KR20070061114A - Apparatus for forming of dual virtual cell in distributed radio system and it's operation method - Google Patents

Abstract

An apparatus for forming a dual virtual cell in a dispersed wireless system and an operating method thereof are provided to prevent the disconnection of communication due to movement of a terminal by setting a candidate virtual cell through estimation of a reaching range of the terminal. An operating method for a virtual cell structure in a dispersed wireless system includes the steps of: including dispersion antennas in a signal reaching range of a terminal as an initial candidate virtual cell, and configuring an initial channel matrix by collecting channel information between the dispersion antenna and the terminal(S100,S102); configuring a channel matrix of the candidate virtual cells according to a first predetermined reference among the dispersion antennas of the initial channel matrix based on the collected channel information(S104); configuring a channel matrix of active virtual cells according to a second predetermined reference among the antennas included in the channel matrix of the candidate virtual cells(S108); and performing a transceiving process with the terminal by using the dispersion antennas included in the channel matrix of the active virtual cells, and performing different communicating processes by a movement speed of the terminal(S114).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus and method for forming a dual virtual cell structure in a distributed wireless system,

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a simplified diagram of a conventional distributed wireless system.

2 is a diagram showing a concept of a virtual cell of a conventional distributed radio system.

3 is a diagram illustrating a configuration of a dual virtual cell in a stationary state according to an embodiment of the present invention.

FIG. 4 is a diagram illustrating a configuration of a dual virtual cell during a fast movement of a terminal according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating a configuration of a dual virtual cell when the mobile station moves at a low speed according to an embodiment of the present invention.

6 is a block diagram schematically illustrating a processor for forming a dual virtual cell structure according to an embodiment of the present invention.

7 is a flowchart illustrating a communication process of a UE in a virtual cell of a distributed wireless system according to an embodiment of the present invention.

8 is a flowchart illustrating a communication process according to a stationary state of a terminal in a dual virtual cell structure according to an embodiment of the present invention.

9 is a flowchart illustrating a communication operation process according to a fast moving state of a UE in a dual virtual cell structure according to an embodiment of the present invention.

10 is a flowchart illustrating a communication operation process according to a low-speed moving state of a terminal in a dual virtual cell structure according to an embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a device for forming a virtual cell structure, and more particularly, to a device for forming a dual virtual cell structure in a distributed wireless system and a method of operating the same.

A distributed wireless system is a system in which a hierarchical structure like a conventional cellular system is constructed horizontally. The basic structure of a distributed wireless system is composed of three layers: a distributed antenna 100, a distributed signal processing, and a distributed control system.

The distributed antenna 100 is a new structure in which a plurality of dispersed antennas are distributed at a high density. Distributed signal processing may be performed in a variety of ways such as modulation / demodulation, channel coding / decoding, joint detection, channel measurement, medium access control (MAC), link layer control (LLC), radio link control ), And radio network control (RNC).

The distributed control system performs all upper layer protocol control such as signal transmission, switching, and mobility management to the logical layer.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a simplified diagram of a conventional distributed wireless system.

Distributed wireless systems distribute radio signals and have no central control devices such as base stations. The signal processing of the distributed wireless system is separated from the antenna and collects radio signals through the distributed antenna 100. [

Each processor 110 processes radio signals transmitted from and received from various antennas, and performs co-processing closely between the different processors 110.

The processing layers may be logically considered as one central processing unit, but a plurality of processors 110 are dispersed in a region to process signals in parallel.

In this structure, the signals coming and going between the multiple antennas are simultaneously processed by the nearest processor 110 so as to maximize the channel capacity or the quality of the radio link through the multi-antenna technique.

In addition, the processors 110 may interoperate through high-speed connectivity 120 to dynamically align and communicate signal processing tasks between the processors 110. Therefore, even if one processor 110 fails, the distributed processor 110 can transfer the processing to another processor 110, thereby increasing the reliability of the system.

In a distributed wireless system, the concept of a cell no longer exists and a new concept called a virtual cell is introduced and used.

In a conventional system, a cell is a concept centered on a base station, whereas a virtual cell is a concept based on a terminal 200. That is, the virtual cell means a set of distributed antennas 100 within the reaching area of the specific terminal 200. [

2 is a diagram showing a concept of a virtual cell of a conventional distributed radio system.

The virtual cell 210 is not an actual cell and is used only for signal processing. The determination of the virtual cell 210 dynamically selects the virtual cell 210 for each terminal 200 in the signal processing layer at the signal processing layer and detects and optimizes the transmission signals in the virtual cell 210 as a whole.

The processor 110 determines the number of antennas of each terminal 200 and the access point 130 and the configuration of the access point 130 in the virtual cell 210 of each terminal 200, The location of the terminal 200 in the virtual cell 210, the location of the other terminals 200 in the overlapping area of the virtual cell 210, the location of the terminal 200 in the area where the virtual cell 210 overlaps, And the transmission speed required for each transmission.

With this information, the processing unit can transmit the data of each terminal 200, such as a transmission antenna configuration, a transmission rate, a transmission power allocation among antennas, a coding rate and a modulation scheme, and a transmission method such as a variable calculation for beamforming .

The above-described cell determination method of the distributed radio system should be repeatedly performed to determine the virtual cell 210 when the propagation environment changes or the location of the terminal 200 changes.

When the terminal 200 tries to communicate using the virtual cell 210, it is necessary to repeat the process of determining the virtual cell 210 in accordance with the movement of the terminal 200. However, There is a problem that the link quality of the terminal 200 is constantly fluctuated and disconnected due to repeated situations where the environment becomes inconsistent.

In the conventional distributed radio system, the quality of the radio wave changes drastically due to the quality degradation or disconnection of the radio link in the continuous transmission process. Therefore, the conventional distributed wireless system has a problem that the estimation information of the channel is configured in units of several seconds, and the available capacity in the network can not be fully utilized.

In order to solve such problems, it is an object of the present invention to provide an apparatus and method for forming a dual virtual cell structure in a distributed wireless system.

According to an aspect of the present invention, there is provided a method of operating a virtual cell structure in a distributed wireless system, the method comprising: (a) including a distributed antenna within a signal arrival range of a terminal as an initial candidate virtual cell; And collecting channel information between the terminals and constructing an initial channel matrix; (b) constructing a channel matrix of candidate virtual cells according to a first specific criterion among dispersion antennas of the initial channel matrix based on the collected channel information; (c) constructing a channel matrix of an active virtual cell according to a second specific criterion among the antennas included in the channel matrix of the candidate virtual cell; And (d) performing a transmission and reception process with the mobile station using a distributed antenna included in the channel matrix of the active virtual cell, and performing different communication processes according to the mobile speed of the mobile station.

An apparatus for forming a dual virtual cell structure in a distributed wireless system according to an aspect of the present invention includes an active virtual cell which is a set of distributed antennas forming a radio channel for actual data communication, A virtual cell setting unit for setting a distributed antenna set of a candidate virtual cell by predicting a reaching range of the candidate virtual cell; And a virtual cell replacement unit that monitors channel information between the distributed antenna and the terminal in the candidate virtual cell in real time and periodically searches for a distributed antenna of the candidate group to delete, add and change the distributed antenna in the candidate virtual cell .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Also, when a part is referred to as " including " an element, it does not exclude other elements unless specifically stated otherwise.

Now, an apparatus for forming a dual virtual cell structure in a distributed wireless system according to an embodiment of the present invention and a method of operating the same will be described in detail with reference to the drawings.

3 is a diagram illustrating a configuration of a dual virtual cell in a stationary state according to an embodiment of the present invention.

In the dual virtual cell according to the embodiment of the present invention, the virtual cell is managed by two structures, that is, an active virtual cell 300 and a candidate virtual cell 310 .

The active virtual cell 300 is a set of distributed antennas 100 in which access points 130 are dispersed at various points in an area so that there is no blind spot of radio waves and channels in which actual data of the terminal 200 are coming and going .

The candidate virtual cell 310 is a set of distributed antennas 100 for preventing performance degradation or disconnection of the user communication link to guarantee quality of service of the user.

Processors 110 that are responsible for signal processing are distributed within an area, and each processor 110 is interconnected for co-processing.

The processors 110 are connected to the dispersed access points 130, and each access point 130 is equipped with antennas for transmitting and receiving radio signals.

 One processing device that becomes a master coordinator is selected through interconnectivity 120 in three processing devices including an antenna of an active virtual cell 300 and a wireless signal processing operation from the terminal 200 And transmitted signals are detected

The dual virtual cell system collects and manages information for quickly transmitting data using a channel state of an antenna when a specific antenna enters a good channel state for communication of a specific terminal 200 during high-speed communication transmission Concept.

The dual virtual cell system must keep track of the high-speed channel changes in real time in order to quickly and dynamically update the communication links of the active virtual cell 300 at high speed when the terminal 200 is moving. Accordingly, in the dual virtual cell system, while the terminal 200 communicates at the current time using the active virtual cell 300, the reaching range of the next time is predicted according to the speed and the moving direction of the terminal 200, And searches for antennas entering a good channel state in the region to construct a candidate virtual cell 310. [

In the dual virtual cell system, when the performance degradation and disconnection of the user communication link and the channel change due to the high-speed movement are required by using the active virtual cell 300 and the candidate virtual cell 310, To improve performance.

As shown in Figure 3, all of the access points 130 with the antenna currently in use by the user in communication are assigned to the active virtual cell 300 as an active virtual cell with candidate groups of antennas obtained by monitoring the channel while the user is communicating. The cells 300 are included in the candidate virtual cell 310 and displayed. However, FIG. 3 does not mean that all the antennas of the access points 130 are included in the active virtual cell 300 or the candidate virtual cell 310.

The active virtual cell 300 and the candidate virtual cell 310 are defined with respect to the user and do not always mean a set of nearby antennas but are composed of antennas having relatively better channel quality do.

Also, a dual virtual cell system according to an embodiment of the present invention is a space-time coding technique combining a channel coding technique and a multi-antenna system in order to continuously maintain reliable communication in a poor radio environment, and a space-time trellis code (Space- Time Trellis Codes (STTC) to improve frequency efficiency and gain time and spatial diversity gain.

While the user is communicating using the active virtual cell 300, the processor 110 continuously searches for the candidate group of antennas having excellent link quality around the UE 200 using the channel information monitored in real time, Deletes, adds, and changes antennas in the candidate virtual cell 310 to update the configuration of the candidate virtual cell 310 in accordance with the current channel status.

Then, the processor 110 quickly switches the channel to the antenna having the higher channel quality of the candidate virtual cell 310 when the quality of the channel is lowered in the active virtual cell 300.

However, the selection of the antennas of the candidate virtual cell 310 may be differently determined according to the operation plan of the network, and in the embodiment of the present invention, the antennas are selected in descending order of the average power gain per path.

FIG. 4 is a diagram illustrating a configuration of a dual virtual cell during a fast movement of a terminal according to an embodiment of the present invention.

When the terminal 200 continues communication while moving at high speed, the network operates with a primary goal of preventing the communication link from being disconnected and promptly changing the communication channel.

The processor 110 holds the coverage of the active virtual cell 400 wide and processes the radio signal in the form of a relay through the interconnection 120 of the processing units. In addition, the processor 110 predicts the coverage of the candidate virtual cell 410 using the speed and the direction of movement of the terminal 200, and updates the coverage with the distributed antennas 100 in the region, To prevent disruption and quality deterioration and to repeat the process, communication channel change is made quickly.

FIG. 5 is a diagram illustrating a configuration of a dual virtual cell when the mobile station moves at a low speed according to an embodiment of the present invention.

In the case where the terminal 200 continues communication while moving at a low speed, the network tries to prevent the communication link from being disconnected and to improve the link quality at the same time.

The processor 110 narrows the coverage of the active virtual cell 500 and the candidate virtual cell 510 and decreases the number of the distributed antennas 100 to be searched to estimate the reach of the terminal 200 at the next time point, It is possible to perform both the rapid change of the communication channel and the improvement of the link quality by simultaneously performing antenna selection with excellent link quality within the predicted range.

3, 4 and 5, the radiuses and shapes of the active virtual cell and the candidate virtual cell are not fixed, but may be dynamic according to changes in the environment such as the speed and the moving direction of the terminal 200, . That is, when the terminal 200 is stopped, the processor 110 narrows the coverage of the dual virtual cell and searches the periphery of the terminal 200 by setting the coverage close to the circle because there is a possibility of moving in all directions .

When the terminal 200 moves at a high speed, the processor 110 searches for a predicted arrival range by setting the coverage in an elliptical form because the processor 110 holds the coverage of the dual virtual cell widely and is most likely to move in the current moving direction.

In the case of moving to the low speed of the terminal 200, the coverage of the double virtual cell is set to be wider than that at the stop, narrower than that at the high speed, and the possibility of movement in the current movement direction is the highest. However, The shape of the double virtual cell is set to be an elliptical shape. In addition, when traffic is concentrated in a specific area and there is a problem of mutual interference of spatial channels in the overlapping areas of the terminals 200, the processor 110 distributes channels of the respective radio signals to decrease the performance of the system It is possible to set the virtual cell so as to prevent it.

In the present invention, the active virtual cell setup process for the communication at the current time of the user is separated from the candidate virtual cell (CVC) setup process for the next-time communication.

6 is a block diagram schematically illustrating a processor for forming a dual virtual cell structure according to an embodiment of the present invention.

The processor 110 according to an embodiment of the present invention includes a virtual cell setting unit 112, a virtual cell searching unit, a virtual cell replacing unit 114, a signal processing unit 116, and a network storage unit 118.

The virtual cell setting unit 112 predicts the reaching range of the next time according to the moving speed and moving direction of the active virtual cell and the terminal 200, which is a set of distributed antennas 100 forming a radio channel for actual data communication, The candidate virtual cell is a set of the distributed antennas 100 of FIG.

The virtual cell setting unit 112 differently configures the coverage areas of the active virtual cell and the candidate virtual cell based on the moving speed and moving direction of the terminal 200 and the like.

That is, when the terminal 200 is in a stationary state, the virtual cell setting unit 112 sets the coverage area of the active virtual cell and the candidate virtual cell close to the circle because the terminal 200 can move in all directions. When the terminal 200 is in the fast moving state based on the location information of the terminal 200, since the virtual cell setting unit 112 has the highest possibility of moving in the moving direction of the current terminal 200, The coverage area of the candidate virtual cell is set to an elliptic shape.

In addition, when the terminal 200 is in a low-speed moving state, the virtual cell setting unit 112 sets the coverage area of the active virtual cell and the candidate virtual cell to be wider than that in the stop state, And sets the coverage area of the active virtual cell and the candidate virtual cell.

In other words, since the terminal 200 has the highest possibility of moving in the current moving direction, the virtual cell setting unit 112 sets the active virtual cell and the candidate virtual The cell coverage area is set.

The virtual cell replacing unit 114 uses the channel information monitored in real time between the dispersed antenna 100 in the candidate virtual cell and the terminal 200 to determine a candidate group of distributed antennas 100) periodically.

When a radio channel to be down-loaded in an active virtual cell occurs, the virtual cell replacing unit 114 changes the average power gain of each of the distributed antennas 100 of the active virtual cell retrieved from the virtual cell searching unit to the predetermined number And deletes the replaced radio channel from the candidate virtual cell

When the radio channel in which the communication quality is lowered in the active virtual cell occurs, the virtual cell replacing unit 114 selects one of the distributed antennas in the candidate virtual cell having the highest average power gain, and changes the selected radio channel.

The virtual cell replacement unit 114 periodically deletes, adds and changes the distributed antenna 100 in the candidate virtual cell to update the configuration of the distributed antenna 100 of the candidate virtual cell to the current radio channel state.

The signal processing unit 116 functions to detect and optimize the transmission / reception signals in the active virtual cell.

The network storage unit 118 stores the number of antennas of each terminal and the access point 130, the access point 130 in the virtual cell of each terminal 200, the channel between the antennas of the access point 130 and the terminal 200, The location information of the terminal 200 in the virtual cell, the location of other terminals 200 in the area where the virtual cells overlap, and the transmission rate required for each terminal 200, .

Hereinafter, a communication operation process according to the state of the terminal 200 in the network will be described with reference to FIG.

7 is a flowchart illustrating a communication process of a UE in a virtual cell of a distributed wireless system according to an embodiment of the present invention.

Unlike conventional point-to-point MIMO, the MIMO technique of a distributed wireless system is based on multipoint-to-point (downlink) or point-to- Multipoint (uplink) system.

First, in a downlink / uplink, a multi-input / output system having a small number of antennas on the terminal 200 side and having a larger number of transmit / receive antennas than a number / transmit antennas is configured. Thus, the antenna selection of the access point 130 is very important for an optimal transmit / receive structure.

In the reception antenna configuration of each access point 130, when there are a plurality of terminals 200, because the virtual cells overlap and one access point 130 accommodates one or more users, care must be taken to minimize mutual interference You have to choose.

The processor 110 according to the embodiment of the present invention includes all of the distributed antennas 100 within the range of reach of the terminal 200 in the candidate virtual cell and includes it in the candidate virtual cell And collects channel information between the distributed antenna 100 and the terminal 200 to construct a channel matrix H (S100, S102). Here, it is assumed that the channel information is transmitted to the processor 110 at regular intervals.

The processor 110 selects the N antennas in the order of the antennas having a higher average power gain per path among the distributed antennas 100 in the initial candidate virtual cell based on the collected channel information to construct the channel matrix H _C of the candidate virtual cell (S104).

The processor 110 continuously estimates the reach range of the terminal 200 using the speed and moving direction of the terminal 200 in preparation for the communication time of the terminal 200 to continuously update the configuration of the candidate virtual cell do.

The processor 110 determines whether to start communication with the terminal 200 (S106). When the communication of the terminal 200 starts, the processor 110 selects M antennas in the order of the antennas having the highest average power gain per channel among the antennas of the channel matrix H _C Thereby constructing a channel matrix H _M of the active virtual cell (S108).

When it is determined that the communication with the terminal 200 is not started, the processor 110 determines whether the channel monitoring period T has passed (S110). If the channel monitoring period has passed, the processor 110 proceeds to step S100. If the period has not passed, the pre-set channel matrix H _C is maintained and the flow advances to step S106 (S112).

The processor 110 starts the transmission / reception process with the terminal 200 using the antenna of the active virtual cell (S114). The processor 110 changes the path coefficient of the antenna overlapping with the channel matrix H _M in the channel matrix H _C to 0 (S116).

The processor 110 determines the moving speed of the terminal 200 using the position information of the terminal 200 (S118). The processor 110 performs a communication operation process related to the stop state of the terminal 200 when the movement speed of the terminal 200 is determined to be in a stop state (S120).

When the processor 110 determines that the movement speed of the terminal 200 is lower than the preset threshold speed, the processor 110 performs a communication operation process related to the low speed movement state of the terminal 200 (S122, S124).

When the processor 110 determines that the movement speed of the terminal 200 is higher than the predetermined threshold speed, the processor 110 performs a communication operation process related to the fast movement state of the terminal 200 (S122 and S126).

The processor 110 determines whether communication with the terminal 200 is continuing (S128) and repeats the step S118 if the communication with the terminal 200 is not finished.

Hereinafter, a communication operation process according to the movement speed of the terminal 200 will be described with reference to FIGS. 8, 9, and 10. FIG.

8 is a flowchart illustrating a communication process according to a stationary state of a terminal in a dual virtual cell structure according to an embodiment of the present invention.

The communication operation process according to the stationary state of the terminal 200 means the process of step S120 shown in FIG.

The processor 110 determines a candidate virtual cell based on the collected channel information (S200). The processor 110 searches the distributed antenna 100 within the determined candidate virtual cell range to determine whether there is an overlapping antenna with the distributed antenna 100 in the active virtual cell described in FIG. 6 (S202, S204).

If it is determined in step S204 that there is no overlapping antenna between the dispersed antenna 100 in the candidate virtual cell and the dispersed antenna 100 in the active virtual cell, the processor 110 searches for the dispersed antenna 100 searched in the candidate virtual cell And stored in the internal memory by a preset number (S206).

The processor 110 constructs a channel matrix H _C of the candidate virtual cell by selecting N antennas in order of the average power gain per distributed antenna 100 in the candidate virtual cell (S208). Then, the processor 110 determines whether a radio channel having a communication quality of less than or equal to a threshold value has occurred in the radio link in use (S210).

When a wireless channel having a communication quality lower than a threshold value is generated among the wireless links in use, the processor 110 replaces the wireless channel with an antenna having the highest average power gain per path in the candidate virtual cell, The channel is deleted from the candidate virtual cell (S212, S214).

In step S216, the processor 110 determines whether the channel monitoring period T has expired when a radio channel having a communication quality of less than or equal to a threshold value is not generated.

The processor 110 channel monitoring period, if the old or less, maintaining the channel matrix H _C of candidate virtual cell configured in step S208 and (S218), the process proceeds to the channel if the monitoring cycle is the last step S202.

FIG. 9 is a flowchart illustrating a communication operation process according to a fast moving state of a UE in a dual virtual cell structure according to an embodiment of the present invention.

The communication operation process according to the fast moving state of the terminal 200 means the process of step S126 shown in FIG.

The processor 110 measures the moving speed and moving direction of the terminal 200 based on the position information of the terminal 200 (S300). The processor 110 expands the dimension of the channel matrix H _M of the active virtual cell described in FIG. 6 to? Times in proportion to the measured moving speed of the terminal 200 (S302).

The processor 110 sets the row or column of the channel matrix excluding the M antennas currently used in the active virtual cell to 0 (S304).

The processor 110 determines the coverage area of the candidate virtual cell in proportion to the moving speed of the mobile station 200 in the moving direction area (S306).

The processor 110 searches the distributed antenna 100 within the candidate virtual cell range determined in step S306 to determine whether there is an overlapping antenna with the distributed antenna 100 in the active virtual cell described in FIG. 6 (steps S308 and S310).

If it is determined in step S310 that there is no overlapping antenna between the distributed antenna 100 in the candidate virtual cell and the distributed antenna 100 in the active virtual cell, The dispersive antenna 100 searched in the candidate virtual cell by the set number (? L) is stored in the internal memory (S312).

The processor 110 constructs a channel matrix H _C of the candidate virtual cell with the search for the distributed antennas 100 (S314). Then, the processor 110 determines whether there is a radio channel whose communication quality is less than or equal to the threshold of the radio link being used, or whose path coefficient is 0, which is overlapped with the channel matrix H _M in the channel matrix H _C (S 316) .

When there is a radio channel in which the communication quality of the radio link of the active virtual cell is equal to or less than a threshold value or a radio channel whose path coefficient is 0 exists, the processor 110 transmits the radio channel to the distributed antenna 100 of the candidate virtual cell. And deletes the replaced radio channel from the candidate virtual cell (S318, S320).

The processor 110 determines whether the channel monitoring period T has expired when a radio channel whose communication quality is less than or equal to a threshold value or a radio channel whose path coefficient is 0 does not exist among the radio links of the active virtual cell S322).

If the channel monitoring period has not passed, the processor 110 maintains the channel matrix H _C of the candidate virtual cell configured in step S314 (S324), and proceeds to step S300 if the channel monitoring period has elapsed.

10 is a flowchart illustrating a communication operation process according to a low-speed moving state of a terminal in a dual virtual cell structure according to an embodiment of the present invention.

The communication operation process according to the fast moving state of the terminal 200 means the process of step S124 shown in FIG.

The processor 110 measures the moving speed and moving direction of the terminal 200 based on the location information of the terminal 200 (S400). The processor 110 expands the dimension of the channel matrix H _M of the active virtual cell described in FIG. 6 in accordance with the measured moving speed of the terminal 200 by a factor of? (S402).

The processor 110 sets 0 or a row or column of the channel matrix excluding M antennas currently used in the active virtual cell (S404).

The processor 110 determines the coverage area of the candidate virtual cell in proportion to the moving speed of the mobile station 200 in the movement direction area (S406).

The processor 110 searches the distributed antenna 100 within the candidate virtual cell range determined in step S406 to determine whether there is an overlapping antenna with the distributed antenna 100 in the active virtual cell described in FIG. 6 (steps S408 and S410).

If it is determined in step S410 that there is no overlapping antenna between the distributed antenna 100 in the candidate virtual cell and the distributed antenna 100 in the active virtual cell, The dispersive antenna 100 searched in the candidate virtual cell by the set number (? L) is stored in the internal memory (S412).

The processor 110 configures the channel matrix H _C of the candidate virtual cell by selecting a predetermined number of distributed antennas 100 in the order of the average power gains per path among the distributed antennas 100 searched for (S414) . Then, it is determined that the processor 110 in use a radio link of the communication quality threshold (Threshold) equal to or less than the channel matrix H _C channel matrix H _M is a wireless channel exists, the path coefficient of the antenna is 0 is the same as in (S416) .

When there is a radio channel in which the communication quality of the radio link of the active virtual cell is equal to or less than a threshold value or a radio channel whose path coefficient is 0 exists, the processor 110 transmits the radio channel to the distributed antenna 100 of the candidate virtual cell. And deletes the replaced radio channel from the candidate virtual cell (S418, S420).

The processor 110 determines whether the channel monitoring period T has expired when a radio channel whose communication quality is less than or equal to a threshold value or a radio channel whose path coefficient is 0 does not exist among the radio links of the active virtual cell S422).

If the channel monitoring period has not passed, the processor 110 maintains the channel matrix H _C of the candidate virtual cell configured in step S414 (S424), and proceeds to step S400 if the channel monitoring period has elapsed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

According to the above-described configuration, while the user communicates through the active virtual cell at the current time, the network predicts the arrival range of the terminal at the next time point through the moving speed and moving direction of the terminal, It is possible to prevent communication disconnection due to movement of the terminal.

The present invention can be expected to provide a radio wave environment with a good channel state because the communication channel can be changed quickly when the link quality of the terminal is degraded.

The present invention can expect the effect of minimizing the fluctuation of the communication link quality in the continuous process of the user communication by simultaneously managing the dual virtual cell.

The present invention reduces the overhead of the UE by overhead burdening the transmission signal restoration process on the received signal using the space time trellis code in the uplink, and not only the diversity gain but also the coding gain Characteristics and low power transmission gain can be expected.

Claims (19)

A method for operating a virtual cell structure in a distributed wireless system, (a) constructing an initial channel matrix by including a distributed antenna in a signal arrival range of a terminal as an initial candidate virtual cell, and collecting channel information between the distributed antenna and the terminal; (b) constructing a channel matrix of candidate virtual cells according to a first specific criterion among dispersion antennas of the initial channel matrix based on the collected channel information; (c) constructing a channel matrix of an active virtual cell according to a second specific criterion among the antennas included in the channel matrix of the candidate virtual cell; And (d) performing transmission and reception processes with the mobile station using a distributed antenna included in the channel matrix of the active virtual cell, and performing different communication processes according to the mobile speed of the mobile station Lt; / RTI > The method according to claim 1, In the step (d) (d1-1) determining a coverage of a first candidate virtual cell based on the collected channel information and searching for a distributed antenna when the moving speed of the terminal is in a stationary state based on position information of the terminal; (d2-1) If the distributed antennas are not overlapped with the distributed antennas of the active virtual cell, a predetermined number of antennas are selected in order of the average power gains per path among the distributed antennas Constructing a channel matrix of one candidate virtual cell; And (d3-1) deleting and changing a distributed antenna in the first candidate virtual cell when a radio channel having a communication quality lower than a threshold value is generated among radio links being used in the active virtual cell Lt; / RTI > 3. The method of claim 2, When a radio channel having a communication quality lower than a threshold value is generated in the radio link currently being used by the active virtual cell in the step (d3-1), the radio channel is allocated to the first candidate virtual cell, Replacing the antenna with an antenna; And Deleting the radio channel from the first candidate virtual cell Lt; / RTI > 3. The method of claim 2, If it is determined in step (d3-1) that there is no radio channel having a communication quality lower than a threshold value among the radio links currently being used in the active virtual cell and the channel monitoring period has elapsed, the process proceeds to step (d1-1) . 3. The method of claim 2, In the step (d3-1), when a radio channel having a communication quality lower than or equal to a threshold value is not generated among the radio links currently being used in the active virtual cell, and the channel monitoring period is not exceeded, the channel matrix of the configured first candidate virtual cell is maintained Further comprising the steps of: The method according to claim 1, In the step (d) (d1-2) measuring a moving speed and a moving direction of the terminal using the position information of the terminal when the moving speed of the terminal is equal to or greater than a reference set value based on the position information of the terminal, Expanding the dimension of the channel matrix of the active virtual cell in proportion to the rate; (d2-2) determining a coverage of a second candidate virtual cell in proportion to a moving speed of the mobile station in a moving direction of the mobile station, and searching for a distributed antenna; (d3-2) constructing a channel matrix of the second candidate virtual cell with the searched distributed antenna if the distributed antenna does not overlap with the distributed antenna of the active virtual cell; And (d4-2) if there is a radio channel having a communication quality lower than a threshold value or a radio channel having a path coefficient of 0 among the radio links being used in the active virtual cell, the distributed antenna in the second candidate virtual cell is deleted and changed Step Lt; / RTI > The method according to claim 6, If there is a radio channel in which the communication quality of the radio link being used by the active virtual cell is less than or equal to a threshold value or a radio channel with the path coefficient of 0 exists in the active virtual cell in the step d4-2, Replacing the cell with an antenna; And Deleting the wireless channel from the second candidate virtual cell Lt; / RTI > The method according to claim 6, If no radio channel having a communication quality lower than or equal to a threshold value of the radio link currently being used by the active virtual cell or no radio channel having the path coefficient of 0 is present in the active virtual cell in step (d4-2) (d1-2). < / RTI > The method according to claim 6, If no radio channel having a communication quality lower than or equal to a threshold value of the radio link currently being used by the active virtual cell or no radio channel having the path coefficient of 0 is present and the channel monitoring period is not exceeded in the step d4-2, And maintaining the channel matrix of the configured second candidate virtual cell. The method according to claim 1, In the step (d) (d1-3) measuring a moving speed and a moving direction of the terminal using the position information of the terminal when the moving speed of the terminal is less than or equal to a reference set value based on the position information of the terminal, Expanding the dimension of the channel matrix of the active virtual cell in proportion to the rate; (d2-3) determining a coverage of a second candidate virtual cell in proportion to a moving speed of the mobile station in a moving direction of the mobile station, thereby searching for a distributed antenna; (d3-3) If the distributed antennas are not overlapped with the distributed antennas of the active virtual cell, a predetermined number of antennas are selected in the order of the antennas having a higher average power gain per path among the search distributed antennas, Constructing a channel matrix of the three candidate virtual cells; And (d4-3) if there is a radio channel in which the communication quality of the radio link being used by the active virtual cell is less than or equal to a threshold value, or if there is a radio channel with a path coefficient of 0, the distributed antenna in the third candidate virtual cell is deleted and changed Step Lt; / RTI > 11. The method of claim 10, If there is a radio channel in which the communication quality of the radio link being used by the active virtual cell is less than a threshold value or a radio channel whose path coefficient is 0 exists in the active virtual cell in the step d4-3, Replacing the cell with an antenna; And Deleting the wireless channel from the third candidate virtual cell Lt; / RTI > 11. The method of claim 10, If no radio channel having a communication quality lower than a threshold value or a radio channel having a path coefficient of 0 is not present among the radio links currently being used by the active virtual cell in the step d4-3, (d1-3). < / RTI > 11. The method of claim 10, If it is determined in step (d4-3) that a radio channel having a communication quality lower than or equal to a threshold value of the radio link being used by the active virtual cell does not exist, or a radio channel having the path coefficient of 0 is not present, And maintaining a channel matrix of the configured third candidate virtual cell. The method according to claim 1, Wherein the first specific criterion and the second specific criterion are determined in descending order of the average power gain per path. An apparatus for forming a dual virtual cell structure in a distributed wireless system, A virtual cell setting unit for setting a distributed antenna set of a candidate virtual cell by predicting a reaching range of a next time according to a moving speed and a moving direction of an active virtual cell and a terminal, which are a set of distributed antennas forming a radio channel for actual data communication; And A virtual cell replacement unit that monitors channel information between the distributed antenna in the candidate virtual cell and the terminal in real time and periodically searches for a distributed antenna of the candidate group to delete, add and change the distributed antenna in the candidate virtual cell, And the second virtual cell structure forming unit includes: 16. The method of claim 15, Wherein the distributed antennas in the candidate virtual cell are selected by a preset number in the order of the antennas having a higher average power gain per path. 17. The method of claim 16, Wherein the distributed antenna of the active virtual cell selects a predetermined number of distributed antennas in the candidate virtual cell in the order of the antennas having a higher average power gain. 16. The method of claim 15, Wherein the virtual cell replacement unit selects one of the distributed antennas in the candidate virtual cell having a high average power gain when the radio channel in which the communication quality is degraded in the active virtual cell is changed to the corresponding radio channel And a second virtual cell structure forming unit for forming a second virtual cell structure. 16. The method of claim 15, Wherein the virtual cell setting unit sets a coverage area of the active virtual cell and the candidate virtual cell in a form of an ellipse in a circle as the speed increases in consideration of a moving speed and a moving direction of the terminal, Forming device.

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