CN108922098A - A kind of forest fire monitoring system and method based on infrared guidance and radar detection - Google Patents
A kind of forest fire monitoring system and method based on infrared guidance and radar detection Download PDFInfo
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- CN108922098A CN108922098A CN201810419631.5A CN201810419631A CN108922098A CN 108922098 A CN108922098 A CN 108922098A CN 201810419631 A CN201810419631 A CN 201810419631A CN 108922098 A CN108922098 A CN 108922098A
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- G—PHYSICS
- G08—SIGNALLING
- G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
- G08B17/00—Fire alarms; Alarms responsive to explosion
- G08B17/005—Fire alarms; Alarms responsive to explosion for forest fires, e.g. detecting fires spread over a large or outdoors area
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/86—Combinations of radar systems with non-radar systems, e.g. sonar, direction finder
- G01S13/867—Combination of radar systems with cameras
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01S—RADIO DIRECTION-FINDING; RADIO NAVIGATION; DETERMINING DISTANCE OR VELOCITY BY USE OF RADIO WAVES; LOCATING OR PRESENCE-DETECTING BY USE OF THE REFLECTION OR RERADIATION OF RADIO WAVES; ANALOGOUS ARRANGEMENTS USING OTHER WAVES
- G01S13/00—Systems using the reflection or reradiation of radio waves, e.g. radar systems; Analogous systems using reflection or reradiation of waves whose nature or wavelength is irrelevant or unspecified
- G01S13/88—Radar or analogous systems specially adapted for specific applications
- G01S13/886—Radar or analogous systems specially adapted for specific applications for alarm systems
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- G—PHYSICS
- G08—SIGNALLING
- G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
- G08B17/00—Fire alarms; Alarms responsive to explosion
- G08B17/10—Actuation by presence of smoke or gases, e.g. automatic alarm devices for analysing flowing fluid materials by the use of optical means
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- G—PHYSICS
- G08—SIGNALLING
- G08B—SIGNALLING OR CALLING SYSTEMS; ORDER TELEGRAPHS; ALARM SYSTEMS
- G08B17/00—Fire alarms; Alarms responsive to explosion
- G08B17/12—Actuation by presence of radiation or particles, e.g. of infrared radiation or of ions
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Abstract
The present invention provides a kind of forest fire monitoring system and method based on infrared guidance and radar detection.In the system and method, infrared sensor and radar detection apparatus are fixed and are integrated on the same rotating platform driven by servo motor, ignition point is found using infrared sensor, the measurement to ignition point distance is realized with radar detection apparatus, carry out kindling point location, and using the topography and geomorphology and vegetative coverage situation of radar detection apparatus monitoring ignition point near zone, in conjunction with wind speed and direction at that time, the fire classification and early warning to transmission line of electricity are realized.To realize automatic discovery, be automatically positioned, the function of automatic alarm, the line tripping accident rate as caused by mountain fire is reduced, the ability that transmission line of electricity resists mountain fire disaster is promoted.
Description
Technical field
It prevents and reduces natural disasters technical field the invention belongs to power grid, is related to a kind of supervising based on the mountain fire of infrared guidance and radar detection
Examining system and method.
Background technique
With the continuous construction and development of power grid, demand of the society to power supply reliability is higher and higher.Transmission line of electricity is electricity
One of important component of net, operating status decide the stabilization and safety of entire power grid, and power transmission line caused by mountain fire
Road failure seriously affects always the safe and stable operation of transmission line of electricity.This is mainly due to transmission line insulator caused by mountain fire is strong
Degree decline, caused by causing air breakdown.The harm how effectively to prevent and reduce mountain fire to passway for transmitting electricity reduces power grid
Failure and power outage, it is that electric power enterprise is urgent that raising power grid operation level, which is more secure and reliable national economy service,
Problem to be solved.Mountain fire is monitored, taking timely measure and carrying out control to the transmission line of electricity in mountain fire region is to reduce
Important means of the mountain fire to the threat of transmission line of electricity.The current disaster monitoring means of transmission line of electricity mainly have manual inspection and use
On-Line Monitor Device cannot still fully meet the requirement of the round-the-clock monitoring of route disaster and early warning.Manual inspection cannot achieve prison
Real-time is surveyed, and various traditional on-Line Monitor Devices have that monitoring range is limited, monitoring data information content is few, it can not
Meet to meteorological disaster, mountain fire, external force destruction is effectively monitored and the requirement of early warning.
Currently, transmission line forest fire monitoring method mainly has video image monitoring, infrared sensing monitoring, satellite remote sensing prison
It surveys.There is easily wrong report and fail to report, monitor regional scope and limited by video equipment performance, cannot achieve mountain fire position in video image monitoring
The defects of positioning set.Infrared sensing monitoring method can realize unattended uninterrupted monitoring, automatic to find in monitoring area
Fiery point, while can also check live realtime graphic, be put out a fire according to the direct command scheduling of intuitive picture.But infrared monitoring can be right
Sunlight, high temp objects etc. generate false-alarm, cannot achieve the accurate positioning to fire source, and misty rain day is to observed range and image clearly
Degree is affected.Satellite Remote Sensing mountain fire is also a kind of common means, and this method can carry out the monitoring of wide area to mountain fire, but
This method has that false alarm rate is high, and is limited by satellite transit time, it is difficult to realize round-the-clock monitoring, additionally there are
Monitoring result monitors the problems such as resolution ratio is not high vulnerable to sky cloud effect.
Radar monitoring technology is in the field of preventing and reducing natural disasters using long-standing.Radar remote, scan area with detection range
Greatly, scanning is limited small advantage, it can be achieved that a wide range of, round-the-clock, quick, dynamic ring rapidly, by visibility and steric requirements
Border and disaster monitoring, and have the characteristics that acquisition of information rapidly and accurately, stable and reliable operation, disaster monitoring, the condition of a disaster assessment, fortune
Animal body monitoring etc. shows huge potentiality.Infrared detection technique has good recognition capability to mountain fire, still
Infrared detector, which usually cannot achieve, measures the distance of ignition point, cannot achieve the accurate positionin to mountain fire.Therefore it ties
The defect of traditional infrared mountain fire monitoring device can effectively be made up by closing millimetre-wave radar and infrared electronic technology, and it is complete to reach round-the-clock
The use purpose of weather realizes the accurate positionin to mountain fire fire point.Realize automatic discovery, automatic positioning, automatic alarm, reduce by
The line tripping accident rate caused by mountain fire promotes the ability that transmission line of electricity resists mountain fire disaster.
Mountain fire is a high-temperature body, other than emitting visible light, while also releasing a large amount of infrared rays, these infrared rays can
The media such as rain, mist, cigarette are penetrated, and are weakened with the increase of medium.Mountain fire regional background temperature is generally at -40~60 DEG C, mountain
Flame temperature is up to several hundred or even thousands of degrees Celsius when fire occurs, and the two temperature difference is larger, and being easy in thermal image can
The combustion case of combustion things is separated from terrain backgrounds, to achieve the purpose that mountain fire detects.
Millimeter wave is the electromagnetic wave between microwave and light wave, and frequency range is 30~300GHz, and wavelength is 1~10mm.
Millimetre-wave radar can obtain under miniature antenna aperture higher antenna gain, and has the advantages that high resolution, can be applicable to
Structure is small, light-weight, high and with good doppler processing characteristic the occasion of resolving power.Compared with microwave, millimeter wave resolving power
Height, structure are light and small;With infrared and visible light ratio, millimetre-wave radar can direct measuring speed and distance.Due to most of occasions
Under, the smoke detection of mountain fire will be earlier than flame detecting, therefore it is to early stage that application millimeter wave, which carries out the smoke detection of mountain fire,
Effective detection mode of mountain fire can be reduced largely because of mountain fire sustained combustion and bring loss, be utilized simultaneously
The characteristic of millimetre-wave radar precision ranging realizes the accurate positionin to fire point.
Summary of the invention
The object of the present invention is to which the shortcomings that being directed to existing method and deficiency, propose that one kind is visited based on infrared guidance and radar
The forest fire monitoring system and method for survey are realized and are worked the monitoring and warning of mountain fire near transmission line of electricity.
In order to achieve this, the scheme that the present invention takes is:
A kind of forest fire monitoring system based on infrared guidance and radar detection, including it is millimetre-wave radar detection device, infrared
Sensor, data processing host;Millimetre-wave radar detection device, infrared sensor are connect with data processing host respectively;
Millimetre-wave radar detection device and infrared sensor are fixedly installed on the same rotary head, utilize servo electricity
Machine drive cloud platform carry out rotary scanning, infrared sensor constantly obtains image information and be sent to data processing host progress it is red
Outer image sensing analysis.
After monitoring identifies ignition point, data processing host locks servo motor, and radar antenna is fixed on kindling
In point orientation;
Aerial smoke particle is remained after the electromagnetic wave detection mountain fire burning of millimetre-wave radar detection device transmitting
Information, and data processing host is sent information to, data processing host installs ignition point and millimetre-wave radar detection device
The distance between place measures;
Data processing host combines the distance of measurement and the ignition point orientation of determination, determines the position coordinates of ignition point,
Determine the position of ignition point;
Geographical environment information of millimetre-wave radar detection device during detecting smog, near detection acquisition ignition point
With vegetative coverage information, data processing host assesses current wind speed according to the moving direction and speed of detection smog,
In conjunction with the specific location of transmission line of electricity, mountain fire is analyzed to the danger classes of transmission line of electricity, division of fire size class is carried out, passes through mountain
Fiery Warning Service device implements early warning work.
It further include having Warning Service device, Warning Service device is connect with data processing host.
The millimetre-wave radar detection device includes radar ontology, pulse-modulator, duplexer, the first frequency mixer, intermediate frequency
Amplifier, stablizes local oscillator, coherent oscillator, the second frequency mixer, phase detector, Moveing target indication at power amplifier
Filter MTI;Radar ontology is connect with duplexer, and pulse-modulator is connect with power amplifier, power amplifier respectively with it is double
Work device, the connection of the second frequency mixer, duplexer connect with the first frequency mixer, stabilization local oscillator respectively with the first frequency mixer, the
The connection of two frequency mixers, the first frequency mixer connect with intermediate frequency amplifier, coherent oscillator respectively with the second frequency mixer, phase detector
Connection, phase detector are connect with Moveing target indication filter MTI, and Moveing target indication filter MTI and data processing host connect
It connects.
The Moveing target indication filter MTI realizes filter function using delay line canceller.
A kind of mountain fire monitoring method based on infrared guidance and radar detection, including the following contents:
A1, the millimetre-wave radar detection device being installed on the same rotary head and infrared sensor are in servo motor
Drive under carry out rotary scanning;
A2, infrared sensor constantly obtain image information and are sent to data processing host;
A3, data processing host carry out infrared image sensing analysis to the image information of acquisition.
Further include:
S1, when data processing host monitoring identify ignition point after, data processing host lock servo motor, by radar
Antenna is fixed in ignition point orientation;
Aerial smog is remained after the electromagnetic wave detection mountain fire burning that S2, millimetre-wave radar detection device emit
Grain information, and data processing host is sent information to, data processing host pacifies ignition point and millimetre-wave radar detection device
The distance between dress place measures;
Data processing host combines the distance of measurement and the ignition point orientation of determination, determines the position coordinates of ignition point,
Determine the position of ignition point;
The geographical environment of S3, millimetre-wave radar detection device during detecting smog, near detection acquisition ignition point
Information and vegetative coverage information, data processing host comment current wind speed according to the moving direction and speed of detection smog
Estimate, in conjunction with the specific location of transmission line of electricity, analyzes mountain fire to the danger classes of transmission line of electricity, carry out division of fire size class, it is real
Apply early warning work.
Data processing host carries out infrared image sensing analysis, including the following contents in the A3:
1) Infrared images pre-processing;
After obtaining infrared image, the median filtering technology for first passing through Local Operator goes mountain fire infrared picture data
It makes an uproar processing, then the current infrared image that will acquire carries out difference with previous image, judges whether there is abnormal generation;If there is
Exception is judged as the image for having fire suspicious region, otherwise, continues waiting for obtaining next image;
By carrying out denoising to mountain fire infrared picture data more accurately to identify conflagration area;
2) image segmentation;
Image space is divided into several regions according to feature, the picture characteristics in the same area is identical, in different zones
Picture characteristics it is different;
3) feature extraction and pattern classification;
The feature extraction and pattern-recognition of infrared image are realized using the method for Digital Image Processing, detailed process includes flat
The contents such as sliding filtering, edge detection, image enhancement.Flame region feature includes four major class:Geometrical characteristic, textural characteristics, gray scale
Histogram feature and flame dynamic features;Wherein, geometrical characteristic includes conflagration area area, circularity, boundary perimeter and boundary
Roughness;Textural characteristics include the mean value of energy, entropy, the moment of inertia, correlation and local stationary;Grey level histogram feature is bright
The mean value and standard deviation of degree and the probability characteristics of gray value;Flame dynamic features are extracted by continuous two picture, packet
Include area of flame change rate and mass center displacement.
Compared with prior art, the present invention has following beneficial effect:
Implementation of the present invention is simple, has stronger applicability.If mountain fire occurs in power transmission line corridor range, answer
The mountain fire in monitoring range can be detected with this system and method, and mountain fire target is determined by feature database comparison,
Early warning is carried out to transmission line of electricity.The application of this system and method can effectively solve the problem that deficiency present in traditional approach, realize defeated
The automatic identification of electric corridor mountain fire, the trip accident to prevent mountain fire from causing provide effective technological means.
Detailed description of the invention
Fig. 1 is the doubtful area's feature extraction flow chart of flame;
Fig. 2 is system structure diagram of the invention;
Fig. 3 is the millimetre-wave radar detection device block diagram for including Moveing target indication filter.
Specific embodiment
Below in conjunction with the accompanying drawings and embodiment the invention will be further described.
The present invention includes a kind of forest fire monitoring system based on infrared guidance and radar detection, and system includes millimetre-wave radar
Detection device, infrared sensor, data processing host, Warning Service device;Millimetre-wave radar detection device, infrared sensor difference
It is connect with data processing host, data processing host is connect with Warning Service device;Millimetre-wave radar detection device includes radar sheet
Body, duplexer, the first frequency mixer, intermediate frequency amplifier, power amplifier, stablizes local oscillator, coherent oscillation at pulse-modulator
Device, the second frequency mixer, phase detector, Moveing target indication filter MTI;Radar ontology is connect with duplexer, pulse-modulator
It is connect with power amplifier, power amplifier is connect with duplexer, the second frequency mixer respectively, and duplexer and the first frequency mixer connect
It connecing, stablizes local oscillator and connect respectively with the first frequency mixer, the second frequency mixer, the first frequency mixer is connect with intermediate frequency amplifier,
Coherent oscillator is connect with the second frequency mixer, phase detector respectively, and phase detector and Moveing target indication filter MTI connect
It connects, Moveing target indication filter MTI is connect with data processing host.Moveing target indication filter MTI uses delay line canceller
Realize filter function.
Millimetre-wave radar detection device and infrared sensor are fixedly installed on the same rotary head, utilize servo electricity
Machine drive cloud platform carry out rotary scanning, infrared sensor constantly obtains image information and be sent to data processing host progress it is red
Outer image sensing analysis, after monitoring identifies ignition point, data processing host locks servo motor, and radar antenna is fixed
In ignition point orientation, that is, utilize infrared sensor discovery ignition point and determining ignition point orientation;
Aerial smog is remained later using the electromagnetic wave detection mountain fire burning of millimetre-wave radar detection device transmitting
Particle information, and data processing host is sent information to, data processing host is to ignition point and millimetre-wave radar detection device
The distance between infield measures;
Data processing host combines the distance of measurement and the ignition point orientation of determination, determines the position coordinates of ignition point,
Determine the position of ignition point;
Geographical environment information during millimetre-wave radar detection smog, near detection acquisition ignition point
With vegetative coverage information, data processing host assesses current wind speed according to the moving direction and speed of detection smog,
In conjunction with the specific location of transmission line of electricity, mountain fire is analyzed to the danger classes of transmission line of electricity, division of fire size class is carried out, passes through mountain
Fiery Warning Service device implements early warning work.
The mountain fire monitoring method based on infrared guidance and radar detection that the invention also includes a kind of, utilizes infrared sensing device
Detection discovery ignition point, and determine the orientation of ignition point, director radar carries out smoke detection in ignition point orientation transmitting electromagnetic wave
Identification, and using the geographical location circumstances information of radar acquisition ignition point, realize the risk evaluation to transmission line of electricity, specific implementation
Process includes following several steps:
(1) radar installations and infrared sensing device are fixedly installed on the same rotary head, utilize servo motor
Drive cloud platform carry out rotary scanning, infrared sensing device carry out infrared image sensing analysis, when monitoring identify ignition point it
Afterwards, servo motor is locked, radar antenna is fixed in ignition point orientation, i.e., finds ignition point and determination with infrared sensing device
Ignition point orientation.
(2) it using aerial smoke particle is remained after the burning of radar installations electromagnetic wave detection mountain fire, realizes opposite
The measurement of the distance between fire point and radar installations infield.In conjunction with the ignition point orientation in step (1), that is, it can determine ignition point
Position coordinates, determine the position of ignition point.
(3) geographical environment information and vegetative coverage during radar detection smog, near detection acquisition ignition point
Information, the moving direction and speed for detecting smog assess current wind speed, in the specific location for combining transmission line of electricity, divide
Mountain fire is analysed to the danger classes of transmission line of electricity, division of fire size class is carried out, implements early warning work.
Further, the mountain fire identification in step (1) is carried out to the collected infrared image of infrared sensor devices
Forest fire.For a width infrared image, it is contemplated that be only made of target and background two parts, and the feature of target and background
Difference belongs to different classifications, scope, therefore the detection to infrared image target, can be regarded as to entire image target
It is the identification using pixel as primitive with the classification of background.To given infrared image, mountain fire monitoring mainly has following step
Suddenly:
1) Infrared images pre-processing:
After obtaining infrared image, current infrared image and the previous image that first will acquire carry out difference, and judgement is
It is no to have abnormal generation.It is judged as the image for having fire suspicious region if there is abnormal, otherwise, continues waiting for obtaining next figure
Picture.In order to more accurately identify conflagration area, it is necessary to carry out denoising to mountain fire infrared picture data.Part is chosen to calculate
The median filtering technology of son is denoised, to improve image matter on the basis of the overall permanence of infrared image will not be destroyed by guaranteeing
Amount, while eliminating picture noise, moreover it is possible to which the edge for keeping image prevents edge blurry.By Protect edge information information, thus
Protect the profile of flame region.
2) image segmentation:
It is often only interested in the target part of infrared image in infrared imaging detection, in order to identify and analyze target,
It needs to separate target and background, that is, needs to carry out image segmentation to infrared image.Image segmentation is according to certain features
Image space is divided into some regions, the picture characteristics in the same area is identical, each not phase of the picture characteristics in different zones
Together.The purpose is to the shape segmentations of " possible target " in the window centered on all target points are come out.
3) feature extraction and pattern classification:
Flame region feature mainly includes four major class:Geometrical characteristic, textural characteristics, grey level histogram feature and flame dynamic
Feature.Wherein, geometrical characteristic includes conflagration area area, circularity, boundary perimeter and edge roughness;Textural characteristics include energy
Amount, entropy, the moment of inertia, the mean value of correlation and local stationary;Grey level histogram feature is the mean value and standard deviation of brightness, and
The probability characteristics of gray value;Flame dynamic features are extracted by continuous two picture, mainly include area of flame change rate
It is displaced with mass center.The doubtful area's feature extraction process of flame is as shown in Figure 1.
Further, the detection mountain fire smog in step (2) and pre-warning system by detection system, data processing host and
Mountain fire Warning Service device composition, as shown in Figure 2.The infrared data detected, radar signal are passed to number by front end detection system
According to processing host pretreatment, find after doubtful fire point by pre-processed results issue mountain fire Warning Service device carry out fiery point sentence knowledge with
Route alarm calculates, and monitoring and warning information are finally distributed to transmission line of electricity operation and maintenance unit, carries out mountain fire emergency disposal.
Further, in step (2) and step (3), detection to mountain fire smog and to mima type microrelief system near ignition point
The detection of the information such as standby requires to carry out the echo of radar signal clutter recognition and signal processing, using delay in the present invention
Line canceller realizes the filter function of Moveing target indication filter (MTI), the composition block diagram of Moveing target indication filter radar
As shown in Figure 3.Radar coherent transmitting is controlled by stablizing local oscillator (STALO).Stablize the output f of local oscillatorLO, with relevant vibration
Swing the output f of deviceCIt carries out mixing and generates tranmitting frequency fLO+fC.Intermediate frequency (IF) fC±fd, by reception signal and fLOMixing is to generate.
By intermediate frequency amplifier, signal fdIt is admitted to phase detector and is converted into baseband signal.Finally, signal is admitted to MTI filter
Wave device.
The content that this specification is not described in detail belongs to the prior art well known to professional and technical personnel in the field.
Claims (9)
1. a kind of forest fire monitoring system based on infrared guidance and radar detection, it is characterised in that:It is detected including millimetre-wave radar
Device, infrared sensor, data processing host;Millimetre-wave radar detection device, infrared sensor respectively with data processing host
Connection;
Millimetre-wave radar detection device and infrared sensor are fixedly installed on the same rotary head, utilize servo motor band
Dynamic cloud platform carries out rotary scanning, and infrared sensor, which constantly obtains image information and is sent to data processing host, carries out infrared figure
As sensing analysis.
2. a kind of forest fire monitoring system based on infrared guidance and radar detection according to claim 1, it is characterised in that:
After monitoring identifies ignition point, data processing host locks servo motor, and radar antenna is fixed in ignition point orientation;
Aerial smoke particle information is remained after the electromagnetic wave detection mountain fire burning of millimetre-wave radar detection device transmitting,
And send information to data processing host, data processing host to ignition point and millimetre-wave radar detection device infield it
Between distance measure;
Data processing host combines the distance of measurement and the ignition point orientation of determination, determines the position coordinates of ignition point, determines
The position of ignition point;
Geographical environment information and plant of the millimetre-wave radar detection device during detecting smog, near detection acquisition ignition point
Capped information, data processing host assesses current wind speed according to the moving direction and speed of detection smog, then ties
The specific location of transmission line of electricity is closed, analysis mountain fire carries out division of fire size class to the danger classes of transmission line of electricity, pre- by mountain fire
Alert server implementation early warning work.
3. a kind of forest fire monitoring system based on infrared guidance and radar detection according to claim 2, it is characterised in that:
It further include having Warning Service device, Warning Service device is connect with data processing host.
4. a kind of monitored based on the mountain fire of infrared guidance and radar detection described in any one of -3 is according to claim 1
System, it is characterised in that:The millimetre-wave radar detection device includes radar ontology, pulse-modulator, duplexer, the first mixing
Device, power amplifier, stablizes local oscillator, coherent oscillator, the second frequency mixer, phase detector, dynamic mesh at intermediate frequency amplifier
Mark display filter MTI;Radar ontology is connect with duplexer, and pulse-modulator is connect with power amplifier, power amplifier point
It is not connect with duplexer, the second frequency mixer, duplexer is connect with the first frequency mixer, is stablized local oscillator and is mixed respectively with first
Device, the connection of the second frequency mixer, the first frequency mixer connect with intermediate frequency amplifier, coherent oscillator respectively with the second frequency mixer, phase
Wave detector connection, phase detector are connect with Moveing target indication filter MTI, Moveing target indication filter MTI and data processing
Host connection.
5. a kind of forest fire monitoring system based on infrared guidance and radar detection according to claim 4, it is characterised in that:
The Moveing target indication filter MTI realizes filter function using delay line canceller.
6. a kind of mountain fire monitoring method based on infrared guidance and radar detection, which is characterized in that including the following contents:A1, peace
Loaded on the millimetre-wave radar detection device and infrared sensor progress driven by servo motor on the same rotary head
Rotary scanning;
A2, infrared sensor constantly obtain image information and are sent to data processing host;
A3, data processing host carry out infrared image sensing analysis to the image information of acquisition.
7. a kind of mountain fire monitoring method based on infrared guidance and radar detection according to claim 6, which is characterized in that
Further include:
S1, when data processing host monitoring identify ignition point after, data processing host lock servo motor, by radar antenna
It is fixed in ignition point orientation;
Aerial smoke particle letter is remained after the electromagnetic wave detection mountain fire burning that S2, millimetre-wave radar detection device emit
Breath, and data processing host is sent information to, data processing host is to ignition point and millimetre-wave radar detection device installation ground
The distance between point measures;
Data processing host combines the distance of measurement and the ignition point orientation of determination, determines the position coordinates of ignition point, determines
The position of ignition point;
The geographical environment information of S3, millimetre-wave radar detection device during detecting smog, near detection acquisition ignition point
With vegetative coverage information, data processing host assesses current wind speed according to the moving direction and speed of detection smog,
In conjunction with the specific location of transmission line of electricity, mountain fire is analyzed to the danger classes of transmission line of electricity, carries out division of fire size class, is implemented pre-
Alert work.
8. a kind of mountain fire monitoring method based on infrared guidance and radar detection according to claim 6 or 7, feature exist
In data processing host carries out infrared image sensing analysis, including the following contents in the A3:
1) after obtaining infrared image, the median filtering technology for first passing through Local Operator denoises mountain fire infrared picture data
Processing, then the current infrared image that will acquire carry out difference with previous image, judge whether there is abnormal generation;If there is different
Often it is judged as the image for having fire suspicious region, otherwise, continues waiting for obtaining next image;
2) image space is divided into several regions according to feature, the picture characteristics in the same area is identical, in different zones
Picture characteristics is different;
3) feature extraction and pattern-recognition of infrared image are carried out using the method for Digital Image Processing.
9. a kind of mountain fire monitoring method based on infrared guidance and radar detection according to claim 8, it is characterised in that:
The feature is flame region feature;
Flame region feature includes geometrical characteristic, textural characteristics, grey level histogram feature and flame dynamic features;Wherein, geometry
Feature includes conflagration area area, circularity, boundary perimeter and edge roughness;Textural characteristics include energy, entropy, the moment of inertia,
Related and local stationary mean value;Grey level histogram feature is the mean value of brightness and the probability of standard deviation and gray value
Feature;Flame dynamic features are extracted by continuous two picture, including area of flame change rate and mass center displacement.
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