. The method of claim 3, wherein And if the broadcast message does not exist in the received downlink subframe based on the indicator, receiving the broadcast data during the reception wait time. The method of claim 3, wherein If the multicast connection identifier according to the broadcast channel selected by the user of the mobile terminal does not exist in the received broadcast message, receiving the broadcast data. In a wireless access system for transmitting and receiving broadcast data, A base station for transmitting an indicator indicating whether a broadcast message including allocation information of the broadcast data is present and a map information including a waiting time indicating a location of a next broadcast message in a downlink subframe; And a mobile terminal receiving the downlink subframe and receiving the broadcast message when the broadcast message exists in the received downlink subframe based on the indicator. The method of claim 6, The mobile terminal And if there is no broadcast message in the received downlink subframe based on the indicator, waiting for the reception time. The method of claim 6, The mobile terminal And if the multicast identifier according to the broadcast channel selected by the user of the mobile terminal does not exist in the received broadcast message, waiting for the reception time.

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