KR20130081621A - Method and apparatus for providing communication service to a mobile station by cooperating a plurality of base stations in a wireless communication system - Google Patents

Abstract

PURPOSE: A method enabling multiple base stations to cooperatively provide a communications service to a single terminal in a wireless communications system and a device thereof are provided to utilize limited resources more efficiently. CONSTITUTION: A control part (820) changes component base stations forming a first cooperation cell based on a resource request response message. The control part allocates resources to a terminal served by the first cooperation cell. A transmission part (800) transmits a resource request message requesting resource allocation to sub-base stations which belong to the first cooperation cell. A reception part (810) receives a resource request response message from each of the sub-base stations receiving the resource request message. The resource request response message includes a result obtained through the control of resource approval considering all the cooperation cells to which each sub-base station belongs. [Reference numerals] (800) Transmission part; (810) Reception part; (820) Control part; (AA) Base station

Description

TECHNICAL AND APPARATUS FOR PROVIDING COMMUNICATION SERVICE TO A MOBILE STATION BY COOPERATING A PLURALITY OF BASE STATIONS IN A WIRELESS COMMUNICATION SYSTEM}

The present invention relates to a method and apparatus for providing a communication service to one terminal by a plurality of base stations of the communication system in cooperation.

Each of the terminals included in the wireless communication system may have a virtual cell that is fluidly formed according to a movement path, and the virtual cell may be understood as a kind of cooperative cell formed for cooperative communication between base stations. The cooperative cell includes at least one base station, and when the cooperative cell including the at least one base station includes two or more base stations, each base station of the cooperative cell simultaneously transmits the same data or different data to the corresponding terminal. Alternatively, it can be transmitted with a time difference.

For example, assuming that the cooperative cell includes two base stations, one base station plays a role of allocating the cooperative cell resource as a master base station and the other base station as a slave base station. It helps to provide a service to the terminal. Since the cooperative cell is formed flexibly according to the movement path of the terminal, the role of the base station in the cooperative cell is also flexible. That is, the primary base station in the first cooperative cell may be changed to another base station, and the primary base station in the first cooperative cell formed to serve the first terminal is a secondary base station in the second cooperative cell formed to serve the second terminal. It may work.

As such, when one base station belongs to several different cooperative cells at the same time, a method for efficiently allocating resources of each base station is required. The main base station of each cooperative cell may use a central control scheme for allocating resources of all base stations in the cooperative cell, or may use a distributed control scheme for each base station of each cooperative cell to perform resource allocation. However, in the case of the central control method, in case of a base station belonging to several cooperative cells at the same time, a resource allocation command from the main base station of each cooperative cell may allocate the same resource and cause a collision. Tuning this can incur significant overhead and time delays. In addition, the distributed control method may not be effective in taking advantage of system yield improvement through inherent cell-to-cell cooperation. Therefore, a method for more efficiently allocating cooperative cell resources is required.

The present invention proposes a method and apparatus for configuring / reconfiguring a cooperative cell in order to provide a communication service to one terminal in cooperation with a plurality of base stations in a wireless communication system.

In addition, the present invention proposes a method and apparatus for determining a primary base station and a secondary base station for providing a communication service in a wireless communication system based on a cooperative cell.

In addition, the present invention proposes a cooperative method and apparatus for efficient resource allocation between a primary base station and a secondary base station in a wireless communication system based on a cooperative cell.

The method proposed by the present invention comprises: A method of providing a service to a terminal by cooperating a plurality of base stations in a wireless communication system, the method comprising: configuring a first cooperative cell in which one primary base station includes at least one secondary base station; A result obtained by transmitting a resource request message for requesting resource allocation to secondary base stations belonging to the cooperative cell, and resource admission control considering all cooperative cells belonging to the secondary base stations belonging to the first cooperative cell; Receiving a resource request response message comprising a; changing the configuration base station constituting the first cooperative cell based on the resource request response message; and resource allocation to the terminal serving in the first cooperative cell It includes the process of implementation.

Another method proposed by the present invention is as follows. A method of providing a service to a terminal by cooperating a plurality of base stations in a wireless communication system, the method comprising: configuring a first cooperative cell including at least one secondary base station by one primary base station; When determining to change the base station, transmitting a primary base station request message requesting the change to the primary base station to the at least one secondary base station, and may be a primary base station from one of the at least one secondary base station Receiving an acknowledgment indicating an acknowledgment, determining a secondary base station transmitting the acknowledgment as a new primary base station of the first cooperative cell, and a primary base station change message informing of the determined new primary base station. Transmitting to at least one secondary base station, and wherein the determined new primary base station is Even it includes the step of cooperation with one of the sub-base station providing a service to the MS.

Another method proposed by the present invention is as follows. A method of receiving a service from a plurality of base stations by a terminal in a wireless communication system, the method comprising: receiving a measurement indication message instructing to measure a channel of neighbor base stations from a primary base station included in a first cooperative cell; Transmitting a measurement report message including a channel measurement result of base stations, receiving configuration information on the first cooperative cell including the primary base station and at least one secondary base station from the primary base station, and And receiving a service provided by the base station and the at least one secondary base station in cooperation.

The apparatus proposed in the present invention comprises: A base station in which a plurality of base stations cooperate to provide a service to a terminal in a wireless communication system, wherein one primary base station configures a first cooperative cell including at least one secondary base station, and based on the resource request response message; A control unit for changing a well-known base station constituting a first cooperative cell and allocating resources to a terminal serving in the first cooperative cell, and a resource request message for requesting resource allocation to sub-base stations belonging to the first cooperative cell. And a transmitting unit for transmitting and a receiving unit for receiving the resource request response message including a result obtained through resource admission control considering all of the cooperative cells to which the secondary base stations belonging to the first cooperative cell belong.

Another apparatus proposed in the present invention is a system comprising: A base station in which a plurality of base stations cooperate to provide a service to a terminal in a wireless communication system, wherein a primary base station constitutes a first cooperative cell including at least one secondary base station and may be a primary base station. A controller for determining a secondary base station which has transmitted a response as a new primary base station of the first cooperative cell, and controlling the determined new primary base station to provide a service to the terminal in cooperation with the at least one secondary base station; Upon determining to change the primary base station of the first cooperative cell, the primary base station request message for requesting the change to the primary base station is transmitted to the at least one secondary base station, and the terminal transmits a primary base station change message indicating the determined new primary base station. And a transmitting unit transmitting to the at least one secondary base station, the at least And a receiving unit for receiving the acknowledgment from one of the secondary base stations.

Another apparatus proposed in the present invention is a system comprising: A terminal receiving a service from a plurality of base stations in a wireless communication system, the terminal comprising: a measurement indication message indicating to measure a channel of neighboring base stations from a primary base station included in a first cooperative cell; Receiving unit for receiving the configuration information for the first cooperative cell consisting of a secondary base station, a service provided by the primary base station and the at least one secondary base station in cooperation with, and including the channel measurement results of the neighboring base stations And a transmitter for transmitting the measurement report message.

The present invention proposes a method of providing a communication service to a single terminal by cooperating a plurality of base stations in a wireless communication system, thereby making it possible to use limited resources more efficiently and thereby improving the quality of service provided to the terminal. .

According to the present invention, in a central control method, a base station belonging to several cooperative cells at the same time can prevent a collision caused by overlapping allocation of the same resource from a primary base station of each cooperative cell.

According to the present invention, in a distributed control scheme, a base station belonging to several cooperative cells at the same time may prevent a collision caused by a duplicate resource allocation command from a primary base station of each cooperative cell.

1 is a diagram illustrating a procedure of configuring a cloud cell in a communication system according to a first embodiment of the present invention;
2 is a diagram illustrating a procedure for reconfiguring a cloud cell in a communication system according to a second embodiment of the present invention;
3 is a diagram illustrating a procedure for changing a primary base station in a cloud cell based communication system according to a third embodiment of the present invention;
4 is a diagram illustrating a procedure for changing a primary base station in a cloud cell based communication system according to a fourth embodiment of the present invention;
5 is a diagram illustrating a process of configuring and reconfiguring a cloud cell by a base station in a communication system;
6 is a diagram illustrating a process of changing a primary base station in a cloud cell based communication system;
7 is a diagram illustrating a procedure for allocating resources to terminals in which a primary base station to which the present invention is applied is configured as the primary base station;
8 is a diagram illustrating a base station apparatus for performing cloud cell configuration / reconfiguration and changing a primary base station in a cloud cell as a plurality of base stations provide a service to one terminal in a communication system;
9 is a diagram illustrating a terminal device performing an operation according to one terminal receiving a service provided from a plurality of base stations.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the operation of the present invention are described, and other background techniques are omitted so as not to disturb the gist of the present invention.

According to the present invention, a plurality of base stations provide a communication service to one terminal in a cell in which a plurality of base stations transmit the same data or different data to one terminal simultaneously or at a time difference, that is, a cooperative cell formed for cooperative communication between the base stations. It proposes a method and apparatus to provide. Hereinafter, the cooperative cell is called cloud cells.

1 is a diagram illustrating a procedure of configuring a cloud cell in a communication system according to a first embodiment of the present invention.

Referring to FIG. 1, a communication system includes a terminal 100, a first base station 102, a second base station 104, a third base station 106, and a fourth base station 108.

The terminal 100 performs a network entry operation to one base station of one of neighbor neighbor base stations close to itself, for example, the first base station 102 (step 110), and then the first base station 102 performs a main base station. Operation (step 112). The first base station 102 acting as the primary base station transmits a measurement indication message to the terminal 100 (step 114) to instruct to measure channels of neighboring base stations, and the terminal 100 instructs the first base station to measure the channel of the neighbor base stations. After measuring the channel of the fourth base station (102-108) and transmits the result to the current primary base station, that is, the first base station 102 through a measurement report message (step 124). The measurement report message may be sent periodically or may be sent by the command of the primary base station.

Upon receiving the measurement report message, the first base station 102 determines a member of the neighboring base stations of the neighboring base stations based on the channel state of the neighboring base stations included in the measurement report message (step 126). The first base station 102 determines a member of the cloud cell centered on base stations having excellent channel conditions according to a predetermined criterion. In addition, the first base station 102 determines the base station having the best channel state among the determined cloud cell members as the primary base station and other base stations as the secondary base station. Then, information about the determined member, that is, configuration information, is transmitted to the terminal 100 and the determined members, that is, the second and third base stations 104 and 106 (steps 130 and 132).

The base stations which receive the configuration information from the first base station perform operations as the primary base station or the secondary base station according to the configuration information. The first base station 102 operates as the first secondary base station (step 136), the second base station 104 operates as the primary base station (step 138), and the third base station 106 operates as the second secondary base station. (Step 140). Thus, the cloud cell is composed of a second base station 104, which is a primary base station, a first base station 102, and a third base station 106, which are secondary base stations.

2 is a diagram illustrating a procedure for reconfiguring a cloud cell in a communication system according to a second embodiment of the present invention.

In FIG. 2, a cloud cell including a primary base station 202 and first and second secondary base stations 204 and 206 is described as an example, but the cloud cell may be configured with one primary base station and one or more secondary base stations. Of course.

The primary base station 202 transmits a resource request message for requesting resource allocation to the first and second secondary base stations 204 and 206 at every scheduling period (step 210 and step 212). In addition, the primary base station 202 may transmit a resource allocation request message to the first and second secondary base stations 204 and 206 as necessary, even if the scheduling period is not fixed. The resource request message includes the amount of resources required and the type of traffic to be serviced (for example, real-time traffic, non-real-time traffic, etc.), and in particular, the maximum delay time allowed when the type of the serviced traffic is real-time traffic (hereinafter, 'maximum Delay time ').

Upon receiving the resource request message, the first and second secondary base stations 204 and 206 perform resource admission control for determining whether to approve the resource allocation request (steps 214 and 216). In this case, the first and second secondary base stations 204 and 206 first allocate resources to a request in which the type of traffic is real-time traffic. If there are a plurality of real-time traffic requests, resources are allocated to the requests with the shortest maximum delay time. If the maximum delay time is the same, resources are first allocated to a secondary base station serving as a primary base station in another cloud cell among the first and second secondary base stations 204 and 206.

Then, each of the first and second secondary base stations 204 and 206 transmits a resource request response message including a resource grant result to the primary base station 202 in response to the resource request message (steps 216 and 218). .

The resource request response message is transmitted as an acknowledgment (ACK: ACKnowledge) message when the resource is allocated as much as requested by the primary base station 202, and a negative response when the resource is not allocated as much as requested by the primary base station 202. It is sent as a (NACK: Negative-ACKnowledge) message. The negative response message may simply include only information indicating the rejection of resource allocation, and the main base station 202 may allocate an amount of resources (possibly from zero) for the terminal 200 requested and the reason for rejecting the resource allocation. May optionally be included. Reasons for refusing the resource allocation may be as follows.

Reasons for Rejection 1. The traffic priority of the other cloud cells to which the first and second secondary base stations 204 and 206 belong is higher.

Reason for rejection 2. The maximum delay time of the other cloud cells to which the first and second secondary base stations 204 and 206 belong are shorter.

Reason for rejection 3. The first and second secondary base stations 204, 206 are primary base stations in another cloud cell to which the first and second secondary base stations 204, 206 belong.

In this case, it is assumed that the first secondary base station 204 approves the resource allocation request of the primary base station 202 and the second secondary base station 206 rejects the primary base station 202 resource allocation request.

The primary base station 202 may reconfigure the cloud cell based on the resource grant result included in the resource request response message. (Step 220). That is, the primary base station 202 determines the secondary base station to participate in the communication and determines the secondary base station to be excluded from the cloud cell member. In FIG. 2, the first secondary base station 204, which has approved the resource allocation request, determines that the secondary base station 204 is to participate in cooperative communication with the primary base station 202, and the second secondary base station 206 responds to the resource allocation request more than a predetermined number of times. When the negative response message is transmitted, the secondary base station may be determined to be excluded from the cloud cell member.

The primary base station 202 then sends a resource allocation message to the first secondary base station 204 that has determined to participate in the cooperative communication (step 224) indicating that it will use the resource, and excludes it from the cloud cell member. The cloud cell information message including the information indicating that the cloud cell is excluded from the cloud cell is transmitted to the second secondary base station 206 which is determined to be determined (step 226). In addition, the primary base station 202 transmits to the terminal 200 a cloud cell resource allocation message indicating from which base stations the entire cloud cell resources are allocated (step 222). In FIG. 2, as an example, the primary base station 202 transmits a resource allocation message indicating that the primary base station 204 is to use the resource. Of course, it may indicate that it will not be used.

As the primary base station 202 uses the resources of the first secondary base station 204 as described above, the primary base station 202 and the first secondary base station 204 may cooperate to transmit data to the terminal 200 (see FIG. Steps 228 and 230).

Meanwhile, the primary base station 202 may be a secondary base station in another cloud cell, and steps 232 to 236 to be described later assume that the primary base station 202 operates as a secondary base station in another cloud cell.

The primary base station 202 receives a resource request message for requesting resource allocation from the primary base station of another cloud cell, that is, the third base station 208 (step 232), and performs resource admission control (step 234). The resource request response message including the admission control result is transmitted to the third base station 208 (step 236).

1 and 2 illustrate a procedure in which a cloud cell is configured and a secondary base station, which is a member of the cloud cell, transmits data in cooperation with a primary base station through resource admission control. 3 and 4, a procedure of changing the primary base station while transmitting data in cooperation with the primary base station and the secondary base station will be described as an example.

3 is a diagram illustrating a procedure of changing a primary base station in a cloud cell based communication system according to a third embodiment of the present invention.

Referring to FIG. 3, the communication system includes a terminal 300, a primary base station 302, a first secondary base station 304, and a second secondary base station 306. The primary base station 302, the first secondary base station 304, and the second secondary base station 306 constitute a first cloud cell, and in particular, the first and second secondary base stations 302, 304 are second cloud cells. Assume that you are a member of.

The primary base station 302 of the first cloud cell determines to change the primary base station of the first cloud cell when it is unable to provide the minimum quality of service to the terminal 300 or when the channel state is less than a threshold for a preset time. (Step 310).

When the primary base station change is determined, the primary base station 302 transmits a primary base station request message to each of the first and second secondary base stations 304 and 306 that are members of the first cloud cell to request that the primary base station be a primary base station. (Steps 312, 314). The primary base station request message includes the kind of traffic (real time traffic, non-real time traffic) and the minimum resource requirement that the primary base station 302 serves. If the traffic serviced by the primary base station 302 is real time traffic, the primary base station request message also includes a maximum delay time. In this case, the first and second secondary base stations 304 and 306, to which the primary base station 302 transmits the primary base station request message, refers to a base station whose channel quality is greater than or equal to a threshold.

Each of the first and second secondary base stations 304 and 306 having received the primary base station request message can provide the minimum quality of service to the terminal 300 through the primary base station admission control (steps 316 and 318). Considers the priority of the primary base station of the second cloud cell and the primary base station 302 of the first cloud cell, which is another cloud cell to which it belongs, and according to the result, an acknowledgment (ACK: ACKnowledge) for the primary base station request message. Message or a Negative-ACKnowledge (NACK) message to the primary base station 302. Each of the secondary base stations 304 and 306 looks at the primary base station request message, allocates resources according to the following resource allocation priority, and then checks whether the secondary base station 304 or 306 can support the minimum resource requirement required by the primary base station request message. If the minimum resource requirement can be supported, an acknowledgment message is sent.

The secondary base station first allocates a resource to a request whose traffic type is real-time traffic. If there are a plurality of real-time traffic requests, resources are allocated to a request having a shortest maximum delay time. If the maximum delay time is the same, resources are first allocated to a secondary base station serving as a primary base station in another cloud cell among the first and second secondary base stations 304 and 306.

When the negative response message is transmitted because the resource request amount required by the primary base station request message cannot be supported, the negative response message may include the following reasons for rejection. Reasons for refusal include, for example:

Reasons for Rejection 1. The traffic priority of other cloud cells to which the first and second secondary base stations 304 and 306 belong is higher.

Reason for rejection 2. The maximum delay time of the other cloud cells to which the first and second secondary base stations 304 and 306 belong are shorter.

Reason for rejection 3. The first and second secondary base stations 304, 306 are primary base stations in other cloud cells to which the first and second secondary base stations 204, 206 belong.

In FIG. 3, it is assumed that the first sub-base station 304 transmits an acknowledgment message (step 320), and the second secondary base station 304 transmits a negative response message (step 322).

The primary base station determines the first secondary base station 304 that has sent the acknowledgment as a new primary base station (step 324), and sends a primary base station change message including information indicating that the primary base station has been changed to the new base station. Each of the secondary base stations 304 and 306 and the terminal 300 are transmitted (steps 326, 328 and 330).

Then, the first secondary base station 304 determined by the primary base station 302 as the new primary base station 304 operates as the primary base station upon receiving the primary base station change message (step 326) (step 334), and the primary base station 302 receives the first base station 302. The secondary base station 306 operates as the secondary base station (step 332), and the second secondary base station 306 operates as the secondary base station according to the reception of the primary base station change message (step 328) (step 336).

In FIG. 3, a case in which an acknowledgment is only received from the first secondary base station 304 is described as an example. However, the acknowledgment may be received from two or more secondary base stations, respectively, and each positive acknowledgment is received from two or more secondary base stations. When a response is received, the primary base station 302 considers other channel conditions, cell loads, and the like to replace one secondary base station with a better primary channel condition or a lower primary cell load if the channel conditions are the same. Determined by the base station.

In addition, if a negative response is received from both the first and second secondary base stations 304 and 306, the primary base station 302 compares the rejection reason received with the negative response and has a relatively low priority. Select the secondary base station and determine the selected secondary base station as the new primary base station. The operation of determining a new primary base station when a negative response is received from both the first and second secondary base stations 304 and 306 will be described in more detail in FIG. 4 below.

4 is a diagram illustrating a procedure of changing a primary base station in a cloud cell based communication system according to a fourth embodiment of the present invention.

Referring to FIG. 4, a communication system includes a first terminal 400, a first base station 402, a second base station 404, a third base station 406, a fourth base station 408, and a fifth base station 410. ). In addition, it is assumed that the communication system includes a first cloud cell and a second cloud cell, and the first cloud cell operates as a first terminal 400, a first base station 402 serving as a primary base station, and a secondary base station. A second base station 404 and 406, the second cloud cell comprising a second terminal (not shown), a second base station 404 acting as a secondary base station, and a fifth base station acting as a primary base station. Base station 410 is configured. In other words, it is assumed that the second base station 404 is a base station included in both the first and second cloud cells.

When the first base station 402 serving as the primary base station receives a negative response message from both the second and third base stations 404 and 406 serving as the secondary base station, indicating that it cannot be the primary base station (step 420). By comparing the rejection reason received with the negative response message, one secondary base station is selected and the selected secondary base station is determined as a new primary base station (step 422).

For example, when the first base station 402 receiving the negative response messages from the second and third base stations 404 and 406 has a base station that has sent the first rejection reason among the rejection reasons included in each of the received negative response messages, The primary base station push message is transmitted to the base station that has sent the rejection reason number 1. If there are several base stations that have sent the rejection reason number 1, the base station having the best channel state is selected among the base stations, and the primary base station push message is transmitted to the selected base station. In this case, when the channel state is the same, a base station having a low cell load is selected, and when the cell load is also the same, a base station is randomly selected.

In addition, the first base station 402 transmits the primary base station push message to the base station that has sent the second reason for rejection if only the base station that has sent the second reason for rejection exists in the rejection reason included in each received negative response message. If there are several base stations that have sent the rejection reason number 2, the base station having the best channel state is selected among the base stations, and the main base station push message is transmitted to the selected base station. In this case, when the channel state is the same, a base station having a low cell load is selected, and when the cell load is also the same, a base station is randomly selected.

In addition, if only the base station which has sent the rejection reason number 3 among the rejection reasons included in each of the received negative response messages, the first base station 402 does not transmit the primary base station push message and measures the first terminal 400. In step 424, the first base station 402 measures the channel of neighboring base stations and transmits the measurement indication message instructing the second base station 404 to find a new base station. In step 426, a primary base station push message for pushing a base station is transmitted.

Upon receiving the primary base station push message, the second base station 404 transmits an acknowledgment message to the first base station 402 to approve the push to the primary base station (step 430) and at the same time the primary base station of the first cloud cell. In operation 428, a primary base station change message is transmitted to another cloud cell to which it belongs, that is, a fifth base station 410 that is a primary base station of the second cloud cell, indicating that the primary base station of the first cloud cell has become the primary base station. ).

Upon receiving the primary base station change message, the fifth base station 410 adjusts the resource allocation of the second cloud cell that is changed as the second base station 404 becomes the primary base station of the first cloud cell (step 434). The result is transmitted to the second base station 404 through the resource allocation message (step 436).

In addition, when the first base station 402 determines the second base station 404 as the new primary base station in step 422, the primary base station 402 includes information indicating that the primary base station of the first cloud cell has been changed to the second base station 404. The change message is transmitted to the second and third base stations 404 and 406 and the first terminal 400 (steps 438, 442 and 440).

Meanwhile, the first terminal 400 receiving the measurement instruction message measures the channel of the first base station 402 and the second to fourth base stations 404-408 (step 432), and reports the result of the measurement. The message is transmitted to the current primary base station, that is, the second base station 404 (step 444). The measurement report message may be sent periodically or may be sent by the command of the primary base station.

Then, the second base station 404 determines to change the primary base station of the first cloud cell if it is unable to provide the minimum quality of service to the first terminal 400 or if the channel state is less than the threshold for a preset time. In operation 446, the fourth base station 408 having the best channel state is determined as the primary base station candidate based on the channel state of the neighbor base stations included in the measurement report message received from the first terminal 400.

The second base station 404 then transmits a primary base station request message to the fourth base station 408 determined as the primary base station candidate to be the primary base station of the first cloud cell (step 448). Upon receiving the primary base station request message, the fourth base station 408 determines whether the minimum quality of service can be provided to the first terminal 400 through the primary base station admission control (step 450). If it is possible to provide the minimum quality of service (400) to the second base station 404 transmits an acknowledgment message to accept the primary base station request message (step 452).

Subsequently, the second base station 404 transmits a primary base station change message indicating that the primary base station of the first cloud cell has been changed from the first base station 408 to the first base station 402, the first terminal 400, and the third base station. 406 and the fourth base station 408, respectively (steps 454-460).

5 is a diagram illustrating a process of configuring and reconfiguring a cloud cell by a base station in a communication system.

Referring to FIG. 5, in step 501, a base station operating as a main base station, that is, a main base station transmits a measurement instruction message indicating to measure channel states of neighboring base stations to the terminal, and proceeds to step 503. In step 503, the primary base station receives a measurement report message including channel measurement results for neighboring base stations from the terminal and proceeds to step 505.

In step 505, the primary base station configures a cloud cell around base stations having a good channel state, for example, base stations whose channel state is greater than or equal to a threshold value based on the received measurement report message, and proceeds to step 507. In step 507, the primary base station transmits a message including configuration information of the cloud cell configured in step 505 to all the cloud cell members and the terminal.

On the other hand, in step 509, when the primary base station arrives at a predetermined scheduling period or needs additional resources other than the resources allocated to it, the primary base station proceeds to step 511 and requests resource allocation to the secondary base stations constituting the cloud cell. Send a message. In step 513, the primary base station receives a resource response message including an admission control result for determining whether to approve the resource allocation request from the secondary base stations, and proceeds to step 515.

In step 515, the primary base station determines the secondary base station to be included in the cloud cell to be reconfigured and the secondary base station to be excluded according to the admission control result, reconfigures the cloud cell according to the determination result, and proceeds to step 517. . Here, the primary base station determines to include in the cloud cell reconfiguration for the secondary base station that can provide the requested resource to the terminal for more than a threshold time, and the secondary base station can not provide the requested resource to the terminal for more than a threshold time. The base station decides to exclude it from the cloud cell reconfiguration.

In step 517, the primary base station transmits a resource allocation message indicating that resources will be used for the secondary base station determined to be included in the cloud cell reconfiguration, and includes information indicating that the primary base station is excluded from the cloud cell for the secondary base station determined to be excluded in the cloud cell reconfiguration. Send cloud cell information message. In addition, the UE transmits a cloud cell resource allocation message indicating which base stations have been allocated all of the cloud cell resources.

6 is a diagram illustrating a process of changing a primary base station in a cloud cell based communication system.

Referring to FIG. 6, in step 601, when the primary base station cannot provide the minimum quality of service or when the channel state is less than the threshold for a preset time, the primary base station determines to change the primary base station of the first cloud cell and proceeds to step 603. Proceed. In step 603, the primary base station transmits a primary base station request message for requesting that each of the secondary base stations constituting the first cloud cell become a primary base station and proceeds to step 605.

In step 605, the primary base station checks whether an acknowledgment indicating that the secondary base station can be the primary base station is received, and proceeds to step 607 when an acknowledgment is received from one of the secondary base stations. In step 607, the primary base station determines the secondary base station that transmits the acknowledgment as the new primary base station of the first cloud cell. In step 609, the primary base station determines the secondary base station and the terminal that constitute the first cloud cell. A primary base station change message indicating that the base station has been changed is transmitted.

In FIG. 6, the case in which the acknowledgment response is received from one secondary base station is described as an example. However, the acknowledgment response may be received from at least two secondary base stations. If the acknowledgment is received from at least two secondary base stations, the primary base station determines one secondary base station determined through other channel conditions and cell loads as a new primary base station.

If the primary base station does not receive any positive response from the secondary base stations in step 605, it proceeds to step 610 and determines whether a negative response indicating that the primary base station cannot be the primary base station is received from the secondary base stations. If a negative response is received from the secondary base stations, the process proceeds to step 611, in which the secondary base station selects one secondary base station having a relatively low priority of the rejection reason by comparing the rejection reason received with the negative response and selects the selected secondary base station. Determine as primary base station. However, if the negative response is not received in step 610, the process proceeds to step 603 to transmit a primary base station request message.

In step 613, the primary base station transmits a push message for pushing the primary base station to the new primary base station determined in step 611 and proceeds to step 615. In step 615, the primary base station determines whether an acknowledgment message for accepting the push for the new primary base station is received, and if the acknowledgment message is received, the primary base station proceeds to step 609 to configure the secondary base stations configuring the first cloud cell. And a primary base station change message indicating that the primary base station has been changed to the determined new base station.

Although not shown, when the new base station determined in step 611 is included not only in the first cloud cell but also in another cloud cell, that is, the second cloud cell, the base station determined as the new primary base station notifies that the base station of the first cloud cell is the primary base station. A resource allocation message including a resource allocation result of transmitting a primary base station change message to a primary base station of the second cloud cell, and adjusted from inclusion of the new primary base station to the second cloud cell from the primary base station of the second cloud cell; Receive

7 is a diagram illustrating a procedure for allocating resources to terminals in which a primary base station to which the present invention is applied is configured as the primary base station.

It is assumed that there are N_BS base stations and N_MS base stations in the system, and that one primary base station and a plurality of secondary base stations are configured in each terminal. In addition, it is assumed that each terminal may receive data from primary or secondary base stations, and resource allocation to each terminal is determined by the primary base station.

The scheduling process consists of four steps, as shown below.

1) Information sharing step

In the step of sharing information (step 701), all the information required to solve the problem in the scheduling assignment step and resolve the conflict is shared between the base stations. In particular, in the information sharing step, information for calculating a specific metric used when allocating resources to terminals, that is, channel state information (CSI), is shared between base stations in cooperating cells. The cooperative cells may be formed around a specific primary base station and may include other primary base stations or secondary base stations of a terminal in which the corresponding primary base station is set as a primary base station or a secondary base station.

2) scheduling assignment step

In the scheduling allocation step 703, each primary base station allocates the resource to the terminals of the primary base station by solving the problem of the scheduling allocation step by using the information shared in the information sharing step.

Each primary base station maximizes (or minimizes) a specific metric calculated for itself and its cooperative cells (eg, the sum of average data rates of each base station considering the fairness between terminals, the sum of the transmit powers of the base stations). Allocate resources to terminals that have set themselves as the primary base station in a direction to make a request.

The primary base station selects terminals that set themselves as the primary base station. In this case, the plurality of terminals may be selected according to Equation 1 below.

In Equation 1, a set U * of terminals maximizing a specific metric among all terminals configured as cooperative cells as a primary base station or a secondary base station is found. As a specific metric (for terminals belonging to the set), the value multiplied by (1 + R _k / ((T-1) * R _k ') is used.

Here, R _k represents a transmission rate (or throughput) that can be transmitted to the k-th terminal when the current resource allocation, R _k 'is the average transmission rate for the k-th terminal until the resource allocation (that is, k to the previous time slot) Average data rate of the first terminal).

Τ represents the window size used to calculate the average transfer rate. That is, it represents the time or interval to take the average to find the average rate.

S _i represents a set of base stations (including the i-th base station) that cooperates with the i-th base station, and M _j represents a set of terminals whose j-th base station is the main base station.

3) Information exchange stage

In the information exchange step 705, the scheduling assignment result and additional information needed in the next step (i.e., conflict resolution step) are exchanged between the base stations in the cooperative cells. The additional information includes priority information for each resource allocation. The priority information indicates the importance of the allocation in relation to the system performance. A collision occurs between two assignments, in which links corresponding to the assignment are included in the same conflict set. A collision set refers to a set of links whose amount of interference affecting each other is greater than or equal to a predetermined threshold.

4) Conflict resolution step

Conflicts may arise between resources allocated by the primary base stations. In the conflict resolution step (706), the conflict is resolved according to a predefined rule. When resources are allocated to two different links belonging to the same conflict set in the conflict resolution step, a collision may occur between two resource allocations.

After the conflict resolution phase, each primary base station can either reallocate the obtained resources or decide not to change the allocation.

The scheduling assignment step, the information exchange step, and the conflict resolution step may be repeatedly performed, and each base station transmits data to the corresponding terminal based on the information allocated in the scheduling assignment step.

FIG. 8 is a diagram illustrating a base station apparatus for performing cloud cell configuration / reconfiguration and changing a primary base station in a cloud cell as a plurality of base stations provide a service to one terminal in a communication system. In addition, the base station apparatus of FIG. 8 performs an operation (see FIG. 7) of allocating resources to terminals having their primary base station configured as their primary base station.

Referring to FIG. 8, the base station includes a transmitter 800, a receiver 810, and a controller 820.

First, an operation of configuring and reconfiguring a cloud cell by a base station will be described.

The control unit 820 transmits a measurement instruction message instructing the transmitter 800 to measure channels of neighboring base stations to the terminal, and when the receiver 810 receives a measurement report message including a channel measurement result, the reception unit 820 receives the measurement report message. Based on the measurement report message, the first cloud cell is configured around the base stations having a channel state equal to or greater than a threshold value, and the sub-base stations and the terminal, which configure the first cloud cell, are transmitted to the respective base stations. The member information of the first cloud cell is transmitted.

When the primary base station needs additional resources other than the resources allocated to the primary base station, it transmits a resource request message for requesting resource allocation to the secondary base stations constituting the first cloud cell through the transmitter 800 and the receiving unit. A resource response message including an admission control result for determining whether to approve the resource allocation request is received from each of the base stations through 810. Then, the controller 820 reconfigures the first cloud cell according to the admission control result.

Next, an operation of changing the primary base station in the cloud cell will be described.

As described above, the controller 820 configures a first cloud cell including one primary base station and at least one secondary base station, and determines that the primary base station of the first cloud cell is to be changed, through the transmitter 800. An acknowledgment that transmits a primary base station request message requesting each of the at least one secondary base station to become a primary base station, and informs the receiver 810 that the primary base station can be a primary base station from any one of the at least one secondary base stations. Receive

Then, the controller 820 determines the secondary base station that has transmitted the acknowledgment as a new primary base station of the first cloud cell, and transmits a primary base station change message indicating the determined new primary base station through the transmitter 700. Transmit to each of the terminal and the at least one secondary base station.

On the other hand, when the control unit 820 receives a negative response and the rejection reason from each of the at least two secondary base stations through the receiving unit 810, the priority of the rejection reason is relatively low by comparing each of the received rejection reasons. A secondary base station is determined as the new primary base station, and a push message is transmitted to the new primary base station determined through the transmitter 700 to be a primary base station.

9 is a diagram illustrating a terminal device that performs an operation according to one terminal receiving a service provided from a plurality of base stations. In addition, the terminal apparatus of FIG. 9 is applied to the allocated terminal in the case where the primary base station allocates resources to terminals having set themselves as the primary base station (see FIG. 7).

Referring to FIG. 9, the terminal includes a transmitter 900, a receiver 910, and a controller 920.

When the receiver 910 receives a measurement indication message indicating that the channel of the neighbor base stations from the primary base station included in the first cooperative cell, the measurement report including the channel measurement results of the neighbor base stations through the transmitter 900 Send a message. Further, after the receiving unit 910 receives member information included in the first cooperative cell including the primary base station and at least one secondary base station from the primary base station, the primary base station and the at least one secondary base station cooperate with each other. Receive the service provided.

On the other hand, when the control unit 920 confirms that the primary base station of the first cooperative cell is changed to a new primary base station, the primary base station change message for notifying the base station determined as the new primary base station from the primary base station through the receiving unit 910. Receive.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. Therefore, the scope of the present invention should not be limited by the illustrated embodiments, but should be determined by the scope of the appended claims and equivalents thereof.

Claims (34)

A method of providing a service to a terminal by a plurality of base stations cooperate in a wireless communication system,
Configuring, by one primary base station, a first cooperative cell including at least one secondary base station;
Transmitting, by the primary base station, a resource request message for requesting resource allocation to secondary base stations belonging to the first cooperating cell;
Receiving, from each of the secondary base stations receiving the resource request message, a resource request response message including a result obtained through resource admission control considering all cooperative cells to which the resource base station belongs;
Changing a configuration base station constituting the first cooperative cell based on the resource request response message;
And allocating a resource to a terminal serving in the first cooperative cell.
The method of claim 1,
The resource request message includes information on the amount of resources required and the type of traffic to be serviced, and when the type of the serviced traffic is real-time traffic, the service providing method further comprising the maximum allowable delay time.
The method of claim 1,
The resource request response message includes at least one of a positive response message and a negative response message, wherein the positive response message indicates that resources are allocated as requested by the primary base station, and the negative response message indicates resource as requested by the primary base station. Service delivery method, characterized in that it is not assigned.
The method of claim 3,
The negative response message includes a reason why the primary base station rejects resource allocation and resource allocation for the terminal.
The method of claim 3, wherein
Changing the configuration base station constituting the first cooperative cell,
Determining that the secondary base station which transmits the negative response message more than a predetermined number of times is excluded from the component base station.
The method of claim 1,
The process of configuring the first cooperation cell,
Transmitting, by the primary base station to the terminal, a measurement indication message instructing to measure channels of neighboring base stations;
Receiving a measurement report message including a channel measurement result from the terminal;
Configure the first cooperative cell including base stations having a channel state equal to or greater than a threshold value as secondary base stations based on the received measurement report message;
And transmitting the configuration information of the first cooperative cell to the secondary base stations and the terminal constituting the first cooperative cell.
The method according to claim 6,
Transmitting, by the primary base station, a resource request message for requesting resource allocation to secondary base stations constituting the first cooperative cell when additional resources other than the resources allocated to the primary base station are needed or when every scheduling period arrives; ,
Receiving a resource response message including whether to approve the resource allocation request from each of the base stations;
And reconfiguring the first cooperative cell according to the received resource response message.
The method of claim 7, wherein
Each of the base stations rejects the resource allocation request if the requested resource cannot be provided to the terminal, and the primary base station rejects the resource allocation request of the main base station more than a predetermined number of times by the base station rejecting the resource allocation request. The service providing method, characterized in that the first cooperative cell is reconfigured so as not to be included in the first cooperative cell.
A base station in which a plurality of base stations cooperate to provide a service to a terminal in a wireless communication system,
One primary base station configures a first cooperative cell including at least one secondary base station, changes a well-known base station constituting the first cooperative cell based on a resource request response message, and serves in the first cooperative cell. A control unit for allocating resources to the terminal;
A transmitter for transmitting a resource request message for requesting resource allocation to secondary base stations belonging to the first cooperative cell;
And a receiving unit which receives the resource request response message including a result obtained through resource admission control in consideration of all cooperative cells to which it belongs from each of the secondary base stations which have received the resource request message.
10. The method of claim 9,
The resource request message includes the information on the amount of resources required and the type of traffic to be serviced, the service providing base station, characterized in that further includes the maximum delay time allowed when the type of the serviced traffic is real-time traffic.
10. The method of claim 9,
The resource request response message includes at least one of a positive response message and a negative response message, wherein the positive response message indicates that resources are allocated as requested by the primary base station, and the negative response message indicates resource as requested by the primary base station. Service base station, characterized in that it is not assigned.
12. The method of claim 11,
The negative response message is a service providing base station, characterized in that the primary base station includes the amount of resources that can be allocated for the terminal and the reason for rejecting the resource allocation.
12. The method of claim 11,
The control unit determines that the secondary base station for transmitting the negative response message more than a predetermined number of times to exclude from the configuration base station.
A method of providing a service to a terminal by a plurality of base stations cooperate in a wireless communication system,
Configuring, by one primary base station, a first cooperative cell including at least one secondary base station;
When determining to change the primary base station of the first cooperative cell, transmitting a primary base station request message to the at least one secondary base station requesting the change to the primary base station;
Receiving an acknowledgment indicating that the primary base station can be a primary base station from one of the at least one secondary base stations;
Determining a secondary base station that has transmitted the positive response as a new primary base station of the first cooperative cell;
Transmitting a primary base station change message indicating the determined new primary base station to all the secondary base stations of the terminal and the first cooperative cell;
Providing the service to the terminal by the determined new primary base station in cooperation with the at least one secondary base station.
15. The method of claim 14,
Receiving negative response and rejection reasons from secondary base stations that receive the primary base station request message;
Comparing the two or more received rejection reasons to determine a secondary base station having a lower priority of the rejection reason as a new primary base station of the first cooperative cell;
And transmitting a push message to the determined new primary base station to push the primary base station of the first cooperating cell.
16. The method of claim 15,
Transmitting a primary base station change message informing the secondary base stations and the terminal of the determined new primary base station to all secondary base stations of the first cooperative cell and the terminal when an acknowledgment message acknowledging that the primary base station is received from the determined new primary base station is received. Service providing method further comprising a.
16. The method of claim 15,
When the determined new primary base station is included in a second cooperative cell different from the first cooperative base station, the determined new primary base station notifies the primary base station of the second cooperative cell that it has become the primary base station of the first cooperative cell. Sending a change message,
And receiving a resource allocation message including a resource allocation result adjusted from the primary base station of the second cooperative cell.
16. The method of claim 15,
And the reason for rejection is represented by at least one of a quality of service level, a transmission latency, and a cell load.
15. The method of claim 14,
When an acknowledgment is received from at least two secondary base stations, determining one of the at least two secondary base stations which transmitted the positive response in consideration of at least one of channel status and cell load as a new base station of the first cooperative cell. Service providing method characterized in that.
15. The method of claim 14,
If the primary base station is unable to provide the minimum quality of service to the terminal or if the channel state is less than the threshold for a predetermined time, the primary base station determines to change the primary base station of the first cooperative cell Service providing method characterized in that.
In the wireless communication system, a terminal receives a service from a plurality of base stations,
Receiving a measurement indication message instructing to measure a channel of neighboring base stations from a primary base station included in the first cooperative cell;
Transmitting a measurement report message including channel measurement results of the neighbor base stations;
Receiving, from the primary base station, configuration information on the first cooperative cell including the primary base station and at least one secondary base station;
And receiving a service provided by the primary base station and the at least one secondary base station in cooperation.
The method of claim 21,
Receiving a primary base station change message informing the determined new base station from the primary base station when the primary base station of the first cooperative cell is changed to a new primary base station.
A base station in which a plurality of base stations cooperate to provide a service to a terminal in a wireless communication system,
A primary base station configures a first cooperative cell including at least one secondary base station, and transmits a secondary base station that transmits an affirmative response indicating that the primary base station can be a primary base station as a new primary base station of the first cooperative cell, A controller for controlling the determined new primary base station to provide a service to the terminal in cooperation with the at least one secondary base station;
When the controller determines to change the primary base station of the first cooperative cell, the primary base station change message for transmitting the primary base station request message requesting the change to the primary base station to the at least one secondary base station, and informs the determined new primary base station; A transmitting unit for transmitting to the terminal and all secondary base stations of the first cooperative cell;
And a receiving unit which receives the acknowledgment from one of the at least one secondary base stations.
24. The method of claim 23,
When the receiver receives a negative response and a rejection reason from at least two secondary base stations, the controller compares the received rejection reason and selects a secondary base station having a relatively low priority of the rejection reason from the new primary cell of the first cooperative cell. The base station, and the transmitting unit transmits a push message to the determined new primary base station to push the primary base station of the first cooperating cell.
25. The method of claim 24,
If the receiving unit receives an acknowledgment message from the determined new primary base station to acknowledge the primary base station, the transmitting unit changes the primary base station informing all the secondary base stations and the terminal of the determined new primary base station in the first cooperative cell; A service providing base station characterized by transmitting a message.
25. The method of claim 24,
If the determined new primary base station is included in a second cooperative cell different from the first cooperation, the transmitter determines that the determined new primary base station has become a primary base station of the first cooperative cell to the primary base station of the second cooperative cell. Transmitting a primary base station change message, wherein the receiving unit receives a resource allocation message including a resource allocation result adjusted from the primary base station of the second cooperative cell.
25. The method of claim 24,
And the reason for rejection is indicated by at least one of a quality of service level, a transmission latency, and a cell load.
24. The method of claim 23,
When the receiver receives an acknowledgment from at least two secondary base stations, the controller selects one of the at least two secondary base stations that transmit the positive response in consideration of at least one of a channel state and a cell load in the first cooperative cell. The service providing base station, characterized in that determined as a new base station.
24. The method of claim 23,
The controller may change the primary base station of the first cooperative cell when the primary base station cannot provide the terminal with a minimum quality of service preset or when a channel state is less than a threshold for a preset time. Determining that the service providing base station.
24. The method of claim 23,
The control unit transmits a measurement instruction message instructing the primary base station to measure channels of neighboring base stations to the terminal, and the receiving unit receives a measurement report message including a channel measurement result from the terminal. Based on the received measurement report message, the first cooperative cell including base stations having a channel state equal to or greater than a threshold is configured as a secondary base station, and then the transmitter is further configured to inform the secondary base stations and the terminal constituting the first cooperative cell. And a service providing base station transmitting configuration information of the first cooperative cell.
31. The method of claim 30,
The transmitter transmits a resource request message for requesting resource allocation to secondary base stations constituting the first cooperative cell when the primary base station needs additional resources other than those allocated to the primary base station or when every scheduling period arrives. And when the receiving unit receives a resource response message including whether to approve the resource allocation request from each of the base stations, the controller reconfigures the first cooperative cell according to the received resource response message. Service serving base station.
32. The method of claim 31,
The control unit rejects the resource allocation request if each of the base stations cannot provide the requested resource to the terminal, and rejects the resource allocation request of the main base station more than a predetermined number of times by the base station rejecting the resource allocation request. The service providing base station, wherein the first cooperative cell is reconfigured so as not to be included in the first cooperative cell.
In a terminal in which a terminal receives a service from a plurality of base stations in a wireless communication system,
Receiving a measurement indication message indicating measurement of a channel of neighboring base stations from a primary base station included in a first cooperative cell, and configuration information of the first cooperative cell including the primary base station and at least one secondary base station; A receiving unit which receives a service provided by the primary base station and the at least one secondary base station in cooperation;
And a transmitter for transmitting a measurement report message including channel measurement results of the neighbor base stations.
34. The method of claim 33,
A control unit for detecting that the primary base station of the first cooperative cell is changed to a new primary base station,
And when the primary base station of the first cooperative cell is changed to a new primary base station, the receiving unit receives a primary base station change message indicating the determined new base station from the primary base station.

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