KR20190117947A - Fire detection system based on machine learning - Google Patents

Abstract

The present invention relates to a fire monitoring system based on machine learning and to a method thereof. The fire monitoring system based on machine learning improves identification accuracy by analyzing continuous images photographed through a thermal imaging camera based on machine learning even when many expensive high resolution cameras are not used in a wide space, and simultaneously learns an image feature for a special environment to track a potential fire occurrence target not to be omitted, thereby ensuring reliability and accuracy.

Description

Fire monitoring system based on machine learning {FIRE DETECTION SYSTEM BASED ON MACHINE LEARNING}

      The present invention relates to a fire monitoring system and method having an image analysis function based on machine learning, and in particular, to improve identification accuracy by analyzing images taken by a thermal imaging camera through a machine learning technique, and at the same time, to images for a special environment. The present invention relates to a fire monitoring system and method based on machine learning technology that ensures reliability and accuracy by learning features and tracking them so as not to miss potential fire objects.

       A fire monitoring system using a thermal imaging camera is a technology that detects infrared rays emitted from an object by using a special sensor to image the temperature value and judges the fire to obtain information about the thermal state of an object or a facility. By using this, you can quickly identify problems that are not visible to the naked eye, so that you can grasp the fire hazards in facilities such as power plants, steel mills, and power companies, as well as airports, oil refineries, and public facilities, to prevent accidents in advance. The maintenance cost can be reduced. However, the low resolution cameras used by some are less accurate for fire judgment due to space and cost, and various complementary methods are continuously developed.

       Existing technology to compensate for this is to install a current sensor on the heater, home appliances, etc., the object of the space to be monitored, and when excessive current flow is detected, the image is taken by a thermal imaging camera to analyze the temperature change. However, this technology has a problem in that a sensor must be attached to all monitored objects, and a problem may occur that some sensors fail to detect a risk.

       Another existing technology mainly compares thermal images taken by focusing on electric power facilities to determine abnormalities of electric facilities. However, since the monitoring space is limited only to the space where the electric power facilities are located, there is a problem that overall monitoring cannot be made.

       In another technology, there is an effort to increase the degree of image identification by using a high resolution camera, but in general, a large number of cameras are used in a wide range, which increases the burden of installation equipment, and even high resolution does not allow time continuous image analysis. There is a problem that the exact operation of the fire judgment is difficult.

In addition, Korean Patent Registration No. 10-1796054 describes a smart fire detection system that performs fire detection using an IP address managed in response to location information including an address number and a block. In addition, the Republic of Korea Patent Publication No. 10-2018-21521 is a fire detection system using a thermal imaging camera that can determine the fire by observing the movement of brightness, temperature, etc. of the area after selecting the area in which the signs of fire appear as a monitoring target area This is described.

       In order to solve the above problems, the present invention improves the identification accuracy by analyzing continuous images taken through a thermal imaging camera based on machine learning without using a large number of expensive high resolution cameras in a large space. To provide a fire protection system and method based on machine learning that ensures the reliability and accuracy of the learned information by continuously learning the image characteristics of the surrounding environment so as not to miss potential fires. There is this.

       In order to solve the above problems, a fire monitoring system based on machine learning according to an embodiment of the present invention includes a camera photographing a fire monitoring area; A switch connected to the camera and selectively transferring an image captured by the camera; A controller configured to process and control an image transmitted from the switch; A display unit which displays a result processed by the controller; And a notification unit that receives a signal and sounds an alarm when it is determined by the controller that the fire has occurred, wherein the controller is configured based on a cyclic neural network (RNN) algorithm of machine learning based on a continuous image frame transmitted from the switch. Decision engine interpreted as; A storage unit for storing the transmitted image frame and storing data for fire verification; And a learning server that manages learning data of machine learning and delivers necessary data connected to the storage unit.

      In addition, the control unit of the present invention is characterized by using a machine learning long long term memory (LSTM) algorithm.

      In addition, when configuring the machine learning learning data of the learning server, it is characterized in that the training by collecting the continuous training data to analyze the continuous image of the special environment to accurately extract the features.

       The learning server may upgrade the learning data by periodically using the fire related information data and the images stored in the storage unit.

       In addition, the fire monitoring system of the present invention comprises the steps of photographing the fire monitoring area using a camera; Selectively transmitting an image captured by the camera; Processing and controlling the transferred image; Displaying the processed and controlled results; And

If it is determined that the result of processing and control is a fire, receiving a signal and sounding a beep, wherein the controlling step is based on the recurrent Neural Network (RNN) algorithm of machine learning the transmitted continuous image frame Interpreting as; Storing the transferred image frame and storing data necessary for fire verification; And configuring a learning server that delivers data required in the step of managing and interpreting the learning data of machine learning.

       In the controlling step, a long learning term (LSTM) algorithm of machine learning is used.

       In addition, when configuring the machine learning learning data of the learning server, it is characterized in that the training by collecting the continuous training data to analyze the continuous image of the special environment to accurately extract the features.

       The learning server may upgrade the learning data by periodically using the stored fire related information data and images thereof.

      The present invention improves the accuracy through continuous monitoring of the identification of the image of the fire hazard through learning based on machine learning to quickly extinguish the risk at an early stage in a special fire environment, and tracks it from the early stage. It also helps to avoid missing fire hazards.

       In addition, the present invention learns the characteristic changes appearing in the image reflecting the characteristics of the working environment, and based on this, by optimizing the machine learning algorithm to accurately identify the image obtained through the camera operating in a special and poor environment, the misjudgment of the fire occurs It has the effect of avoiding it.

1 is a block diagram of a fire monitoring system based on machine learning according to an embodiment of the present invention.
2 is a structural diagram illustrating a Recurrent Neural Network (RNN) algorithm of machine learning used in the present invention.
3 is a flow chart illustrating a fire monitoring process of a fire monitoring system based on machine learning according to an embodiment of the present invention.

      Hereinafter, with reference to the accompanying drawings will be described a detailed embodiment of the present invention.

      Like reference numerals in the drawings denote like parts. In addition, specific structures or functional descriptions in the embodiments of the present invention are merely for the purpose of describing the embodiments according to the present invention, and unless otherwise defined, all terms used herein, including technical terms, are used in the technical field to which the present invention belongs. Has the same meaning as commonly understood by one of ordinary skill.

       1 is a block diagram of a fire monitoring system based on machine learning according to an embodiment of the present invention. As shown, a plurality of cameras 100 for photographing the fire monitoring area, a switch 200 connected to the camera 100 and to select and transfer one of the images taken from the camera 100, and the switch ( The control unit 300 for processing and controlling the image received from the 200, the display unit 400 for displaying a fire detection result for displaying the result processed by the control unit 300, and the fire occurs by the control unit 300 If it is determined to include the alarm unit 500 that sounds a warning sound.

       In an embodiment of the present invention, the camera 100 is a thermal imaging camera for photographing a thermal image may be composed of one or more cameras located at different places in the fire monitoring area. The control values (tilt, focus, angle of view, etc.) of the thermal imaging camera may be preset and stored and then adjusted by the controller 300 in the event of a fire. The switch 200 is a communication device that connects network units and selects one of a plurality of inputs. The switch 200 selects one of thermal images captured by the camera 100 and quickly transfers it to the control unit 300. .

       The controller 300 stores a decision engine 302 and a transmitted image frame based on a continuous neural network (RNN) algorithm of machine learning based on a continuous image frame received from the switch 200. The storage unit 301 stores data necessary for fire verification, and a learning server 303 that manages the training data and is connected to the storage unit 301 to transmit necessary data.

       The display unit 400 displays images interpreted by the controller 300 as a possibility of a fire and informs the manager of the progress. When the control unit 300 determines that the fire occurs, the alarm unit 500 transmits a signal to sound an alarm. The alarm unit 500 may be a device that sounds an actual warning sound, and may simultaneously include a service of notifying a fire to a control server through a separate application or messenger configured to notify a fire to a control server.

       As described above, the fire monitoring system based on the machine learning according to the present invention continuously learns the characteristics of the image according to the environmental characteristics of the fire monitoring area through the machine learning, thereby accurately identifying the fire occurrence possibility for the fire occurrence target. To help reduce the risk of fire in the early stages of the fire by keeping track of the video and keeping an eye on the video prior to a potential fire situation.

       Based on the above configuration, the detailed operation of the present invention will be described.

      Referring to FIG. 2, a method of configuring learning data by a learning server using an RNN algorithm is described. The RNN algorithm is an algorithm suitable for sequentially processing data, and has an advantage in that a structure can be variously and flexibly formed as needed. For example, learning data may be constructed by patterning environmental features that cannot be distinguished from general images into data sequences until the temperature gradually rises and spreads over a wide range, such as a coal reservoir. Long short term memory (LSTM) algorithm, which is a type of RNN algorithm, may be used.

       To create training data, a training data set is constructed and features are extracted through the RNN algorithm. The extracted features are classified and stored in the server as initial learning data. A new training data set is entered and learning takes place by repeating these actions. For accurate classification, it is important to construct a large number of training data sets to form a large number of training data sets. It is also a big feature of the present invention to construct a training data set so that a feature can be accurately extracted by analyzing an image of a special environment.

        Hereinafter, an example of the training data will be described as a thermal imaging camera image of a coal storage. An arbitrary number of consecutive video frames is formed at regular time intervals. If the temperature of one section is detected to be increased by more than 10 degrees Celsius in the continuous frame image, the section is recognized as a fire-prone area and learn to watch the input image frame afterwards. Then, if a continuous increase in temperature is detected, for example, the monitor is taught to display a warning message on the monitor as soon as the detected temperature rises above 200 degrees Celsius.

       Other learning data suggest that if the temperature does not increase by more than 10 degrees Celsius, but the range of the area that is higher than 10 degrees Celsius higher than the ambient temperature gradually expands, this section is regarded as a fire-prone area and watched for an image frame input afterwards. do. If the temperature range extends by more than 1㎡, for example, learn to display a warning message on the monitor. Although it is not recognized as a fire in a typical environment, in a special environment such as a coal reservoir, embers can spread out of the loaded coal and cause a fire.

       In this way, according to the special environment in which the fire monitoring system is installed, the situation in which there is a risk of fire is learned in advance, and the system is configured to recognize the situation before generating a large fire and prevent the fire in advance.

       When the learning server constructing the learning data is completed, the controller 300 receives an actual image set and extracts a feature through an RNN algorithm. After that, the characteristics are accurately classified and compared with the learning data stored in the learning server, and the classification results are analyzed to determine whether or not a fire has occurred.

       The learning server inputs a continuous image frame of various features as a training data set to generate and store high-level learning data having excellent feature extraction through repetitive learning. When a fire occurs in the fire monitoring system, since the information data thereof is stored in the storage unit 301, the learning server periodically upgrades the learning data by inputting the fire related information data and its image. With the continuous upgrade of learning data, the reliability and accuracy of the fire monitoring system is further improved.

       3 is a flowchart illustrating a fire monitoring process of a fire monitoring system based on machine learning according to the present invention. In the present embodiment, for example, the present invention will be described through a fire monitoring process that detects an image in which a temperature change gradually occurs in a coal storage and monitors whether there is a risk of fire. However, the present invention is not limited thereto.

       In step S100 of the figure, the fire monitoring system according to the present invention receives an image frame. Subsequently, in step S200, it is determined whether the temperature change has occurred by more than a predetermined value compared to a previously received image frame. If no temperature change occurs, the process returns to step S100 again to continue receiving a new image frame.

       If the temperature change is greater than a predetermined value, the image frame is continuously transmitted to the decision engine based on machine learning in step S300. In step S400, the determination engine determines whether there is a fire possibility in association with the training data. If it is determined that there is no possibility of a fire, the flow returns to step S100 to receive a new image frame.

       If it is determined that there is a possibility of a fire, it is determined whether or not a fire occurrence alarm should be sounded at step S500. When it is determined that the fire alarm should be sounded, a signal is sent to the alarm unit 500 to notify the occurrence of a fire. If it is determined that the still watching step, in step (S600), including the degree of danger, the display unit 400 displays the image that can be generated by the fire and informs the manager of the progress. Subsequently, the image of the spot is continuously watched to determine whether the fire alarm should be continuously generated.

       In step S400, for example, when the ignition spontaneously ignites in the coal storage, and small embers in the coal gradually spread, the temperature increases over a predetermined value with time as a criterion for determining the possibility of fire. A decision engine based on machine learning is interpreted as being fire in connection with learning data.

       As described above, in the present invention, the fire detection system determines the situation by extracting and accurately classifying features of continuous images through learning based on machine learning so that a risk can be quickly suppressed at an early stage in a specific environment. And it tracks it from an early stage, so that it does not miss any risk factor. In addition, since the present invention configures the training data using continuous images reflecting the characteristics of the working environment, the machine learning algorithm is optimized to accurately identify images obtained through a camera operating in a special and poor environment or an existing thermal imaging camera. It is characterized by supporting the prevention of false positives on fire.

       Various components described in the present invention can be implemented by hardware circuitry, firmware, software, or a combination thereof.

       Although the present invention has been described with reference to the embodiments shown in the drawings, this is only an embodiment, and those skilled in the art to which the related art will recognize that various modifications and other embodiments are possible from this. will be. Therefore, the technical protection scope of the present invention should be judged by the following claims.

The present invention can be used in the field of fire detection using a thermal imaging camera.

Claims (8)

A camera for photographing fire surveillance areas;
A switch connected to the camera and selectively transferring an image captured by the camera;
A controller configured to process and control an image transmitted from the switch;
A display unit which displays a result processed by the controller; And
If it is determined that the fire caused by the control unit comprises a notification unit for receiving a signal to sound an alarm,
Always the controller
A decision engine for interpreting continuous image frames transmitted from the switch based on a recurrent neural network (RNN) algorithm of machine learning;
A storage unit for storing the transmitted image frame and storing data for fire verification; And
A fire monitoring system based on machine learning, comprising a learning server that manages learning data of machine learning and delivers necessary data connected to the storage unit. The method of claim 1,
And a control unit using a machine learning long short term memory (LSTM) algorithm. The method of claim 1,
When configuring the machine learning learning data of the learning server, based on the machine learning, the continuous training data is collected and executed to analyze the continuous images of the special environment so as to accurately extract the features. One fire surveillance system. The method of claim 1,
The learning server is a fire monitoring system based on machine learning, characterized in that for upgrading the learning data using the fire-related information data and the images stored in the storage unit periodically. Photographing the fire surveillance area using a camera;
Selectively transmitting an image captured by the camera;
Processing and controlling the transferred image;
Displaying the processed and controlled results; And receiving a signal and sounding an alarm if it is determined that the result of the processing and control is a fire occurrence,
The controlling step
Interpreting the transmitted consecutive image frames based on a machine learning's Recurrent Neural Network (RNN) algorithm;
Storing the transmitted image frame and storing data necessary for fire verification; And configuring a learning server for managing the learning data of the machine learning and delivering the necessary data in the interpreting step. The method of claim 5,
Fire monitoring method based on the machine learning, characterized in that for using the control step of the machine learning long short term memory (LSTM) algorithm. The method of claim 5,
When configuring the machine learning learning data of the learning server, based on the machine learning, the continuous training data is collected and executed to analyze the continuous images of the special environment so as to accurately extract the features. Fire monitoring method. The method of claim 5,
The learning server fire monitoring method based on machine learning, characterized in that for upgrading the learning data using the stored fire-related information data and the images periodically.

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