CN109345541A - A kind of working method of intelligent monitor system - Google Patents

Abstract

The present invention relates to a kind of working method of intelligent monitor system, the intelligent monitor system includes: server, the monitoring device and warning device being connected with the server；Wherein the monitoring device is set in monitoring area and includes: processor, the temperature collecting module and video monitoring module being connected with the processor；The working method includes: the temperature data of the temperature collecting module acquisition monitoring area, and is sent to Cloud Server by a communication module；The video data of the video monitoring module acquisition monitoring area, and Cloud Server is sent to by the communication module；And the Cloud Server is equipped with analysis and processing module, to analyze temperature data and video data, and control warning device issues alarm when occurring abnormal；The working method of intelligent monitor system of the present invention passes through the combination of video monitoring and monitoring temperature, can complete to improve the range of monitoring to comprehensive monitoring is realized in computer room, guarantee the safety in computer room.

Description

A kind of working method of intelligent monitor system

Technical field

The present invention relates to monitoring technology field more particularly to a kind of working methods of intelligent monitor system.

Background technique

Will use large-scale computer room in large-scale service-type firm, current computer room when arranging monitoring device only Only arrangement camera is monitored, while monitoring personnel being cooperated to carry out tour processing, and such monitor mode cannot in all directions Computer room is monitored, there are security risks.

Summary of the invention

The object of the present invention is to provide a kind of working methods of intelligent monitor system.

In order to solve the above-mentioned technical problems, the present invention provides a kind of working method of intelligent monitor system, the intelligence Monitoring system includes: server, the monitoring device and warning device being connected with the server；Wherein the monitoring device is set to prison It controls in region and includes: processor, the temperature collecting module and video monitoring module being connected with the processor；The working method Include: the temperature data of the temperature collecting module acquisition monitoring area, and Cloud Server is sent to by a communication module；Institute The video data of video monitoring module acquisition monitoring area is stated, and Cloud Server is sent to by the communication module；And institute Cloud Server is stated equipped with analysis and processing module, to analyze temperature data and video data, and is controlled when occurring abnormal Warning device issues alarm.

Preferably, the video monitoring module uses the general camera of more light；The general camera of more light, which is suitable for identification in real time, is supervised Target position is controlled, and the method for identification target to be monitored position includes the following steps: in real time

Step 1: the spectrum picture of target area is obtained by multi-optical spectrum imaging system, involved by the multi-optical spectrum imaging system And optical filter wave-length coverage covers visible wavelength to infrared wavelength；Step 2: extracting any imaging of the multi-optical spectrum imaging system The spectral information is directed into the spectral information data of the multi-optical spectrum imaging system by the spectral information of the spectrum picture in channel Library carries out Data Matching, completes preliminary information screening；Step 3: if it fails to match for the spectral information, the multispectral imaging Main control chip control in system carries out the acquisition of next frame target area spectrum picture；Step 4: if the spectral information data Corresponding spectral information is matched in library, the main control chip is automatically positioned out position of the spectral information in spectrum picture Coordinate, and according to the position coordinates, the main control chip controls the full side that the multi-optical spectrum imaging system carries out target area Position camera-shooting scanning, obtains the spectrum picture under visible wavelength and infrared wavelength scale respectively, and to the visible wavelength and Spectrum picture under infrared wavelength scale carries out image co-registration processing；Step 5: the image after the fusion treatment being carried out non-equal Even correction.

Preferably, the main control chip includes FPGA, and the spectral information carries out data in the internal RAM of FPGA Match.

Preferably, the step 4 specifically includes: step 4.1: the main control chip is automatically positioned out the spectral information and exists After position coordinates in spectrum picture, determines the center of the spectral information of successful match, calculate the imaging The angle of the imaging target and horizontal direction of system, and determine the camera module in the imaging target and the imaging system Between deflection angle, the main control chip, which controls the multi-optical spectrum imaging system, to carry out resolution ratio along the deflection angle and sweeps It retouches, completes the comprehensive camera-shooting scanning of target area；Step 4.2: in the multi-optical spectrum imaging system along the deflection angle When carrying out resolution scan, the main control chip passes through to the spectral information identification region and infrared wavelength in visible wavelength Interior spectral information identification region carries out motion detection, determines its motion profile, and complete the fitting of two motion profiles, chooses Change of scale matrix generates visible images and infrared image to be fused using the matrix；Step 4.3: the master control core Piece further control the image co-registration processing unit in FPGA to the visible images and infrared image carry out brightness regulation, The operation such as denoising, centre registration, fusion and image enhancement, wherein described image fusion treatment unit includes DSP, FLASH with And dimension correction memory；The FPGA combination dimension correction memory completes the detail extraction and profile of infrared image jointly It extracts, and completes to be registrated geometric scale transformation and image detail and profile fusion between spectrum picture and infrared image；Institute DSP connection image encoder is stated, and combines the RAM in connection FLASH and FPGA, for believing treated digital video Number combine that row, field sync signal synthesizes analog video signal and driven in order to show；Step 4.4: when the master control When chip controls carry out the visible images and infrared image fusion, described image fusion treatment unit is to the visible light Image and infrared image are each separated into nonoverlapping piece, calculate separately information content therein, by the visible images and Infrared image is divided into the image of different scale using gaussian pyramid, and the FPGA extracts minutia, and root in different scale It is weighted assessment according to the information measure feature, is finally synthesized using laplacian pyramid, forms new blending image； Step 4.5: brightness detection being carried out to fused image, and is compared with a normal brightness, when described image brightness is lower than When the normal brightness, brightness of image is handled to reach the brightness value for being suitable for test；Step 4.6: to fused figure As carrying out image denoising, described image denoising is denoised only for the spectral information identification region, to reduce the master control The operation of chip consumes；Step 4.7: image enhancement processing is carried out to fused image using adaptive image enhancement technology；

Preferably, in the step 5, non-uniform correction method is carried out to the image after the fusion treatment, it is specific Include:

Step 5.1: before the multi-optical spectrum imaging system is for target area imaging, acquiring the multispectral imaging respectively Response data of the photosensitive member of each imaging band of system under each temperature value, and each temperature is calculated separately using following formula The gain coefficient G of section_ijWith biasing coefficient Q_ij

Wherein X_ij(H) and X_ijIt (L) is response of the pixel (i, j) under high temperature and low temperature homogeneous radiation background, V respectively_HWith V_LIt is the average output of all pixels in the infrared camera respectively；

Step 5.2: the main control chip of the imaging system is by the gain coefficient G of above-mentioned each temperature section_ijWith biasing coefficient Q_ij Real-time storage is to FPGA internal RAM, in case subsequent use；

Step 5.3: special using the texture and edge of blending image for fused image after the completion of the step 4 It levies and depth recognition is carried out to the spectral information identification region in blending image；Step 5.4: the different spectrum according to blending image are believed Target optical spectrum region is carried out image segmentation, forms each characteristic area by breath distribution；Step 5.5: the parallel processing based on FPGA Ability carries out nonuniformity correction to each characteristic area of the blending image respectively simultaneously；For each characteristic area, institute The mean temperature that main control chip calculates each point in the characteristic area first is stated, then according to the mean temperature, from described Corresponding correction parameter is read in RAM in FPGA, and completes nonuniformity correction according to the following formula

WhereinThe image that infrared detector exports under the conditions of expression Uniform Irradiation degree；

Step 5.6: the blending image after correction compensates boundary gray value using mean filter method.

The beneficial effects of the present invention are: the working method of intelligent monitor system of the present invention passes through video monitoring and monitoring temperature Combination, can complete to comprehensive monitoring is realized in computer room, improve the range of monitoring, guarantee the safety in computer room, simultaneously Also the stability of computer room is improved.

Detailed description of the invention

Fig. 1 is the functional block diagram of intelligent monitor system in the present invention；

Fig. 2 is the flow chart for identifying the method for target to be monitored position in the present invention in real time；

Fig. 3 is the image co-registration process flow diagram for the method for identifying target to be monitored position in the present invention in real time；

Fig. 4 is the Nonuniformity Correction flow chart for the method for identifying target to be monitored position in the present invention in real time.

Specific embodiment

It is described below for disclosing the present invention so that those skilled in the art can be realized the present invention.It is excellent in being described below Embodiment is selected to be only used as illustrating, it may occur to persons skilled in the art that other obvious modifications.It defines in the following description Basic principle of the invention can be applied to other embodiments, deformation scheme, improvement project, equivalent program and do not carry on the back Other technologies scheme from the spirit and scope of the present invention.

Embodiment

As shown in Figure 1, a kind of working method of intelligent monitor system is present embodiments provided, the intelligent monitor system packet It includes: server, the monitoring device and warning device being connected with the server；Wherein the monitoring device be set to monitoring area in and It include: processor, the temperature collecting module and video monitoring module being connected with the processor；The working method includes: described Temperature collecting module acquires the temperature data of monitoring area, and is sent to Cloud Server by a communication module；The video prison The video data of module acquisition monitoring area is controlled, and Cloud Server is sent to by the communication module；And the cloud service Device is equipped with analysis and processing module, to analyze temperature data and video data, and controls warning device when occurring abnormal Issue alarm.

Specifically, the temperature collecting module such as, but not limited to uses infrared photography to pop one's head in.

The working method of intelligent monitor system of the present invention passes through the combination of video monitoring and monitoring temperature, can complete to machine Comprehensive monitoring is realized in room, improves the range of monitoring, guarantees the safety in computer room, while also improving the stability of computer room.

Further, in order to improve the monitoring precision of video monitoring module, so that quality monitoring of the invention is further increased, The video monitoring module uses the general camera of more light；The general camera of more light is suitable for identification target to be monitored position in real time, and real When identification target to be monitored position method include the following steps:

Step 1: the spectrum picture of target area is obtained by multi-optical spectrum imaging system, involved by the multi-optical spectrum imaging system And optical filter wave-length coverage covers visible wavelength to infrared wavelength；

Step 2: the spectral information of the spectrum picture of any imaging band of the multi-optical spectrum imaging system is extracted, by the light The spectral information database that spectrum information is directed into the multi-optical spectrum imaging system carries out Data Matching, completes preliminary information screening；

Step 3: if it fails to match for the spectral information, the main control chip in the multi-optical spectrum imaging system, which controls, to be carried out The acquisition of next frame target area spectrum picture；

Step 4: if being matched to corresponding spectral information in the spectral information database, the main control chip automatic positioning Position coordinates of the spectral information in spectrum picture out, and according to the position coordinates, described in the main control chip control Multi-optical spectrum imaging system carries out the comprehensive camera-shooting scanning of target area, obtains under visible wavelength and infrared wavelength scale respectively Spectrum picture, and under the visible wavelength and infrared wavelength scale spectrum picture carry out image co-registration processing；

Step 5: the image after the fusion treatment is subjected to nonuniformity correction.

Preferably, the main control chip includes FPGA, and the spectral information carries out data in the internal RAM of FPGA Match.

Preferably, as shown in Fig. 2, the step 4 specifically includes:

Step 4.1: after the main control chip is automatically positioned out position coordinates of the spectral information in spectrum picture, really The center of making the spectral information of successful match calculates the imaging target and horizontal direction of the imaging system Angle, and determine the deflection angle between the camera module in the imaging target and the imaging system, the master control core Piece controls the multi-optical spectrum imaging system and carries out resolution scan along the deflection angle, completes the comprehensive of target area and takes the photograph As scanning；

Step 4.2: when the multi-optical spectrum imaging system carries out resolution scan along the deflection angle, the master control Chip is carried out by the spectral information identification region to the spectral information identification region in visible wavelength and in infrared wavelength Motion detection determines its motion profile, and completes the fitting of two motion profiles, chooses change of scale matrix, uses the matrix Generate visible images and infrared image to be fused；

Step 4.3: the main control chip further controls the image co-registration processing unit in FPGA to the visible light figure Picture and infrared image carry out the operation such as brightness regulation, denoising, centre registration, fusion and image enhancement, wherein described image Fusion treatment unit includes DSP, FLASH and dimension correction memory；The FPGA combination dimension correction memory is jointly complete At the detail extraction and contours extract of infrared image, and complete to be registrated geometric scale change between spectrum picture and infrared image Change and image detail and profile fusion；The DSP connection image encoder, and combine in connection FLASH and FPGA RAM, for combining row, field sync signal to synthesize analog video signal treated digital video signal and driving In order to show；

Step 4.4: when main control chip control carries out the visible images and infrared image merges, the figure As fusion treatment unit is each separated into nonoverlapping piece to the visible images and infrared image, letter therein is calculated separately The visible images and infrared image, are divided into the image of different scale by breath amount using gaussian pyramid, and the FPGA exists Different scale extracts minutia, and is weighted assessment according to the information measure feature, finally uses laplacian pyramid It is synthesized, forms new blending image；

Step 4.5: brightness detection being carried out to fused image, and is compared with a normal brightness, described image is worked as When brightness is lower than the normal brightness, brightness of image is handled to reach the brightness value for being suitable for test；

Step 4.6: image denoising being carried out to fused image, described image denoising is identified only for the spectral information Region is denoised, to reduce the operation consumption of the main control chip；

Step 4.7: image enhancement processing is carried out to fused image using adaptive image enhancement technology；

Preferably, as shown in figure 3, in the step 5, nonuniformity correction side is carried out to the image after the fusion treatment Method specifically includes:

Step 5.1: before the multi-optical spectrum imaging system is for target area imaging, acquiring the multispectral imaging respectively Response data of the photosensitive member of each imaging band of system under each temperature value, and each temperature is calculated separately using following formula The gain coefficient G of section_ijWith biasing coefficient Q_ij

Wherein X_ij(H) and X_ijIt (L) is response of the pixel (i, j) under high temperature and low temperature homogeneous radiation background, V respectively_HWith V_LIt is the average output of all pixels in the infrared camera respectively；

Step 5.2: the main control chip of the imaging system is by the gain coefficient G of above-mentioned each temperature section_ijWith biasing coefficient Q_ij Real-time storage is to FPGA internal RAM, in case subsequent use；

Step 5.3: special using the texture and edge of blending image for fused image after the completion of the step 4 It levies and depth recognition is carried out to the spectral information identification region in blending image；

Step 5.4: the different spectral informations according to blending image are distributed, and target optical spectrum region is carried out image segmentation, shape At each characteristic area；

Step 5.5: the parallel processing capability based on FPGA, respectively to each characteristic area of the blending image simultaneously into Row nonuniformity correction；For each characteristic area, the main control chip calculates being averaged for each point in the characteristic area first Temperature reads corresponding correction parameter then according to the mean temperature from the RAM in the FPGA, and according to following public affairs Formula completes nonuniformity correction

WhereinThe image that infrared detector exports under the conditions of expression Uniform Irradiation degree；

Step 5.6: the blending image after correction compensates boundary gray value using mean filter method.

The above-mentioned target identification method based on multi-optical spectrum imaging system is simple to operation, using FPGA as imaging system Main control chip, so that imaging system operation efficiency with higher, algorithm is accurate, can faster carry out to target to be identified real When identify have the advantages that simple and easy, accuracy is higher, be suitable for popularization and application.

The present embodiment is identified in the method for target to be monitored position in real time and is tentatively sieved by the spectral information to extraction It selects, main control chip control multi-optical spectrum imaging system carries out omnibearing imaging scanning after successful match, passes through the visible light to acquisition Image and infrared image carry out image co-registration processing and nonuniformity correction, complete final target identification, avoid single Visible images and single infrared image are unsuitable for lacking for target identification in clarity, texture and in terms of highlighting degree It falls into, so that multi-optical spectrum imaging system can quickly and accurately carry out the realtime graphic identification of target to be identified；The present embodiment is known in real time Imaging system may be implemented adaptively in the method for other target to be monitored position, by image co-registration processing unit to visible light figure Picture and infrared image carry out the processing such as brightness regulation, denoising, fusion, image enhancement, then carry out nonuniformity correction to blending image, So that blending image resolution ratio is further enhanced, to improve the accuracy of identification of target to be identified；The present embodiment it is more Spectrum camera uses core processing unit of the FPGA as imaging system main control chip, makes full use of its parallel processing capability to figure Each of picture cut zone carries out nonuniformity correction, image processing speed is greatly improved, so that the knowledge of imaging system It does not feed back much sooner.

It should be understood by those skilled in the art that foregoing description and the embodiment of the present invention shown in the drawings are only used as illustrating And it is not intended to limit the present invention.The purpose of the present invention has been fully and effectively achieved.Function and structural principle of the invention exists It shows and illustrates in embodiment, under without departing from the principle, implementation method of the invention can have any form or modification.

Claims (5)

1. a kind of working method of intelligent monitor system, which is characterized in that the intelligent monitor system includes: server, with this Server connected monitoring device and warning device；Wherein

The monitoring device is set in monitoring area and includes: processor, the temperature collecting module and view being connected with the processor Frequency monitoring module；

The working method includes:

The temperature data of the temperature collecting module acquisition monitoring area, and Cloud Server is sent to by a communication module；

The video data of the video monitoring module acquisition monitoring area, and Cloud Server is sent to by the communication module； And

The Cloud Server is equipped with analysis and processing module, to analyze temperature data and video data, and exception is occurring When control warning device issue alarm.

2. the working method of intelligent monitor system according to claim 1, which is characterized in that

The video monitoring module uses the general camera of more light；

The general camera of more light is suitable for identification target to be monitored position in real time, and the method packet of identification target to be monitored position in real time Include following steps:

Step 1: the spectrum picture of target area, the involved filter of the multi-optical spectrum imaging system are obtained by multi-optical spectrum imaging system Mating plate wave-length coverage covers visible wavelength to infrared wavelength；

Step 2: extracting the spectral information of the spectrum picture of any imaging band of the multi-optical spectrum imaging system, the spectrum is believed The spectral information database that breath is directed into the multi-optical spectrum imaging system carries out Data Matching, completes preliminary information screening；

Step 3: if it fails to match for the spectral information, the main control chip control in the multi-optical spectrum imaging system carries out next The acquisition of frame target area spectrum picture；

Step 4: if being matched to corresponding spectral information in the spectral information database, the main control chip is automatically positioned out institute Position coordinates of the spectral information in spectrum picture are stated, and according to the position coordinates, the main control chip controls the mostly light Spectrum imaging system carries out the comprehensive camera-shooting scanning of target area, obtains the light under visible wavelength and infrared wavelength scale respectively Spectrogram picture, and image co-registration processing is carried out to the spectrum picture under the visible wavelength and infrared wavelength scale；

Step 5: the image after the fusion treatment is subjected to nonuniformity correction.

3. the working method of intelligent monitor system according to claim 2, which is characterized in that the main control chip includes FPGA, the spectral information carry out Data Matching in the internal RAM of FPGA.

4. the working method of intelligent monitor system according to claim 3, which is characterized in that the step 4 specifically includes:

Step 4.1: after the main control chip is automatically positioned out position coordinates of the spectral information in spectrum picture, determining The center of the spectral information of successful match calculates the folder of the imaging target and horizontal direction of the imaging system Angle, and determine the deflection angle between the camera module in the imaging target and the imaging system, the main control chip It controls the multi-optical spectrum imaging system and carries out resolution scan along the deflection angle, complete the comprehensive camera shooting of target area Scanning；

Step 4.2: when the multi-optical spectrum imaging system carries out resolution scan along the deflection angle, the main control chip By being moved to the spectral information identification region in visible wavelength and the spectral information identification region in infrared wavelength Detection determines its motion profile, and completes the fitting of two motion profiles, chooses change of scale matrix, is generated using the matrix Visible images and infrared image to be fused；

Step 4.3: the main control chip further control the image co-registration processing unit in FPGA to the visible images with And infrared image carries out the operation such as brightness regulation, denoising, centre registration, fusion and image enhancement, wherein described image fusion Processing unit includes DSP, FLASH and dimension correction memory；The FPGA combination dimension correction memory is completed red jointly The detail extraction and contours extract of outer image, and complete to be registrated geometric scale transformation between spectrum picture and infrared image, And image detail and profile merge；The DSP connection image encoder, and the RAM in connection FLASH and FPGA is combined, For by treated digital video signal combine row, field sync signal synthesize analog video signal and drive so as to In display；

Step 4.4: when main control chip control carries out the visible images and infrared image merges, described image is melted It closes processing unit and nonoverlapping piece is each separated into the visible images and infrared image, calculate separately information therein The visible images and infrared image, are divided into the image of different scale, the FPGA is not by amount using gaussian pyramid Extract minutia with scale, and assessment be weighted according to the information measure feature, finally use laplacian pyramid into Row synthesis, forms new blending image；

Step 4.5: brightness detection being carried out to fused image, and is compared with a normal brightness, when described image brightness When lower than the normal brightness, brightness of image is handled to reach the brightness value for being suitable for test；

Step 4.6: image denoising being carried out to fused image, described image is denoised only for the spectral information identification region It is denoised, to reduce the operation consumption of the main control chip；

Step 4.7: image enhancement processing is carried out to fused image using adaptive image enhancement technology.

5. the working method of intelligent monitor system according to claim 4, which is characterized in that in the step 5, to institute Image after stating fusion treatment carries out non-uniform correction method, specifically includes:

Step 5.1: before the multi-optical spectrum imaging system is for target area imaging, acquiring the multi-optical spectrum imaging system respectively Each imaging band response data of the photosensitive member under each temperature value, and calculate separately each temperature section using following formula Gain coefficient G_ijWith biasing coefficient Q_ij

Wherein X_ij(H) and X_ijIt (L) is response of the pixel (i, j) under high temperature and low temperature homogeneous radiation background, V respectively_HAnd V_LPoint It is not the average output of all pixels in the infrared camera；

Step 5.2: the main control chip of the imaging system is by the gain coefficient G of above-mentioned each temperature section_ijWith biasing coefficient Q_ijIn real time It stores to FPGA internal RAM, in case subsequent use；

Step 5.3: after the completion of the step 4, for fused image, utilizing the texture and edge feature pair of blending image Spectral information identification region in blending image carries out depth recognition；

Step 5.4: the different spectral informations according to blending image are distributed, and target optical spectrum region is carried out image segmentation, are formed each A characteristic area；

Step 5.5: the parallel processing capability based on FPGA respectively carries out each characteristic area of the blending image non-simultaneously Uniformity correction；For each characteristic area, the main control chip calculates the mean temperature of each point in the characteristic area first, Then according to the mean temperature, corresponding correction parameter is read from the RAM in the FPGA, and is completed according to the following formula Nonuniformity correction

WhereinThe image that infrared detector exports under the conditions of expression Uniform Irradiation degree；

Step 5.6: the blending image after correction compensates boundary gray value using mean filter method.