KR20170009448A - Cell control apparatus and control method for cell in coexistence network - Google Patents

Abstract

The present invention suggests a cell control apparatus and method for controlling a cell in a coexistence network. The cell control apparatus can optimally adjust (set) the uplink/downlink ratio of a TDD cell in consideration of the specific environmental factor of a coexistence network in which an FDD cell and a TDD cell. Moreover, the cell control apparatus can optimally allocate the uplink control channel of a concurrent access terminal simultaneously accessed to the FDD cell and the TDD. The cell control apparatus comprises a radio resource measurement part, a coverage measurement part, a ratio setting control part.

Description

TECHNICAL FIELD [0001] The present invention relates to a cell control apparatus and a coexistence network control method,

The present invention relates to a coexistence network in which an FDD cell and a TDD cell coexist. More particularly, the present invention relates to a coexistence network in which an FDD cell and a TDD cell coexist, And more particularly to a cell control apparatus and a coexistence network control method capable of optimally allocating an uplink control channel of a concurrent access terminal simultaneously connected to an FDD cell and a TDD cell.

As the type of communication service and the transmission request speed in the LTE communication system become various, the LTE frequency extension and the evolution into the 5G communication system are actively proceeding.

Meanwhile, the communication system uses a duplex technique to service an uplink (UL) and a downlink (DL). Duplex technology can be roughly divided into FDD (Frequency Division Duplex) and TDD (Time Division Duplex).

In the case of FDD, the frequency band for UL and the frequency band for DL are fixedly allocated and used. Since the use of the frequency band can not be changed, even if DL traffic increases, it is difficult to take special measures.

On the other hand, in the case of TDD, UL and DL can be allocated and used in units of subframes in one frame in such a manner that the same frequency band is variably allocated to UL or DL according to time.

In this way, in the case of TDD, since the use of the same frequency band can be changed over time, for example, if the DL traffic amount instantaneously increases, the number of DL subframes increases in one frame, (Hereinafter referred to as Dynamic TDD, D-TDD) in which adaptation to UL / DL traffic can be achieved by adjusting the uplink / downlink ratio, such as reducing the number of subframes.

Therefore, it is expected that the TDD usage will increase in the new frequency band when the LTE frequency extension and the 5G communication system are evolved in the communication system. Therefore, in the coexistence network environment where the FDD cell using the FDD and the TDD cell using the TDD coexist Will be developed.

As described above, in the coexistence network environment in which the FDD cell and the TDD cell coexist, the uplink / downlink ratio of the TDD cell can be optimally adjusted (set) in consideration of the peculiar environmental factors in which the FDD cell and the TDD cell coexist We need to find new ways.

On the other hand, in an environment in which a plurality of cells (FDD cell and TDD cell) coexist, a plurality of cells (FDD cells and TDD cells) are connected based on a multiple frequency simultaneous access technology such as a Carrier Aggregation technique and a Dual Connectivity technique. (Hereinafter referred to as a concurrent access terminal) exists in a cell (e.g., a TDD cell) of a plurality of cells (e.g., a PCD cell) Allocate.

Therefore, considering a specific environmental factor of the coexistence network in which the FDD cell and the TDD cell coexist, a new scheme for optimally allocating the uplink control channel of the concurrent access terminal is needed.

Therefore, in the present invention, it is possible to optimally adjust (set) the uplink / downlink ratio of the TDD cell in consideration of a specific environmental factor of the coexistence network in which the FDD cell and the TDD cell coexist, It is proposed to allocate the uplink control channel of the simultaneous access terminal concurrently connected to the cell with optimal allocation.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances and an object of the present invention is to provide a TDD cell in which the uplink / downlink ratio of a TDD cell A cell control apparatus and a coexistence network control method capable of optimally controlling (setting) an uplink control channel of a concurrent access terminal simultaneously accessing an FDD cell and a TDD cell.

In order to achieve the above object, a cell control apparatus according to a first aspect of the present invention is a cell control apparatus in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist, a radio resource Measuring unit; A coverage measurement unit for measuring coverage related information for the TDD cell; And setting uplink / downlink ratios for the TDD cell based on the measured radio resource usage rate and the measured coverage related information so that the capacity based on the radio resource and the coverage based quality in the TDD cell are balancedly improved And a ratio setting control unit.

Preferably, the coverage measurement unit includes: concurrent access support terminal coverage related information for the terminals supporting concurrent access to the FDD cell and the TDD cell; information for simultaneously supporting concurrent access to the FDD cell and the TDD cell; It is possible to measure information related to simultaneous access non-coverage terminal coverage targeting the terminal.

Preferably, the rate setting control unit changes the uplink / downlink ratio for the TDD cell according to the measured radio resource usage rate, and determines a service disconnection rate of the TDD cell that is confirmed based on the measured coverage related information Outage of the uplink / downlink ratio is not larger than a preset threshold value before the change after the change of the uplink / downlink ratio, the uplink / downlink ratio may be set as the uplink / downlink ratio for the TDD cell.

Preferably, the rate setting control unit determines that the service disconnection rate (Outage) of the TDD cell, which is checked according to the measured coverage related information, is greater than the threshold value before the change by changing the uplink / downlink ratio, The uplink / downlink ratio immediately before the change can be set as the uplink / downlink ratio for the TDD cell.

The UE may further include a UL control channel allocation controller for adaptively allocating an uplink control channel of the concurrent access terminal simultaneously accessed to the FDD cell and the TDD cell to the FDD cell or the TDD cell.

Preferably, the UL control channel assignment controller determines that the number of uplink control channels required by the concurrent access terminal is greater than the total number of uplink control channels provided in the FDD cell, An uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the TDD cells may be allocated to the specific TDD cell and an uplink control channel of the remaining concurrent access terminals may be allocated to the FDD cell.

Preferably, the specific TDD cell may be a predetermined number of TDD cells sequentially selected from TDD cells having the lowest service disconnection rate (Outage), which is determined according to the measured coverage related information among the TDD cells.

According to a second aspect of the present invention, there is provided a cell control apparatus for performing a concurrent access to an FDD cell using the FDD and a TDD cell using the TDD, A terminal confirmation unit for confirming the terminal; And a UL control channel allocation controller for adaptively allocating the uplink control channel of the concurrent access terminal to the FDD cell or the TDD cell.

Preferably, the UL control channel assignment controller determines that the number of uplink control channels required by the concurrent access terminal is greater than the total number of uplink control channels provided in the FDD cell, An uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the TDD cells may be allocated to the specific TDD cell and an uplink control channel of the remaining concurrent access terminals may be allocated to the FDD cell.

Preferably, the specific TDD cell includes a predetermined number of TDD cells sequentially selected from a TDD cell having the lowest service disconnection rate (Outage), which is determined according to the coverage related information measured for the TDD cell among the TDD cells .

Preferably, the specific TDD cell may be a predetermined number of TDD cells sequentially selected from TDD cells having the best cell environment according to the TDD cell environment information collected from the concurrent access terminal, among the TDD cells.

Preferably, if the number of uplink control channels required by the concurrent access terminal is equal to or less than the total number of uplink control channels provided by the FDD cell, An uplink control channel may be allocated to the FDD cell.

According to a third aspect of the present invention, there is provided a method of controlling a coexistence network cell in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist, A radio resource measurement step of measuring a resource utilization rate; The cell control apparatus comprising: a coverage measurement step of measuring coverage related information for the TDD cell; And the cell controller sets an uplink / downlink ratio for the TDD cell based on the measured radio resource usage rate and the measured coverage related information, And a rate setting control step for allowing the quality to be improved in a balanced manner.

Preferably, the rate setting control step changes the uplink / downlink ratio for the TDD cell according to the measured radio resource utilization rate, and determines a service disconnection rate of the TDD cell that is determined according to the measured coverage related information Down rate to the TDD cell if the uplink / downlink ratio does not increase after the change of the uplink / downlink ratio by a predetermined threshold value or more before the change.

Preferably, the cell control apparatus further includes a UL control channel allocation control step of adaptively allocating an uplink control channel of a concurrent access terminal simultaneously accessed to the FDD cell and the TDD cell to the FDD cell or the TDD cell .

Preferably, the UL control channel assignment control step may include: when the number of uplink control channels required by the concurrent access terminal is greater than the total number of uplink control channels provided by the FDD cell, The uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the TDD cells may be allocated to the specific TDD cell and the uplink control channel of the remaining concurrent access terminals may be allocated to the FDD cell.

Preferably, the specific TDD cell may be a predetermined number of TDD cells sequentially selected from TDD cells having the lowest service disconnection rate (Outage), which is determined according to the measured coverage related information among the TDD cells.

According to a fourth aspect of the present invention, there is provided a method of controlling a coexistence network cell in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist, A terminal confirmation step of confirming a concurrent access terminal connected to a cell simultaneously; And a UL control channel allocation control step of the cell control device adaptively allocating an uplink control channel of the concurrent access terminal to the FDD cell or the TDD cell.

Preferably, the UL control channel assignment control step may include: when the number of uplink control channels required by the concurrent access terminal is greater than the total number of uplink control channels provided by the FDD cell, Allocates an uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the TDD cells to the specific TDD cell and allocates an uplink control channel of the remaining concurrent access terminals to the FDD cell, The uplink control channels of all the concurrent access terminals may be allocated to the FDD cells when the number of requested link control channels is equal to or less than the total number of the uplink control channels.

Preferably, the specific TDD cell includes a predetermined number of TDD cells sequentially selected from a TDD cell having the lowest service disconnection rate (Outage), which is determined according to the coverage related information measured for the TDD cell, among the TDD cells. Or a predetermined number of TDD cells sequentially selected from the TDD cell having the best cell environment according to the TDD cell environment information collected from the concurrent access terminal, among the TDD cells.

Therefore, according to the cell control apparatus and the coexistence network control method of the present invention, considering the specific environmental factors of the coexistence network in which the FDD cell and the TDD cell coexist, the uplink / downlink ratio of the TDD cell can be optimally adjusted In addition, it is possible to optimally allocate an uplink control channel of a concurrent access terminal simultaneously accessing an FDD cell and a TDD cell.

Therefore, according to the cell control device and the coexistence network cell control method of the present invention, the uplink / downlink ratio of the TDD cell can be optimally adjusted (set) and the uplink control channel Thereby optimizing the system performance of the coexistence network as a result.

1 is an exemplary diagram showing a coexistence network environment to which the present invention is applied.
2 is a block diagram showing a configuration of a cell control apparatus according to a first preferred embodiment of the present invention.
3 is a block diagram showing a configuration of a cell control device according to a second preferred embodiment of the present invention.
4 and 5 are flowcharts illustrating a control flow of a coexistence network control method according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

1 is an exemplary diagram showing a coexistence network environment to which the present invention is applied.

As shown in FIG. 1, the coexistence network to which the present invention is applied is based on coexistence of an FDD cell using FDD (Frequency Division Duplex) and a TDD cell using TDD (Time Division Duplex).

1, the macro cell C100 of the macro base station 100 uses FDD and the small cells C10 and C20 of the small base stations 10, 20, 30, 40 and 50 located in the macro cell C100 , C30, C40, C50) are shown using TDD.

It is, of course, also possible that the macro cell C100 uses the TDD and the small cells C10, C20, C30, C40, and C50 use the FDD in order to explain the present invention .

In the following description, the present invention will be described with reference to the coexistence network environment of FIG. 1 for convenience of explanation. In the following description, macrocells C100 and FDD cells C110 are used in combination and small cells C10, C20, C30, C40, and C50, and TDD cells C10, C20, C30, C40, and C50.

1, the macro base station 100 forms an FDD cell C110 and the small base stations 10, 20, 30, 40 and 50 form TDD cells C10, C20, C30, C40 and C50 But it is only an embodiment and it is also possible that a single base station (not shown) forms all the FDD cell C110 and each TDD cell C10, C20, C30, C40, C50.

When the downlink (DL) traffic volume increases momentarily, the small cells C10, C20, C30 and C40, i.e., the TDD cells C10, C20, C30, C40 and C50 using the TDD, DL TDD function adaptively responding to UL / DL traffic by adjusting the uplink / downlink ratio, such as increasing the number of DL subframes and decreasing the number of uplink (UL) subframes.

However, if the uplink / downlink ratios are adjusted in consideration of only the amount of downlink (DL) traffic in the TDD cells C10, C20, C30, C40 and C50, If the ratio of the uplink becomes too low, the mismatch between the uplink / downlink coverage becomes intensified, and quality degradation based on the coverage may occur.

Accordingly, in the present invention, a method for optimally adjusting (setting) the uplink / downlink ratio of a TDD cell is proposed in consideration of peculiar environmental factors of a coexistence network in which FDD cells and TDD cells coexist.

Meanwhile, in an environment in which a plurality of cells, that is, an FDD cell C100 and a TDD cell C10, C20, C30, C40 and C50 coexist as shown in FIG. 1, a carrier aggregation technique, a dual connectivity (Hereinafter referred to as a simultaneous access terminal) exists in the FDD cell and the TDD cell on the basis of a multiple frequency simultaneous access technology such as a TDD (E. G., PCell). ≪ / RTI >

The CA technology can secure a wider frequency band through the integration of multiple unit frequency bands (CCs), and each frequency band (CC) Is used as an LTE frequency band for the LTE terminal, so that compatibility with the previous communication system can be maintained.

Therefore, it is assumed that the macro base station 100 and the small base stations 10, 20, 30, and 40 shown in FIG. 1 are base stations supporting CA technology, and the terminals 1, 2, 5 is assumed to support CA technology (hereinafter referred to as CA terminal).

The CA terminal first accesses the base station through a primary cell (PCell) of a predetermined frequency band among a plurality of frequency bands (CC), and then transmits the secondary cell, SCell), and a plurality of frequency band cells, that is, a basic cell (PCell) and a supplementary cell (SCell) are integrated to use the communication service.

At this time, the simultaneous access terminal means a CA terminal in a state in which the CA cell is simultaneously connected to the basic cell (PCell) and the auxiliary cell (SCell), that is, the CA function is activated.

1, it is assumed that the FDD cell C100 is the basic cell and the TDD cell C10 is the auxiliary cell SCell. In this case, FDD cell C100 and then concurrently connects to the small base station 10 through the auxiliary cell SCell or TDD cell C10 as necessary so that a plurality of frequency band cells, The cells C100 and PCell, and the TDD cells C10 and SCell may be integrated to use the communication service.

When the terminal 1 simultaneously accesses the FDD cells C100 and PCell and the TDD cells C10 and SCell and uses the communication service, the terminal 1 selects one of the FDD cells C100 and PCell and the TDD cells C10 and SCell An uplink control channel is allocated only through one cell used as a base cell (PCell).

That is, when the terminal 1 simultaneously accesses the FDD cell (C100, PCell) and the TDD cell (C10, SCell) and uses the communication service, the downlink channel for receiving the data is the FDD cell (C100, PCell) and the TDD cell CIl, MIMO-related RI, etc. for the downlink channel of each of the information related to the downlink channel such as the FDD cell (C100, PCell) and the TDD cell (C10, SCell) The uplink control channel is allocated only through one of the FDD cells C100 and PCell and the TDD cells C10 and SCell.

At this time, as in the case of the existing CA technology, the CA terminal which is simultaneously connected to the concurrent access terminals, i.e., the FDD cell (C100, PCell) and the TDD cell (C10, C20, C30, C40, C50) If the uplink control channel is collectively allocated to the FDD cell C100 used as the base cell (PCell), the downlink control channel provided by the FDD cell C100 may cause a problem of degradation of radio resource efficiency .

However, the uplink control channel of the CA terminal that is simultaneously connected to the concurrent access terminals, i.e., the FDD cell (C100, PCell) and the TDD cell (C10, C20, C30, C40, C50) (At least one of C10, C20, C30, C40, and C50, SCell) is too low, if the ratio of the uplink to the downlink is too low in the TDD cell (at least one of C10, C20, C30, C40, , The radio resource efficiency may be degraded.

Accordingly, in consideration of the specific environmental factors of the coexistence network in which the FDD cell and the TDD cell coexist, the present invention can optimally allocate the uplink control channel of the concurrent access terminals simultaneously connected to the FDD cell and the TDD cell .

Hereinafter, a cell control device for realizing the above-mentioned measures proposed by the present invention will be described in detail.

First, the configuration of a cell control apparatus according to a first preferred embodiment of the present invention will be described in detail with reference to FIG.

The cell control apparatus 200 of the present invention includes a radio resource measurement unit 210 for measuring a radio resource usage rate of the TDD cell in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist, A coverage measurement unit 220 for measuring coverage related information on the TDD cell, and an uplink / downlink ratio for the TDD cell based on the measured radio resource usage rate and the measured coverage related information, And a rate setting control unit 230 for improving the capacity of the radio resource based and coverage based quality in the cell in a well-balanced manner.

Hereinafter, for convenience of explanation, the macro cell C100 shown in FIG. 1 is referred to as an FDD cell, and the small cells C10, C20, C30, C40, and C50 shown in FIG. 1 are referred to as TDD cells do.

The cell controller 200 of the present invention may be a macro base station 100 capable of interworking with the small base stations 10, 20, 30, 40, 50, a small base station 100 capable of interworking with the macro base station 100, 40, and 50, and further may be a separate device (not shown) interlocked with the macro base station 100 and the small base stations 10, 20, 30, 40, and 50 .

The radio resource measurement unit 210 measures the radio resource usage rate for the TDD cell in the coexistence network in which the FDD cell and the TDD cell coexist.

That is, the radio resource measurement unit 210 measures the radio resource utilization rate for each of the TDD cells C10, C20, C30, C40, and C50 in the coexistence network as shown in FIG.

More specifically, the radio resource measurement unit 210 measures at least one of an uplink UL and a downlink DL for each of the TDD cells C10, C20, C30, C40, and C50 in the coexistence network as shown in FIG. One radio resource usage rate can be measured.

The radio resource measurement unit 210 will be described later in more detail.

The coverage measurement unit 220 measures coverage related information for each of the TDD cells C10, C20, C30, C40, and C50.

More specifically, the coverage measurement unit 220 measures the coverage of each of the TDD cells C10, C20, C30, C40, and C50, which is a terminal supporting the simultaneous connection to the FDD cell and the TDD cell, Access support terminal coverage related information, and concurrent access non-coverage terminal coverage related information for a terminal that does not support simultaneous access to the FDD cell and the TDD cell, that is, a CA supported terminal.

Here, the concurrent access support terminal coverage related information includes the frequency (c) of the deletion (Delete) of the TDD cell designated by the CA terminal in the auxiliary cell (SCell) and the number (c) of concurrent access terminals d, and further includes an average BLER (Block Error Rate) during a predetermined time (Time Window).

Meanwhile, the concurrent access non-coverage terminal coverage related information includes a frequency of a handover from the CA unsupported terminal to the FDD cell from the TDD cell and a call drop rate (b) that is a rate at which a call drop occurs, And further includes an average BLER during a predetermined time (Time Window).

The rate setting control unit 230 receives the TDD cells C10, C20, C30, C40, and C50 based on the radio resource usage rate measured by the radio resource measurement unit 210 and the coverage related information measured by the coverage measurement unit 220, And sets the uplink / downlink ratio for each of them.

Hereinafter, a specific embodiment will be described with reference to a TDD cell C10 which is one of the TDD cells C10, C20, C30, C40, and C50.

A specific procedure for measuring the radio resource usage rate of the TDD cell to the radio resource measurement unit 210 by referring to the TDD cell C10 will be described below.

In the TDD cell C10, there will be a currently set up / down link ratio.

For example, Table 1 below shows an example of allocating UL and DL for each subframe according to the uplink / downlink ratio of the TDD cell, that is, the configuration.

In the TDD cell C10, one frame, that is, 6 subframes out of 10 subframes is allocated to the DL and 3 subframes are allocated to the UL as the current uplink / downlink ratio. 3 is set.

In measuring the radio resource usage rate, the radio resource measurement unit 210 operates in a mode for measuring the UL radio resource usage rate (hereinafter referred to as UL priority mode) or a mode for measuring the DL radio resource usage rate (Hereinafter referred to as a DL priority mode) or a mode for measuring both the UL and DL radio resource usage rates (hereinafter referred to as UL / DL priority mode).

In addition, it is preferable that the change set value beta for performing the uplink / downlink rate change is set for each priority mode.

Accordingly, if the DL priority mode is set, the radio resource measurement unit 210 measures the DL radio resource usage rate for the TDD cell C10.

That is, the radio resource measurement unit 210 measures the uplink / downlink ratio currently set, that is, Config. 3 is used to determine how many of the six subframes allocated to the DL in one frame are assigned to the UE during a predetermined time period and the average of the measurement results is measured as the DL radio resource utilization rate )can do.

Of course, in the same manner as the above-described DL priority mode, when the UL priority mode is set, the radio resource measurement unit 210 determines the uplink / downlink ratio currently set for the TDD cell C10, that is, Config. 3, and if the UL / DL priority mode is set, the uplink / downlink ratio currently set for the TDD cell C10, that is, Config. 3 will measure UL / DL radio resource utilization.

A concrete procedure of measuring the coverage-related information for the TDD cell in the coverage measuring unit 220 by referring to the TDD cell C10 will be described below.

The coverage measurement unit 220 measures information related to simultaneous connection support terminal coverage for the CA terminal supporting the simultaneous connection to the FDD cell C100 and the TDD cell C10 with respect to the TDD cell C10.

That is, the coverage measurement unit 220 is connected to the FDD cell C100 as the basic cell PCell and to the TDD cell C10 as the auxiliary cell SCell, or to the TDD cell C10 as the auxiliary cell SCell, (C) for deleting a TDD cell (C10) in which the corresponding CA terminal is a supplementary cell (SCell) for a predetermined time (Time Window) and a concurrent access terminal The number of activated CA terminals) d, and the average BLER.

Also, the coverage measurement unit 220 may acquire information about concurrent access non-coverage terminal coverage related to the CA unsupported terminal that does not support concurrent access to the FDD cell C100 and the TDD cell C10 with respect to the TDD cell C10 .

That is, the coverage measurement unit 220 measures the frequency of handover from the TDD cell C10 to the FDD cell C100 for a predetermined time (Time Window) for a CA-supported terminal connected to the TDD cell C10 (a), a call drop rate (b) which is a rate at which a call drop occurred, and an average BLER.

Hereinafter, a specific procedure for setting the uplink / downlink ratio for the TDD cell in the rate setting controller 230 will be described with reference to the TDD cell C10.

For convenience of description, an example in which the radio resource measurement unit 210 measures the DL radio resource usage rate for the TDD cell C10 according to the DL priority mode will be described later.

First, the rate setting control unit 230 changes the uplink / downlink ratio for the TDD cell C10 according to the radio resource usage rate measured by the radio resource measurement unit 210. [

For example, when the DL radio resource utilization rate for the TDD cell C10 is measured as described above, the rate setting control unit 230 determines that the DL radio resource usage rate measured for the TDD cell C10 is the DL priority mode If the set change value (?) Is exceeded, the uplink / downlink ratio set in the current TDD cell (C10), that is, Config. If the DL ratio is one step higher than the uplink / downlink ratio (Config. 4 can be changed.

The ratio setting control unit 230 then determines whether the service disconnection rate (Outage) of the TDD cell C10 that is checked according to the coverage related information measured by the coverage measuring unit 220 is less than If the uplink / downlink ratio is not larger than the predetermined threshold value?, The uplink / downlink ratio changed in this step is set as the uplink / downlink ratio for the TDD cell C10.

On the other hand, the rate setting controller 230 determines whether the service disconnection rate (Outage) of the TDD cell C10, which is checked according to the coverage related information measured by the coverage measuring unit 220, The uplink / downlink ratio immediately before the change is set as the uplink / downlink ratio for the TDD cell C10.

More specifically, the ratio setting control unit 230 sets the ratio of the coverage related information measured by the coverage measuring unit 220, that is, the TDD according to (a), (b), (c) The service disconnection rate (Outage) of the cell C10 is checked.

At this time, the service disconnection rate (Outage) of the TDD cell C10 checked by the rate setting controller 230 becomes larger as the handover frequency a becomes larger, the Call Drop Rate (b) becomes larger, the larger the number d of the concurrent access terminals (CA terminals activated by the CA function) is, and the larger the average BLER, the larger the outage rate of service.

Therefore, for example, the rate setting control unit 230 may set the coverage related information (the above-mentioned (a), (b), and (c) described above) measured by the coverage measuring unit 220 before the change of the uplink / (Out.) of the TDD cell C10 determined according to the average BLER (b), (c), (d) and the average BLER) as a reference value 1 and changes the uplink / downlink ratio (Config. The service disconnection rate of the TDD cell C10 according to the coverage related information (a), (b), (c), (d) and the average BLER measured by the coverage measuring unit 220 Outage) can be confirmed.

The ratio setting control unit 230 then determines whether the service disconnection rate (Outage) of the TDD cell C10 is lower than the threshold value (?,? : 10%), the current upper / lower link ratio, that is, Config. 4 as the uplink / downlink ratio for the TDD cell C10.

This means that the service disconnection rate (Outage) of the TDD cell C10 does not become larger than the threshold value? Before the change after the change of the uplink / downlink ratio (Config. 3 → Config. 4) (Config. 3 → Config. 4) by changing the uplink / downlink ratio in consideration of the radio resource utilization rate of the radio resources (Config. Due to the fact that the mismatch between the uplink / downlink coverage of the TDD cell C10 is not intensified enough to cause a quality degradation due to the uplink / downlink coverage of the TDD cell C10.

On the other hand, if the service disconnection rate (Outage) of the TDD cell C10 is less than the threshold value (?,?) Before the change after the change of the uplink / downlink ratio : 10%), the upper / lower link ratio immediately before the change, that is, Config. 3 as the uplink / downlink ratio for the TDD cell C10.

This means that the service disconnection rate (Outage) of the TDD cell C10 becomes larger than the threshold value? Before the change after the change of the uplink / downlink ratio (Config. 3 → Config. 4) (Config. 3 → Config. 4), the capacity of the radio resource base is improved, but the uplink / downlink ratio is changed by changing the uplink / downlink ratio (Config. ) Causes a degradation in quality, resulting in an increase in mismatch between the uplink / downlink coverage of the TDD cell (C10).

As described above, the cell control apparatus 200 of the present invention considers the specific environmental factors of the coexistence network, that is, the radio resource utilization rate and the coverage related information, in the coexistence network in which the FDD cell and the TDD cell coexist, It is possible to optimally adjust (set) the uplink / downlink ratio of the TDD cell so that the capacity of the radio resource and the quality of coverage based on the cell are improved in a balanced manner.

Although the present invention has been described with reference to the TDD cell C10 which is one of the TDD cells C10, C20, C30, C40 and C50 shown in FIG. 1, the TDD cell C10 other than the TDD cell C10 , C30, C40, C50) will be similarly applied.

In addition, as shown in FIG. 2, the cell control apparatus 200 of the present invention may further include a UL control channel assignment control unit 240.

The UL control channel assignment control unit 240 performs a function of adaptively allocating an uplink control channel of a concurrent access terminal simultaneously connected to an FDD cell and a TDD cell to an FDD cell or a TDD cell.

That is, the UL control channel assignment controller 240 controls the simultaneous access terminal (CA terminal with the CA function activated) connected to the FDD cell C100 and the TDD cells C10, C20, C30, C40, (At least one of the FDD cell C100 and the TDD cells C10, C20, C30, C40, and C50) of the uplink control channel (UCI)

More specifically, the UL control channel assignment controller 240 determines whether or not the concurrent access terminals (concurrently accessing the FDD cell C100 and the TDD cells C10, C20, C30, C40, and C50) The number of uplink control channels required by the CA terminal is greater than the total number of uplink control channels? Provided by the FDD cell C100.

Hereinafter, for convenience of description, the terminals 1, 2, and 4 shown in FIG. 1 are simultaneously connected to the FDD cell C100 and the TDD cells C10, C20, C30, C40, And the terminal (the CA terminal with the CA function activated).

At this time, the terminal 1 is connected to the FDD cell C100 as a base cell (PCell) and connected to the TDD cell C10 as the auxiliary cell SCell, and the terminal 2 is connected to the FDD cell C100 as a base cell (PCell) And the terminal 4 is connected to the FDD cell C100 as the basic cell PCell and connected to the TDD cell C40 as the auxiliary cell SCell while the terminal 4 is connected to the TDD cell C20 as the auxiliary cell SCell .

In this case, the UL control channel assignment controller 240 determines the number of uplink control channel requests (for example, six) required by the UEs 1, 2, and 4 based on the uplink control channel Is greater than the total number [epsilon].

The UL control channel assignment controller 240 determines the number of uplink control channel requests (for example, six) required by the UEs 1, 2, and 4 based on the total of the uplink control channels provided by the FDD cell C100 When the number of UEs connected to a specific TDD cell among the TDD cells C10, C20, C30, C40 and C50 among the UEs 1, 2 and 4 is greater than the number And allocates the uplink control channel of the remaining concurrent access terminals to the FDD cell C100.

Here, the specific TDD cell means a TDD cell having excellent coverage, in other words, there is no discrepancy between the uplink / downlink coverage and there is no fear of quality degradation based on the coverage.

More specifically, the specific TDD cell is configured to transmit the coverage related information measured by the coverage measuring unit 220, that is, the above-mentioned (a), (b), (c) (e.g., 2) TDD cells sequentially selected from the TDD cell having the lowest service disconnection rate (Outage) determined according to the average BLER.

More specifically, the specific TDD cell includes coverage related information measured by the coverage measuring unit 220, among the TDD cells (C10, C20, C30, C40, C50) (E.g., 2) TDD cells sequentially selected from the TDD cell having the lowest service disconnection rate (Outage) identified according to the number d of the CA terminals for which the CA function is activated.

Alternatively, the specific TDD cell may be configured to select one of the TDD cells (C10, C20, C30, C40, and C50) based on the TDD cell environment information (e.g., MCS information) May be a predetermined number (e.g., two) of TDD cells sequentially selected from the best TDD cell.

Hereinafter, it is assumed that the TDD cells C10 and C20 among the TDD cells C10, C20, C30, C40, and C50 are specific TDD cells for convenience of explanation.

In this case, the UL control channel assignment controller 240 controls the uplink (UL) of the terminal 1 connected to the specific TDD cell C10 among the TDD cells C10, C20, C30, C40, The control channel is allocated to a specific TDD cell C10 and the uplink control channel of the UE 2 connected to the specific TDD cell C20 is assigned to the specific TDD cell C20 and the uplink control channel of the remaining UE 4 is allocated FDD cell < RTI ID = 0.0 > C100. ≪ / RTI >

On the other hand, the UL control channel assignment controller 240 determines whether the number (for example, six) of the uplink control channels required by the concurrent access terminals, i.e., the terminals 1, 2, and 4, If the total number of control channels is equal to or less than the total number of control channels, the uplink control channels of all of the UEs 1, 2, and 4 are allocated to the FDD cell C100.

As described above, in the coexistence network in which both the FDD cell and the TDD cell coexist, the cell control apparatus 200 of the present invention has the unique environmental factor of the coexistence network, that is, the total number of uplink control channels of the FDD cell, It is possible to optimally allocate the uplink control channel of the concurrent access terminal in consideration of the coverage goodness.

Therefore, according to the present invention, in the coexistence network in which the FDD cell and the TDD cell coexist, the uplink / downlink ratio of the TDD cell is optimally adjusted (set) By optimally allocating the control channel, the effect of improving the system performance of the coexistence network is deduced.

Hereinafter, the configuration of a cell control apparatus according to a second preferred embodiment of the present invention will be described in detail with reference to FIG.

The cell control apparatus 300 of the present invention includes a terminal confirmation unit 310 for identifying a simultaneous access terminal connected to the FDD cell and the TDD cell simultaneously in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist 310 and an UL control channel allocation controller 320 adaptively allocating an uplink control channel of the concurrent access terminal to the FDD cell or the TDD cell.

Hereinafter, for convenience of explanation, the macro cell C100 shown in FIG. 1 is referred to as an FDD cell, and the small cells C10, C20, C30, C40, and C50 shown in FIG. 1 are referred to as TDD cells do.

The cell controller 300 of the present invention may be a macro base station 100 capable of interworking with the small base stations 10, 20, 30, 40, 50, a small base station 100 capable of interworking with the macro base station 100, 40, and 50, and further may be a separate device (not shown) interlocked with the macro base station 100 and the small base stations 10, 20, 30, 40, and 50 .

The terminal confirmation unit 310 is a terminal that simultaneously connects to the FDD cell C100 and the TDD cells C10, C20, C30, C40, and C50 in the coexistence network as shown in FIG. CA terminal).

Hereinafter, for convenience of description, the terminals 1, 2, and 4 shown in FIG. 1 are simultaneously connected to the FDD cell C100 and the TDD cells C10, C20, C30, C40, And the terminal (the CA terminal with the CA function activated).

At this time, the terminal 1 is connected to the FDD cell C100 as a base cell (PCell) and connected to the TDD cell C10 as the auxiliary cell SCell, and the terminal 2 is connected to the FDD cell C100 as a base cell (PCell) And the terminal 4 is connected to the FDD cell C100 as the basic cell PCell and connected to the TDD cell C40 as the auxiliary cell SCell while the terminal 4 is connected to the TDD cell C20 as the auxiliary cell SCell .

That is, the terminal confirmation unit 310 can identify the terminals 1, 2, and 4 as a concurrent access terminal (CA terminal with CA function activated).

Accordingly, the UL control channel assignment controller 320 adaptively allocates the uplink control channel (UCI) of the concurrent access terminals, i.e., the UEs 1, 2, and 4, to the FDD cell or the TDD cell.

More specifically, the UL control channel assignment controller 320 determines whether the number (for example, six) of uplink control channels required by the concurrent access terminals, i.e., the terminals 1, 2, and 4, Is greater than a total number (?) Of uplink control channels to be provided.

Therefore, the UL control channel assignment controller 320 determines whether the number (for example, 6) of UL control channel required by the UEs 1, 2, and 4 is equal to the total number of uplink control channels provided in the FDD cell C100 When the number of UEs connected to a specific TDD cell among the TDD cells C10, C20, C30, C40 and C50 among the UEs 1, 2 and 4 is greater than the number And allocates the uplink control channel of the remaining concurrent access terminals to the FDD cell C100.

Here, the specific TDD cell means a TDD cell having excellent coverage, in other words, there is no discrepancy between the uplink / downlink coverage and there is no fear of quality degradation based on the coverage.

More specifically, the specific TDD cell is a TDD cell having the lowest service disconnection rate (Outage), which is determined according to the coverage related information measured for the TDD cell among the TDD cells (C10, C20, C30, C40 and C50) (E.g., two) TDD cells that are selected as the TDD cells.

For example, the cell control device 300 of the present invention may have the function of the coverage measurement unit 220 described in the cell control device 200 according to the first embodiment described above.

Therefore, the specific TDD cell is information related to the coverage, which is measured by the function of the coverage measurement unit 220 included in the cell control device 300, among the TDD cells C10, C20, C30, C40, (e.g., two) TDD cells sequentially selected from the TDD cells having the lowest service disconnection rate (Outage), which are determined according to a), b), c), and d) .

More specifically, the specific TDD cell is configured to detect the coverage related information, particularly the TDD cell deletion frequency (c), the concurrent access terminal (CA terminal) of the TDD cells (C10, C20, C30, C40, C50) (E.g., 2) TDD cells sequentially selected from the TDD cell having the lowest service disconnection rate (Outage) that is determined according to the number (d).

Alternatively, the specific TDD cell may be configured to select one of the TDD cells (C10, C20, C30, C40, and C50) based on the TDD cell environment information (e.g., MCS information) May be a predetermined number (e.g., two) of TDD cells sequentially selected from the best TDD cell.

Hereinafter, it is assumed that the TDD cells C10 and C20 among the TDD cells C10, C20, C30, C40, and C50 are specific TDD cells for convenience of explanation.

In this case, the UL control channel assignment controller 320 determines that the uplink (UL) of the terminal 1 connected to the specific TDD cell C10 among the TDD cells C10, C20, C30, C40, The control channel is allocated to a specific TDD cell C10 and the uplink control channel of the UE 2 connected to the specific TDD cell C20 is assigned to the specific TDD cell C20 and the uplink control channel of the remaining UE 4 is allocated FDD cell < RTI ID = 0.0 > C100. ≪ / RTI >

Meanwhile, the UL control channel assignment controller 320 determines whether the number of requests (e.g., 6) of the uplink control channels required by the concurrent access terminals, i.e., the terminals 1, 2, and 4, If the total number of control channels is equal to or less than the total number of control channels, the uplink control channels of all of the UEs 1, 2, and 4 are allocated to the FDD cell C100.

As described above, in the coexistence network in which the FDD cell and the TDD cell coexist, the cell control apparatus 300 of the present invention is characterized in that the specific environmental factor of the coexistence network, that is, the total number of uplink control channels of the FDD cell, It is possible to optimally allocate the uplink control channel of the concurrent access terminal in consideration of the coverage goodness.

Therefore, according to the present invention, in the coexistence network in which the FDD cell and the TDD cell coexist, the uplink control channel of the simultaneous access terminal simultaneously connected to the FDD cell and the TDD cell is optimally allocated, And an improvement effect is derived.

Hereinafter, a coexistence network cell control method according to the present invention will be described with reference to FIGs. 4 and 5. FIG. For convenience of description, the reference numerals of FIGS. 1 to 3 will be described.

First, with reference to FIG. 4, a process of optimally adjusting (setting) the uplink / downlink ratio of a TDD cell in the coexistence network control method according to the present invention will be described in detail. Here, for convenience of explanation, the cell control device 200 will be described.

According to the coexistence network control method of the present invention, the cell control apparatus 200 measures the radio resource utilization rate for each of the TDD cells C10, C20, C30, C40 and C50 in the coexistence network as shown in FIG. 1 (S100).

Hereinafter, a specific embodiment will be described with reference to a TDD cell C10 which is one of the TDD cells C10, C20, C30, C40, and C50.

In the TDD cell C10, there will be a currently set up / down link ratio.

For example, Table 1 above shows an example of UL and DL allocation in units of subframes according to the uplink / downlink ratio of the TDD cell, that is, the Configuration.

In the TDD cell C10, one frame, that is, 6 subframes out of 10 subframes is allocated to the DL and 3 subframes are allocated to the UL as the current uplink / downlink ratio. 3 is set.

Then, the cell control device 200 operates in a mode for measuring a UL radio resource usage rate (hereinafter referred to as a UL priority mode) or a mode for measuring a DL radio resource usage rate (Hereinafter referred to as a DL priority mode) or a mode for measuring both UL and DL radio resource usage rates (hereinafter referred to as UL / DL priority mode).

In addition, it is preferable that the change set value beta for performing the uplink / downlink rate change is set for each priority mode.

Thus, if the DL priority mode is set, the cell control device 200 measures the DL radio resource usage rate for the TDD cell C10.

That is, the cell control device 200 sets the uplink / downlink ratio currently set to the TDD cell C10, that is, Config. 3 is used to determine how many of the six subframes allocated to the DL in one frame are assigned to the UE during a predetermined time period and the average of the measurement results is measured as the DL radio resource utilization rate )can do.

Of course, in the same manner as the DL priority mode described above, the cell control apparatus 200 determines whether the uplink / downlink ratio currently set for the TDD cell C10, that is, Config. 3, and if the UL / DL priority mode is set, the uplink / downlink ratio currently set for the TDD cell C10, that is, Config. 3 will measure UL / DL radio resource utilization.

The cell control apparatus 200 measures coverage related information for each of the TDD cells C10, C20, C30, C40, and C50 (S110).

Hereinafter, a specific embodiment will be described with reference to a TDD cell C10 which is one of the TDD cells C10, C20, C30, C40, and C50.

The cell control device 200 measures information related to simultaneous connection support terminal coverage for the CA terminal supporting the simultaneous connection to the FDD cell C100 and the TDD cell C10 with respect to the TDD cell C10.

That is, the cell control device 200 is connected to the FDD cell C100 as the basic cell PCell and to the TDD cell C10 as the auxiliary cell SCell or to the TDD cell C10 as the auxiliary cell SCell, (C) for deleting a TDD cell (C10) in which the corresponding CA terminal is a supplementary cell (SCell) for a predetermined time (Time Window) and a concurrent access terminal The number of activated CA terminals) d, and the average BLER.

The cell control apparatus 200 also transmits to the TDD cell C10 the concurrently connected unsupported terminal coverage related information for the CA unsupported terminal that does not support concurrent access to the FDD cell C100 and the TDD cell C10 .

That is, the cell control apparatus 200 performs a handover from the TDD cell C10 to the FDD cell C100 for a predetermined time (Time Window) with respect to the CA unsupported terminal connected to the TDD cell C10 (a), a call drop rate (b) which is a rate at which a call drop occurred, and an average BLER.

The cell control apparatus 200 determines the uplink / downlink ratio for each of the TDD cells C10, C20, C30, C40, and C50 based on the radio resource utilization rate measured in step S100 and the coverage related information measured in step S110 Setting.

Hereinafter, a specific procedure for setting the uplink / downlink ratio for the TDD cell will be described with reference to the TDD cell C10. For convenience of explanation, an example in which the cell control apparatus 200 measures the DL radio resource usage rate for the TDD cell C10 according to the DL priority mode will be described later.

First, the cell control apparatus 200 changes the uplink / downlink ratio for the TDD cell C10 according to the radio resource usage rate measured in step S100 (S120, S130).

For example, when the DL radio resource utilization rate for the TDD cell C10 is measured as described above, the cell control apparatus 200 determines that the DL radio resource utilization rate measured for the TDD cell C10 is in the DL priority mode It is determined whether it exceeds the set change value? (S120).

The cell control apparatus 200 determines whether the DL radio resource usage rate measured for the TDD cell C10 exceeds the change setting value beta set in the DL priority mode, The link rate, ie Config. If the DL ratio is one step higher than the uplink / downlink ratio (Config. 4 (S130).

After that, the cell control apparatus 200 determines whether the service disconnection rate (Outage) of the TDD cell C10, which is checked according to the coverage related information measured in step S110, is greater than or equal to a preset threshold Is greater than the value [lambda] (S1140).

If the service disconnection rate (Outage) of the TDD cell C10 does not increase by more than the threshold value? Before the change after the change of the uplink / downlink ratio, the cell control device 200 determines that the uplink / To the uplink / downlink ratio for the TDD cell C10 (S160).

On the other hand, when the service disconnection rate (Outage) of the TDD cell C10 becomes larger than the threshold value? Before the change after the change of the uplink / downlink ratio, the cell control device 200 transmits the up / The link rate is set as the uplink / downlink ratio for the TDD cell C10 (S150).

More specifically, the cell control apparatus 200 transmits the coverage related information measured in step S110, that is, the TDD cell C10 according to (a), (b), (c), (d) The outage of the service is checked.

At this time, the service disconnection rate (Outage) of the TDD cell C10 to be confirmed becomes larger as the handover frequency a becomes larger, the call drop rate b becomes larger, the TDD cell deletion frequency c becomes larger, The smaller the number d of the access terminals (the CA terminals with the CA function activated) is, and the larger the average BLER, the larger the service disconnection rate (Outage).

Therefore, for example, the cell control apparatus 200 may transmit the coverage related information (the above-mentioned (a), (b), (c)) measured before the change of the uplink / , the service disconnection rate (Outage) of the TDD cell (C10) confirmed according to the average (BLER), the average (BLER), and the average BLER The service disconnection rate of the TDD cell C10 according to the information (the above-mentioned (a), (b), (c), (d) and the average BLER).

Therefore, the cell control apparatus 200 determines that the service disconnection rate (Outage) of the TDD cell C10 is lower than the threshold value (?,?) After the change of the uplink / downlink ratio : 10%), the current upper / lower link ratio, that is, Config. 4 as the uplink / downlink ratio for the TDD cell C10.

This means that the service disconnection rate (Outage) of the TDD cell C10 does not become larger than the threshold value? Before the change after the change of the uplink / downlink ratio (Config. 3 → Config. 4) (Config. 3 → Config. 4) by changing the uplink / downlink ratio in consideration of the radio resource utilization rate of the radio resources (Config. Due to the fact that the mismatch between the uplink / downlink coverage of the TDD cell C10 is not intensified enough to cause a quality degradation due to the uplink / downlink coverage of the TDD cell C10.

On the other hand, when the service disconnection rate (Outage) of the TDD cell C10 is less than the threshold value (?,?) After the change of the uplink / downlink ratio (Config. 3? : 10%), the upper / lower link ratio immediately before the change, that is, Config. 3 as the uplink / downlink ratio for the TDD cell C10.

This means that the service disconnection rate (Outage) of the TDD cell C10 becomes larger than the threshold value? Before the change after the change of the uplink / downlink ratio (Config. 3 → Config. 4) (Config. 3 → Config. 4), the capacity of the radio resource base is improved, but the uplink / downlink ratio is changed by changing the uplink / downlink ratio (Config. ) Causes a degradation in quality, resulting in an increase in mismatch between the uplink / downlink coverage of the TDD cell (C10).

Then, the cell control device 200 repeatedly performs the operations after step S100 as long as the cell control function in the coexistence network is not turned off (No in S170), thereby continuously changing the uplink / downlink ratio of the TDD cell to the optimal (Setting).

As described above, in the coexistence network control method of the present invention, in the coexistence network in which the FDD cell and the TDD cell coexist, considering the specific environmental factors of the coexistence network, that is, The uplink / downlink ratio of the TDD cell can be optimally adjusted (set) so that the capacity of the radio resource base and the quality based on the coverage are improved in a balanced manner.

Hereinafter, with reference to FIG. 5, a process of optimally allocating the uplink control channel of a concurrent access terminal simultaneously connected to the FDD cell and the TDD cell in the coexistence network control method according to the present invention will be described in detail. Here, for convenience of explanation, the cell control device 300 will be described.

The cell control apparatus 300 may be configured to control at least one of the FDD cell C100 and the TDD cells C10, C20, C30, C40, and C50 in the coexistence network as shown in FIG. (CA terminal in which the CA function is activated) (step S200).

Hereinafter, for convenience of description, the terminals 1, 2, and 4 shown in FIG. 1 are simultaneously connected to the FDD cell C100 and the TDD cells C10, C20, C30, C40, And the terminal (the CA terminal with the CA function activated).

At this time, the terminal 1 is connected to the FDD cell C100 as a base cell (PCell) and connected to the TDD cell C10 as the auxiliary cell SCell, and the terminal 2 is connected to the FDD cell C100 as a base cell (PCell) And the terminal 4 is connected to the FDD cell C100 as the basic cell PCell and connected to the TDD cell C40 as the auxiliary cell SCell while the terminal 4 is connected to the TDD cell C20 as the auxiliary cell SCell .

Accordingly, the cell control apparatus 300 adaptively allocates the uplink control channel (UCI) of the concurrent access terminals, i.e., the UEs 1, 2, and 4, to the FDD cell or the TDD cell.

More specifically, the cell control device 300 determines whether the number (for example, six) of uplink control channels required by the concurrently connected terminals, i.e., the terminals 1, 2, and 4, Is greater than a total number [epsilon] of uplink control channels (S210).

The cell control apparatus 300 determines whether the number of uplink control channel requests (for example, six) required by the UEs 1, 2, and 4 is equal to the total number of uplink control channels provided in the FDD cell C100竜), a specific TDD cell is selected from the TDD cells C10, C20, C30, C40, and C50 (S220).

Here, the specific TDD cell means a TDD cell having excellent coverage, in other words, there is no discrepancy between the uplink / downlink coverage and there is no fear of quality degradation based on the coverage.

More specifically, if a specific TDD cell is selected based on the cell, the cell control device 300 is checked according to the coverage related information measured for the TDD cell among the TDD cells C10, C20, C30, C40, and C50 A predetermined number of TDD cells (for example, two) can be sequentially selected as a specific TDD cell starting from the TDD cell having the lowest service disconnection rate (Outage).

For example, the cell control device 300 may have the function of the coverage measurement unit 220 described in the cell control device 200 according to the above-described first embodiment.

Therefore, the cell control apparatus 300 can acquire the coverage related information (i.e., the information related to the coverage) measured by the function of the coverage measurement unit 220 included in the cell control apparatus 300 among the TDD cells C10, C20, C30, C40, A predetermined number of TDD cells (for example, two TDD cells) starting from the lowest service outage rate (Outage) identified according to the above-mentioned (a), (b), (c) You can select a specific TDD cell.

More specifically, the cell control device 300 determines the coverage related information, particularly the TDD cell deletion frequency (c), the concurrent access terminal (CA function) of the TDD cells C10, C20, C30, C40, (For example, two) TDD cells starting from the TDD cell having the lowest service disconnection rate (Outage) confirmed according to the number (d).

Alternatively, if the TDD cell is selected on the basis of the terminal, the cell control apparatus 300 selects the TDD cell from among the TDD cells (C10, C20, C30, C40, C50) A predetermined number of TDD cells (for example, two) can be sequentially selected as a specific TDD cell from the TDD cell having the best cell environment according to information (e.g., MCS information).

Hereinafter, it is assumed that the TDD cells C10 and C20 among the TDD cells C10, C20, C30, C40, and C50 are specific TDD cells for convenience of explanation.

When the cell control device 300 selects the TDD cells C10 and C20 as the specific TDD cell among the TDD cells C10, C20, C30, C40 and C50, The uplink control channel of the specific concurrent access terminal connected to the cells or TDD cells C10 and C20 is allocated to the TDD cells C10 and C20 at step S230 and the uplink control channels of the remaining concurrent access terminals are allocated to the FDD cell C100) (S240).

That is, the cell control apparatus 300 allocates the uplink control channel of the terminal 1 connected to the specific TDD cell C10 among the terminals 1, 2, and 4 to the specific TDD cell C10, The uplink control channel of the terminal 2 connected to the specific TDD cell C20 is allocated to the specific TDD cell C20 (S230).

Then, the cell control device 300 will allocate the uplink control channel of the remaining terminal 4 among the terminals 1, 2, and 4 to the FDD cell C100 (S240).

On the other hand, the cell control apparatus 300 determines whether the number (for example, six) of the uplink control channels required by the concurrent access terminals, i.e., the terminals 1, 2, and 4, (S210 No), the uplink control channels of all of the UEs 1, 2, and 4 are allocated to the FDD cell C100 (S260).

Then, the cell control apparatus 200 repeatedly performs the operations after step S200 described above so long as the cell control function in the coexistence network is not turned off (S250 No), thereby continuously changing the uplink control channel of the concurrent access terminal .

As described above, in the coexistence network in which the FDD cell and the TDD cell coexist, the cell control apparatus 300 of the present invention is characterized in that the specific environmental factor of the coexistence network, that is, the total number of uplink control channels of the FDD cell, It is possible to optimally allocate the uplink control channel of the concurrent access terminal in consideration of the coverage goodness.

Of course, in the coexistence cell control method according to the present invention described with reference to FIG. 4, the cell control apparatus 200 performs the downlink rate optimal setting operation (S100 to S160) of the TDD cell It is also possible to perform the uplink control channel optimal allocation operation (S200 to S260) of the concurrent access terminal described with reference to FIG.

As described above, according to the present invention, the uplink / downlink ratio of the TDD cell can be optimally adjusted (set) in consideration of the specific environmental factors of the coexistence network in which the FDD cell and the TDD cell coexist, Further, it is possible to optimally allocate an uplink control channel of a concurrent access terminal simultaneously connected to an FDD cell and a TDD cell.

Therefore, according to the present invention, an uplink / downlink ratio of a TDD cell is optimally adjusted (set) and an uplink control channel of a concurrent access terminal simultaneously connected to an FDD cell and a TDD cell is optimally allocated, Thereby improving the system performance of the system.

The coexistence network control method according to an embodiment of the present invention may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

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, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the cell control apparatus and the coexistence network cell control method according to the present invention, considering the specific environmental factors of the coexistence network in which the FDD cell and the TDD cell coexist, the uplink / downlink ratio of the TDD cell can be optimally adjusted And further allocates an uplink control channel of a simultaneous access terminal simultaneously connected to the FDD cell and the TDD cell, optimally allocates the UE to the FDD cell and the TDD cell, It is not only a possibility that the device is commercially available or operable, but it is an industrially applicable invention since it is practically possible to carry out clearly.

1, 2, 3, 4, 5: terminal 10, 20, 30, 40, 50:
100: macro base station
200: Cell control device
210: Radio resource measurement unit 220: Coverage measurement unit
230: rate setting control unit 240: UL channel allocation control unit

Claims (20)

A radio resource measurement unit for measuring a radio resource utilization rate for the TDD cell in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist;
A coverage measurement unit for measuring coverage related information for the TDD cell; And
And a rate setting controller for setting up / down link ratios for the TDD cell based on the measured radio resource usage rate and the measured coverage related information. The method according to claim 1,
The above-
Information about simultaneous access support terminal coverage related to the terminals supporting the simultaneous access to the FDD cell and the TDD cell and information on the simultaneous access support terminal coverage for the FDD cell and the terminal supporting the simultaneous access to the TDD cell And measures the coverage-related information. The method according to claim 1,
Wherein the ratio setting control unit comprises:
Changing the uplink / downlink ratio for the TDD cell according to the measured radio resource utilization rate,
If the service disconnection rate of the TDD cell confirmed according to the measured coverage related information does not become larger than a preset threshold value before the change after the change of the uplink / downlink ratio, the changed uplink / downlink ratio To the uplink / downlink ratio for the TDD cell. The method of claim 3,
Wherein the ratio setting control unit comprises:
When the service disconnection rate of the TDD cell confirmed according to the measured coverage related information increases beyond the threshold value before the change after the change of the uplink / downlink ratio, the uplink / downlink ratio immediately before the change And setting up the uplink / downlink ratio for the TDD cell. The method according to claim 1,
Further comprising a UL control channel allocation controller for adaptively allocating an uplink control channel of a concurrent access terminal simultaneously connected to the FDD cell and the TDD cell to the FDD cell or the TDD cell. . 6. The method of claim 5,
Wherein the UL control channel assignment controller comprises:
When the number of uplink control channels required by the concurrent access terminal is larger than the total number of uplink control channels provided by the FDD cell,
Allocating an uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the concurrent access terminals to the specific TDD cell and allocating an uplink control channel of the remaining concurrent access terminals to the FDD cell The cell control apparatus comprising: The method according to claim 6,
The specific TDD cell includes:
Wherein the TDD cell is a predetermined number of TDD cells sequentially selected from TDD cells having the lowest service disconnection rate out of the TDD cells, which is determined according to the measured coverage related information. A terminal confirmation unit for confirming a simultaneous access terminal connected to the FDD cell and the TDD cell simultaneously in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist; And
And a UL control channel allocation controller for adaptively allocating an uplink control channel of the concurrent access terminal to the FDD cell or the TDD cell. 9. The method of claim 8,
Wherein the UL control channel assignment controller comprises:
When the number of uplink control channels required by the concurrent access terminal is larger than the total number of uplink control channels provided by the FDD cell,
Allocating an uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the concurrent access terminals to the specific TDD cell and allocating an uplink control channel of the remaining concurrent access terminals to the FDD cell The cell control apparatus comprising: 10. The method of claim 9,
The specific TDD cell includes:
Wherein the TDD cell is a predetermined number of TDD cells sequentially selected from the TDD cell having the lowest service disconnection rate (Outage) determined according to the coverage related information measured for the TDD cell. 10. The method of claim 9,
The specific TDD cell includes:
Wherein the TDD cell is a predetermined number of TDD cells sequentially selected from TDD cells having the best cell environment according to the TDD cell environment information collected from the concurrent access terminal among the TDD cells. 9. The method of claim 8,
Wherein the UL control channel assignment controller comprises:
When the number of uplink control channels required by the concurrent access terminal is less than or equal to the total number of uplink control channels provided by the FDD cell,
And allocates uplink control channels of all the concurrent access terminals to the FDD cell. A radio resource measurement step of measuring a radio resource usage rate for the TDD cell in a coexistence network in which a cell control apparatus coexists with an FDD cell using FDD and a TDD cell using TDD;
The cell control apparatus comprising: a coverage measurement step of measuring coverage related information for the TDD cell; And
And a rate setting control step of setting the uplink / downlink ratio for the TDD cell based on the measured radio resource usage rate and the measured coverage related information, Way. 14. The method of claim 13,
Wherein the ratio setting control step comprises:
Changing the uplink / downlink ratio for the TDD cell according to the measured radio resource usage rate,
If the service disconnection rate of the TDD cell confirmed according to the measured coverage related information does not become larger than a preset threshold value before the change after the change of the uplink / downlink ratio, the changed uplink / downlink ratio Is set as an uplink / downlink ratio for the TDD cell. 14. The method of claim 13,
The cell control apparatus further comprises a UL control channel allocation control step of adaptively allocating an uplink control channel of a concurrent access terminal simultaneously accessed to the FDD cell and the TDD cell to the FDD cell or the TDD cell A coexistence network cell control method characterized by. 16. The method of claim 15,
Wherein the UL control channel assignment control step comprises:
When the number of uplink control channels required by the concurrent access terminal is larger than the total number of uplink control channels provided by the FDD cell,
Allocating an uplink control channel of a specific concurrent access terminal connected to a specific TDD cell among the concurrent access terminals to the specific TDD cell and allocating an uplink control channel of the remaining concurrent access terminals to the FDD cell Wherein the coexistence network cell control method comprises: 17. The method of claim 16,
The specific TDD cell includes:
Wherein the TDD cell is a predetermined number of TDD cells sequentially selected from a TDD cell having the lowest service disconnection rate (Outage) determined according to the measured coverage related information among the TDD cells. A cell checking step of confirming a concurrent access terminal simultaneously accessing the FDD cell and the TDD cell in a coexistence network in which an FDD cell using FDD and a TDD cell using TDD coexist; And
Wherein the cell control apparatus includes a UL control channel allocation control step of adaptively allocating an uplink control channel of the concurrent access terminal to the FDD cell or the TDD cell. 19. The method of claim 18,
Wherein the UL control channel assignment control step comprises:
When the number of uplink control channels required by the concurrent access terminal is greater than the total number of uplink control channels provided by the FDD cell, Assigning an uplink control channel of a specific concurrent access terminal to the specific TDD cell and allocating an uplink control channel of the other concurrent access terminal to the FDD cell,
And allocating an uplink control channel of all the concurrent access terminals to the FDD cell when the number of requests of the uplink control channel is equal to or less than the total number of the uplink control channels. 20. The method of claim 19,
The specific TDD cell includes:
A predetermined number of TDD cells sequentially selected from a TDD cell having the lowest service disconnection rate (Outage), which is determined according to coverage related information measured for the TDD cell,
Wherein the TDD cell is a predetermined number of TDD cells sequentially selected from TDD cells having the best cell environment according to the TDD cell environment information collected from the concurrent access terminal among the TDD cells.

Images