KR20120002945A - Apparatus and method for transmitting and receiving mbs data - Google Patents

Abstract

PURPOSE: An apparatus for transmitting and receiving MBS(Multicast Broadcast Service) data and method thereof are provided to transmit accurate information to an MBS reception apparatus by transmitting bitmap data. CONSTITUTION: An area allocation information creation unit(115) creates area allocation information for an MBS area and a non-MBS area. An MBS area allocation unit allocates the allocated time sections to one or more MBS areas. An MBS area separation information creation unit(125) creates MBS area allocation information for the MBS areas. A control data transmission unit(140) transmits the area allocation information and the MBS area allocation information. An MBS data transmission unit(150) transmits the MBS data through the time section allocated to the MBS area.

Description

Apparatus and method for transmitting and receiving MBS data {APPARATUS AND METHOD FOR TRANSMITTING AND RECEIVING MBS DATA}

The present invention relates to a base station, a relay station and a mobile station. In particular, the present invention relates to an apparatus and method for transmitting and receiving multicast broadcast service (MBS) data.

The mobile communication system can support multiple carriers.

In this case, the mobile station may be separately allocated a carrier for non-MBS mainly serving unicast and a carrier for multicast broadcast service (MBS).

However, since a mobile station having one transceiver needs to receive non-MBS data and MBS data through carrier switching, it receives only non-MBS data or only MBS data in a specific time interval.

Therefore, although the MBS transmission apparatus needs to perform scheduling to transmit the non-MBS data and the MBS data, the structure of the MBS transmission apparatus may be complicated to schedule the plurality of mobile stations because the MBS data is transmitted to the plurality of mobile stations. have.

Meanwhile, the MBS transmission apparatus may support a mixed carrier which may include a non-MBS region for transmitting non-MBS data and an MBS region for transmitting MBS data. However, even if the MBS transmission apparatus uses a mixed carrier, bandwidth may not be sufficient for allocating a non-MBS region of the mixed carrier to all mobile stations that receive the MBS data of the mixed carrier. As a result, the MBS transmission apparatus may require some mobile stations to transmit non-MBS data on carriers other than mixed carriers, so the structure of the MBS transmission apparatus may still be complicated.

The signal transmitted through one carrier supporting the MBS may be divided into a plurality of subbands on the frequency axis. All of the plurality of subbands may be allocated to the MBS region. In addition, the plurality of subbands may be allocated to the MBS region and the non-MBS region, or may be allocated to the MBS region and the unused region. Each region consists of one or more subbands.

Meanwhile, the MBS area may be divided into a plurality of MBS zones. Each MBS zone consists of one or more subbands.

Therefore, the MBS transmitting apparatus needs to transmit information to the mobile station so that the MBS receiving apparatus can recognize the MBS zone and identify each MBS zone.

To this end, a method may be used in which the MBS transmitting apparatus provides the mobile station with allocation information about the zone and a zone flag regarding whether the last zone is allocated to the non-MBS region.

According to this method, in a network including zone # 1, zone # 2, and zone # 3, zone # 1 and zone # 2 are assigned to MBS and zone # 3 is assigned to unicast or MBS.

Accordingly, a mobile station serviced by MBS transmission apparatuses belonging to zone # 1 and zone # 2 can recognize zone # 1 and zone # 2 to be allocated to MBS through zone assignment information, and zone # 3 is determined through zone flag. It can be recognized whether it has been allocated to the non-MBS region.

However, the mobile station serviced by the MBS transmission apparatus belonging to zone # 1 only cannot know whether zone # 2 is assigned to the non-MBS region, so the MBS transmission apparatus belonging to zone # 1 only assigns zone # 2 to the non-MBS region. Can not. In addition, since the mobile station serviced by the MBS transmission apparatus belonging to only zone # 2 cannot recognize whether zone # 1 is assigned to the non-MBS region, the MBS transmission apparatus belonging to zone # 2 only assigns zone # 1 to the non-MBS region. Can not. Therefore, bandwidth waste may be caused.

One object of the present invention is to provide an area allocation method and an MBS zone allocation method for facilitating scheduling of an MBS transmission apparatus.

In addition, another technical problem to be achieved by the present invention is to provide a method for providing MBS zone allocation information to reduce bandwidth waste.

According to an embodiment of the present invention, a method of transmitting MBS data by a multicast broadcast service (MBS) transmitting apparatus may allocate each of a plurality of time intervals of an MBS transmission carrier to an MBS region and a non-MBS region. Making; Generating region allocation information for the MBS region and the non-MBS region; Allocating a time interval allocated to the MBS region to at least one MBS zone; Generating MBS zone assignment information for the one or more MBS zones; Transmitting the area allocation information and the MBS zone allocation information; And transmitting MBS data through a time interval allocated to the MBS region, wherein the region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region or the non-MBS region. .

The region allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals, and each bit of the first bitmap includes a corresponding time interval allocated to the MBS region or the non-MBS. It can indicate whether it is assigned to an area.

Allocating a time interval allocated to the MBS region to one or more MBS zones includes allocating each of the time intervals allocated to the MBS region to the one or more MBS zones, wherein the MBS zone allocation information includes the MBS. Each of the time intervals allocated to the region may indicate to which MBS zone.

The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the MBS region, and each bit of the second bitmap corresponds to a corresponding one. It may indicate whether a time interval is allocated to the same MBS zone as the previous time interval.

Allocating a time interval allocated to the MBS region to at least one MBS zone includes assigning each of a plurality of subbands to the at least one MBS zone within a time interval allocated to the MBS region. Zone allocation information may indicate to which MBS zone each of the plurality of subbands is allocated.

The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except for the first subband among the plurality of subbands, wherein each bit of the second bitmap includes a corresponding subband. It may indicate whether it is allocated to the same MBS zone as the previous subband.

The MBS data transmission method may further include transmitting non-MBS data through a time interval allocated to the non-MBS region.

The non-MBS region may correspond to an unused region.

The area allocation information may be broadcasted through a system information message, and the MBS zone allocation information may be broadcasted through a MBS specific message.

In accordance with another aspect of the present invention, an apparatus for transmitting a multicast broadcast service (MBS) includes: an area allocator configured to allocate each of a plurality of time intervals of an MBS transport carrier to an MBS area and a non-MBS area; An area allocation information generator configured to generate area allocation information for the MBS area and the non-MBS area; An MBS zone allocator configured to allocate a time interval allocated to the MBS area to at least one MBS zone; An MBS zone assignment information generation unit for generating MBS zone assignment information for the one or more MBS zones; A control data transmitter for transmitting the area allocation information and the MBS zone allocation information; And an MBS data transmitter configured to transmit MBS data through a time interval allocated to the MBS region, wherein the region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region or the non-MBS region. Indicates.

The region allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals, and each bit of the first bitmap includes a corresponding time interval allocated to the MBS region or the non-MBS. It can indicate whether it is assigned to an area.

The MBS zone allocator allocates each of the time intervals allocated to the MBS region to the one or more MBS zones, and the MBS zone allocation information is assigned to the remaining time intervals except the first time interval among the time intervals allocated to the MBS region. A second bitmap composed of a corresponding plurality of bits, each bit of the second bitmap may indicate whether a corresponding time interval is allocated to the same MBS zone as the previous time interval.

The MBS zone allocator allocates each of a plurality of subbands to the one or more MBS zones within a time interval allocated to the MBS region, and the MBS zone allocation information includes the remaining subbands except the first subband of the plurality of subbands. And a second bitmap composed of a plurality of bits respectively corresponding to the bands, wherein each bit of the second bitmap may indicate whether the corresponding subband is allocated to the same MBS zone as the previous subband.

According to another embodiment of the present invention, a method for receiving MBS data by a multicast broadcast service (MBS) receiving apparatus includes: receiving region allocation information for an MBS region and a non-MBS region; Allocating each of a plurality of time intervals of an MBS transport carrier to the MBS area and the non-MBS area based on the received area allocation information; Receiving MBS zone allocation information for the one or more MBS zones; Allocating a time interval allocated to the MBS region to at least one MBS zone based on the MBS zone allocation information; And receiving MBS data through a time interval allocated to each of the one or more MBS zones, wherein the region allocation information is assigned to the non-MBS region whether each of the plurality of time intervals is allocated to the MBS region. Can be assigned.

The region allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals, and each bit of the first bitmap includes a corresponding time interval allocated to the MBS region or the non-MBS. It can indicate whether it is assigned to an area.

Allocating a time interval allocated to the MBS region to one or more MBS zones includes allocating each of the time intervals allocated to the MBS region to the one or more MBS zones, wherein the MBS zone allocation information includes the MBS. And a second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the region, wherein each bit of the second bitmap corresponds to a previous time interval. It may indicate whether or not it is allocated to the same MBS zone.

Allocating a time interval allocated to the MBS region to at least one MBS zone includes assigning each of a plurality of subbands to the at least one MBS zone within a time interval allocated to the MBS region. The zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except for the first subband of the plurality of subbands, wherein each bit of the second bitmap includes a previous subband. It may indicate whether or not it is allocated to the same MBS zone as the subband.

An apparatus for receiving a multicast broadcast service (MBS) according to another embodiment of the present invention receives area allocation information for an MBS area and a non-MBS area and MBS zone allocation information for the one or more MBS zones. A control data receiver; An area allocator for allocating each of a plurality of time intervals of MBS transport carriers to the MBS area and the non-MBS area based on the received area allocation information; An MBS zone allocator configured to allocate a time interval allocated to the MBS area to at least one MBS zone based on the MBS zone allocation information; And an MBS data receiver configured to receive MBS data through a time interval allocated to each of the one or more MBS zones, wherein the region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region. Indicates whether it is assigned to an area.

The region allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals, and each bit of the first bitmap includes a corresponding time interval allocated to the MBS region or the non-MBS. The second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the MBS region; Each bit of the map may indicate whether a corresponding time interval is allocated to the same MBS zone as the previous time interval.

The region allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals, and each bit of the first bitmap includes a corresponding time interval allocated to the MBS region or the non-MBS. Each of the MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except for the first subband among the plurality of subbands; The bit may indicate whether the corresponding subband is allocated to the same MBS zone as the previous subband.

Since the MBS transmission apparatus allocates each of the plurality of time intervals of the MBS transmission carrier to the MBS region and the non-MBS region, there is a time interval in which the MBS data is not transmitted in the MSI. Can be scheduled.

In addition, the MBS transmitting apparatus allocates each of the time intervals allocated to the MBS region to the plurality of MBS zones, thereby utilizing the time intervals of the remaining MBS zones to transmit non-MBS data to the MBS receiving apparatus that receives only a portion of the MBS zones. As such, the MBS transmission apparatus can easily schedule MBS data and non-MBS data.

In addition, the MBS transmitting apparatus allocates a subband corresponding to an unsupported MBS zone to a non-MBS region by transmitting region allocation information indicating whether each of the plurality of subbands is allocated to an existing MBS region or a non-MBS region. This can prevent bandwidth waste.

In addition, the MBS transmitting apparatus can transmit clear information to the MBS receiving apparatus with a small bit amount by transmitting the bitmap as the area allocation information and the MBS zone allocation information.

1 shows a structure of an MBS carrier according to an embodiment of the present invention.
2 shows a structure of an MBS carrier according to another embodiment of the present invention.
3 shows a structure of an MBS carrier according to another embodiment of the present invention.
4 shows a structure of an MBS carrier according to another embodiment of the present invention.
5 shows a structure of an MBS carrier according to another embodiment of the present invention.
6 shows a structure of an MBS carrier according to another embodiment of the present invention.
7 shows a structure of an MBS carrier according to another embodiment of the present invention.
8 is a block diagram showing the configuration of an MBS transmission apparatus according to an embodiment of the present invention.
9 is a flowchart illustrating the operation of an MBS transmission apparatus according to an embodiment of the present invention.
10 is a block diagram showing the configuration of an MBS receiving apparatus according to an embodiment of the present invention.
11 is a flowchart illustrating the operation of an MBS receiving apparatus according to an embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

In this specification, a mobile station (MS) includes a terminal, a mobile terminal (MT), a subscriber station (SS), a portable subscriber station (PSS), and a user equipment. It may also refer to a user equipment (UE), an access terminal (AT), and the like, and may include all or some functions of a mobile terminal, a subscriber station, a portable subscriber station, a user device, and the like.

In the present specification, a base station (BS) is an access point (AP), a radio access station (Radio Access Station, RAS), a Node B (Node B), a base transceiver station (Base Transceiver Station, BTS), MMR ( Mobile Multihop Relay) -BS and the like, and may include all or part of functions such as an access point, a radio access station, a Node B, a base transceiver station, and an MMR-BS.

In addition, the term transmit in this specification covers the concept of unicast, the concept of multicast, and the concept of broadcast (broadcast).

Hereinafter, a structure of an MBS carrier according to various embodiments of the present disclosure will be described with reference to FIGS. 1 to 7.

1 shows a structure of an MBS carrier according to an embodiment of the present invention.

In FIG. 1, a carrier for MBS transmission corresponds to a dedicated carrier and together shows a primary carrier for convenience.

Signals transmitted on the primary carrier and signals transmitted on the dedicated carrier are separated in time by superframe units. The superframe consists of a plurality of frames. A plurality of superframes in a dedicated carrier forms an MBS scheduling interval (MSI).

The signal transmitted on the dedicated carrier may be divided into a plurality of subbands on the frequency axis. All of the plurality of subbands may be allocated to the MBS region. In addition, the plurality of subbands may be allocated to the MBS area and the unused area. Each region consists of one or more subbands.

Meanwhile, the MBS region in the MSI may be divided into a plurality of MBS zones on the frequency axis. Each MBS zone consists of one or more subbands. In each MBS zone, the MBS map is located in front of the MBS scheduling interval including a plurality of superframes.

In FIG. 1, a dedicated carrier consists of three MBS zones.

However, even if the MBS transmitting apparatus uses the MBS carrier as shown in FIG. 1, the MBS receiving apparatus having one transceiver must receive the non-MBS data and the MBS data through carrier switching, and thus, the non-MBS data in a specific time interval. Receive only or receive only MBS data.

Therefore, although the MBS transmitting apparatus needs to perform scheduling to transmit the non-MBS data and the MBS data, the structure of the MBS transmitting apparatus to schedule the plurality of MBS receiving apparatuses because the MBS data is transmitted to the plurality of MBS receiving apparatuses. Can still be complicated.

In particular, since each MBS zone spans all superframes in the MSI, when the MBS receiving apparatus needs to receive data in all sections of a particular MBS zone, the MBS receiving apparatus cannot receive non-MBS data in the MSI. .

2 shows a structure of an MBS carrier according to another embodiment of the present invention.

In FIG. 2, the carrier for MBS transmission corresponds to a mixed carrier and together shows a primary carrier for convenience.

Signals transmitted on the primary carrier and signals transmitted on the mixed carrier are separated in time by superframe units. The superframe consists of a plurality of frames. A plurality of superframes in a mixed carrier forms an MBS scheduling interval (MSI).

The signal transmitted on the mixed carrier may be divided into a plurality of subbands on the frequency axis. All of the plurality of subbands may be allocated to the MBS region. In addition, the plurality of subbands may be allocated to the MBS region and the non-MBS region. Each region consists of one or more subbands.

Meanwhile, the MBS region in the MSI may be divided into a plurality of MBS zones on the frequency axis. Each MBS zone consists of one or more subbands. In each MBS zone, the MBS map is located in front of the MBS scheduling interval including a plurality of superframes.

In FIG. 2, the mixed carrier consists of three MBS zones and one non-MBS region.

However, even if the MBS transmitting apparatus uses the mixed carrier as shown in FIG. 2, the bandwidth may not be sufficient to allocate the non-MBS region of the mixed carrier to all the MBS receiving apparatuses that receive the MBS data of the mixed carrier. As a result, since the MBS transmitting apparatus requires some MBS receiving apparatus to transmit non-MBS data through a carrier other than a mixed carrier, the structure of the MBS transmitting apparatus may still be complicated.

In particular, since each MBS zone spans all superframes in the MSI, when the MBS receiving apparatus needs to receive data in all sections of a particular MBS zone, the MBS receiving apparatus cannot receive non-MBS data in the MSI. .

3 shows a structure of an MBS carrier according to another embodiment of the present invention.

In FIG. 3, signals transmitted through the MBS carrier are separated in time by superframe units. The superframe consists of a plurality of frames. A plurality of superframes in the MBS carrier forms an MBS scheduling interval (MSI).

All of the plurality of frames constituting each superframe may be allocated to the MBS region. In addition, the plurality of frames may be allocated to the MBS area and the non-MBS area. In addition, the plurality of frames can be allocated to the MBS area and the unused area.

Frames allocated to the MBS area may be allocated to a plurality of MBS zones. Each MBS zone consists of one or more frames.

The MBS map is located in front of the first frame of the plurality of frames constituting each MBS zone within the MBS scheduling interval.

The MBS transmitting apparatus generates area allocation information for transmitting allocation information for the MBS region and the non-MBS region to the MBS receiving apparatus, and separates the area allocation information for transmitting the allocation information for the MBS zone to the MBS receiving apparatus. Create MBS zone allocation information.

The area allocation information and the MBS zone allocation information according to an embodiment of the present invention are bitmaps including a plurality of bits.

The number of bits of the area allocation bitmap is equal to the number of frames constituting the subframe, and the plurality of bits respectively correspond to the plurality of frames. Each bit in the area allocation bitmap indicates whether the corresponding frame is allocated to the MBS area or the non-MBS area. In an embodiment of the present invention, the high level bits indicate that the corresponding frame is assigned to the MBS region, and the low level bits indicate that the corresponding frame is assigned to the non-MBS region.

The number of bits of the MBS zone allocation bitmap is equal to minus one from the number of frames allocated to the MBS region in each superframe in the MSI. The plurality of bits of the MBS zone allocation bitmap correspond to the remaining frames except the first frame among the frames allocated to the MBS region in each superframe. Each bit of the MBS zone allocation bitmap indicates whether or not the corresponding frame is allocated to the same MBS zone as the previous frame. In an embodiment of the invention, the low level bits indicate that the corresponding frame is assigned to the same MBS zone as the previous frame, and the high level bits indicate that the corresponding frame is assigned to a different MBS zone than the previous frame. After all, the number of bits in the high level plus one represents the number of MBS zones.

As shown in FIG. 3, each superframe in the MSI consists of four frames, the first, second, and fourth frames of each superframe are allocated to the MBS region, and the third frame of each superframe is allocated to the non-MBS region. The first and second frames of each superframe are allocated to MBS zone # 3, and the fourth frame of each superframe is allocated to MBS zone # 4. If each frame consists of one or more downlink subframes and one or more uplink subframes, the downlink subframe of each frame may be allocated to the MBS region.

Therefore, the region allocation bitmap for one MSI shown in FIG. 3 corresponds to "1101", and the MBS zone allocation bitmap corresponds to "01".

As such, since the MBS region and the non-MBS region are allocated to different time intervals in the MSI, and there is a time interval in which the MBS data is not transmitted, the MBS transmission apparatus can easily schedule the MBS data and the non-MBS data. .

In addition, according to the embodiment of FIG. 3, a plurality of MBS zones are allocated to different time intervals in the MSI, and the time intervals of the remaining MBS zones are transmitted to transmit non-MBS data to an MBS receiving apparatus that receives only a portion of the MBS zones. Since it can be utilized, the MBS transmission apparatus can easily schedule MBS data and non-MBS data.

The area allocation information and the MBS zone allocation information for the MBS carrier according to the embodiment of the present invention may both be transmitted through a system information message by the MBS transmission apparatus. The system information message is a message for periodically broadcasting system configuration information for receiving data of a non-MBS region by the MBS receiving apparatus and may correspond to a system configuration descriptor (SCD) message.

Meanwhile, since the MBS zone allocation information for the MBS carrier according to the embodiment of the present invention is necessary information only for the MBS receiving apparatus that receives the MBS, the MBS specific message such as the MBS configuration (MBS configuration, MBS-CFG) message may be used. ) May be transmitted by the MBS transmission apparatus. The MBS-CFG message includes MBS configuration information necessary for MBS operation of the MBS receiving apparatus and is broadcast by the MBS transmitting apparatus.

4 shows a structure of an MBS carrier according to another embodiment of the present invention.

The structure of the MBS carrier shown in FIG. 4 is basically similar to that of the MBS carrier shown in FIG.

However, the MBS transmitting apparatus may transmit information on the range in which the area allocation and the MBS zone allocation are valid in the MSI to the MBS receiving apparatus.

For example, if the MSI consists of 16 superframes and the MBS transmitting device sends information to the MBS receiving device that the area allocation and MBS zone allocation are valid within the MSI from the first superframe to the 14th superframe, Every frame in the 16th superframe corresponds to a non-MBS region.

5 shows a structure of an MBS carrier according to another embodiment of the present invention.

In FIG. 5, signals transmitted through the MBS carrier are classified in time in superframe units. The superframe consists of a plurality of frames. A plurality of superframes in the MBS carrier forms an MBS scheduling interval (MSI).

All of the plurality of frames constituting each superframe may be allocated to the MBS region. In addition, the plurality of frames may be allocated to the MBS area and the non-MBS area. In addition, the plurality of frames can be allocated to the MBS area and the unused area. If each frame consists of one or more downlink subframes and one or more uplink subframes, the downlink subframe of each frame may be allocated to the MBS region.

Frames allocated to the MBS area may be allocated to a plurality of MBS zones. The signal transmitted on the MBS carrier may be divided into a plurality of subbands on the frequency axis. Each MBS zone consists of one or more subframes.

The MBS map is located in front of the subbands constituting each MBS zone within the MBS scheduling interval.

The MBS transmitting apparatus generates area allocation information for transmitting allocation information for the MBS region and the non-MBS region to the MBS receiving apparatus, and separates the area allocation information for transmitting the allocation information for the MBS zone to the MBS receiving apparatus. Create MBS zone allocation information.

The area allocation information and the MBS zone allocation information according to an embodiment of the present invention are bitmaps including a plurality of bits.

The number of bits of the area allocation bitmap is equal to the number of frames constituting the subframe, and the plurality of bits respectively correspond to the plurality of frames. Each bit in the area allocation bitmap indicates whether the corresponding frame is allocated to the MBS area or the non-MBS area. In an embodiment of the present invention, the high level bits indicate that the corresponding frame is assigned to the MBS region, and the low level bits indicate that the corresponding frame is assigned to the non-MBS region.

The number of bits of the MBS zone allocation bitmap is equal to the number of subbands constituting the MBS carrier minus one. The plurality of bits of the MBS zone allocation bitmap correspond to the remaining subbands except the first subband among the plurality of subbands. Each bit of the MBS zone allocation bitmap indicates whether or not the corresponding subband is assigned to the same MBS zone as the previous subband. In an embodiment of the invention, the low level bits indicate that the corresponding subband is assigned to the same MBS zone as the previous subband, and the high level bits indicate that the corresponding subband is assigned to a different MBS zone than the previous subband. It is displayed. After all, the number of bits in the high level plus one represents the number of MBS zones.

As shown in FIG. 5, each superframe in the MSI is composed of four frames, the first, second, and fourth frames of each superframe are allocated to the MBS region, and the third frame of each superframe is allocated to the non-MBS region. The MBS carrier consists of three subbands, the first and second subbands are allocated to MBS zone # 3, and the third subband is allocated to MBS zone # 4.

Accordingly, the region allocation bitmap for one MSI shown in FIG. 5 corresponds to "1101", and the MBS zone allocation bitmap corresponds to "01".

As such, since the MBS region and the non-MBS region are allocated to different time intervals in the MSI, and there is a time interval in which the MBS data is not transmitted, the MBS transmission apparatus can easily schedule the MBS data and the non-MBS data. .

6 shows a structure of an MBS carrier according to another embodiment of the present invention.

As shown in FIG. 6, one MSI of the MBS carrier is composed of a plurality of superframes, and a plurality of superframes in the MSI may be allocated to the MBS region and the non-MBS region.

A plurality of superframes allocated to the MBS region may be allocated to a plurality of MBS zones. Each MBS zone consists of one or more superframes.

The MBS map is located in front of the plurality of superframes constituting each MBS zone.

The MBS transmitting apparatus generates area allocation information for transmitting allocation information for the MBS region and the non-MBS region to the MBS receiving apparatus, and separates the area allocation information for transmitting the allocation information for the MBS zone to the MBS receiving apparatus. Create MBS zone allocation information.

The area allocation information and the MBS zone allocation information according to an embodiment of the present invention are bitmaps including a plurality of bits.

The number of bits of the area allocation bitmap is equal to the number of superframes constituting the MSI, and the plurality of bits respectively correspond to the plurality of superframes. Each bit of the area allocation bitmap indicates whether the corresponding superframe is allocated to the MBS area or the non-MBS area. In an embodiment of the present invention, the high level bits indicate that the corresponding superframe is assigned to the MBS region, and the low level bits indicate that the corresponding superframe is assigned to the non-MBS region.

The number of bits of the MBS zone allocation bitmap is equal to the number of superframes allocated to the MBS region in the MSI minus one. The plurality of bits of the MBS zone allocation bitmap correspond to the remaining superframes except for the first superframe among the plurality of superframes allocated to the MBS region in the MSI. Each bit of the MBS zone allocation bitmap indicates whether or not the corresponding superframe is allocated to the same MBS zone as the previous superframe. In an embodiment of the invention, the low level bits indicate that the corresponding superframe is assigned to the same MBS zone as the previous superframe, and the high level bits are assigned to the MBS zone where the corresponding superframe is different from the previous superframe. It is displayed. After all, the number of bits in the high level plus one represents the number of MBS zones.

As shown in FIG. 6, the MSI consists of 16 superframes, and superframes 0, 1, 2, 3, 4, 5, 6, 7, 12, 13, 14, and 15 are allocated to the MBS region, Superframes 8, 9, 10, and 11 are allocated to non-MBS regions, superframes 0, 1, 2, 3, and 4 are assigned to MBS zone # 1, and superframes 5, 6, and 7 are assigned to MBS zone # 2. Superframes 12, 13, 14, and 15 are allocated to MBS zone # 3.

Therefore, the region allocation bitmap for one MSI shown in FIG. 6 corresponds to “1111111100001111” and the MBS zone allocation bitmap corresponds to “00001001000”.

As such, since the MBS region and the non-MBS region are allocated to different time intervals in the MSI, and there is a time interval in which the MBS data is not transmitted, the MBS transmission apparatus can easily schedule the MBS data and the non-MBS data. .

In addition, according to the embodiment of FIG. 6, a plurality of MBS zones are allocated to different time intervals in the MSI, and the time intervals of the remaining MBS zones are transmitted to transmit non-MBS data to an MBS receiving apparatus that receives only a portion of the MBS zones. Since it can be utilized, the MBS transmission apparatus can easily schedule MBS data and non-MBS data.

7 shows a structure of an MBS carrier according to another embodiment of the present invention.

As shown in FIG. 7, one MSI of the MBS carrier is composed of a plurality of superframes, and a plurality of superframes in the MSI may be allocated to the MBS region and the non-MBS region.

A plurality of superframes allocated to the MBS region may be allocated to a plurality of MBS zones. The signal transmitted on the MBS carrier may be divided into a plurality of subbands on the frequency axis. Each MBS zone consists of one or more subbands.

The MBS map is located in front of the plurality of subbands constituting each MBS zone in the MSI.

The MBS transmitting apparatus generates area allocation information for transmitting allocation information for the MBS region and the non-MBS region to the MBS receiving apparatus, and separates the area allocation information for transmitting the allocation information for the MBS zone to the MBS receiving apparatus. Create MBS zone allocation information.

The area allocation information and the MBS zone allocation information according to an embodiment of the present invention are bitmaps including a plurality of bits.

The number of bits of the area allocation bitmap is equal to the number of superframes constituting the MSI, and the plurality of bits respectively correspond to the plurality of superframes. Each bit of the area allocation bitmap indicates whether the corresponding superframe is allocated to the MBS area or the non-MBS area. In an embodiment of the present invention, the high level bits indicate that the corresponding superframe is assigned to the MBS region, and the low level bits indicate that the corresponding superframe is assigned to the non-MBS region.

The number of bits of the MBS zone allocation bitmap is equal to the number of subbands constituting the MBS carrier minus one. The plurality of bits of the MBS zone allocation bitmap correspond to the remaining subbands except the first subband among the plurality of subbands. Each bit of the MBS zone allocation bitmap indicates whether or not the corresponding subband is assigned to the same MBS zone as the previous subband. In an embodiment of the invention, the low level bits indicate that the corresponding subband is assigned to the same MBS zone as the previous subband, and the high level bits indicate that the corresponding subband is assigned to a different MBS zone than the previous subband. It is displayed. After all, the number of bits in the high level plus one represents the number of MBS zones.

As shown in FIG. 7, the MSI consists of 16 superframes, and superframes 0, 1, 2, 3, 4, 5, 6, 7, 12, 13, 14, and 15 are allocated to the MBS region, Superframes 8, 9, 10, and 11 are allocated to the non-MBS region, the first to fifth subbands are allocated to MBS zone # 1, the sixth to eighth subbands are allocated to MBS zone # 2, and the ninth 10th subband is allocated to MBS zone # 3.

Therefore, the region allocation bitmap for one MSI shown in FIG. 7 corresponds to "1111111100001111", and the MBS zone allocation bitmap corresponds to "000010010".

As such, since the MBS region and the non-MBS region are allocated to different time intervals in the MSI, and there is a time interval in which the MBS data is not transmitted, the MBS transmission apparatus can easily schedule the MBS data and the non-MBS data. .

8 is a block diagram showing the configuration of an MBS transmission apparatus according to an embodiment of the present invention.

As shown in FIG. 8, the MBS transmission apparatus 100 includes an area allocation unit 110, an area allocation information generation unit 115, an MBS zone determination unit 120, an MBS zone allocation information generation unit 125, and control. The message transmitter 140, the MBS data transmitter 150, and the non-MBS data transmitter 160 are included. Operation of components of the MBS transmission apparatus 100 according to an embodiment of the present invention will be described with reference to FIG. 9.

9 is a flowchart illustrating the operation of an MBS transmission apparatus according to an embodiment of the present invention.

The area allocator 110 allocates a part of the plurality of time intervals of the MBS transport carrier to the MBS area and the rest to the non-MBS area (S101). The time interval may correspond to a superframe, a frame, a subframe, a slot, and the like.

The area allocation information generator 115 generates area allocation information as described with reference to FIGS. 3 to 7 (S103).

The MBS zone allocator 120 allocates a plurality of time intervals allocated to the MBS area to one or more MBS zones (S105). The MBS zone allocator 120 may allocate each of the plurality of time intervals allocated to the MBS area to one of the plurality of MBS zones. In addition, the MBS zone allocator 120 may allocate each of the plurality of subbands to one of the plurality of MBS zones within a plurality of time intervals allocated to the MBS region.

The MBS zone assignment information generation unit 125 generates MBS zone assignment information as described above with reference to FIGS. 3 to 7 (S107).

The control message transmitter 140 transmits the area allocation information and the MBS zone allocation information to the MBS receiving apparatus (S113). The area allocation information and the MBS zone allocation information may be transmitted through different control messages, or may be transmitted through one control message. Both the area allocation information and the MBS zone allocation information may be transmitted through a system information message. The area allocation information may be transmitted through a system information message and may be transmitted through an MBS specific message.

The MBS data transmitter 150 multicasts or broadcasts the MBS data through a time interval allocated to the MBS area (S115). In particular, the MBS data transmitter 150 transmits MBS data for each MBS zone through a time interval or subband allocated to the MBS zone.

The non-MBS data transmitter 160 transmits non-MBS data through a time interval allocated to the non-MBS region (S117).

10 is a block diagram showing the configuration of an MBS receiving apparatus according to an embodiment of the present invention.

As shown in FIG. 10, the MBS receiving apparatus 200 includes a control message receiving unit 210, an area allocating unit 220, an MBS zone allocating unit 230, an MBS data receiving unit 250, and a non-MBS data receiving unit ( 260).

Next, the operation of the components of the MBS receiving apparatus 200 according to the embodiment of the present invention will be described with reference to FIG. 11.

11 is a flowchart illustrating the operation of an MBS receiving apparatus according to an embodiment of the present invention.

The control message receiving unit 210 receives the area allocation information and the MBS zone allocation information from the MBS transmitting apparatus (S201).

The region allocator 220 allocates a plurality of time intervals of the MBS transport carrier to the MBS region and the non-MBS region based on the region allocation information received as described with reference to FIGS. 3 to 7 (S203).

As described above with reference to FIGS. 3 to 7, the MBS zone allocator 230 allocates a plurality of time intervals allocated to the MBS area to one or more MBS zones based on the received MBS zone allocation information (S205).

The MBS data receiver 250 receives the MBS data through the time interval allocated to the MBS area (S209). In particular, the MBS data receiver 250 receives MBS data for each MBS zone through a time interval or subband allocated to the MBS zone.

The non-MBS data receiving unit 260 receives non-MBS data through a time interval allocated to the non-MBS area (S211).

As such, since the MBS transmission apparatus allocates each of the plurality of time intervals of the MBS transmission carrier to the MBS region and the non-MBS region, there is a time interval in which the MBS data is not transmitted in the MSI. Data can be easily scheduled.

In addition, the MBS transmitting apparatus allocates each of the time intervals allocated to the MBS region to the plurality of MBS zones, thereby utilizing the time intervals of the remaining MBS zones to transmit non-MBS data to the MBS receiving apparatus that receives only a portion of the MBS zones. As such, the MBS transmission apparatus can easily schedule MBS data and non-MBS data.

In addition, the MBS transmitting apparatus allocates a subband corresponding to an unsupported MBS zone to a non-MBS region by transmitting region allocation information indicating whether each of the plurality of subbands is allocated to an existing MBS region or a non-MBS region. This can prevent bandwidth waste.

In addition, the MBS transmitting apparatus can transmit clear information to the MBS receiving apparatus with a small bit amount by transmitting the bitmap as the area allocation information and the MBS zone allocation information.

According to an embodiment of the present invention, the MBS transmitting apparatus may be a base station or a relay station, and the MBS receiving apparatus may be a mobile station.

The embodiments of the present invention described above are not only implemented by the apparatus and method but may be implemented through a program for realizing the function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded, The embodiments can be easily implemented by those skilled in the art from the description of the embodiments described above.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

MBS transmission apparatus 100, area allocation unit 110, area allocation information generation unit 115,
MBS zone determination unit 120, MBS zone assignment information generation unit 125,
Control message transmitter 140, MBS data transmitter 150,
Non-MBS data transmission unit 160,
MBS receiving apparatus 200, control message receiving unit 210, area allocating unit 220,
MBS zone allocator 230, MBS data receiver 250,
Non-MBS data receiver 260

Claims (20)

In the method of transmitting a multicast broadcast service (MBS) transmission device MBS data,
Assigning each of the plurality of time intervals of the MBS transport carrier to an MBS region and a non-MBS region;
Generating region allocation information for the MBS region and the non-MBS region;
Allocating a time interval allocated to the MBS region to at least one MBS zone;
Generating MBS zone assignment information for the one or more MBS zones;
Transmitting the area allocation information and the MBS zone allocation information; And
Transmitting MBS data through a time interval allocated to the MBS region;
The region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region or the non-MBS region.
MBS data transmission method. The method of claim 1,
The area allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals.
Each bit of the first bitmap indicates whether a corresponding time period is allocated to the MBS region or the non-MBS region.
MBS data transmission method. The method of claim 2,
Allocating the time interval allocated to the MBS region to one or more MBS zones
Allocating each of the time intervals allocated to the MBS region to the one or more MBS zones,
The MBS zone allocation information indicates to which MBS zone each of the time intervals allocated to the MBS region is allocated.
MBS data transmission method. The method of claim 3,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the MBS region,
Each bit of the second bitmap indicates whether or not the corresponding time interval is allocated to the same MBS zone as the previous time interval.
MBS data transmission method. The method of claim 2,
Allocating the time interval allocated to the MBS region to one or more MBS zones
Allocating each of a plurality of subbands to the one or more MBS zones within a time interval allocated to the MBS region;
The MBS zone allocation information indicates to which MBS zone each of the plurality of subbands is allocated.
MBS data transmission method. The method of claim 5,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except the first subband among the plurality of subbands.
Each bit of the second bitmap indicates whether or not the corresponding subband is allocated to the same MBS zone as the previous subband.
MBS data transmission method. The method of claim 2,
The MBS data transmission method
Transmitting non-MBS data through a time interval allocated to the non-MBS region;
MBS data transmission method. The method of claim 2,
The non-MBS region corresponds to an unused region.
MBS data transmission method. The method of claim 2,
The area allocation information is broadcast through a system information message,
The MBS zone allocation information is broadcasted through an MBS specific message.
MBS data transmission method. In the multicast broadcast service (MBS) transmission apparatus,
An area allocator for allocating each of a plurality of time intervals of the MBS transport carrier to an MBS area and a non-MBS area;
An area allocation information generator configured to generate area allocation information for the MBS area and the non-MBS area;
An MBS zone allocator configured to allocate a time interval allocated to the MBS area to at least one MBS zone;
An MBS zone assignment information generation unit for generating MBS zone assignment information for the one or more MBS zones;
A control data transmitter for transmitting the area allocation information and the MBS zone allocation information; And
An MBS data transmitter for transmitting MBS data through a time interval allocated to the MBS region;
The region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region or the non-MBS region.
MBS transmission device. The method of claim 10,
The area allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals.
Each bit of the first bitmap indicates whether a corresponding time period is allocated to the MBS region or the non-MBS region.
MBS transmission device. The method of claim 11,
The MBS zone allocator assigns each of the time intervals allocated to the MBS area to the one or more MBS zones,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the MBS region,
Each bit of the second bitmap indicates whether or not the corresponding time interval is allocated to the same MBS zone as the previous time interval.
MBS transmission device. The method of claim 11,
The MBS zone allocator assigns each of a plurality of subbands to the one or more MBS zones within a time interval allocated to the MBS region,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except the first subband among the plurality of subbands.
Each bit of the second bitmap indicates whether or not the corresponding subband is allocated to the same MBS zone as the previous subband.
MBS transmission device. In the method for receiving a multicast broadcast service (MBS) receiving device MBS data,
Receiving area allocation information for the MBS area and the non-MBS area;
Allocating each of a plurality of time intervals of an MBS transport carrier to the MBS area and the non-MBS area based on the received area allocation information;
Receiving MBS zone allocation information for the one or more MBS zones;
Allocating a time interval allocated to the MBS region to at least one MBS zone based on the MBS zone allocation information; And
Receiving MBS data through a time interval allocated to each of the one or more MBS zones,
The region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region or the non-MBS region.
How to receive MBS data. The method of claim 14,
The area allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals.
Each bit of the first bitmap indicates whether a corresponding time period is allocated to the MBS region or the non-MBS region.
How to receive MBS data. 16. The method of claim 15,
Allocating the time interval allocated to the MBS region to one or more MBS zones
Allocating each of the time intervals allocated to the MBS region to the one or more MBS zones,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the MBS region,
Each bit of the second bitmap indicates whether or not the corresponding time interval is allocated to the same MBS zone as the previous time interval.
How to receive MBS data. 16. The method of claim 15,
Allocating the time interval allocated to the MBS region to one or more MBS zones
Allocating each of a plurality of subbands to the one or more MBS zones within a time interval allocated to the MBS region;
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except the first subband among the plurality of subbands.
Each bit of the second bitmap indicates whether or not the corresponding subband is allocated to the same MBS zone as the previous subband.
How to receive MBS data. An apparatus for receiving a multicast broadcast service (MBS),
A control data receiver for receiving area allocation information for MBS area and non-MBS area and MBS zone allocation information for the one or more MBS zones;
An area allocator for allocating each of a plurality of time intervals of MBS transport carriers to the MBS area and the non-MBS area based on the received area allocation information;
An MBS zone allocator configured to allocate a time interval allocated to the MBS area to at least one MBS zone based on the MBS zone allocation information; And
An MBS data receiver configured to receive MBS data through a time interval allocated to each of the one or more MBS zones;
The region allocation information indicates whether each of the plurality of time intervals is allocated to the MBS region or the non-MBS region.
MBS receiving device. The method of claim 18,
The area allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals.
Each bit of the first bitmap indicates whether a corresponding time interval is allocated to the MBS region or the non-MBS region,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining time intervals except for the first time interval among the time intervals allocated to the MBS region,
Each bit of the second bitmap indicates whether or not the corresponding time interval is allocated to the same MBS zone as the previous time interval.
MBS receiving device. 20. The method of claim 19,
The area allocation information includes a first bitmap composed of a plurality of bits respectively corresponding to the plurality of time intervals.
Each bit of the first bitmap indicates whether a corresponding time interval is allocated to the MBS region or the non-MBS region,
The MBS zone allocation information includes a second bitmap including a plurality of bits respectively corresponding to the remaining subbands except the first subband among the plurality of subbands.
Each bit of the second bitmap indicates whether or not the corresponding subband is allocated to the same MBS zone as the previous subband.
MBS receiving device.

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