KR101801944B1 - Method for communication using carrier switching in mobile communication system supporting multiple carrier - Google Patents

Abstract

A method for transmitting data by a base station in a Multicast Broadcast Service (MBS) supporting a multi-carrier in a wireless communication system is provided. A method for transmitting data by a base station includes receiving a switching request message from the terminal indicating which E-MBS service the terminal requests; Transmitting a switching response message including information on a switching time point between a plurality of carriers set in the terminal to the terminal; And transmitting data on the E-MBS service object from the switching time point to the terminal through the primary carrier.
Also, a method for receiving data by a terminal in an MBS supporting a multi-carrier in a wireless communication system is provided. A method for receiving data by a terminal includes: transmitting a switching request message to a base station indicating which E-MBS service the terminal requests; Receiving from a base station a switching response message including information on a switching time point between a plurality of carriers set in the terminal; Switching from a secondary carrier to a primary carrier at the switching time; And receiving data on the E-MBS service object from the base station through the primary carrier.

Description

TECHNICAL FIELD [0001] The present invention relates to a communication method using a carrier wave switching in a wireless communication system supporting multi-

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a wireless communication system supporting multi-carriers between a terminal and a base station, and more particularly, to a communication method using carrier switching for terminals that can not process a plurality of carriers at the same time.

3GPP (Long Term Evolution) and IEEE (Institute of Electrical and Electronics Engineers) 802.16m are being developed as candidates for next generation wireless communication systems. The 802.16m specification contains two aspects: the continuity of the past modification of the existing 802.16e standard and the future continuity of the specifications for the next generation IMT-Advanced system. Accordingly, the 802.16m standard requires that all the advanced requirements for the IMT-Advanced system be satisfied while maintaining compatibility with the Mobile WiMAX system based on the 802.16e standard.

Wireless communication systems typically use one bandwidth for data transmission. For example, a second-generation wireless communication system uses a bandwidth of 200 KHz to 1.25 MHz, and a third-generation wireless communication system uses a bandwidth of 5 MHz to 10 MHz. To support increasing transmission capacity, recent 3GPP LTE or 802.16m continues to expand its bandwidth to 20MHz or higher. Increasing the bandwidth to increase the transmission capacity is essential, but supporting large bandwidths even at low levels of required services can result in large power consumption.

Accordingly, there is a multi-carrier system that defines a carrier having a bandwidth and a center frequency, and can transmit and / or receive data over a plurality of carriers in a wide band. By using one or more carriers, it is possible to support narrowband and broadband at the same time. For example, if one carrier corresponds to a bandwidth of 5 MHz, it can support a maximum bandwidth of 20 MHz by using four carriers.

The IEEE 802.16m system supports Enhanced Multicast Broadcast Service (E-MBS). The E-MBS is a point-to-multipoint system in which data packets are simultaneously transmitted from one source to a plurality of destinations. Broadcast means the ability to transmit content to all users. Multicast refers to content destined for a particular group of subscribed users to receive a particular service. Static multicast and dynamic multicast can be supported.

An efficient switching method is needed to smoothly provide the E-MBS service when the UE can not process a plurality of carriers in a multi-carrier system, that is, a system in which a plurality of uplink carriers and a plurality of downlink carriers are used.

SUMMARY OF THE INVENTION The present invention provides a method of transmitting data using carrier wave switching in a wireless communication system supporting multi-carrier.

In one aspect, a method for transmitting data by a base station in a Multicast Broadcast Service (MBS) supporting a multi-carrier in a wireless communication system includes receiving from a terminal a switching request message indicating which E-MBS service the terminal requests, ; Transmitting a switching response message including information on a switching time point between a plurality of carriers set in the terminal to the terminal; And transmitting data on the E-MBS service object from the switching time point to the terminal through the primary carrier.

According to another aspect of the present invention, there is provided a method of receiving data in a MBS supporting a multi-carrier in a wireless communication system, the method comprising: transmitting a switching request message to a base station indicating which E-MBS service the terminal requests; Receiving from a base station a switching response message including information on a switching time point between a plurality of carriers set in the terminal; Switching from a secondary carrier to a primary carrier at the switching time; And receiving data on the E-MBS service object from the base station through the primary carrier.

For E-MBS service supporting multi-carrier operation, different carriers can be switched to operate without delay or interruption of data and service.

1 shows a wireless communication system.
2 shows an example of a protocol structure for supporting multicarrier.
3 shows an example of a frame structure for multi-carrier operation.
4 is a flowchart illustrating a carrier wave switching process according to the present invention.
5 shows an example of a switching period according to the present invention.
6 shows that the inverse switching time according to the present invention is earlier than the original time or delayed.
Figure 7 shows the forwarding or delaying of the switching time according to the invention.
8 shows an example of the base station informing the switching information through the MBS MAP.
FIG. 9 shows an example of informing switching information through an MBS MAP in a super frame.
FIG. 10 shows an example in which the MBS MAP includes a plurality of pieces of switching information.

1 shows a wireless communication system. The wireless communication system 10 includes at least one base station 11 (BS). Each base station 11 provides a communication service to a specific geographical area (generally called a cell) 15a, 15b, 15c. The cell may again be divided into multiple regions (referred to as sectors). A mobile station (MS) 12 may be fixed or mobile and may be a user equipment (UE), a mobile terminal (MT), a user terminal (UT), a subscriber station (SS), a wireless device, (personal digital assistant), a wireless modem, a handheld device, and the like. The base station 11 generally refers to a fixed station that communicates with the mobile station 12 and may be referred to in other terms such as an evolved-NodeB (eNB), a Base Transceiver System (BTS), an access point, have. Hereinafter, downlink refers to communication from a base station to a terminal, and uplink refers to communication from a terminal to a base station. In the downlink, the transmitter may be part of the base station, and the receiver may be part of the terminal. In the uplink, the transmitter may be part of the terminal, and the receiver may be part of the base station.

The size (i.e. bandwidth) of the multi-carriers may be different. For example, assuming that five carriers are used for a 70 MHz band configuration, a 5 MHz carrier (carrier # 0) +20 MHz carrier (carrier # 1) +20 MHz carrier (carrier # 2) +20 MHz carrier (carrier # 3) + 5MHz carrier (carrier # 4).

A multiple carrier system (MCS) refers to a system that supports multi-carrier based on spectral aggregation.

2 shows an example of a protocol structure for supporting multicarrier. A common Medium Access Control (MAC) entity 210 manages a PHY (physical) layer 220 using a plurality of carriers. A MAC management message sent on a specific carrier may be applied to other carriers. PHY layer 220 may operate in Time Division Duplex (TDD) and / or Frequency Division Duplex (FDD).

3 shows an example of a frame structure for multi-carrier operation. A superframe is composed of four radio frames F0, F2, F3 and F3, and each radio frame is composed of eight subframes. The subframe includes a plurality of OFDM symbols. The superframe header (SFH) is located in the first subframe in the superframe. SFH refers to a unit in which a plurality of frames are transmitted, and includes essential system parameters and system configuration information, and is transmitted to the UE. P-SFH (Primary SFH) and S-SFH (Secondary SFH), and P-SFH is mainly transmitted in every superframe. The P-SFH defines whether the S-SFH is transmitted or not, and the period can be transmitted in one or more superframe units. Each carrier can have its own SFH. SFH is transmitted over the broadcast channel and carries essential system parameters. Some carriers may have only a fraction of the SFH. The multi-carriers may or may not be adjacent to each other. The terminal may support one or more carriers according to its capabilities.

The carriers may be divided into a fully configured carrier and a partially configured carrier depending on the directionality. A full set carrier is a bidirectional carrier and refers to a carrier capable of transmitting and / or receiving all control signals (synchronization, broadcast, multicast, unicast control signal) and data, It is applicable to both terminal and terminal. The partially set carrier refers to a carrier capable of transmitting only downlink data in a unidirectional carrier and refers to a downlink carrier in the TDD scheme or a downlink carrier not paired with the uplink carrier in the FDD scheme. The partial set carrier may be mainly used for Multicast and broadcast service (MBS) and / or Single Frequency Network (SFN), but the UE can not perform network entry or handover to a partially set carrier.

Carriers can be divided into a primary carrier and a secondary carrier depending on whether they are active or not. The primary carrier is a carrier that is always active and is a carrier through which traffic and a PHY / MAC control signal are transmitted between the base station and the terminal. Even if the base station supports multi-carrier, (single carrier mode), communication is performed on only one carrier wave. The secondary carrier is a carrier that is activated / deactivated according to a specific condition, which is an additional carrier to the primary carrier and is used for transmission of traffic or for a particular command or rule applied from the primary carrier. Here, activation means that transmission or reception of traffic data is performed or is in a ready state. Deactivation means that transmission or reception of traffic data is impossible and measurement or transmission or reception of minimum information is possible.

In one common MAC (MAC) of a multi-carrier system, radio resources are made through a primary carrier and one or more secondary carriers. However, full control of the mobility, state, and context of the terminal is performed only through the primary carrier.

The terminal may use only one primary carrier or use one or more secondary carriers in addition to the primary carrier. A terminal may receive a primary carrier and / or a secondary carrier from a base station. The primary carrier may be a pre-set transfer file and is a carrier on which the primary control information between the base station and the terminal is exchanged. The secondary carrier can be a pre-set carrier or a partially-configured return file, and is a carrier that is allocated according to the request of the terminal or the instruction of the base station.

The primary carrier may be used for network entry of the terminal and / or allocation of the secondary carrier. The primary carrier may be selected from a full set of carriers, rather than being fixed to a particular carrier. A carrier set to a secondary carrier can also be changed to a primary carrier.

The carrier switching will be described below.

In a wireless communication system supporting a multi-carrier, it is possible to switch a corresponding physical layer connection of a mobile station from a primary carrier to a secondary carrier or to switch from a secondary carrier to a primary carrier according to an instruction of a base station . This is called carrier switching. In particular, carrier switching occurs frequently when the secondary carrier is a partially set carrier. When a terminal is connected to a secondary carrier for a certain period of time, the terminal does not need to continue the connection between the primary carrier and the physical layer.

Carrier switching may be performed by a MAC management message transmitted on a primary carrier in a periodic or event-triggered manner. When a terminal is switched to a secondary carrier, the primary carrier of the terminal provides basic information such as timing and frequency adjustment for synchronizing with the secondary carrier.

In the MAC management message transmitted by the UE for switching the carrier wave, a plurality of pieces of information are transmitted through a carrier, including a target partial set carrier, a switching mode, a start time, a switching interval, A switching period, and the like.

The switching mode refers to either a periodic switching mode or an event-triggered switching mode. The switching time refers to a time point from a certain carrier to another carrier, and can be expressed by a super frame number. The switching period refers to the time to stay on the carrier after being switched. For example, when switching from the primary carrier to the secondary carrier, it is time to stay on the secondary carrier. The switching period corresponds to the periodic switching, and refers to the time from the previous switching point to the next switching point. The switching period or the switching period may be expressed in superframe units.

When switching from the primary carrier to the secondary carrier, it is possible to switch from the secondary carrier to the primary carrier again after the switching period, which is called reverse switching. Conversely, when switching from the secondary carrier to the primary carrier, switching from the primary carrier to the secondary carrier after switching period is reverse switching.

When an E-MBS service is provided in a multicarrier system, an interval having a certain pattern in which a plurality of frames are simultaneously transmitted is called an MBS Scheduling Interval (MSI). There is at least one control channel in the MSI interval, and the user mainly instructs the super frame header to search for the position and area of the control channel. The control channel may include an MBS MAP. The MBS MAP indicates where the MBS data burst is located.

In an E-MBS service of a general multi-carrier system, carrier switching is performed by instructing a switching point, a switching period, and a switching period from a base station to a mobile station. However, considering the transmission of data for the uplink of the UE and the E-MBS service, it is necessary to further subdivide and switch efficiently.

Hereinafter, the switching from the secondary carrier to the primary carrier according to the present invention will be described. In the case of the E-MBS service, since a base station transmits data unidirectionally to a plurality of terminals at the same time, it is often a partial set carrier supporting a downlink and often performs a service through a carrier, which is a secondary carrier. In the case of the secondary carrier, since it is not possible to perform uplink transmission from the terminal to the base station, it may be necessary to perform carrier switching from the secondary carrier to the primary carrier. However, the scope of the invention is not limited thereto.

The base station calculates the switching start time and informs the terminal through the DSA process. However, if the base station calculates the switching start time but does not have a point in time available, the base station may receive a request from the terminal. Even before switching to the primary carrier, i.e., in a situation where data is being transmitted on the secondary carrier, the base station may be requested to start switching from the terminal. At this time, the base station can open and monitor an uplink control channel (UL control channel) capable of receiving a signal of the terminal. The uplink control channel may exist in the primary carrier or in the secondary carrier.

4 is a flowchart illustrating a carrier wave switching process according to the present invention.

Referring to FIG. 4, the MS transmits a switching request message to the BS in order to indicate which E-MBS service it is requesting (S410). The base station transmits a switching response message including information on switching times between a plurality of carriers set in the terminal to the terminal (S420). In step S430, the MS refers to the switching response message, switches the carrier from the secondary carrier to the primary carrier at the switching time, and receives data from the BS through the primary carrier from the switching point. And may be switched back from the primary carrier to the secondary carrier after the switching period.

When the carrier switching is performed (for example, when the carrier switching mode is 0b1), the UE can inform the base station of which E-MBS service (or content) is to be received through the switching request message . For example, the switching request message may be an E-MBS notification message (E-MBS-REP message). After receiving the switching request message, the BS calculates an interval during which the UE can perform the unicast scheduling on the primary carrier. In this case, the E-MBS connection bitmap of the switching request message can be used. The base station schedules the unicast service of the terminal on the primary carrier based on the valid period calculated using the E-MBS connection bitmap in the switching request message. When the MS changes the E-MBS service concurrently received, the MS transmits a switching request message including the updated E-MBS connection bitmap.

The switching request message is transmitted from the terminal to the base station when one of the following conditions is satisfied.

1. When the terminal requests a start time to switch to the E-MBS carrier after DSA, DSC or DSD transaction from the base station.

2. Updating an indication of the E-MBS stream that the current terminal receives without releasing the assigned E-MBS connection via the DSA-REQ or DSA-RSP message.

3. If the UE indicates the time to stop E-MBS carrier switching without releasing the allocated E-MBS connection via the DSA-REQ or DSA-RSP message

The switching request message may be transmitted through at least one of a ranging, a subheader, an existing MAC management message, a new MAC management message, or a control channel.

Table 1 below is an example showing a switching request message.

Attributes / Array of attributes Size (bits) Value / Notes Conditions MAC Control Message Type 8 AAI_E-MBS-REP message E-MBS Zone ID 7 Indicates E-MBS Zone from which the AMS is currently receiving E-MBS data Report Mode 2 Indicates the AMS starts / changes / ends E-MBS
0b00: AMS requests ABS to assign a carrier switching start time
0b01: AMS updates E-MBS connection Bitmap
0b10: AMS ends E-MBS carrier switching
0b11: reserved E-MBS Connection Bitmap 16 Each bit of the bitmap represents an E-MBS connection for which service flows have been established.
The E-MBS service (s) are mapped in ascending order of their E-MBS ID + FID value from LSB to MSB of the bitmap.
For each bit:
Value 0: The AMS does not intend to receive the E-MBS service.
Value 1: The AMS may currently receive E-MBS or the AMS may switch to the near future. Shall be included if the value of Report Mode is 0b01.

Referring to Table 1, the E-MBS connection bitmap may be composed of 16 bits as an example and may be included when the report mode is 0b01. Each bit of the E-MBS connection bitmap represents an E-MBS connection in which a service flow is created using DSA, DSC or DSD processing in one E-MBS zone. The E-MBS service is mapped from the LSB to the MSB of the bitmap in ascending order of the sum of the E-MBS ID and the FID value. If the bit is 0, the UE does not receive the E-MBS service and if the bit is 1, the UE receives the E-MBS or switches it to receive it in the near future.

The base station receiving the switching request message through the uplink control channel replies with a switching response message. At this time, the base station refers to the E-MBS service (or the content) received by the UE through the switching request message or the E-MBS service (or the content) And transmits a switching response message so that carrier switching is performed. In particular, the MBS MAP defining the E-MBS service (or the content) may indicate the time and period of receiving the corresponding E-MBS service (or contents) and the time point of switching the carrier again to the primary carrier. The switching response message may be referred to as an E-MBS response message (E-MBS-RSP message).

Table 2 below is an example showing a switching response message.

Attributes / Array of attributes Size (bits) Value / Notes Conditions MAC Control Message Type 8 AAI_E-MBS-RSP message Carrier Switching Start time 4 4 LSBs of superframe number at which the AMS switches carrier to receive E-MBS Present when the report mode is AAI_E-MBS-REP message is 0b00 Unicast Available Interval Bitmap Variable Indicates when the AMS should be available in the primary carrier using N bits b _o b ₁ b ₂ ... b _{N -1 1}
If b _i == 0, then AMS is available for E-MBS data scheduling in secondary carrier
If b _i == 1, then AMS is available for unicast scheduling in primary carrier

N _MSI = 2 superframes: N = 4 bits
N _MSI = 4 superframes: N = 4 bits
N _MSI = 8 superframes: N = 8 bits
N _MSI = 16 superframes: N = 16 bits
Depending on the N _MSI , the number of bits per subframe changes
If N _MSI = 2, then 2 frames per bit
If N _MSI = 4, 8 and 16, then 4 frames per bit Present when the report mode is AAI_E-MBS-REP message is 0b01

Referring to Table 2, the switching response message includes a Unicast Available Interval Bitmap, and the unicast valid interval bitmap is available when the terminal is available on the primary carrier using an N-bit bitmap, Whether or not it is. That is, it indicates whether the terminal can receive the control signal through the primary carrier. For example, if each bit of the unicast valid interval bitmap is 0, the UE is enabled to perform E-MBS data scheduling on the secondary carrier, and if 1, the unicast scheduling is effective on the primary carrier. Depending on the number of superframes in the MSI, the size of the unicast valid interval bitmap may vary.

After the MS receives the switching response message and switches the carrier from the secondary carrier to the primary carrier at the switching time, the MS receives data from the BS through the primary carrier from the switching point. The switching period may be switched back from the primary carrier to the secondary carrier again after the switching period, which is the time for the carrier to stay on the switched carrier.

On the other hand, the switching period may be the MSI period or the transmission period of the MBS MAP.

5 shows an example of a switching period according to the present invention. The switching section consists of four superframes. The MBS MAP 501 is transmitted to the first superframe and the MBS MAP 502 is transmitted to the fifth superframe. In this case, the reverse switching is performed in the fifth superframe in which the MBS MAP is transmitted without performing the second superframe. That is, the switching period is four superframes, which is the transmission period of the MBS MAP. However, the four superframes are only examples, and the switching period may be longer or shorter.

Because of the characteristics of the E-MBS service, one base station performs several services to the terminal, and the base station transmits the signal and the terminal receives the signal in most cases. The terminal occasionally transmits a control signal to the base station. In this way, even if the terminal is only receiving from the base station in many cases, if switching is performed every superframe, the service may be delayed and quality of service (QoS) may not be satisfied.

It is more effective to perform carrier switching in accordance with the MSI period or the MBS MAP transmission period composed of one or more superframes instead of the super frame unit, Can be solved. Here, FIG. 5 shows only one example of the present invention. The transmission period of the MSI period or MBS MAP may be different from that of FIG. 5, and thus the switching period may vary.

The switching time or reverse switching time may be delayed or delayed. Also, as the switching time and the reverse switching time are changed, the switching period can be extended or shortened. In the case of E-MBS service, there are many cases in which MSI has a certain pattern. Such pattern is mainly performed in superframe. It is favorable for things with fixed patterns, but not for patterns that vary.

6 shows the reverse switching timing according to the present invention ahead of or behind the original timing.

Referring to FIG. 6, when reverse switching from a secondary carrier to a primary carrier occurs, there is a case where transmission of data is delayed or transmission of additional data is required, and a period for transmitting a signal to a secondary carrier may be extended , And delaying the inverse switching time (S610). Conversely, even in a switching period, there may be a case where a reverse carrier must be immediately switched to a primary carrier for transmission of uplink data. This can be solved by advancing the reverse switching time (S620).

Figure 7 shows the forwarding or delaying of the switching time according to the invention.

Referring to FIG. 7, there may occur a case where switching is not desired, or a change point is to be pulled or delayed. In switching from the secondary carrier to the primary carrier, the switching point itself is advanced (S710) (S720), the switching time can be flexibly adjusted. It can be an effective response when the control information must be immediately transmitted to the primary carrier or when the transmission of data is delayed.

Hereinafter, a method of informing the switching time and the switching period information will be described.

8 shows an example of the base station informing the switching information through the MBS MAP. In the MBS MAP 801, a superframe after two superframes is indicated as a switching time point. At step S820, the mobile station switches from the primary carrier to the secondary carrier at step S810. At step S820, the mobile station remains on the secondary carrier for the switching period indicated by the MBS MAP. Here, the switching timing after 2 superframes is merely an example, and the switching time and the switching period may be changed. The switching time may be an offset value from the superframe including the MBS MAP, or may be a number of the superframe. Or the start time of the MBS area of the data area of the super frame including the MBS MAP.

FIG. 9 shows an example of informing switching information through an MBS MAP in a superframe. The SFH 901 instructs the MBS MAP 902 (S910), and instructs the switching time and the switching interval in the MBS area 903 of the data area through the MBS MAP (S920). And transmits data during the switching period after switching at the switching point.

When the MBS MAP of the primary carrier includes control information such as a switching time point, the UE recognizes the MBS area indicated by the MBS MAP and switches to a secondary carrier at a certain point in the MBS area as a switching point have. In this case, the switching period may be a period from the switching time point to the end of the MBS area. When the switching period ends, the second carrier may be switched back to the first carrier.

The MBS MAP may include not only one switching time and switching period but also information of the next switching time and the next switching period.

FIG. 10 shows an example in which the MBS MAP includes a plurality of pieces of switching information. The first switching (S1011) and the reverse switching (S1012) can be performed by the instruction of the MBS MAP (S1010). If the MBS MAP includes the next switching time and the next switching interval information, the UE performs a first switching operation from the next switching time to the secondary carrier from the next switching time by the instruction of the MBS MAP (S1020) (S1021). Data can be transmitted or received during a section switched to the primary carrier, and reverse switching (S1022) can be performed after the end of the next switching section.

On the other hand, switching can be applied not only to MBS MAP but also to content. At this time, the MBS MAP defining the content can also indicate the time and period for receiving the content and the time point of switching the carrier again to the primary carrier.

The switching time, the switching period, and the switching time from the secondary carrier to the primary carrier are not only the MBS MAP, but also a multicarrier related message, another MBS MAP, a subheader, an existing MAC management message, a new MAC management message, But also through a combination of one or more of the control channels.

The above-described embodiments include examples of various aspects. While it is not possible to describe every possible combination for expressing various aspects, one of ordinary skill in the art will recognize that other combinations are possible. Accordingly, it is intended that the invention include all alternatives, modifications and variations that fall within the scope of the following claims.

Claims (15)

A method for transmitting data by a base station in a multicast broadcast service (MBS) supporting a multi-carrier in a wireless communication system,
Receiving a switching request message from the terminal indicating which E-MBS service the terminal requests;
Transmitting a switching response message including information on a switching time point between a plurality of carriers set in the terminal to the terminal; And
And transmitting data on the E-MBS service requested by the UE to the UE through the primary carrier from the switching time point,
The switching response message includes a unicast available bitmap indicating whether or not unicast scheduling from the primary carrier to the terminal is available after switching from a secondary carrier to the primary carrier, And an Interval Bitmap). The method according to claim 1,
The switching request message includes an E-MBS connection bitmap, and each bit of the E-MBS connection bitmap is transmitted in one E-MBS zone using DSA, DSC, or DSD processing MBS connection in which a flow is generated. delete The method according to claim 1,
Wherein the switching time point can be advanced or delayed. The method according to claim 1,
Wherein the switching request message or the switching response message further includes a switching interval that is a period during which the switching request message or the switching response message is continuously switched,
Wherein the switching period can be extended or shortened.
The method according to claim 1,
Wherein the switching response message is included in an MBS MAP. The method according to claim 6,
The switching point is a point in the MBS region of the MBS MAP,
Wherein the switching time is determined by the base station. 6. The method of claim 5,
And switching back from the primary carrier to the secondary carrier at the end of the switching period. The method according to claim 6,
Switching from the secondary carrier to the primary carrier at the next switching time by referring to information of the next switching time and a next switching interval when the MBS MAP includes information on a next switching time and a next switching interval ; And
Further comprising the step of the terminal receiving data from the base station on the primary carrier during the next switching interval. The method according to claim 6,
The switching time is a time point at which the transmission ends in an MBS region indicated by the MBS MAP of the secondary carrier,
And switching from the secondary carrier to the primary carrier at the start of the next MBS MAP when the MBS MAP indicates the next MBS MAP. The method according to claim 6,
If the MBS MAP further includes information on a next switching time and a next switching interval, the MBS MAP switches back from the secondary carrier to the primary carrier at the next switching time by referring to the information of the next switching time and the next switching interval step; And
Further comprising the step of the terminal receiving data from the base station on the primary carrier during the next switching interval. The method according to claim 1,
The switching request message includes:
When the MS requests a point of time to switch to a carrier wave after DSA, DSC or DSD transaction from the BS, it does not release the allocated E-MBS connection via the DSA-REQ or DSA-RSP message When the UE updates an indication of an E-MBS stream currently received by the UE or does not release an E-MBS connection allocated via a DSA-REQ or DSA-RSP message, the UE performs E-MBS carrier switching And indicating the time to stop the transmission of the data. A method for receiving data in a Multicast Broadcast Service (MBS) supporting a multi-carrier in a wireless communication system,
Sending a switching request message to the base station indicating which E-MBS service the terminal requests;
Receiving from a base station a switching response message including information on a switching time point between a plurality of carriers set in the terminal;
Switching from a secondary carrier to a primary carrier at the switching time; And
And receiving data on the E-MBS service requested by the terminal from the base station through the primary carrier,
The switching response message includes a Unicast Available Interval Bitmap indicating whether or not unicast scheduling is enabled in the primary carrier after switching to the primary carrier. Wherein the data reception method comprises: 14. The method of claim 13,
The switching request message includes an E-MBS connection bitmap, and each bit of the E-MBS connection bitmap is transmitted in one E-MBS zone using DSA, DSC, or DSD processing MBS connection in which a flow is generated. delete

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