KR100587975B1 - Adaptive spectrum allocation method using spectrum sharing among multi-band wireless access system, and system controlling method using it - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an adaptive spectrum allocation method through frequency sharing between multi-band radio access systems and a system control method using the same in a mobile communication system.

2. The technical problem to be solved by the invention

The present invention is to set the shared frequency band for each system when the call demand of the voice service or low-speed data service of the user changes over time, so that the service according to the real-time user request is easy in the mobile communication system, and changes over time It is an object of the present invention to provide an adaptive spectrum allocation method capable of increasing spectrum utilization efficiency and a system control method using the same by occupying the shared frequency band of another system in response to the call demand.

3. Summary of Solution to Invention

According to an aspect of the present invention, there is provided a method for allocating a spectrum in a mobile communication system, the method comprising: a base station arranging step of disposing base stations of heterogeneous wireless systems in a same location in a cell where a service area overlaps; A frequency allocation step of allocating a portion of the spectrum allocated to each wireless system to the shared frequency band, thereby setting the fixed allocated spectrum to the fixed frequency band and the shared frequency band; And when the user terminal requests a service in the cell area, adaptively allocates a call volume channel and a carrier frequency to the user terminal in the first wireless system, so that the user terminal is available when there is an available frequency band of the second wireless system. And adaptive spectrum allocation to occupy a shared frequency band of the second wireless system.

4. Important uses of the invention

The present invention is used in a mobile communication system.

Adaptive Spectrum Allocation, Frequency Sharing, Dynamic Spectrum Allocation, Dynamic Channel Allocation

Description

Adaptive spectrum allocation method using frequency sharing among multi-band wireless access system, and system controlling method using it}             

1 is an exemplary cell configuration in which base stations between heterogeneous wireless systems to which the present invention is applied are arranged in the same location;

2 is an exemplary spectrum configuration for allocating a part of a spectrum fixedly allocated to an individual system to a shared frequency band according to the present invention;

3 is an exemplary explanatory diagram showing an adaptive spectrum allocation method according to the present invention;

4 is an explanatory diagram showing a conventional dynamic spectrum allocation method;

5 is a flowchart illustrating an embodiment of a system control method according to the present invention;

6 is a flowchart of an embodiment of an adaptive spectrum allocation method according to the present invention.

* Explanation of symbols on the main parts of the drawing

100: cell area 101102: wireless system

103: base station 104: mobile communication terminal

The present invention relates to an adaptive spectrum allocation method through frequency sharing between multi-band radio access systems in a mobile communication system and a system control method using the same. Adaptive spectrum that can increase spectrum utilization efficiency by setting a shared frequency band for each system when the call demand changes over time, and occupying the shared frequency band of another system in response to the call demand that changes over time. An allocation method and a system control method using the same.

The conventional spectrum allocation method is a fixed spectrum allocation method that allocates a radio frequency having a constant bandwidth to a service provider in consideration of service environment, quality, and interference effects. Operators use these allocated radio frequency resources to provide users with wireless communication services.

This fixed spectrum allocation method has to consider the interference between adjacent bands, the environment in the service environment, there is a limit of the service and system capacity provided. In particular, when providing a mobile communication service, the influence of the wireless environment is greatly affected, so the capacity of the mobile communication system is more limited. In order to increase the capacity of the mobile communication system according to the fixed spectrum allocation, the spectrum utilization technique uses a dynamic channel allocation technique ("Dynamic channel allocation based on cost function in a cellular system (Korean Patent Laid-Open No. 1999-0077621, Oct. 25, 1999). ) ").

Dynamic channel allocation technology can be applied when frequency reuse is possible in a single system. When providing voice and low-speed data services to users in a macro cell and a micro cell, such as a cellular environment, each channel in a single service area is provided. When there is no interference with a frequency allocated to a neighboring cell base station among frequency carriers fixedly assigned to a wireless network according to a radio channel environment of an independent cell, a base station in a cell area to be serviced is provided with an available carrier.

However, the dynamic channel allocation method is a dynamic carrier allocation method limited to a single system, and has a disadvantage in that it is difficult to individually control a base station located in a cell of the entire area providing the same service.

On the other hand, dynamic spectrum allocation method ("Communication system and method of sharing a communication resource (EP1 220557A1, published 3 July 2002)", "A Summary of Dynamic Spectrum Allocation Result from DRiVE (IST Movile and Wireless Telecommunication Summit 2002, Leaves) .P et al., Pp245-250, 2002.6) ") is a method for utilizing limited resources as systems become more integrated and services diversified, and the use of limited spectrum resources is limited. It is a method to increase frequency utilization efficiency by sharing part of spectral resources with other systems.

Accordingly, while the dynamic channel allocation method is a method of dynamically allocating available frequency carriers according to a service area among frequency carriers allocated to a single system, the dynamic spectrum allocation method has various systems in the same service area, By setting a part of the fixed allocated spectrum or a part of the spectrum fixedly allocated to the third system to the shared frequency band, a part of the shared frequency carrier is leased to the shared frequency band available to the other system as required by another system. This is how you assign it. This dynamic spectrum allocation method needs to share the shared spectrum appropriately between heterogeneous systems, and thus requires an etiquette related to frequency allocation so that the shared spectrum can be occupied without collisions according to the needs of the systems.

For better understanding, a conventional dynamic spectrum allocation method will now be described with reference to FIG. 4.

The conventional dynamic spectrum allocation technique sets the spectrum held by the individual system 400 or 401 to the shared frequency band 402 or 403, and appropriately sets the shared frequency band of another system according to the load when the traffic congestion occurs. By leasing, the leasing system increases the spectrum efficiency by allocating carrier frequencies to user terminals 411 or 412 requesting service.

Looking at the dynamic spectrum allocation method of renting and allocating the shared frequency band of another system from the system side, the system 410 has a shared spectrum 402 or 403, and each system (System A (400) according to user service requirements. The system B 401 assigns carrier frequencies 404 and 405 to each terminal (terminal A 411 and terminal B 412) requesting service. That is, when a traffic volume congestion occurs in the system A 400 and no congestion occurs in the system B 401, the available frequency band 406 in the system B 401 is leased in the system A 400 to provide a service. By allocating the carrier frequency 407 to the requesting user terminal (A) 411, it is possible to efficiently use limited resources. On the other hand, when a traffic volume congestion occurs in the system B 401 and no congestion occurs in the system A 400, the available frequency band 408 in the system A 400 is leased in the system B 401 to serve. By allocating the carrier frequency 409 to the user terminal (B) 412 requesting the network, limited resources can be efficiently used.

According to an example of a dynamic spectrum allocation technique studied in Europe, a call volume of a user requesting a wireless communication service in a heterogeneous individual system varies with time, and varies depending on the system, and the call volume pattern required between the individual systems may be correlated. The analysis results show that the shared spectrum can be increased by applying dynamic spectrum allocation etiquette. In this case, a method of estimating the frequency requirements required in the next time zone considering the call demands for each time zone and assigning frequencies to other systems when available frequencies exist is presented.

Here, the applied method is to give priority to one system, to randomly allocate, to the system that requires a lot of carriers, or to the number of carriers when the average call demand that changes with time between individual systems is used as a database A method of preferentially assigning to an assigned system is presented. As another example, a time prediction method is applied to calculate a real-time frequency requirement. The time prediction method has a disadvantage in that it is difficult to apply when the call volume changes rapidly for a short time. In addition, when individual system call volume patterns have a close correlation with each other, spectrum utilization efficiency is similar to that of using a fixed spectrum allocation method. In other words, the spectrum utilization efficiency of the entire system is not increased.

In particular, considering the time-varying call demand situation, the conventional dynamic spectrum allocation method rapidly increases the call demand in an environment where heterogeneous systems (eg, system A and system B) coexist in terms of systems. The system (for example, system B) can lease the available shared frequency held by another system (for example, system A) to allocate the carrier frequency to the user terminal B requesting the service and provide the service. In addition, there was a problem in that it is difficult to provide a service according to a user's demand in real time.

The present invention has been proposed to solve the above problems, in order to facilitate service provision according to real-time user demands in a mobile communication system, when a call demand of a voice service or a low-speed data service of users changes over time, sharing by system The purpose of the present invention is to provide an adaptive spectrum allocation method and a system control method using the same by setting a frequency band and occupying a shared frequency band of another system in response to the call demands changing over time. There is this.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. In addition, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

According to an aspect of the present invention, there is provided a method for allocating a spectrum in a mobile communication system, the method comprising: a base station arranging step of disposing base stations of heterogeneous wireless systems in a same location in a cell where a service area overlaps; A frequency allocation step of allocating a portion of the spectrum allocated to each wireless system to the shared frequency band, thereby setting the fixed allocated spectrum to the fixed frequency band and the shared frequency band; And when the user terminal requests a service in the cell area, adaptively allocates a call volume channel and a carrier frequency to the user terminal in the first wireless system, so that the user terminal is available when there is an available frequency band of the second wireless system. And an adaptive spectrum allocation step for occupying the shared frequency band of the second wireless system.

In addition, the present invention provides a system control method in a mobile communication system, comprising: a system initialization step of setting a fixed frequency band and a shared frequency band allocated to a wireless system and allocating an optimal number of service channels for each allocated frequency band; A user call request and power control step of optimizing system capacity and simultaneously controlling transmission / reception power in the first wireless system when the user terminal requests a call by accessing a first wireless system to receive a service; In order to efficiently utilize the spectrum allocated to the system when the user terminal requests a service, an adaptive frequency band and a carrier frequency are adaptively allocated to the user terminal in the first wireless system, so that an available frequency band of the second wireless system is changed. An adaptive spectrum allocation step, if present, allowing the user terminal to occupy a shared frequency band of the second wireless system; And a user call blocking step of blocking a service request call of the user terminal when the spectrum allocated to the first and second wireless systems is insufficient.

In the present invention, in order to facilitate service provision according to a real-time user's demand, the system does not rent a shared frequency from another system, but varies the shared frequency band within the system and allocates a carrier frequency to a user using another system to share the service. In this case, the user terminal receives a part of the shared frequency band of another system as a carrier frequency and directly accesses the other system to receive the service in real time. In the conventional dynamic spectrum allocation method, the service frequency bandwidth between heterogeneous systems is increased. If different, we will minimize the disadvantages of system performance degradation that can be caused by allocating available shared frequency bands to other systems, and facilitate system control related to spectrum allocation.

To this end, in the present invention, the base station of the heterogeneous systems in the same position in the cell, the power control technology for allowing users to access the heterogeneous system at the same time, real-time frequency conversion technology in the user terminal, fixed allocation between heterogeneous systems Shared frequency band setting technology for serving part of the spectrum to other users, fixed frequency band allocation method, heterogeneous system shared frequency band allocation method, heterogeneous system according to call demand of heterogeneous system There is a need for an adaptive spectrum allocation technique for adaptively allocating spectrum between systems by sequentially applying a system shared frequency band allocation method.

According to the present invention, the overall spectrum efficiency is increased in the environment in which the mobile communication network is integrated, the service is easily provided according to the real-time user service request, and the system control according to the adaptive spectrum allocation method is easy.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is an exemplary cell configuration in which base stations between heterogeneous wireless systems to which the present invention is applied are arranged in the same location. This is a case where the base stations of individual systems are present at the same location, and cells with the same service providing area for each system are overlapped.

The base station 103 of the system A 101 and the base station 103 of the system B 102 exist in the same location, and the cell area 100 to which the user's mobile communication terminal 104 can be serviced is defined in each system ( The same is true of the system A 101 and the system B 102.

Since the base station 103 and the service area 100 overlap in the same location, each system (System A 101 and System B 102) can simultaneously control power, thereby allowing users to independently operate in heterogeneous systems. I can connect it.

2 is a diagram illustrating an example of a spectrum configuration in which a portion of a spectrum fixedly allocated to an individual system is allocated to a shared frequency band according to the present invention. It is fixed to system A and system B in order to increase spectrum utilization efficiency by sharing frequencies between frequency bands 200 and 201 and heterogeneous systems which are currently fixedly allocated to system A and system B, respectively, to provide services in mobile communication systems. A portion of the allocated spectrum is set to the shared frequency band 202 of the system A and the shared frequency band 203 of the system B.

The fixed allocated total spectrum 200 of System A is the sum of System A's shared frequency band 202 for applying adaptive spectrum allocation technology and the fixed frequency band 204 for providing fixed service in System A. The same, the fixed allocated total spectrum 201 of System B is the shared frequency band 203 of System B for applying the adaptive spectrum allocation technique and the fixed frequency band 205 for providing fixed service in System B. Is equal to the sum of.

The user may be provided with the service desired by the user in the system A and the system B, and may use the shared frequency band 202 or 203 allocated to the other system.

3 is an exemplary explanatory diagram illustrating an adaptive spectrum allocation method according to the present invention.

As shown in FIG. 3, the system A 312 and the system B 313 share user information and call volume information of an individual system. The system A 312 and the system B 313 share a call volume channel and a carrier frequency according to a time-varying call load. 314 and 315, the spectrum of the system 300 is divided into a shared frequency band (302, 304) and a fixed frequency band (303, 305), the user terminal 301 is a terminal 301 and the system 300 Whenever there is an available frequency band in the system 300, the carrier frequency 306, 307 is adaptively selected from the system 300 whenever a service request is made to the system 300 so as to receive the service from the system 300. Can be assigned.

In the system 300 side, a call volume channel and a carrier frequency may be adaptively allocated to the user terminal 301, and if there is an available frequency band of another system in the terminal 301 side, shared frequency bands 302 and 304 of the other system. In the adaptive spectrum allocation method capable of occupying, (Action-1), in order to stably provide a service to a user requesting a service, the system A 312 having the fixed frequency band 303 is a user's service. When a request is made, the user terminal A 314 assigns a carrier frequency 306 of the fixed frequency band 303, and the system B 313 having the fixed frequency band 305 has a user's request for service. A fixed frequency band allocation method assigns the carrier frequency 307 of the fixed frequency band 305 to the user terminal B 315.

In addition, (operation-2) has a large amount of call demand according to a user's service request, and thus, call blocking may occur due to difficulty in providing services to users due to system capacity exceeding the fixed frequency bands 303 and 305 according to (operation-1). In this case, the same system shared frequency band allocation method allocates fixed frequency bands 303 and 305 and adjacent shared frequency bands 302 and 304 for service provision in order to minimize adjacent frequency interference and frequency conversion. That is, when the system A 312 having the available shared frequency band 302 requests a service of the user, the system A 312 allocates the carrier frequency 308 of the available shared frequency band 302 to the user terminal A 314. When the system B 313 having the available shared frequency band 304 requests the service of the user, the user terminal B 315 allocates the carrier frequency 309 of the available shared frequency band 304 to the user terminal B 315.

Further, (operation-3) is a user due to exceeding the system capacity in the fixed frequency bands 303 and 305 according to (operation-1) or exceeding the system capacity in the shared frequency bands 302 and 304 according to (operation-2). If call blocking occurs due to difficulty in providing services to the service providers, if there is an available frequency band in the shared frequency band 304 or 302 of another system, the user requesting the service may allocate the shared frequency band 304 or 302 of the other system. Note is a method for allocating a heterogeneous system shared frequency band.

That is, when the system A 312 having the available shared frequency band 302 requests a service from the user, the system A 312 allocates the carrier frequency 311 of the available shared frequency band 302 to the user terminal B 315. The user terminal B 315 converts the frequency into a carrier frequency 311 allocated from the system A 312, accesses the system A 312, receives a call volume channel, and receives a service from the system A 312. On the other hand, when the system B 313 having the available shared frequency band 304 requests the service of the user, the carrier frequency 310 of the available shared frequency band 304 is allocated to the user terminal A 314. The user terminal A 314 converts a frequency into a carrier frequency 310 allocated from the system B 313, accesses the system B 313, receives a call volume channel, and receives a service from the system B 313. At this time, if the available frequency sharing band according to (Operation-3) does not exist, the call for the service is blocked.

5 is a flowchart illustrating an embodiment of a system control method according to the present invention.

First, a fixed frequency band and a shared frequency band allocated to a system are set, and an optimal number of service channels for each allocated frequency band is allocated (system initialization step) (501).

Then, when a user accesses a random system to request a service and requests a call (user call request step) (502), the mobile communication multi-band radio access system optimizes system capacity and simultaneously controls transmission and reception power (power Control step 503, which drives an adaptive spectrum allocation algorithm (see FIG. 6) to efficiently utilize the spectrum allocated to the system when the user requests a service (adaptive spectrum allocation step) 504.

If the spectrum allocated to the heterogeneous system is insufficient (505), the call of the user who requested the service is blocked (user call blocking step) (506).

The adaptive spectrum allocation algorithm (method) includes a fixed frequency band allocation process (operation-1) 507, a same system shared frequency band allocation process (operation-2) 508, a heterogeneous system shared frequency band allocation process ( Operation 3) 509 is applied sequentially.

In the system initialization step 501, the fixed allocation spectrum for each system is set to a fixed frequency band and a shared frequency band, and the maximum user capacity of each system is determined when the fixed spectrum allocation process (operation-1) is applied. To determine the number of service channels.

In the user call request step 502, when users requesting a new service are activated, the users request a call from any system in order to receive service from the system.

In the power control step 503, when active users requesting various services are distributed in an arbitrary cell area, the mobile communication multi-band radio access system optimizes each system capacity and simultaneously controls transmission and reception power.

In the adaptive spectrum allocation step 504, the fixed frequency band allocation process (operation-1) 507, the same system shared frequency band allocation process (operation-2) 508, and the like to maximize the efficiency of spectrum use between heterogeneous systems. The heterogeneous system shared frequency allocation process (operation-3) 509 is applied sequentially.

That is, the fixed spectrum allocated to each system is set to a fixed frequency band and a shared frequency band.In the initial adaptive spectrum allocation step, the system allocates a fixed frequency band to provide a service to a user. Using operation-1) (507) ', if the fixed frequency band is insufficient, the system provides the service in real time to continuously provide the service to the user requesting the service if there are available traffic channels and carrier frequencies on the shared frequency. It uses the same system shared frequency band allocation process (Action-2) 508, which provides a traffic channel to a user requesting and assigns a carrier frequency of a shared frequency band. Frequency band and shared frequency band) are exhausted. When the system receives the information that the shared frequency band of another system is available, the heterogeneous system shared frequency band allocation process that can access the other system, allocate the available carrier frequency from the other system, and receive the service from the other system (operation- 3) 509 '.

Meanwhile, in the user call blocking step 506, when the fixed spectrum allocated to the system requesting the service and the other system is exhausted (505), the user's call request is blocked.

Next, the adaptive spectrum allocation step 504 will be described in more detail with reference to FIG. 6.

First, when the adaptive spectrum allocation method according to the user service request is requested, the adaptive spectrum allocation method operation is started, and in the operation of the fixed frequency band allocation method operation (operation-1) 601, users are requested to the service. In order to provide fixed and stable service without changing the system, the carrier frequency is allocated to the user when the carrier frequency in the fixed frequency band is available in the fixed frequency band allocated to the system. At this time, if there are available carrier frequencies in the fixed allocated frequency band in the system (602), the system applies the fixed frequency band allocation process (operation-1) (601) to users requesting service. If provided to the users, but the available carrier frequency is not left in the fixed frequency band (602), proceed to the next step before blocking the user call.

Here, the next step is the selection process (604-607) of the same system shared frequency band allocation method operation (operation-2) 608 or the heterogeneous system shared frequency band allocation method operation (operation-3) 609. It is about.

The selection process (604-607) of the same system shared frequency band allocation method operation (operation-2) 608 or the heterogeneous system shared frequency band allocation method operation (operation-3) 609 is performed according to the time in the individual system. The average required call demand load information 603 is used to first calculate a difference between call demands in the same time zone between heterogeneous systems (604), calculate call demand thresholds (605), and calculate two values (604, 605). Compare.

As a result of the comparison (606), if the difference in call demand between the heterogeneous systems in the same time zone is less than the call demand load threshold, the same system exists when there are available traffic channels and carrier frequencies in the shared frequency band (607). The shared frequency band allocation process is operated (operation-2) (608), and when the shared frequency band is exhausted in the system and the selection comparison value is large (606), the heterogeneous system shared frequency band allocation process is operated (operation-2). -3) (609).

In the fixed frequency band allocation process (operation-1) 601, in order to stably provide a service to a user requesting a service, when the system A having a fixed frequency band requests a service of the user, the user terminal A The carrier frequency of the fixed frequency band is assigned to the system, and the system B having the fixed frequency band allocates the carrier frequency of the fixed frequency band to the user terminal B when the user requests a service.

In addition, the same system shared frequency band allocation process (operation-2) 608 may assign a carrier frequency of the available shared frequency band to the user terminal A when the system A having the available shared frequency band requests a service from the user. When the system B having the available shared frequency band requests a service of the user, the system B allocates the carrier frequency of the available shared frequency band to the user terminal B.

In addition, the heterogeneous system shared frequency band allocation process (operation-3) 609 may allocate a carrier frequency of the available shared frequency band to the user terminal B when the system A having the available shared frequency band requests a service of the user. The user terminal B converts the frequency into a carrier frequency allocated from the system A, accesses the system A, receives a call volume channel, and receives a service from the system A. On the contrary, when the system B having the available shared frequency band requests the service of the user, the system B allocates the carrier frequency of the available shared frequency band to the user terminal A, and the user terminal A converts the frequency into the carrier frequency allocated from the system B. The system accesses the system B, receives a call volume channel, and receives a service from the system B.

On the other hand, the process of calculating the difference between the call demand in the same time zone between different systems (604) and calculates the call demand threshold value (605), using the average call demand load information according to the time in the individual system The difference in call demands in the same time zone between heterogeneous systems is calculated based on [Equation 1] below, and the call demand thresholds are calculated using the call demand load information, which is averaged according to time in individual systems. It can be calculated based on Equation 2].

As described above, the method of the present invention may be implemented as a program and stored in a recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto-optical disk, etc.) in a computer-readable form. Since this process can be easily implemented by those skilled in the art will not be described in more detail.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

As described above, the present invention is easy to provide a service according to a real-time user request in a mobile communication multi-band wireless access system, and can be directly connected to another system to receive a service only by frequency conversion of the user terminal, and coexisting carriers Even if the frequency bandwidth is different, performance degradation can be minimized, system control by adaptive spectrum allocation is easy, and when the fixed spectrum allocation method is applied in an integrated system, the adaptive spectrum allocation is performed by sharing the spectrum rather than the total system user capacity. When the method is applied, the total user capacity is increased, that is, the spectrum utilization efficiency can be increased.

Claims (11)

In the spectrum allocation method in a mobile communication system, A base station disposing step of disposing base stations of heterogeneous wireless systems in the same location in a cell where the service areas overlap; A frequency allocation step of allocating a portion of the spectrum allocated to each wireless system to the shared frequency band, thereby setting the fixed allocated spectrum to the fixed frequency band and the shared frequency band; And When the user terminal requests a service in the cell area, the call volume channel and the carrier frequency are adaptively allocated to the user terminal in the first wireless system, so that the user terminal is located when there is an available frequency band of the second wireless system. Adaptive spectrum allocation step to occupy shared frequency band of second wireless system Adaptive spectrum allocation method through frequency sharing between multi-band wireless access system in a mobile communication system comprising a. The method of claim 1, In the adaptive spectrum allocation step, Adaptive spectrum allocation method through frequency sharing between multi-band radio access systems in a mobile communication system characterized by sequentially applying a fixed frequency band allocation process, the same system shared frequency band allocation process, heterogeneous system shared frequency band allocation process . The method of claim 2, The fixed frequency band allocation process, In order to stably provide a service to a user requesting a service, when the first wireless system having a fixed frequency band requests a service of the user, the carrier frequency of the fixed frequency band is allocated to the first user terminal. Adaptive spectrum through frequency sharing between multi-band radio access systems in a mobile communication system, characterized in that the second radio system having a system assigns a carrier frequency of a fixed frequency band to the second user terminal when the user requests a service Assignment method. The method of claim 3, wherein The same system shared frequency band allocation process, To minimize the adjacent frequency interference and frequency conversion when call blocking occurs due to a large amount of call demand according to a user's service request, it is difficult to provide services to users due to excess system capacity in the fixed frequency band according to the fixed frequency band allocation process. To allocate a fixed frequency band and adjacent shared frequency bands for service, The first wireless system having an available shared frequency band allocates a carrier frequency of the available shared frequency band to the first user terminal when the user requests a service; The second radio system having an available shared frequency band allocates a carrier frequency of an available shared frequency band to the second user terminal when a service request is made by the user. Adaptive Spectrum Allocation Method by Sharing Frequency Between. The method of claim 4, wherein The heterogeneous system shared frequency band allocation process, When a call blocking occurs due to difficulty in providing services to users due to an excess of system capacity in a fixed frequency band according to the fixed frequency band allocation process or an excess of system capacity in a shared frequency band according to the same system shared frequency band allocation process, If an available frequency band exists in the shared frequency band of another wireless system, the shared frequency band of another wireless system is allocated to the user requesting the service. The first wireless system having an available shared frequency band allocates a carrier frequency of an available shared frequency band to the second user terminal when the user requests a service, and the second user terminal assigns a frequency to the first wireless system. Converts to a carrier frequency allocated from the mobile station, accesses the first wireless system, receives a call volume channel, and receives a service from the first system; The second wireless system having an available shared frequency band allocates a carrier frequency of an available shared frequency band to the first user terminal when the user requests a service, and the second user terminal sets a frequency to the second wireless system. A frequency between the multi-band radio access systems in the mobile communication system, converting to a carrier frequency allocated from the mobile communication system, and accessing the second radio system to receive a call volume channel to receive a service from the second radio system. Adaptive Spectrum Allocation Method by Sharing. The method according to any one of claims 1 to 5, The user terminal, It is possible to receive a service by receiving a carrier frequency from the first wireless system, and at the same time, the frequency conversion is possible to receive a service by receiving a carrier frequency from the second wireless system, Between the multi-band radio access system in the mobile communication system, characterized in that the service channel can be provided by receiving the service channel from the first wireless system and the service channel can be provided by receiving the service channel from the second wireless system Adaptive Spectrum Allocation Method by Frequency Sharing. The method according to any one of claims 1 to 5, The wireless system, respectively It is possible to exchange call requirement information and system state information between integrated systems, and to vary the number of service channels and carrier frequencies to provide services to user terminals in a shared frequency band allocated to a wireless system, An adaptive spectrum allocation method through frequency sharing between multi-band radio access systems in a mobile communication system, which can provide a service not only to a user terminal but also to a user terminal of another wireless system. The method according to any one of claims 1 to 5, In the base station arrangement step, since the base station and the service area are overlapped at the same location, the first and second wireless systems can simultaneously control power, so that the user terminal can independently access the heterogeneous wireless system, The first and second wireless systems share user information and call volume information of individual wireless systems, and can adaptively allocate a call volume channel and a carrier frequency to a user terminal according to a time-varying call volume load. Adaptive spectrum allocation method through frequency sharing between multiband radio access systems in a mobile communication system. The method of claim 8, The adaptive spectrum allocation step, Providing a carrier frequency by applying the fixed frequency band allocation process to users requesting service when there are available carrier frequencies within a fixed allocated frequency band in a wireless system; Calculating a difference of call demands in the same time zone between heterogeneous wireless systems using average demand call load information over time in an individual wireless system, calculating a call demand threshold, and comparing the two values; And As a result of the comparison, when the difference of call demands in the same time zone between heterogeneous wireless systems is smaller than the call demand load threshold, the same system shared frequency band allocation if there are available traffic channels and carrier frequencies in the shared frequency band in the corresponding wireless system. Performing the process, and performing the heterogeneous system shared frequency band allocation process when the shared frequency band is exhausted in the corresponding wireless system and when the selection comparison value is large. Adaptive spectrum allocation method through frequency sharing between multi-band wireless access system in a mobile communication system comprising a. In the system control method in a mobile communication system, A system initialization step of setting a fixed frequency band and a shared frequency band allocated to the wireless system and allocating an optimal number of service channels for each allocated frequency band; A user call request and power control step of optimizing system capacity and simultaneously controlling transmission / reception power in the first wireless system when a user terminal requests a call by accessing a first wireless system to receive a service; In order to efficiently utilize the spectrum allocated to the system when the user terminal requests a service, an adaptive frequency band and a carrier frequency are adaptively allocated to the user terminal in the first wireless system, so that an available frequency band of the second wireless system is changed. An adaptive spectrum allocation step, if present, allowing the user terminal to occupy a shared frequency band of the second wireless system; And User call blocking step of blocking a service request call of the user terminal when the spectrum allocated to the first and second wireless systems is insufficient; System control method comprising a. The method of claim 10, In the adaptive spectrum allocation step, The fixed frequency band allocation process, the same system shared frequency band allocation process, and the heterogeneous system shared frequency band allocation process are sequentially applied. The service frequency is shared by varying a shared frequency band in the first wireless system and assigning a carrier frequency to the user terminal using the second wireless system, wherein the user terminal shares a portion of the shared frequency band of the second wireless system. The system control method, characterized in that by being assigned to a carrier frequency to directly access to the second wireless system to be serviced in real time.

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