KR20060112962A - System and method for scheduling in a frequency overlay communication system - Google Patents

Abstract

A priority-based scheduling system and method in a frequency overlay communication system are provided to be compatible with an existing communication system that uses a different central frequency band. The first MS(Mobile Station) uses the first frequency band. The second MS uses the second frequency band. The first MS requests a base station to allocate resources required for using the first frequency band. The second MS requests the base station to allocate resources required for using the first frequency band. The base station determines an amount of channel quality information which the first and second MSs will feed back in consideration of the first MS preferentially according to the amount of resources requested by the MSs, and informs the MSs of the decided result.

Description

Scheduling system and method in frequency overlay communication system {SYSTEM AND METHOD FOR SCHEDULING IN A FREQUENCY OVERLAY COMMUNICATION SYSTEM}

1 schematically illustrates frequency allocation in a frequency overlay communication system of the present invention.

2 is a diagram schematically illustrating an example of a transceiver module used in an EB communication system according to an embodiment of the present invention.

3 is a view schematically showing another example of a transceiver module used in an EB communication system according to an embodiment of the present invention;

4 is a diagram showing the amount of CQI feedback in the overlaid frequency band of the NB and EB communication system according to an embodiment of the present invention

5 is a diagram illustrating a base station apparatus for determining an amount of CQI to be fed back by NB-MSs and EB-MSs in an overlaid frequency band in an EB communication system according to an embodiment of the present invention;

6 is a flowchart illustrating a process of determining an average CQI feedback amount by a base station according to an embodiment of the present invention.

7 is a diagram illustrating the internal operation of the CQI feedback amount determiners 504 and 506 for NB-MS and EB-MS in the overlaid frequency band according to an embodiment of the present invention.

8 is a diagram illustrating an apparatus for transmitting a base station according to an embodiment of the present invention.

9 is a flowchart illustrating a process of transmitting a CQI feedback amount determined by a base station according to an embodiment of the present invention.

10 is a diagram illustrating an apparatus structure for NB-MS to generate and feed back a CQI according to an embodiment of the present invention.

11 is a flowchart illustrating a process in which an NB-MS generates and feeds back a CQI according to an embodiment of the present invention.

12 illustrates an apparatus structure for EB-MS generating and feeding back CQI according to an embodiment of the present invention.

13 is a flowchart illustrating a process of generating and feeding back a CQI by an EB-MS according to an embodiment of the present invention.

The present invention relates to a scheduling system and method in a communication system, and more particularly, to a system and method for scheduling in a frequency overlayed communication system (hereinafter referred to as a frequency overlay communication system).

As the communication system develops, the types of services to be provided in the communication system are diversified. Accordingly, there is a need for a broadband communication system that provides broadband services. In general, since frequency resources are limited resources in the communication system, frequency bands in which a broadband communication system can also be used are limited. In addition, there is a difficulty in the design because backward compatibility with already installed communication systems must also be considered.

Meanwhile, currently proposed broadband communication systems are systems designed on the assumption that they use different frequency bands. However, as communication technology advances, a demand for increasing frequency bands for the broadband service is inevitable. Accordingly, the license cost for the use of the frequency band is increased, and the various methods proposed for providing broadband services are delayed due to the increase in the license cost.

Therefore, there is a need for a method for smoothly providing the broadband service while overcoming the limitation of the frequency band, that is, solving the problem of increasing the license cost for the frequency band. As one of these methods, a broadband communication system overlaid on an existing communication system and a specific frequency band may be considered. In this case, there is a need for a scheduling scheme that prioritizes a mobile station using the overlaid frequency band while maximizing performance, that is, maximizing frequency efficiency, between a user of the broadband communication system overlaid on the specific frequency band and a user of the existing communication system.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a scheduling method and system for maximizing frequency efficiency in a frequency overlay communication system.

Another object of the present invention is to provide a priority based scheduling method and a system for compatibility with an existing communication system using a different center frequency band in a frequency overlay communication system.

The system of the present invention for achieving the above objects; In a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, a system for performing scheduling, comprising: a base station, a first mobile station using the first frequency band; And a second mobile station using up to the second frequency band, wherein the first mobile station requests the base station to allocate an amount of resources for using the first frequency band, and the second mobile station uses the first frequency band. The base station requests resource allocation for use, and the base station determines the amount of channel quality information to be fed back to each of the first mobile station and the second mobile station in consideration of the first mobile station according to the amount of resources requested by the mobile stations. To notify the mobile stations.

The first method of the present invention for achieving the above objects; In a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, a method for performing scheduling by a base station, comprising: at least one mobile station using the first frequency band; At least one mobile station using up to the second frequency band exists, wherein the mobile stations receive resource amount information required by the first frequency band, and preferentially consider the mobile station using the first frequency band. And determining the amount of channel quality information to be fed back to each mobile station according to the requested resource amount information and notifying the mobile stations.

The second method of the present invention for achieving the above objects; In a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, the mobile station using the second frequency band transmits the channel quality information for scheduling of the base station. The method may further include receiving channel quality information amount information to be fed back from the base station in the first and second frequency bands, generating channel quality information corresponding to the channel quality information amount information, and specifying the channel quality information. And transmitting using a channel.

The apparatus of the present invention for achieving the above objects; In a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, the apparatus for performing scheduling, wherein the mobile stations using the first frequency band are selected from the first frequency band. Inputs the first resource amount information required by the mobile station and the second resource amount information requested by the mobile stations using the second frequency band, and takes the first and second resource amount information into consideration in consideration of the first and second resource amount information. A first average channel quality information amount to be fed back by the mobile stations using the first frequency band and a second average channel quality information amount to be fed back to the first frequency band by the mobile stations using the second frequency band; A first channel quality information feedback amount determiner and the first average channel quality information amount to be input, and the first frequency A second channel quality information feedback amount determiner for determining the amount of channel quality information to be fed back from the first frequency band by each of the mobile stations using several bands, and inputting the second average channel quality information amount to the second frequency band; Each of the mobile stations using the apparatus includes a third channel quality information feedback amount determiner for determining an amount of channel quality information to be fed back in the first frequency band.

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

The present invention proposes a scheduling scheme for mobile stations using an overlaid frequency band or an unoverlaid frequency band in a frequency overlayed communication system (hereinafter referred to as a frequency overlay communication system). do.

More specifically, a base station according to the present invention is a priority for scheduling mobile stations using an overlaid frequency band and mobile stations using an extended frequency band including the overlaid frequency band. Consider (priority). Here, the mobile station using the overlaid frequency band will be referred to as 'NB-MS' (Narrow Band-Mobile Station), and the mobile station using up to the extended frequency band including the overlaid frequency band is referred to as 'EB-MS'. It will be referred to as (Extended Band-Mobile Station). Accordingly, the base station determines the amount of channel quality information (hereinafter referred to as 'CQI') to which the NB-MS and the EB-MSs should feed back, between the NB-MSs and the EB-MSs. Determine your priority. That is, a mobile station with a large amount of CQI feedback is allocated a large amount of resources, and a mobile station with a small amount of CQI feedback is allocated a small amount of resources. In addition, since the frequency band used by the NB-MS is relatively smaller than the frequency band used by the EB-MS, scheduling of the NB-MS should be performed first.

1 is a diagram schematically showing frequency allocation in the frequency overlay communication system of the present invention.

Referring to FIG. 1, first, an existing communication system is an NB communication system having a center frequency f _c1 . The existing communication system may have a situation in which the frequency bandwidth needs to be increased due to the diversification of services and an increase in required transmission capacity. Accordingly, a communication system having an extended frequency bandwidth may be considered, and a communication system having an extended frequency bandwidth, that is, an EB communication system may be designed to be overlaid on the NB communication system with a frequency band. In FIG. 1, the EB communication system has a center frequency f _c2 . Here, the NB communication system only means that the bandwidth is relatively narrow compared to the frequency bandwidth used in the EB communication system, and does not limit the frequency band itself used in the NB communication system to the narrow band. Thus, the reason for extending the frequency bandwidth by applying the frequency overlay scheme is as follows.

(1) Reduction of license cost for frequency band

If a frequency band different from the frequency band used in the NB communication system is deployed in a new communication system without using the frequency overlay method, the license fee for the frequency band incurs the same as using a new frequency band. Done. On the contrary, when using the frequency overlay scheme, only the license fee for the additionally expanded bandwidth except for the existing frequency band is generated. Therefore, the operator only has to bear the additional license fee, so that the license fee for the frequency band acts as a relatively less burden.

(2) Increase of frequency resource efficiency in overlay frequency band

When the frequency overlay scheme is applied, frequency resource efficiency is increased in the overlaid frequency band. The frequency resource efficiency is important because service providers can generate revenue from their subscribers in proportion to the efficiency of the frequency resource.

In general, when the number of mobile stations that can be accommodated in a specific frequency band increases, a scheduling gain can be obtained, which is called a multiuser diversity gain. Therefore, when the frequency overlay scheme is used, the overlay frequency band is shared not only with the mobile stations of the NB communication system but also with the mobile stations of the EB communication system, thereby increasing the number of mobile stations that can be accommodated in the overlay frequency band. . This means that the frequency resource efficiency is increased in the overlay frequency band. Of course, the specific increase in the frequency resource efficiency is determined according to the scheduling scheme of the scheduler used in the EB communication system, and a scheduling scheme for maximizing the efficiency of the frequency resource will be described using an embodiment of the present invention. Shall be.

2 is a diagram schematically showing an example of a transceiver module used in an EB communication system according to an embodiment of the present invention.

Referring to FIG. 2, first, an Inverse Fast Fourier Transformer (IFFT) of a transceiver module used in a communication system, that is, an NB communication system, before the bandwidth of a used frequency band is expanded, will be referred to as 'IFFT'. (FFT: Fast Fourier Transform, hereinafter referred to as 'FFT') Assuming that the number of points is 'N', a communication system after the bandwidth of the used frequency band is expanded, that is, EB communication It is assumed that the number of IFFT / FFT points of a transceiver module used in the system is 'M' (where M> N).

The base station 200 does not have an N-point IFFT / FFT module separately, but the mobile station # 1 (240) of the NB communication system and the mobile station # 2 (260) of the EB communication system do not have an M-point IFFT / FFT module alone. ) Can support the service. One IFFT / FFT module as above, i.e. In order to support services to both MSs of the NB communication system and the EB communication system using only the M-point IFFT / FFT module, a guard band must be provided in the boundary frequency band of the NB communication system and the EB communication system. The specific size of the guard band depends on the performance of a band-pass filter.

3 is a diagram schematically showing another example of a transceiver module used in an EB communication system according to an embodiment of the present invention.

Referring to FIG. 3, as described in FIG. 2, it is assumed that the number of IFFT / FFT points of a transceiver module used in an NB communication system is 'N', and the number of IFFT / FFT points of a transceiver module used in an EB communication system is shown. Assume that 'M' (where M> N).

By the way, it is preferable to arrange a base station using a frequency overlay method when the system is expanded, as described above with reference to FIG. 2, but a situation may occur in which a base station using a frequency overlay method cannot be disposed in a specific region. In this case, the base station using the N-point IFFT / FFT used in the existing NB communication system is maintained.

Hereinafter, for convenience of description, a base station using a scheme corresponding to the EB communication system will be referred to as an 'EB-BS', and a base station using a scheme corresponding to the NB communication system will be referred to as a 'NB-BS'.

Of course, when the system expansion is completed, the case where only the NB-BS exists for a specific region rarely occurs, but occurs in the intermediate stage of the system expansion. Accordingly, unlike the description of FIG. 2, when the BS is the NB-BS, the IFFT / FFT point of the transceiver module used in the EB communication system must be considered.

The NB-BS 300 uses only the N-point IFFT / FFT module. As described above with reference to FIG. 2, when only a guard band exists between a frequency band used in an EB communication system and a frequency band used in an NB communication system, the NB-BS 300 may use an N-point IFFT / FFT module. Communication can be performed not only with mobile station # 1 340 using the point IFFT / FFT module, but also with mobile station # 2 360 using the M-point IFFT / FFT module. In addition, as described in FIG. 2, the specific size of the guard band depends on the performance of the BPF, and the guard band is not related to the present invention, and thus a detailed description thereof will be omitted.

포인트 IFFT 모듈과 후술하는 NB 통신 시스템의 N 포인트 FFT 모듈간 통신 운용이 가능한 이유는 다음과 같다. However, the M point of the EB communication system, for example,

The reason why the communication operation between the point IFFT module and the N point FFT module of the NB communication system described below is possible is as follows.

포인트 IFFT 모듈에서 N 포인트 부분에만 매핑된다고 가정한다. 다음으로, 상기 M 포인트 IFFT 모듈을 통과한 상기 데이터는 대역 통과 필터링 과정을 통해 NB 통신 시스템에서 사용하는 반송파 주파수(carrier frequency)

대역으로 업 컨버젼(Up conversion)이 이루어진다. 이후 상기

포인트가 차지하는 대역폭(

)을 고려한 밴드 패스 필터링이 수행된다. 상기와 같은 과정을 거친 데이터는 송신 안테나(Tx Ant)를 통해 전송된다.For example, the actual receiver wants

It is assumed that only the N point portion of the point IFFT module is mapped. Next, the data passing through the M point IFFT module is a carrier frequency used in the NB communication system through a band pass filtering process

Up conversion is done to the band. Since the above

The bandwidth occupied by the point (

Band pass filtering is performed. The data passed through the above process is transmitted through a transmission antenna (Tx Ant).

)만큼 대역 통과 필터링을 수행한다. 상기와 같은

대역폭 밴드 패스 필터링으로 인해 상기 BS에서 M 포인트, 즉

포인트 IFFT로 전송한 데이터인 경우에도

포인트 FFT가 아닌 N 포인트 FFT만으로도 복원이 가능하게 된다. 상기 대역 통과 필터링이 끝난 신호는 N 포인트 FFT 모듈(470)을 통해 원래의 신호로 복원할 수 있게 된다. 즉, 제어 신호를 통해 상기 NB-MS는 자신에게 할당된 리소스 위치를 파악하고, 이후 트래픽 신호를 복원하게 된다.Meanwhile, the NB-MS corresponding to the receiving end in the downlink receives a signal transmitted from the transmitting end, that is, the BS, through a receiving antenna Rx Ant. The MS then has a bandwidth corresponding to N points (

Perform bandpass filtering by). Same as above

M point at the BS, i.e. due to bandwidth band pass filtering

Even if the data is sent by point IFFT

Restoration is possible only by the N point FFT, not the point FFT. The band pass filtered signal can be restored to the original signal through the N point FFT module 470. That is, the NB-MS determines the resource location allocated to the NB-MS through a control signal and then restores the traffic signal.

4 is a diagram illustrating the amount of CQI feedback in the overlaid frequency band of the NB and EB communication system according to an embodiment of the present invention.

Referring to FIG. 4, first, as described with reference to FIGS. 2 and 3, compatibility between the NB communication system and the EB communication system should be guaranteed. The EB communication system overlays a specific frequency band of the existing NB communication system. In addition, the EB communication system may exist not only EB-MS but also NB-MS. This means that the EB-MS and the NB-MS can use the overlaid frequency band of the EB communication system. Therefore, there is a need for a scheduling method for EB-MSs and NB-MSs to efficiently use limited frequency resources.

In the present invention, the base station may determine the amount of CQI to be fed back to the mobile station in consideration of the amount of resources required by the EB-MSs and NB-MS, the mobile station generates a CQI according to the amount of CQI to be fed back feedback do.

Accordingly, in the overlaid frequency band, the average CQI feedback amount of NB-MSs is defined as 'L _NB , _avg ' and the average CQI feedback amount of EB-MSs is defined as 'L _EB , _avg '. do. That is, the base station can maximize the frequency resource efficiency by determining the L _NB , _avg and L _EB , _avg according to the amount of resources required by the NB-MSs and the EB-MSs.

5 is a diagram illustrating a base station apparatus for determining an amount of CQI to be fed back by NB-MSs and EB-MSs in an overlaid frequency band in an EB communication system according to an embodiment of the present invention.

Referring to FIG. 5, first, the CQI feedback amount determiner 502 of the base station determines the average CQI feedback amount using resource amount information requested by the mobile stations. That is, the CQI feedback amount determiner 502 uses the resource amount R _{NB, req} required by the NB-MSs and the resource amount R _{EB, req} required by the _EB -MSs. NB-MS CQI feedback amount determiner 504 and EB-MS CQI feedback amount determiner 506 by determining the average CQI feedback amount L _NB , _avg ) and the average CQI feedback amount L _EB , _{avg of} EB-MS. Will be printed respectively.

The NB-MS CQI feedback amount determiner 504 determines the amount of CQI to be fed back to each NB-MS by using L _NB , _avg received from the CQI feedback amount determiner 502. Herein, the NB-MS when the total number of assuming that one K _1, CQI feedback quantity to the K ₁ beonjjae NB-MS can be defined as L _{NB, K1.}

In addition, the EB-MS CQI feedback amount determiner 506 determines and outputs the amount of CQIs to be fed back to each EB-MS using L _EB and _avg received from the CQI feedback amount determiner 502. Herein, when it is assumed that the total number of EB-MSs is K ₂ , the amount of CQIs to be fed back by the K _2nd EB-MS may be defined as L _{EB, K2} . Therefore, NB-MS 1 to NB-MS K ₁ should each feed back the amount of CQI determined by the base station, and EB-MS 1 to EB-MS K _{2 should} also feed back the amount of CQI determined by the base station. . If the amount of CQIs fed back by the NB-MS or EB-MS is large, the base station allocates a lot of resources to the mobile stations, and if the amount of feedbacks is low, the base station allocates less resources to the mobile stations.

6 is a flowchart illustrating a process of determining an average CQI feedback amount by a base station according to an embodiment of the present invention.

Referring to FIG. 6, in step 602, the base station calculates the total amount of resources required by NB-MSs and EB-MSs and proceeds to step 604. Here, the base station can calculate the total amount of resources required by the NB-MSs and the total amount of resources required by the EB-MSs in the overlaid frequency band using Equations 1 and 2 below.

은 상기 오버레이 된 주파수 대역에서 NB-MS들이 요구하는 전체 자원량을 의미한다.In Equation 1, K ₁ represents the total number of NB-MSs. In other words,

Means the total amount of resources required by the NB-MSs in the overlaid frequency band.

은 상기 오버레이 된 주파수 대역에서 EB-MS들이 요구하는 전체 자원량을 의미한다.In Equation 2, k ₂ means the total number of EB-MSs. In other words,

Means the total amount of resources required by the EB-MSs in the overlaid frequency band.

이 미리 설정된 기준값

보다 큰 값을 가지는지 비교한다. 비교 결과,

이

보다 큰 값을 가지면 606단계로 진행하고, 작은 값을 가지면 608단계로 진행한다. In step 604, the base station determines the total amount of resources required by NB-MSs.

This preset threshold

Compare with greater value. As a result of the comparison,

this

If the value is larger, the operation proceeds to step 606. If the value is smaller, the operation proceeds to step 608.

으로 설정하고, EB-MS들의 평균 CQI 피드백 량 L_EB,avg을 0으로 설정한다. 여기서, 상기

와

은 시스템 구현에 따라 미리 설정된 값들이다.In step 606, the base station recognizes that the traffic demands of the NB-MSs are high, and sets the average CQI feedback amount L _{NB, avg} of the NB-MSs to a preset maximum value.

Set to, and set the average CQI feedback amount L _{EB, avg} of the EB-MSs to zero. Where

Wow

Are preset values according to the system implementation.

보다 적은 경우 상기 오버레이 된 주파수 대역을 EB-MS들이 사용하도록 스케줄링 한다. 이를 위해, 상기 기지국은

이

값보다 작은 값을 가지는지 비교한다. 여기서, 상기

은 오버레이 된 주파수 대역 중 상기 NB-MS들이 요구하는 자원량을 제외한 나머지 자원량을 의미한다. 상기 비교 결과,

가 더 큰 작은값을 가지는 경우 610단계로, 더 큰 값을 가지는 경우 612단계로 진행한다.Meanwhile, in step 608, the base station determines the total amount of resources required by NB-MSs.

If less, the overlaid frequency band is scheduled for use by EB-MSs. To this end, the base station

this

Compares with a value less than it. Where

Means an amount of resources other than the amount of resources required by the NB-MSs in the overlaid frequency band. As a result of the comparison,

If the value has a larger value, go to step 610, and if the value has a larger value, go to step 612.

In step 610, the base station determines the average CQI feedback amount of NB-MSs and the average CQI feedback amount of EB-MSs using Equations 3 and 4 below.

In step 612, the base station determines the average CQI feedback amount of NB-MSs and the average CQI feedback amount of EB-MSs using Equations 5 and 6 below.

The base station determines an average CQI feedback amount for NB-MSs using Equation 5 in the overlaid frequency band, and allocates remaining resources for EB-MSs except for a resource corresponding to the average CQI feedback amount. However, EB-MSs that have not been allocated resources in the overlaid frequency band are allocated resources in the remaining frequency bands except for the overlaid frequency band among the EB frequency bands.

7 is a diagram illustrating an internal operation of the CQI feedback amount determiners 504 and 506 for NB-MS and EB-MS in the overlaid frequency band according to an embodiment of the present invention.

Referring to FIG. 7, first, the NB-MS CQI feedback amount determiner 504 includes K ₁ comparison value calculators, that is, first NB-MS comparison value calculators 702 to K ₁ NB-MS comparison values. K ₁ comparison value calculators of calculator 706 and NB-MS CQI feedback amount calculator 708. In addition, the EB-MS CQI feedback quantity determiner 506 is K ₂ the two comparison value calculator, that is, K ₂ of claim 1 EB-MS comparison value calculator 712 to the K ₂ EB-MS comparison value calculator 716 Two comparison value calculators, and an EB-MS CQI feedback amount calculator 718.

The NB-MS CQI feedback amount determiner 504 inputs L _{NB, avg} , and each of the first NB-MS comparison value calculator 702 to K ₁ NB-MS comparison value calculator 706 is represented by the following equation. Calculate the comparison value c _{NB, k} as shown in 7. The reason why each of the first NB-MS comparison value calculator 702 to the K ₁ NB-MS comparison value calculator 706 calculates the comparison value c _{NB, k} in consideration of the L _{NB, avg} is the NB. This is because the MS CQI feedback amount determiner 504 determines the CQI feedback amount in consideration of resource requirements of respective NB-MSs.

는 제k NB-MS가 임의의 시구간 T동안 평균적으로 수신한 데이터량을 나타내며, 상기 시구간 T는 통신 시스템의 상황에 따라 가변적으로 설정될 수 있다. 여기서, 상기

는 하기 하 기 수학식 8에 나타낸 바와 같이 1로 초기화한다.In Equation 7,

Denotes the amount of data received by the k-th NB-MS on an average during any time interval T, and the time interval T may be variably set according to the situation of the communication system. Where

Is initialized to 1 as shown in Equation 8 below.

That is, when the communication is first started, the base station cannot recognize the average received data amount for all NB-MSs, and the base station initializes the average received data amount of all NB-MSs to 1 as shown in Equation (8). .

If in the same manner described above, calculating the claim 1 NB-MS) to (K ₁ NB-MS each comparison value, NB-MS CQI feedback quantity calculator 708 to use the equation (9) the k NB-MS Determine the amount of CQI feedback.

과 N 중에 최소값을 선택하는 함수이다. 또한, N은 직교 주파수 분할 다중 접속 통신 시스템인 경우 전체 서브 캐리 어들의 개수를 나타내며,

₁은 모든 NB-MS들의 전체 CQI 피드백 량 혹은 모든 NB-MS들간 CQI 피드백 량의 평균값에 적용되는 가중치(weight)를 의미한다. 따라서, 상기 가중치

₁은 하기 수학식 10과 같이 나타낼 수 있다. In Equation 9, L _{NB, k} represents the amount of CQI to be fed back to the k-th NB-MS, min () function is

Selects the minimum value between and. In addition, N represents the total number of subcarriers in the orthogonal frequency division multiple access communication system,

₁ means a weight applied to an average value of the total CQI feedback amount of all NB-MSs or the CQI feedback amount between all NB-MSs. Thus, the weight

₁ may be expressed as in Equation 10 below.

과 N 중에 최소값을 선택하는 이유는 상기 제k NB-MS가 CQI를 피드백하는 최대 서브캐리어들의 개수는 N을 초과할 수 없기 때문이다.Here, using the min () function

The reason why the minimum value is selected from and N is that the maximum number of subcarriers to which the k-th NB-MS feeds back the CQI cannot exceed N.

를 사용함으로써 결정되는 각 EB-MS의 CQI 피드백 량이 하기 수학식 11에 의해 결정되는 것만이 상이하다.Meanwhile, the internal operation of the EB-MS CQI feedback amount determiner 506 is also similar to the internal operation of the NB-MS CQI feedback amount determiner 504 described above. However, the EB-MS CQI feedback amount determiner 506 receives L _{EB, avg} and assumes that the total number of EB-MSs is K ₂ , with weights.

Only the amount of CQI feedback of each EB-MS determined by using is determined by the following equation (11).

8 is a diagram illustrating an apparatus for transmitting a base station according to an embodiment of the present invention.

)과, EB-MS들이 요구하는 전체 자원량(

)을 입력하여, NB-MS들 각각이 피드백하여야 할 CQI 피드백 량 및 EB-MS들 각각이 피드백하여야 할 CQI 피드백 량을 결정한다. NB-CQIACH 생성기(820)는 상기 결정된 각 NB-MS 및 EB-MS들의 CQI 피드백 량을 이용하여 협대역-CQI량 채널(NB-CQIACH: Narrowr Band-CQI Amount Channel, 이하 'NB-CQIACH'라 칭하기로 한다)을 생성한다. Referring to FIG. 8, first, the CQI feedback amount determiner 810 of the base station determines the total resource amount required by the NB-MSs.

) And the total amount of resources required by EB-MSs (

) To determine the amount of CQI feedback that each of the NB-MSs should feed back and the amount of CQI feedback that each of the EB-MSs should feed back. The NB-CQIACH generator 820 uses a narrow-band-CQI amount channel (NB-CQIACH) based on the determined CQI feedback amount of each of the NB-MS and EB-MSs. It will be referred to as).

The NB-CQIACH is one of channels proposed in the EB communication system according to the present invention and constitutes a part of a narrow band-control channel (hereinafter, referred to as 'NB-CCH'). In addition, the NB-CQIACH is a channel including information on the amount of CQI to be fed back to the NB-MS and EB-MS. Of course, the CQI amounts to be fed back by the NB-MS and the EB-MS may be a fixed amount or a variable amount according to the determination of the base station.

The NB-CCH constitutes a part of the EB-CCH, and the EB-CCH is referred to as a Narrow Band-Dependent Control CHannel (NB-DCCH) (hereinafter, referred to as 'NB-DCCH'). Is made).

Accordingly, the NB-CCH generator 830 generates an NB-CCH channel using channels other than the generated NB-CQIACH. The generated NB-CCH constitutes an EB-CCH, and the EB-CCH, a traffic channel used for data transmission of NB-MSs and EB-MSs, and the like are input to a multiplexer 840. The multiplexer 840 allocates time and frequency resources to the channels. Thereafter, the signal is transmitted through the M-point IFFT unit 850 and the radio frequency (hereinafter referred to as RF) processor 860.

9 is a flowchart illustrating a process of transmitting a CQI feedback amount determined by a base station according to an embodiment of the present invention.

및

을 이용하여 오버레이 된 주파수 대역에서 상기 NB-MS들 및 EB-MS들의 CQI 피드백 량 L_NB,avg 및 L_EB,avg 을 결정하고 904단계로 진행한다. 상기 904단계에서 상기 기지국은 상기 결정된 CQI 피드백 량들을 이용하여 NB-CQIACH를 생성하고 906단계로 진행한다. 상기 906단계에서 상기 기지국은 상기 NB-CQIACH 및 다른 채널들과 함께 NB-CCH를 생성하고 908단계로 진행한다. 상기 908단계에서 상기 기지국은 각 채널들에 시간 및 주파수 자원을 할당하고 910단계로 진행한다. 상기 910단계에서 상기 기지국은 상기 채널들의 IFFT 연산을 수행하고 912단계로 진행한다. 상기 912단계에서 상기 기지국은 상기 IFFT 연산된 채널들을 RF 처리하고 914단계에서 수신측, 즉 이동국들로 송신한다.Referring to FIG. 9, first, in step 902, the base station determines the amount of resources required from NB-MSs and EB-MSs.

And

In step 904 _, the CQI feedback amounts L _{NB, avg} and L _{EB, avg} of the NB-MSs and the EB-MSs are determined in the overlaid frequency band. In step 904, the base station generates an NB-CQIACH using the determined CQI feedback amounts and proceeds to step 906. In step 906, the base station generates an NB-CCH along with the NB-CQIACH and other channels, and proceeds to step 908. In step 908, the base station allocates time and frequency resources to each channel, and proceeds to step 910. In step 910, the base station performs an IFFT operation on the channels and proceeds to step 912. In step 912, the base station RF-processes the IFFT-calculated channels and transmits the received signal to the receiver, i.e., mobile stations, in step 914.

FIG. 10 is a diagram illustrating an apparatus structure in which an NB-MS generates and feeds back a CQI according to an embodiment of the present invention.

Referring to FIG. 10, the NB-MS down-converts a signal received from a base station from an RF processor 1002 to an intermediate frequency (IF) band, and in an N-point FFT device 1004. After performing the FFT, the FFT is output to the first demultiplexer 1006. The first demultiplexer 1006 distinguishes the traffic channel and the NB-CCH by demultiplexing the FFT-calculated signal into a plurality of channels. Thereafter, the second demultiplexer 1008 demultiplexes the NB-CCH to distinguish a plurality of channels. NB-CQIACH exists among the divided channels. The NB-CQIACH is a channel used by the NB-MS to transmit a CQI to a base station as described above. Accordingly, the CQI generator 1010 estimates the channel and generates a CQI for the overlaid frequency band to be fed back to the base station. The UL-NB-CCH generator 1012 combines the NB-CQIACH including the generated CQI with other channels to generate a UL-NB-CCH.

11 is a flowchart illustrating a process of NB-MS generating and feeding back CQI according to an embodiment of the present invention.

Referring to FIG. 11, first, in step 1102, the NB-MS receives a predetermined signal from a base station and proceeds to step 1104. In step 1104, the NB-MS performs an RF process for down-converting the received signal to an intermediate frequency band and proceeds to step 1106. In step 1106, the NB-MS performs an FFT operation on the RF processed signal and proceeds to step 1108. In step 1108, the NB-MS demultiplexes the FFT-calculated signal into a plurality of channels and proceeds to step 1110. In step 1110, the NB-MS demultiplexes the NB-CCH among the divided channels, and proceeds to step 1112. In step 1112, the NB-MS generates a CQI to be fed back to the base station, includes the generated CQI in the NB-CQIACH separated by demultiplexing of the NB-CCH, and proceeds to step 1114. In step 1114, the NB-MS generates a UL-NB-CCH in combination with the NB-CQIACH and other channels and transmits a signal to a base station.

12 is a diagram illustrating an apparatus structure in which an EB-MS generates and feeds back a CQI according to an embodiment of the present invention.

Referring to FIG. 12, the EB-MS down-converts a signal received from a base station from an RF processor 1202 to an intermediate frequency (IF) band, and at an M-point FFT device 1204. The FFT is performed and then output to the first demultiplexer 1206. The first demultiplexer 1206 distinguishes the traffic channel and the EB-CCH by demultiplexing the FFT-calculated signal into a plurality of channels. Thereafter, the second demultiplexer 1208 and the third demultiplexer 1210 demultiplex the EB-CCH to distinguish a plurality of channels. The second demultiplexer 1208 distinguishes NB-CQIACH by demultiplexing the EB-CCH, and the third demultiplexer 1210 distinguishes NB-DCQIACH by demultiplexing the EB-CCH. The NB-CQIACH is a channel used for transmitting the CQI of the frequency band overlaid with the EB-MS to the base station. In addition, the NB-DCQIACH is a channel used for transmitting the CQI of the frequency band except for the frequency band over which the EB-MS is overlaid with the base station. Here, the base station determines the amount of CQI to be fed back to the mobile station in a frequency band other than the overlaid frequency band.

Accordingly, the CQI generator 1212 generates a CQI for the overlaid frequency band to be fed back to the base station, and includes the generated CQI in the NB-CQIACH separated by demultiplexing of the EB-CCH. In addition, the CQI generator 1214 generates a CQI for the overlaid frequency band to be fed back to the base station, and includes the generated CQI in the NB-DCQIACH separated by demultiplexing of the EB-CCH. The UL-NB-CCH generator 1216 combines the NB-CQIACH and other channels to generate a UL-NB-CCH. In addition, the UL-NB-DCCH generator 1218 combines the NB-DCQIACH and other channels to generate a UL-NB-DCCH.

13 is a flowchart illustrating a process of generating and feeding back a CQI by an EB-MS according to an embodiment of the present invention.

Referring to FIG. 13, in step 1302, the EB-MS receives a predetermined signal from a base station and proceeds to step 1304. In step 1304, the EB-MS performs RF processing for down-converting the received signal to an intermediate frequency band. In step 1306, the EB-MS performs an FFT operation on the RF processed signal and proceeds to step 1308. In step 1308, the EB-MS demultiplexes the FFT-computed signal into a plurality of channels, and proceeds to step 1310 and step 1316.

In step 1310, the EB-MS demultiplexes the NB-CCH among the divided plurality of channels and proceeds to step 1312. In step 1312, the EB-MS generates a CQI to be fed back to the base station, and includes the generated CQI in the NB-CQIACH separated by demultiplexing of the NB-CCH. Here, the EB-MS measures the CQI for the overlaid frequency band. In step 1314, the EB-MS generates a UL-NB-CCH in combination with the NB-CQIACH and other channels and transmits a signal to a base station.

Meanwhile, in step 1316, the EB-MS demultiplexes the NB-DCCH among the divided plurality of channels and proceeds to step 1318. In step 1318, the EB-MS generates a CQI to be fed back to the base station, and includes the generated CQI in the NB-DCQIACH separated by demultiplexing of the NB-DCCH. Here, the EB-MS measures the CQI for the remaining frequency bands except for the overlaid frequency bands. In step 1320, the EB-MS generates a UL-NB-DCCH in combination with the NB-DCQIACH and other channels and transmits a signal to a base station.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by those equivalent to the scope of the claims.

As described above, the present invention uses a mobile station using an existing band, i.e., an overlaid frequency band, and up to the extended frequency band in a communication system using an extended band including an overlaid frequency band. It is advantageous to provide a method for performing resource allocation scheduling of a mobile station. That is, the base station has an advantage in that scheduling can be performed to maximize the frequency efficiency of the overlaid frequency band.

Claims (22)

A system for performing scheduling in a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, Base station, A first mobile station using the first frequency band, There is a second mobile station using up to the second frequency band, The first mobile station requests the base station to allocate an amount of resources for using the first frequency band, The second mobile station requests the base station to allocate an amount of resources for using the first frequency band, The base station determines the amount of channel quality information to be fed back to each of the first mobile station and the second mobile station in consideration of the first mobile station according to the amount of resources requested by the mobile station to notify the mobile stations. system. The method of claim 1, And the first mobile station and the second mobile station generate and transmit the channel quality information amount corresponding to the amount of channel quality information notified from the base station to the base station. The method of claim 2, And the base station determines priorities of the respective mobile stations according to the amount of channel quality information received from the first and second mobile stations. The method of claim 1, The base station determines a first sum value obtained by adding the amount of resources requested by the first mobile station in the first frequency band, and a second sum value obtained by adding the amount of resources requested by the second mobile station in the first frequency band. , And when the first sum value exceeds a preset reference value, the first mobile station determines an average channel quality information amount to be fed back as a maximum value preset in the system. The method of claim 4, wherein The reference value is a value for determining whether the amount of resources required by the first mobile station is large, and the system can be set according to a system situation. The method of claim 4, wherein When the first sum is less than or equal to the first reference value, the base station subtracts the amount of resources required by the second mobile station in the first frequency band from the reference value by subtracting the amount of resources required by the first mobile station in the first frequency band. Compares to less than the result When the amount of resources required by the second mobile station is less than the result value, the average channel quality information amount to be fed back by the first mobile station and the average channel quality information amount to be fed back by the second mobile station are determined by Equation 12 below. Said system.

In Equation 12,

Is the average amount of channel quality information to be fed back by the first mobile station,

Is the preset maximum value,

Is the total amount of resources required by the second mobile station in the first frequency band,

Is the reference value,

Denotes an average amount of channel quality information to be fed back by the second mobile station in the first frequency band. The method of claim 6, When the amount of resources required by the second mobile station is greater than or equal to the result value, the average channel quality information amount to be fed back to the first mobile station and the average channel quality information amount to be fed back to the second mobile station are determined by Equation 13 below. Said system.

In Equation 13,

Is the average amount of channel quality information that the first mobile station should feed back in the first frequency band,

Is the preset maximum value,

Is the total amount of resources required by the second mobile station in the first frequency band.

Is the reference value,

Denotes an average amount of channel quality information to be fed back by the second mobile station in the first frequency band. The method of claim 1, And the base station transmits the determined channel quality information amount information to the narrowband channel quality information amount channel (NB-CQIACH) to be transmitted to the first and second mobile stations. A frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, the method of the base station performs the scheduling, At least one mobile station using the first frequency band and at least one mobile station using up to the second frequency band, wherein the mobile stations receive resource amount information required by the first frequency band; And determining the amount of channel quality information to be fed back to each mobile station according to the requested resource amount information while noting the mobile station using the first frequency band first, and notifying the mobile stations. The method of claim 9, And the base station receives channel quality information corresponding to the amount of channel quality information to which each informed mobile station should feed back from the mobile stations. The method of claim 10, The base station further comprises the step of determining the priority for resource allocation of each of the mobile stations according to the amount of channel quality information received from the first mobile station and the second mobile station. The method of claim 9, The base station may include a first sum value obtained by adding up the amount of resources required by each mobile station using the first frequency band, and each mobile station using the second frequency band is requested in the first frequency band. Determining a second sum of the sum of the amount of resources; And when the first sum value exceeds a preset reference value, determining, by the mobile station using the first frequency band, an average channel quality information amount to be fed back as a maximum value preset in the system. The method. The method of claim 12, The reference value is a value for determining whether the amount of resources required by the first mobile station is large, and the value can be set according to a system situation. The method of claim 12, If the first sum is less than or equal to the reference value, the mobile stations using the first frequency band from the reference value may require the total amount of resources required by the mobile stations using the second frequency band from the first frequency band. Comparing the result of subtracting the total amount of resources required by If the amount of resources required by the mobile stations using the second frequency band is less than the result value, the average channel quality information amount to be fed back by the mobile stations using the first frequency band and the mobile stations using the second frequency band should be fed back. And determining the average amount of channel quality information by Equation (14).

In Equation 14,

The average channel quality information amount to be fed back by the mobile stations using the first frequency band,

Is the preset maximum value,

Is the total amount of resources required by the mobile stations using the second frequency band in the first frequency band,

Is the reference value,

Denotes an average amount of channel quality information to be fed back by the mobile stations using the second frequency band in the first frequency band. The method of claim 14, If the amount of resources required by the mobile stations using the second frequency band is greater than or equal to the result value, the average channel quality information amount to be fed back by the mobile stations using the first frequency band and the average channel quality information amount to be fed back by the second mobile station. Is determined by the following equation (15).

In Equation 15,

Is the average amount of channel quality information to be fed back by the mobile stations using the first frequency band in the first frequency band,

Is the preset maximum value,

Is the total amount of resources required by the mobile stations using the second frequency band in the first frequency band,

Is the reference value,

Denotes an average amount of channel quality information to be fed back by the mobile stations using the second frequency band in the first frequency band. The method of claim 9, And the channel quality information amount information to be fed back by the mobile stations is included in a narrowband channel quality information amount channel (NB-CQIACH) and transmitted. In a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, the mobile station using the second frequency band transmits the channel quality information for scheduling of the base station. In Receiving channel quality information quantity information to be fed back in the first and second frequency bands from the base station; Generating channel quality information corresponding to the channel quality information amount information; And transmitting the channel quality information using a specific channel. The method of claim 17, When the channel quality information for the first frequency band is transmitted, the specific channel becomes an uplink narrowband control channel (UL-NB-CCH), and the UL-NB-CCH is a channel quality to be fed back received from the base station. The narrowband channel quality information quantity channel (NB-CQIACH) including information quantity information. The method of claim 17, When the channel quality information is transmitted for a frequency band other than the first frequency band in the second frequency band, the specific channel becomes an uplink narrowband dependent control channel (UL-NB-DCCH), and the UL-NB- And the DCCH includes a narrowband dependent channel quality information amount channel (NB-DCQIACH) including channel quality information amount information to be fed back received from the base station. An apparatus for performing scheduling in a frequency overlay communication system in which a first frequency band and a second frequency band including the first frequency band exist, Input first resource amount information required by the mobile stations using the first frequency band in the first frequency band and second resource amount information requested by the mobile stations using the second frequency band in the first frequency band, and The first average channel quality information amount to which mobile stations using the first frequency band should feed back in the first frequency band in consideration of first and second resource amount information and the mobile stations using the second frequency band are determined by the first frequency. A first channel quality information feedback amount determiner for determining a second average channel quality information amount to be fed back in a band; A second channel quality information feedback amount determiner for inputting the first average channel quality information amount to determine the amount of channel quality information to which each of the mobile stations using the first frequency band should feed back in the first frequency band; Inputting the second average channel quality information amount, wherein each of the mobile stations using the second frequency band includes a third channel quality information feedback amount determiner for determining the amount of channel quality information to be fed back in the first frequency band; Said device. The method of claim 20, The amount of channel quality information that each of the mobile stations using the first frequency band should feed back in the first frequency band and the amount of channel quality information that each of the mobile stations that use the second frequency band should feed back in the first frequency band A first channel generator for inputting and generating a first channel including the amount of channel quality information; And a second channel generator for combining the first channel and other channels to generate a second channel. The method of claim 21, Wherein the first channel generator generates a narrowband channel quality information amount channel (NB-CQIACH) and the second channel generator generates a narrowband control channel (NB-CCH).

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