CN111131728A - Infrared image processing method, device and system based on coding - Google Patents

Abstract

The application provides an infrared image processing method, an infrared image processing device and an infrared image processing system based on coding, wherein the method is applied to a data center and comprises the following steps: receiving an infrared image sent by infrared imaging equipment, wherein coding information is embedded in the infrared image, and the coding information is obtained by coding the place where the infrared imaging equipment is located and equipment information according to a preset coding format; and decoding the coded information of the infrared image according to a preset decoding format to obtain the location and equipment information of the infrared imaging equipment corresponding to the infrared image. In the embodiment, the location of the infrared imaging device, the device information and other contents are encoded, and only a string of simple codes is embedded in the image instead of substantial content information, so that the data size of the image is not affected, meanwhile, the data center is favorable for quickly positioning abnormal points and quickly retrieving data, and after the codes are coded, the location and the device information in all infrared images are unified, and the operation is easy.

Description

Infrared image processing method, device and system based on coding

Technical Field

The application relates to the technical field of data monitoring, in particular to an infrared image processing method, device and system based on coding.

Background

With the rapid development of the power industry, the capacity and the voltage level of a power grid are also continuously improved, and in order to ensure the reliability and the safety of power supply, monitoring and diagnosing of each power device operated in a transformer substation are very important. At present, infrared imaging equipment is generally used for observing the heating condition of transformer substation operation equipment, abnormal heating points in a transformer substation can be found in time by analyzing infrared images, an important role is played for early warning of heating faults, and the safety and reliability of the transformer substation equipment can be effectively improved.

However, because the number of the power devices of the substation is too large and the number of the deployed infrared imaging devices is also large, a large number of infrared images will be generated every second, and the infrared images contain a large amount of device data information, so that the abnormal heating points are inconvenient to quickly locate, and inconvenience is caused when data retrieval and statistics are performed.

Disclosure of Invention

An object of the embodiments of the present application is to provide a method, an apparatus, and a system for processing an infrared image based on a code, in which information such as a location and a device is converted into a string of simple codes by a coding method, so that a data center can quickly locate an abnormal heating point, and data retrieval, statistics, and analysis are more convenient.

In a first aspect, an embodiment of the present application provides an infrared image processing method based on coding, which is applied to a data center, and the method includes: receiving an infrared image sent by infrared imaging equipment, wherein coding information is embedded in the infrared image, and the coding information is obtained by coding the place where the infrared imaging equipment is located and equipment information according to a preset coding format; and decoding the coded information of the infrared image according to a preset decoding format to obtain the location and equipment information of the infrared imaging equipment corresponding to the infrared image.

In the scheme, the location of the infrared imaging device, the device information and other contents are encoded in advance and then added to the infrared image to be transmitted, and because only one string of simple codes is embedded in the infrared image instead of substantial content information, the size of the infrared image is not greatly influenced after the coded information is embedded, and the method is favorable for the data center to quickly locate abnormal points and quickly search data. Meanwhile, after the infrared images are coded, the positions and equipment information in all the infrared images are unified, the operation is easy, and great convenience is provided for the subsequent processing of a data center.

Optionally, the encoded information includes a location field and an equipment field, where the location field and the equipment field respectively include a plurality of subfields, and the encodings of the subfields are arranged according to a preset order.

Optionally, the decoding the encoded information of the infrared image according to the preset decoding format includes: splitting the coding information into a place field and an equipment field according to the preset field length; and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

The decoding process is the reverse process of coding, and the data center carries out reverse analysis according to the preset location and the coding method of the equipment.

Optionally, the plurality of subfields of the location field include: the province, the city, the county and the substation of the infrared imaging equipment; the plurality of subfields of the device field include: the manufacturer of the infrared imaging device, the device type, and the device number.

In a second aspect, an embodiment of the present application provides an infrared imaging apparatus, including: the camera is used for collecting infrared images; the processor is used for embedding the coding information stored in the memory into the infrared image collected by the camera; the coded information is obtained by coding the location of the infrared imaging equipment and the equipment information according to a preset coding format; and the transceiver is used for sending the infrared image processed by the processor to a connected data center so that the data center can obtain the location and equipment information of the infrared imaging equipment after decoding the coded information of the infrared image according to a preset decoding format.

In a third aspect, an embodiment of the present application provides an infrared image processing apparatus based on coding, where the apparatus is configured in a data center, and the apparatus includes: the infrared imaging device comprises a receiving module, a processing module and a processing module, wherein the receiving module is used for receiving an infrared image sent by the infrared imaging device, coding information is embedded in the infrared image, and the coding information is obtained by coding the place where the infrared imaging device is located and device information according to a preset coding format; and the decoding module is used for decoding the coded information of the infrared image according to a preset decoding format to obtain the location and the equipment information of the infrared imaging equipment corresponding to the infrared image.

Optionally, the encoding information includes a location field and an equipment field, where the location field and the equipment field include a plurality of subfields, and the encodings of the subfields are arranged according to a preset order, and the decoding module is specifically configured to: splitting the coding information into a place field and an equipment field according to the preset field length; and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

In a fourth aspect, an embodiment of the present application provides an infrared image processing system based on coding, including: the system comprises a data center and a plurality of infrared imaging devices, wherein the infrared imaging devices are respectively deployed in a plurality of substations; the infrared imaging equipment is used for acquiring infrared images, embedding stored coding information into the acquired infrared images and sending the stored coding information to the data center, wherein the coding information is obtained by coding the places where the infrared imaging equipment is located and equipment information according to a preset coding format; the data center is used for receiving the infrared image sent by the infrared imaging equipment, decoding the coded information of the infrared image according to a preset decoding format, and obtaining the location and equipment information of the infrared imaging equipment corresponding to the infrared image.

Optionally, the encoding information includes a location field and an equipment field, where the location field and the equipment field include a plurality of subfields, and the encodings of the subfields are arranged according to a preset order, and the data center is specifically configured to: splitting the coding information into a place field and an equipment field according to the preset field length; and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

In a fifth aspect, embodiments of the present application provide a storage medium having a computer program stored thereon, where the computer program is executed by a processor to perform the method according to the first aspect.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments of the present application will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and that those skilled in the art can also obtain other related drawings based on the drawings without inventive efforts.

Fig. 1 is a schematic diagram of an infrared image processing system provided in an embodiment of the present application;

fig. 2 is a flowchart of an infrared image processing method provided in an embodiment of the present application;

fig. 3 is a schematic diagram of an infrared image processing apparatus according to an embodiment of the present application;

fig. 4 is a schematic diagram of an infrared imaging apparatus provided in an embodiment of the present application.

Detailed Description

The technical solutions in the embodiments of the present application will be described below with reference to the drawings in the embodiments of the present application.

The embodiment of the application provides an infrared image processing method, device and system based on coding. Fig. 1 shows a schematic diagram of the infrared image processing system, in which processing system: the system comprises a data center 110 and a plurality of infrared imaging devices 120, wherein the plurality of infrared imaging devices 120 are respectively deployed in substations in provinces (direct prefecture city), cities (ground level city) and counties (county level city or district) of the whole country, a plurality of infrared imaging devices can be simultaneously deployed in one substation, and each infrared imaging device is used for performing infrared imaging on at least one power device in the substation.

The infrared imaging device 120 performs infrared imaging on the thermal state of the power device in the substation to obtain an infrared image, where the infrared image corresponds to the thermal distribution field on the surface of the power device, and the temperature condition of the surface of the power device to be measured can be determined by different colors on the infrared image. After the infrared image is obtained, the infrared imaging device 120 sends the acquired infrared image to the remote data center 110, and the data center 110 analyzes whether the corresponding power device has an abnormal heating condition according to the infrared image, and performs early warning in time when the abnormal condition occurs. In the above process, the infrared imaging device 120 may acquire an infrared image of the detected power device in real time and transmit the infrared image to the data center 110 in real time.

The embodiment of the application adopts a coding mode, converts the place where the infrared imaging equipment is located and the equipment information into the coded information through a preset coding format, and embeds the coded information into the infrared image, so that the place and the equipment information in all the infrared images are unified and easy to operate on the one hand, and on the other hand, the subsequent processing and analysis flow is simplified, and the abnormal heating point can be quickly positioned conveniently. The following describes the infrared image processing method and the encoding method used in this embodiment in detail.

Fig. 2 shows a flow chart of an infrared image processing method, in which the following steps are included:

step 210: the infrared imaging equipment collects infrared images, embeds the stored coding information into the collected infrared images and sends the infrared images to the data center.

Before that, the corresponding encoding information needs to be preset in each infrared imaging device, so that the encoding mode of the encoding information is defined first, and this embodiment provides a possible encoding mode.

Specifically, the coded information includes a location field and a device field, where the location field indicates a location of the infrared imaging device, the device field indicates device information of the infrared imaging device, and the coded information is obtained by combining a code of the location field and a code of the device field. The location field and the device field respectively include a plurality of subfields, and encodings of the plurality of subfields are sequentially arranged in a preset order.

The encoded information may specifically be a series of numerical numbers. In the plurality of subfields of the place field, the places of the infrared imaging equipment are sequentially arranged according to province, city, county and substation, and codes of all subfields are combined in sequence to form codes of the place field. The province referred to above may represent a province or a prefecture city, the city may represent a prefecture city, and the county may represent a county, a county city, or a district. Wherein the number of encoding bits of each subfield can be set according to the total number. For example, the number of coded bits of the province field can be set according to the total number of provinces and prefectural cities in the country, such as two bits; the number of the located substation can represent the number of the substation in the national substation or the numbers of the substations in the county, so the number of the coded digits can be set according to the number of the national substations or the number of the substations in the county, such as three-digit or four-digit.

For example, each subfield in the location field is set to three-bit encoding, and the encoding format of the location field is: xxxxxyyyyyyy, where XXX represents the code of province/prefecture city, XXX represents the code of city (city of prefecture), YYY represents the code of county/district, YYY represents the code of substation, and combining the codes of the subfields in order is the unique location code.

Assuming that the code in Guangdong province is 021, the code in Shenzhen City is 020, and the code in Rohu region is 010, then combining the above codes, the site code represented by the No. 30 substation in the Rohu region in Guangdong province is: 021020010030.

and in a plurality of subfields of the equipment field, the equipment information of the infrared imaging equipment is sequentially arranged according to the manufacturer, the equipment type and the equipment number of the infrared imaging equipment, and the codes of each subfield are combined in sequence to form the code of the equipment field. The device number represents a sequence number of the infrared imaging device, and the sequence number may be a sequence number obtained after all infrared imaging devices in the substation to which the device number belongs are uniformly numbered, or a sequence number obtained after infrared imaging devices of the same type installed in the substation to which the device number belongs are uniformly numbered. In actual implementation, the device number can be set according to requirements, and if statistical analysis is required to be performed on infrared images acquired by different types of devices in a data center, the device number can be implemented according to the meaning indicated by the latter. The number of encoding bits of each subfield in the device field can be set according to how many of the total number.

For example, each subfield in the device field is set to two-bit encoding, and the encoding format of the device field is: AAaaBB, where AA represents a vendor code, AA represents a device type code, and BB represents a device number of an infrared imaging device, such as may be the serial number of this type of device installed at a substation.

Assuming that the code of a certain red-eye infrared imager manufacturer is 28, the code of a certain outdoor infrared imager produced is 17, and the serial number of the outdoor infrared imager at the substation to which the outdoor infrared imager belongs is 09, the codes of the multiple subfields are combined to obtain the code of the device field: 281709.

according to the above embodiment, the encoding format of the encoded information obtained by combining the location field and the device field is: xxxxxyyyyyaaabb, according to the example given above, the coded information of the infrared imaging device is: 021020010030281709.

when each infrared imaging device is deployed in a substation, a corresponding code is allocated to each infrared imaging device according to the coding mode, and the corresponding code is stored in a memory of the infrared imaging device. In practical implementation, the data center can uniformly manage the coded information of the plurality of infrared imaging devices, and assign corresponding codes to each newly added infrared imaging device. Optionally, a management table of coded information is stored in the data center, and when a new infrared imaging device is added, the infrared imaging device firstly sends position information, factory preset manufacturer information and device types to a data center, the data center determines a transformer substation where the device is located according to the position information, determines a corresponding location code according to a preset coding rule, then, determining the codes of the corresponding subfields according to the sent manufacturer information and the equipment types, distributing the sequence numbers in a downward delay manner according to the stored sequence numbers existing in the transformer substation, if 10 infrared imaging devices are recorded in the coded information management table, the sequence number of the device is set to be 11, and finally, combining the location code and the equipment code to obtain the unique code information of the equipment, and issuing the code information to the infrared imaging equipment by the data center. Of course, the coded information of the infrared imaging device can also be preset in the device after being coded by the staff.

After step 210, step 220 is performed: the data center receives the infrared image sent by the infrared imaging equipment, decodes the coded information of the infrared image according to a preset decoding format, and obtains the place information and the equipment information carried in the infrared image.

After the infrared imaging device transmits the image back to the data center, the data center decodes according to a preset decoding format, and can acquire the specific location where the device for acquiring the infrared image is located and device information. The decoding process is the reverse process of the coding, and the data center carries out reverse analysis according to the coding method of the place and the equipment. The specific analysis process comprises the following steps: firstly, splitting coding information into a place field and an equipment field according to a preset field length; then, decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield; and finally, combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

For example, for an infrared image with coded information of 021020010030281709 sent by an infrared imaging device, the first 12 bits represent a location field and the last 6 bits represent a device field according to a set coding rule, so according to such a rule, splitting is performed between the 12 th bit and the 13 th bit, and a code 021020010030 of the location field and a code 281709 of the device field are obtained through splitting. Then, the codes of each subfield in the location field and the equipment field are respectively analyzed, and the analysis result is as follows: 021020010030 is resolved into No. 30 transformer substation of Guangdong province (number: 021) Shenzhen city (number: 020) Rohu region (number: 010); 281709 is resolved as: the red eye infrared imager manufacturer (number: 28) and the outdoor infrared imager (number: 17) have the sequence number of 09 in the transformer substation to which the red eye infrared imager manufacturer belongs; the final overall analytical result obtained is: transformer substation No. 30 of the Roche region of Shenzhen, Guangdong province, and device No. 09 of the outdoor infrared imager produced by the red-eye infrared imager manufacturer.

The infrared images transmitted back to the data center can be stored separately according to the location and equipment codes. In real-time early warning monitoring, infrared imaging equipment needs to acquire infrared images in real time and upload the infrared images to a data center, and the quantity of the infrared imaging equipment is large, so that the data volume received by the data center in each second is huge, if all the infrared images and corresponding coding information are uniformly stored under a folder or at the same position, retrieval is very troublesome under the condition of storing a large amount of data, so that the data of different transformer substations can be independently stored in different directories or databases, namely, the infrared images with the same first 12-bit codes are stored in the same directory, and after the data center receives one infrared image, the infrared images are stored in the corresponding directories according to the first 12-bit codes in the coding information. Optionally, under the condition that the number of the infrared imaging devices is large, the infrared imaging devices can be stored according to the device codes at the same time, that is, images of the same type of infrared imaging devices in the same substation are stored in the same directory, and during statistical analysis, the rules existing among the infrared images acquired by different types of devices can be analyzed.

After the infrared imaging equipment is deployed in the transformer substation, the data center can receive infrared images obtained after the infrared imaging equipment images the power equipment, and when the data center needs displaying and data analysis, the data source and the geographic position can be quickly determined by directly reading coding information in the infrared images. For example, an image analysis system or a video analysis system is deployed on a data center and used for monitoring an infrared image on a page in real time, when an abnormality is found in the image, for example, a particularly bright point or a point with an ultrahigh temperature exists in the image, an alarm program can be started immediately, a substation where the abnormal point is located and which infrared imaging device in the substation shoots the abnormal point can be quickly located through coded information in the image, and relevant personnel can be timely notified to conduct investigation.

Furthermore, when statistical analysis is performed, for example, abnormal situations of all substations in a certain province (such as a province code is 021) in the year need to be checked, because when the image analysis is performed, when one abnormality occurs in a certain infrared image, the code of the infrared image is recorded while an alarm is given, when statistics is performed, only the code of which the first three-digit code is 021 needs to be screened out from a plurality of recorded abnormal information, and the abnormal situations of all substations of the province can be quickly determined; if the abnormity of a certain transformer substation needs to be counted specifically, the abnormity can be quickly determined only according to the first 12-bit codes. The method in the embodiment provides convenience for retrieval, statistics and analysis of the data center and also accelerates the processing speed of the data center by encoding the location and equipment information into the number.

In addition, when the data center performs statistical analysis, the image analysis system can be combined with the environmental weather of a place, for example, a place has the characteristics of high altitude, luxuriant forest, much rain and the like, and the image analysis system and the recorded abnormal conditions can be analyzed in a linkage manner, for example, which transformer substations are abnormal frequently in the whole province, and what is the reason why the transformer substations are abnormal frequently. Specifically, the data center quickly analyzes a certain rule from the abnormal code information through a certain analysis means, and if the abnormal frequency of the province with the province code 021 in the abnormal code information is found in the recorded abnormal information, or the abnormal frequency of the substation in a certain area (for example, the adjacent substation has the adjacent substation number) is found to be the maximum, the province or the area can be quickly located to analyze the abnormal reason.

In summary, in the present embodiment, the preset encoding rule is used to encode the location of the infrared imaging device, the device information, and other contents, and then add the encoded contents to the infrared image to be transmitted, so that the information stored in the infrared image is complete and simple. Meanwhile, the data center can determine the physical position and the equipment information of the shooting equipment of each infrared image through a preset decoding rule, each shooting equipment is provided with a unique site + equipment code, the unique code is added in each frame of image in real-time image acquisition, and the data center can perform operations of data classification storage, data display, data analysis and other infrared images according to the unique code. In the embodiment, since only a string of codes is embedded in the infrared image, and not substantial content information, the data size of the infrared image is not greatly affected after the code information is embedded, and moreover, the method is beneficial to the quick positioning of abnormal points and the quick retrieval of data by a data center. Meanwhile, after the infrared images are coded, the positions and equipment information in all the infrared images are unified, the operation is easy, the problems that the information in all the infrared images is incomplete, the formats are not unified, the arrangement sequence of all the information is irregular and the like are solved, and great convenience is provided for the subsequent processing of a data center.

Based on the same inventive concept, an embodiment of the present application further provides an infrared image processing apparatus based on encoding, where the apparatus is configured in a data center, and as shown in fig. 3, the apparatus includes:

the receiving module 310 is configured to receive an infrared image sent by an infrared imaging device, where coding information is embedded in the infrared image, and the coding information is obtained by coding a location where the infrared imaging device is located and device information according to a preset coding format;

the decoding module 320 is configured to decode the encoded information of the infrared image according to a preset decoding format, and obtain a location and device information of the infrared imaging device corresponding to the infrared image.

Optionally, the encoded information includes a location field and an equipment field, where the location field and the equipment field respectively include a plurality of subfields, and the encodings of the subfields are arranged according to a preset order.

Optionally, the decoding module 320 is specifically configured to: splitting the coding information into a place field and an equipment field according to the preset field length; and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

Optionally, the plurality of subfields of the location field include: the province, the city, the county and the substation of the infrared imaging equipment; the plurality of subfields of the device field include: the manufacturer of the infrared imaging device, the device type, and the device number.

The basic principle and the resulting technical effect of the above-mentioned encoding-based infrared image processing apparatus are the same as those of the previous method embodiment, and for the sake of brief description, no part of this embodiment is mentioned, and reference may be made to the corresponding contents in the above-mentioned method embodiment, which is not described herein again.

The embodiment of the present application further provides a storage medium, where a computer program is stored on the storage medium, and when the computer program is executed by a processor, the method for processing an infrared image based on coding according to the embodiment is executed. The foregoing storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk. In one embodiment, the data center can receive, through the computer program stored on the storage medium, the infrared images sent by the infrared imaging devices deployed in the substations, and decode the encoded information embedded in the infrared images to obtain the location and device information of the infrared imaging devices.

An embodiment of the present application further provides an infrared imaging apparatus, as shown in fig. 4, the infrared imaging apparatus 120 includes: a camera 410, a processor 420, a memory 430, and a transceiver 440, wherein the camera 410 is coupled to the processor 420, and the processor 420, the memory 430, and the transceiver 440 are interconnected and in communication with each other via a communication bus 450 and/or other form of coupling mechanism (not shown).

The Memory 430 includes one or more (Only one is shown in the figure), which may be, but not limited to, a Random Access Memory (RAM), a Read Only Memory (ROM), a Programmable Read Only Memory (PROM), an Erasable Read Only Memory (EPROM), an electrically Erasable Read Only Memory (EEPROM), and the like. Processor 420, and possibly other components, may access, read, and/or write data from memory 430.

Processor 420 includes one or more (only one shown) which may be an integrated circuit chip having signal processing capabilities. The Processor 420 may be a general-purpose Processor, and includes a Central Processing Unit (CPU), a Micro Control Unit (MCU), a Network Processor (NP), or other conventional processors; or a special-purpose Processor, including a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable logic device, a discrete Gate or transistor logic device, and a discrete hardware component.

The transceiver 440 includes one or more (only one shown) that can be used to communicate directly or indirectly with other devices for data interaction. The transceiver 440 may communicate with the data center through an ethernet or a mobile communication network.

One or more computer program instructions may be stored in memory 430 and read and executed by processor 420 to implement the steps of the code-based infrared image processing method provided by the embodiments of the present application and other desired functions. The memory 430 further stores encoded information corresponding to the infrared imaging device 120, where the encoded information is obtained by encoding the location and device information of the infrared imaging device 120 according to a preset encoding format, and the encoded information may be encoded by a data center and then sent to the infrared imaging device 120, or may be embedded in the memory 430 by a worker.

In this embodiment, the infrared imaging device acquires an infrared image of the power device in the substation through the camera 410, the processor 420 embeds the encoded information stored in the memory into the infrared image acquired by the camera, and transmits the infrared image processed by the processor to the connected data center through the transceiver 440. After receiving the infrared image, the data center decodes the coded information of the infrared image to obtain the location and equipment information of the infrared imaging equipment.

In the embodiments provided in the present application, it should be understood that the disclosed apparatus and method may be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units is only one logical division, and there may be other divisions when actually implemented, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of devices or units through some communication interfaces, and may be in an electrical, mechanical or other form.

In addition, units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

Furthermore, the functional modules in the embodiments of the present application may be integrated together to form an independent part, or each module may exist separately, or two or more modules may be integrated to form an independent part.

It should be noted that the functions, if implemented in the form of software functional modules and sold or used as independent products, may be stored in a computer readable storage medium. Based on such understanding, the technical solution of the present application or portions thereof that substantially contribute to the prior art may be embodied in the form of a software product stored in a storage medium and including instructions for causing a computer device (which may be a personal computer, a server, or a network device) to execute all or part of the steps of the method according to the embodiments of the present application. And the aforementioned storage medium includes: various media capable of storing program codes, such as a usb disk, a removable hard disk, a Read-Only Memory (ROM), a Random Access Memory (RAM), a magnetic disk, or an optical disk.

In this document, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions.

The above description is only an example of the present application and is not intended to limit the scope of the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. An infrared image processing method based on coding is characterized by being applied to a data center, and the method comprises the following steps:

receiving an infrared image sent by infrared imaging equipment, wherein coding information is embedded in the infrared image, and the coding information is obtained by coding the place where the infrared imaging equipment is located and equipment information according to a preset coding format;

and decoding the coded information of the infrared image according to a preset decoding format to obtain the location and equipment information of the infrared imaging equipment corresponding to the infrared image.

2. The method of claim 1, wherein the encoded information comprises a location field and a device field, wherein the location field and the device field each comprise a plurality of subfields, and wherein the plurality of subfields are encoded in a predetermined order.

3. The method according to claim 2, wherein the decoding the encoded information of the infrared image according to a preset decoding format comprises:

splitting the coding information into a place field and an equipment field according to the preset field length;

and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

4. The method of claim 2, wherein the plurality of subfields of the location field comprise: the province, the city, the county and the substation of the infrared imaging equipment; the plurality of subfields of the device field include: the manufacturer of the infrared imaging device, the device type, and the device number.

5. An infrared imaging apparatus, comprising:

the camera is used for collecting infrared images;

the processor is used for embedding the coding information stored in the memory into the infrared image collected by the camera; the coded information is obtained by coding the location of the infrared imaging equipment and the equipment information according to a preset coding format;

and the transceiver is used for sending the infrared image processed by the processor to a connected data center so that the data center can obtain the location and equipment information of the infrared imaging equipment after decoding the coded information of the infrared image according to a preset decoding format.

6. An infrared image processing device based on coding, characterized in that the device is configured in a data center, and the device comprises:

the infrared imaging device comprises a receiving module, a processing module and a processing module, wherein the receiving module is used for receiving an infrared image sent by the infrared imaging device, coding information is embedded in the infrared image, and the coding information is obtained by coding the place where the infrared imaging device is located and device information according to a preset coding format;

and the decoding module is used for decoding the coded information of the infrared image according to a preset decoding format to obtain the location and the equipment information of the infrared imaging equipment corresponding to the infrared image.

7. The apparatus according to claim 6, wherein the encoded information includes a location field and an equipment field, wherein the location field and the equipment field respectively include a plurality of subfields, and the encodings of the plurality of subfields are arranged according to a preset order, and the decoding module is specifically configured to:

splitting the coding information into a place field and an equipment field according to the preset field length;

and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

8. An infrared image processing system based on coding, comprising: the system comprises a data center and a plurality of infrared imaging devices, wherein the infrared imaging devices are respectively deployed in a plurality of substations;

the infrared imaging equipment is used for acquiring infrared images, embedding stored coding information into the acquired infrared images and sending the stored coding information to the data center, wherein the coding information is obtained by coding the places where the infrared imaging equipment is located and equipment information according to a preset coding format;

the data center is used for receiving the infrared image sent by the infrared imaging equipment, decoding the coded information of the infrared image according to a preset decoding format, and obtaining the location and equipment information of the infrared imaging equipment corresponding to the infrared image.

9. The system according to claim 8, wherein the encoded information includes a location field and an equipment field, wherein the location field and the equipment field respectively include a plurality of subfields, and the plurality of subfields are encoded according to a predetermined order, and the data center is specifically configured to: splitting the coding information into a place field and an equipment field according to the preset field length; and decoding the codes of each subfield in the location field and the equipment field respectively to obtain specific parameters represented by each subfield, and combining the specific parameters of each subfield according to a preset sequence to obtain the location and equipment information of the infrared imaging equipment.

10. A storage medium, having stored thereon a computer program which, when executed by a processor, performs the method according to any one of claims 1-4.

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