KR101125041B1 - Scheduling apparatus for broad band spectrum sensing and method threrfor - Google Patents

Abstract

The present invention relates to an apparatus and method for scheduling broadband spectrum sensing. Since the sensor which finishes spectrum sensing for a predetermined frequency band is performed by supporting spectrum sensing for another frequency band, the overall sensing time can be reduced and the same size can be achieved. By reducing the time it takes to find a band, you can find more bands at the same time, increase channel utilization for secondary users, and navigate and move to other bands in less time, reducing interference first. The service performance of the user and the first user is improved, and assuming that the same power is used when sensing the sensors, the number of sensing is reduced, so that there is an advantage in terms of power consumption.

Description

SCHEDULING APPARATUS FOR BROAD BAND SPECTRUM SENSING AND METHOD THRERFOR

The present invention relates to broadband spectrum sensing scheduling, and more particularly, to an apparatus and method for broadband spectrum sensing scheduling that reduces sensing time by efficiently using a plurality of sensors when sensing broadband spectrum.

The present invention is derived from a study conducted as part of the IT industrial source technology development project of the Ministry of Knowledge Economy and the Korea Institute of Industrial Technology Evaluation and Management. [Task Management Number: 2008-F-044-02, Title: Electromagnetic Waves, Sound and Building Environment Development of intelligent construction IT convergence new technology to improve the].

Radio-aware technology detects empty frequencies that are allocated but not actually used and efficiently share them. In such a wireless recognition technology, spectrum sensing to detect the frequency usage is essential. The spectrum sensing technology senses the frequency usage to prevent interference with a primary user using a licensed frequency band. Secondary users (secondary users) must first empty the user when the user wants to use the frequency band, so the sensing time must be short in order to provide a seamless service to the secondary users. In the existing scheme, the sensor of the secondary user senses the band multiple times without using any sensing scheduling scheme and uses the band when the limited probability of missed detection is satisfied.

Suppose that the performance of the sensor varies depending on the location due to shadowing or fading caused by the building. In the existing scheme, regardless of the situation, each sub-user needs to find and use the frequency band. The sensor's performance will vary depending on the environment it is in, even if it senses the same width for the same amount of time. This is because the detection error probability in a bad channel condition is greater than the detection error in a good channel condition even with the same sensor.

When sensing a specific band, the detection error probability that there is no user must be less than 5%, and the sensing ability can be determined and the use of the corresponding band can be determined. If the detection error probability is high, the user can use the corresponding band after believing the wrong detection result, and then the user can use it only if the band satisfies the limited detection error probability because the user is more likely to receive interference by the secondary user. Will be done.

)이 높을 경우 여러 번 센싱을 하여 검출 오류 확률을 줄여 사용하면 되는데 이 때 '논리합 규칙(OR rule)'을 사용하여 검출 오류 확률을 줄일 수 있다. 이는 여러 번 센싱을 하여 한번이라도 우선 사용자가 감지되면 부 사용자가 해당 대역에 우선 사용자가 있다고 판단하는 규칙이다. 이에 따라 '논리합 규칙'을 이용하였을 때의 총 검출 오류 확률(

)은 부 사용자가 N번 센싱 하였을 때에 아래의 수학식 1과 같이 표현된다.In the conventional scheme, the detection error probability (

If the) is high, it can be used several times to reduce the probability of detection error. In this case, the OR rule can be used to reduce the probability of detection error. This is a rule that the secondary user judges that there is a priority user in the corresponding band when sensing the user several times to detect the priority user at least once. Accordingly, the total probability of detection error when using the 'logical logic rule' (

) Is expressed by Equation 1 below when the secondary user senses N times.

As in the conventional method, if the sensor where the channel environment is located in a good channel environment is less than 5% and the sensor located in the channel environment is sensed without cooperation with each other, the sensor located in the channel environment is bad. N sensings should be performed until less than 5%.

1 is a network diagram illustrating a femto access point (AP) installation scenario.

In FIG. 1, it is assumed that the zone A 101, the zone B 102, and the zone C 103 having different channel conditions are less than 5% in the detection zone A in the zone A 101. Suppose that the detection error probability is less than 10% and the detection error probability in the C region 103 is 40% or more. According to the conventional scheme, when the sensor of the zone A 101 finishes sensing in one time, the sensor of the zone C 103 must sense four times to satisfy the detection error probability.

In the case of broadband over several GHz, the range of bands available to the secondary user is wide, which can increase the channel utilization by accommodating more of the secondary users. Regardless of the number of secondary users and the amount of bandwidth required, if inefficient sensing is applied according to the existing scheme, sensors located in poor channel conditions will increase the frequency of sensing to find multiple bands. If the same sensing time is assumed assuming that the sensing method is performed according to the conventional scheme, there is a problem in that a secondary user whose service performance is deteriorated due to a long sensing time depending on the channel state can be generated.

Spectrum sensing is first performed by secondary users to determine whether a user uses a band. Through this, first of all, if it is confirmed whether the user uses the corresponding frequency, the user must first move to another frequency band without interrupting the user and continue communication or stop the service. Because sensors can typically sense tens of MHz bands at a time, it takes a long time to sense a broadband over several GHz without the cooperation of sensors. When it takes a long time to find a new frequency band, it becomes difficult to provide a seamless service for secondary users.

The present invention has been proposed to solve such a problem, and provides a broadband spectrum sensing scheduling apparatus that improves service performance of secondary users by reducing the overall sensing time by appropriately distributing the performance of sensors through an efficient sensing scheduling technique.

In addition, in spectrum sensing technology, when the secondary user finds multiple bands that satisfy the limited sensing error probability, the broadband spectrum sensing scheduling enables the secondary users to quickly find the desired band so that the secondary users can quickly find the desired band. Provide a method.

In accordance with a first aspect of the present invention, an apparatus for scheduling broadband spectrum sensing is a device for scheduling a spectrum sensing operation by a plurality of sensors for sensing a frequency use environment by performing spectrum sensing for each frequency band. A sensing result processing unit for accumulating and updating a detection error probability value for each frequency band and a previously stored previously detected error probability value received for each frequency band by receiving the result; and updating the detection error probability value for each frequency band and for each preset frequency band Re-execution of the spectrum sensing operation for the same frequency band for each sensor or support of the spectrum sensing operation for another frequency band or the spectrum sensing operation for the plurality of sensors based on a comparison result with a limit detection error probability value Sen to determine the end of A scheduling controller which controls an operation determining unit, the sensing result processing unit, and the sensing operation determining unit to provide the plurality of sensors with a scheduling command for the spectrum sensing operation to perform the re-execution, the support execution, or the termination; It may include.

In accordance with a second aspect of the present invention, a method for scheduling broadband spectrum sensing is a scheduling method by an apparatus for scheduling a spectrum sensing operation by a plurality of sensors for sensing a frequency use environment by performing spectrum sensing for each frequency band. Accumulating and updating a detection error probability value for each frequency band and a pre-stored previous detection error probability value received for each frequency band and receiving the spectrum sensing result by the frequency band, and updating the detection error probability value for each frequency band and the preset frequency. Instructing the plurality of sensors to re-execute the spectrum sensing operation for the same frequency band for each sensor based on a comparison result with a limit detection error probability value for each band; and for the plurality of sensors based on the comparison result For different frequency bands per sensor May comprise an instruction group performs the support of the spectrum sensing operation or termination of the spectrum sensing operation.

The broadband spectrum sensing scheduling apparatus according to an embodiment of the present invention may be installed in a wireless recognition system such as a base station of a mobile communication network to schedule spectrum sensing operations by a plurality of sensors. In the case of broadband over a few GHz, it is obvious that it takes a long time when sensing using a conventional sensor that senses several tens of MHz bands as in the prior art, and the long time spectrum sensing time causes the service of the secondary user to be interrupted. According to an exemplary embodiment of the present invention, since the sensor which finishes spectrum sensing for a predetermined frequency band is performed by supporting spectrum sensing for another frequency band, the overall sensing time can be reduced.

In this way, the time taken to find the same sized band can be reduced, so that more bands can be found at the same time, thereby increasing channel utilization of the secondary user. It can also navigate to other bands quickly, reducing interference first. As a result, the service performance of secondary users and preferred users is improved.

In addition, assuming that the same power is used when sensing the sensors, the number of sensing is reduced, so that there is an effect of gaining power.

1 is a network diagram illustrating a femto AP installation scenario;
2 is a block diagram of a broadband spectrum sensing scheduling apparatus according to an embodiment of the present invention;
3 is a flowchart illustrating a wideband spectrum sensing scheduling method according to an embodiment of the present invention.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but can be implemented in various different forms, and only the embodiments make the disclosure of the present invention complete, and the general knowledge in the art to which the present invention belongs. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. Like numbers refer to like elements throughout.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, terms to be described below are terms defined in consideration of functions in the embodiments of the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be based on the contents throughout this specification.

Combinations of each step in the accompanying flowcharts may be performed by computer program instructions. These computer program instructions may be mounted on a processor of a general purpose computer, special purpose computer, or other programmable data processing equipment such that the instructions performed through the processor of the computer or other programmable data processing equipment are described in each step of the flowchart. It will create a means to perform them. These computer program instructions may be stored in a computer usable or computer readable memory that can be directed to a computer or other programmable data processing equipment to implement functionality in a particular manner, and thus the computer usable or computer readable memory. The instructions stored therein may also produce an article of manufacture containing instruction means for performing the functions described in each step of the flowchart. Computer program instructions may also be mounted on a computer or other programmable data processing equipment, such that a series of operating steps may be performed on the computer or other programmable data processing equipment to create a computer-implemented process to create a computer or other programmable data. Instructions for performing the processing equipment may also provide steps for executing the functions described in each step of the flowchart.

In addition, each step may represent a module, segment or portion of code that includes one or more executable instructions for executing a specified logical function (s). It should also be noted that in some alternative embodiments, the functions noted in the steps may occur out of order. For example, the two steps shown in succession may in fact be performed substantially concurrently or the blocks or steps may sometimes be performed in the reverse order, depending on the functionality involved.

2 is a block diagram of a broadband spectrum sensing scheduling apparatus according to an embodiment of the present invention.

As described above, the broadband spectrum sensing scheduling apparatus 200 may include a sensing result processor 201, a sensing operation determiner 203, a scheduling controller 205, and the like. The sensing result processor 201 may include a detection error probability calculator 210, a detection error probability storage unit 220, and a detection error probability update unit 230. The sensing operation determiner 203 may include a sensing band. The determination unit 240 and the sensing end determination unit 250 may be included.

The sensing result processor 201 may accumulate and update a detection error probability value for each frequency band and a pre-stored previous detection error probability value calculated by receiving the spectrum sensing results by a plurality of sensors for each frequency band.

The detection error probability calculation unit 210 constituting the sensing result processing unit 201 calculates a detection error probability value for each frequency band based on spectrum sensing results by a plurality of sensors, and the detection error probability storage unit 220 The detection error probability value calculated by the detection error probability calculation unit 210 is stored for each frequency band, and the detection error probability update unit 230 stores the previous detection error probability value and the detection error previously stored in the detection error probability storage unit 220. The detection error probability value for each frequency band stored in the detection error probability storage unit 220 may be updated by accumulating the current detection error probability value calculated by the probability calculator 210 for each frequency band. Here, the detection error probability update unit 230 may update the average value between the previous detection error probability value and the current detection error probability value to the limit detection error probability value for each frequency band.

The sensing operation determiner 203 is the same for each sensor for the plurality of sensors based on a comparison result between the detection error probability value for each frequency band updated by the sensing result processor 210 and the limit detection error probability value for each frequency band. It may be determined to re-perform the spectrum sensing operation for the frequency band, to perform the support of the spectrum sensing operation for the other frequency band, or to terminate the spectrum sensing operation.

The sensing band determiner 240 constituting the sensing operation determiner 203 determines a plurality of sensors based on a result of determining whether a detection error probability value for each frequency band reaches a preset limit detection error probability for each frequency band. Determining the re-execution of the spectrum sensing operation for the same frequency band for each sensor or performing support of the spectrum sensing operation for another frequency band, the sensing end determination unit 250 is a frequency band by the sensing band determination unit 240 When it is determined that all frequency bands of the star detection error probability values have reached the limit detection error probability for each frequency band, the termination of the spectrum sensing operation may be determined. Here, the sensing band determiner 240 may determine whether to support the spectrum sensing operation for the frequency band having the largest detection error probability value for each frequency band among other frequency bands.

The scheduling controller 205 may control the sensing result processor 201 and the sensing operation determiner 203 to provide a scheduling command for a spectrum sensing operation to the plurality of sensors.

The broadband spectrum sensing scheduling apparatus 200 may be installed in a wireless recognition system, such as a base station of a mobile communication network, to schedule spectrum sensing operations by a plurality of sensors. Here, the sensor may be installed in, for example, a mobile communication terminal to detect a frequency use environment by performing spectrum sensing for each frequency band. Accordingly, the broadband spectrum sensing scheduling apparatus 200 may be referred to as a central control apparatus of a wireless recognition system. When the broadband spectrum sensing scheduling apparatus 200 provides a scheduling command to a plurality of sensors, for example, a frequency using a mobile communication terminal is used. Band users can share spectrum sensing results. In the case of broadband over several GHz, the range of bands available to users increases as the range of bands available to users first increases, and conventional sensors that sense tens of MHz bands at a time are used. When sensing like technology, it is obvious that it will take quite a long time, and long spectrum sensing time can cause service performance degradation such as discontinuing service of secondary user. Accordingly, according to the present invention, since the sensor which finishes the spectral sensing for the predetermined frequency band is performed by supporting the spectral sensing for the other frequency band, the overall sensing time can be reduced.

A spectrum sensing scheduling method by the broadband spectrum sensing scheduling apparatus according to the embodiment of the present invention configured as described above will be described with reference to FIGS. 1 to 3.

First, a plurality of sensors sense a spectrum for each frequency band and provide the sensing result to the broadband spectrum sensing scheduling apparatus 200 (S301), and the detection error probability calculation unit 210 of the sensing result processing unit 201 is the scheduling controller. The detection error probability value for each frequency band is calculated based on the spectrum sensing results of the plurality of sensors according to the control signal of 205, and the calculated error probability value for each frequency band is stored in the detection error probability storage unit 220. (S303).

In addition, in a situation where a previous detection error probability value for each frequency band is stored in the detection error probability storage unit 220, the detection error probability update unit 230 of the sensing result processor 201 according to the control signal of the scheduling controller 205. The previously stored error detection probability value and the currently calculated detection error probability value for each frequency band are accumulated for each frequency band to update the detection error probability value for each frequency band stored in the detection error probability storage unit 220. In this case, the detection error probability updating unit 230 may update the average value between the previous detection error probability value and the current detection error probability value to the limit detection error probability value for each frequency band (S305).

Then, the sensing band determiner 240 of the sensing operation determiner 203 compares the detection error probability value for each frequency band and the limit detection error probability value for each frequency band updated according to the control signal of the scheduling controller 205. In operation S307, when the detection error probability value for each frequency band does not reach the limit detection error probability value for each frequency band, it is determined to re-execute the spectrum sensing operation for the same frequency band for each sensor for a plurality of sensors. Accordingly, when the scheduling control unit 205 provides a re-execution command to the plurality of sensors or some of the sensors, the rescheduling of the spectrum sensing operation by the corresponding sensor is performed (S309).

When the detection error probability value for each frequency band reaches the limit detection error probability value for each frequency band in step S307, the sensing band determination unit 240 performs a spectrum sensing operation for a different frequency band for each sensor for a plurality of sensors. When the scheduling control unit 205 provides the support execution command to the plurality of sensors or some of the sensors, spectrum sensing support is performed by the corresponding sensor. Here, the sensing band determiner 240 may determine whether to support the spectrum sensing operation for the frequency band having the largest detection error probability value for each frequency band among other frequency bands (S311).

Meanwhile, the sensing end determiner 250 of the sensing operation determiner 203 indicates that all frequency bands of the detection error probability values for each frequency band reach the limit detection error probability for each frequency band by the sensing band determiner 240. If it is determined, the end of the spectrum sensing operation is determined. Accordingly, when the scheduling control unit 205 provides an end command of the spectrum sensing operation to the plurality of sensors or some of the sensors, spectrum sensing by all sensors is terminated (S313).

200: broadband spectrum sensing scheduling apparatus
201: sensing result processing unit 203: sensing operation determination unit
205: scheduling controller 210: detection error probability calculation unit
220: detection error probability storage unit 230: detection error probability updating unit
240: sensing band determination unit 250: sensing end determination unit

Claims (9)

An apparatus for scheduling a spectrum sensing operation by a plurality of sensors for sensing the frequency use environment by performing spectrum sensing for each frequency band,
A sensing result processing unit for accumulating and updating the detection error probability value for each frequency band and the previously stored error detection probability value calculated for each frequency band by receiving the spectrum sensing results by the plurality of sensors;
Re-execution of the spectrum sensing operation for the same frequency band for each of the plurality of sensors based on a result of the comparison between the updated detection error probability value for each frequency band and the limited detection error probability value for each frequency band; A sensing operation determiner which determines one of performing support of the spectrum sensing operation for a frequency band or terminating the spectrum sensing operation for the other frequency band;
A scheduling controller configured to control the sensing result processor and the sensing operation determiner to provide a scheduling command for the spectrum sensing operation to the plurality of sensors so that any one of the re-execution, the support execution, or the termination is performed;
Broadband spectrum sensing scheduling apparatus. The method of claim 1,
The sensing result processing unit may include a detection error probability calculation unit configured to calculate a detection error probability value for each frequency band based on the spectrum sensing result;
A detection error probability storage unit for storing the detection error probability value calculated by the detection error probability calculation unit for each frequency band;
Accumulating the previous detection error probability value previously stored in the detection error probability storage unit and the current detection error probability value calculated by the detection error probability calculation unit for each frequency band to detect the detection error for each frequency band stored in the detection error probability storage unit. A detection error probability updater for updating the probability value
Broadband spectrum sensing scheduling apparatus. The method of claim 2,
The detection error probability updating unit updates the average value of the previous detection error probability value and the current detection error probability value to the limit detection error probability value for each frequency band.
Broadband spectrum sensing scheduling apparatus. The method of claim 1,
The sensing operation determining unit performs the spectrum sensing operation on the same frequency band for each of the plurality of sensors based on a result of determining whether the detection error probability value for each frequency band reaches a preset limit detection error probability for each frequency band. A sensing band determining unit which determines re-execution of the signal or determines whether to support the spectrum sensing operation for another frequency band;
And a sensing end determination unit determining the end of the spectrum sensing operation when it is determined by the sensing band determination unit that all frequency bands of the detection error probability values for each frequency band have reached the limit detection error probability for each frequency band.
Broadband spectrum sensing scheduling apparatus. The method of claim 4, wherein
The sensing band determination unit determines to perform the support for a frequency band having the largest detection error probability value for each frequency band among the other frequency bands.
Broadband spectrum sensing scheduling apparatus. A scheduling method by an apparatus for performing spectrum sensing for each frequency band to schedule spectrum sensing operations by a plurality of sensors sensing a frequency use environment.
Accumulating and updating a detection error probability value for each frequency band and a pre-stored previous detection error probability value calculated for each frequency band by receiving the spectrum sensing results by the plurality of sensors;
Command the re-execution of the spectrum sensing operation on the same frequency band for each sensor for the plurality of sensors based on the updated comparison result of the detection error probability value for each frequency band and the limit detection error probability value for each frequency band. To do that,
Instructing the plurality of sensors to perform the support of the spectrum sensing operation for a different frequency band for each sensor or to terminate the spectrum sensing operation based on the comparison result.
Broadband Spectrum Sensing Scheduling Method. The method according to claim 6,
The updating may include calculating a detection error probability value for each frequency band based on the spectrum sensing result;
Storing the calculated detection error probability value for each frequency band;
And accumulating the previous detection error probability value previously stored and the current detection error probability value for each frequency band to update and store the previous detection error probability value.
Broadband Spectrum Sensing Scheduling Method. The method of claim 7, wherein
The updating and storing may include updating an average value of the previous detection error probability value and the current detection error probability value to the limit detection error probability value for each frequency band.
Broadband Spectrum Sensing Scheduling Method. The method according to claim 6,
The performing of the support of the spectrum sensing operation or the end of the spectrum sensing operation may include: performing the support for the frequency band having the largest detection error probability value for each frequency band among the other frequency bands.
Broadband Spectrum Sensing Scheduling Method.

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