CN111651551B - Smart city supervision system and method - Google Patents

Abstract

The invention discloses a smart city supervision system, and belongs to the processing technology of public service utilities. The system comprises a plurality of mobile operation ends, an operation management end, an operation database, a plurality of supervision ends, a storage unit, a geocode base, a data extraction unit, a built-in management unit and a remote management unit. The supervising end shoots the image file containing the mobile operation vehicle, the image file is firstly audited by the built-in management unit of the invention, and if the audit is not passed, the problem event instruction is directly output. If the audit is passed, the corresponding department performs image audit, so that the audit speed is improved. The invention also discloses a smart city supervision method.

Description

Smart city supervision system and method

Technical Field

The invention relates to a processing technology for public service, in particular to a smart city supervision system and a smart city supervision method.

Background

Smart city management may be participated by the public who uploads city management data via a portable electronic device. A cloud data based digital city management data sharing system such as CN 105023188A. The smart city management relates to the management of the working vehicle, in particular to whether the working content and the working position of the working vehicle meet the requirements or not. For example, CN107203158A discloses an illegal construction site identification method based on muck work. The method comprises the steps of firstly obtaining a stopping point of a muck vehicle in driving and extracting an unauthenticated place in the stopping point. And judging whether the unauthenticated site is an illegal construction site according to the working condition of the muck truck at the unauthenticated site.

The identification of the work vehicle can refer to the license plate of the work vehicle. CN106257500B relates to an intelligent operation and inspection management system for road sanitation and cleaning, which comprises a management server, a plurality of identification boards at least internally provided with an ultrahigh frequency RFID electronic tag, and a plurality of intelligent terminals. In addition, the management server of the system is provided with an electronic map interface. The electronic map is used to identify the location of the vehicle. In addition, a method for recognizing the position of a vehicle by constructing a map is also disclosed in a smart city-based environmental sanitation supervision method of CN 110874696A. The method comprises the steps of constructing a three-dimensional supervision view of the urban sanitation, and dividing the three-dimensional supervision view of the urban sanitation into a plurality of three-dimensional visual management areas; and constructing a transportation network map and a sanitation personnel cleaning scheme for the sanitation vehicles in each three-dimensional visual management area.

With the progress of network technology and the improvement of monitoring consciousness of citizens, more and more city management software is provided with citizen access ports. The citizen can be connected with the urban management system through the mobile phone and upload the photos of the working vehicle in the abnormal working state at any time. In the prior art, the operation vehicle mainly adopts a manual mode to check the operation photos. For various operation vehicles of multiple departments, different auditing authorities exist, and feedback supervision delay is caused by multi-level data processing paths.

Disclosure of Invention

The invention provides a smart city supervision system and a smart city supervision method, which are used for citizen supervision of mobile operation and improve the feedback efficiency of supervision departments.

A smart city supervision system, characterized by comprising:

the mobile operation ends are used for moving operation in a preset area;

the system comprises an operation management end, a time collection and a geocoding collection, wherein the operation management end is used for generating a plurality of groups of standard operation files, and each standard operation file consists of an identification collection, a time collection and a geocoding collection which are mutually associated;

the operation database is used for storing standard operation files of a plurality of mobile operation ends;

the system comprises a plurality of supervision terminals, a plurality of image processing modules and a plurality of image processing modules, wherein the supervision terminals are used for generating image files, each supervision terminal comprises an image acquisition module, a time module and a positioning module, and each image file comprises identification data, time data and position data;

a storage unit for storing image files;

the geographic coding library is used for storing geographic coding data of a preset area and corresponding position data;

the data extraction unit is used for extracting identification data, time data and position data from the image file and calling a geocode library to generate a field operation file, wherein the field operation file comprises the identification data, the time data and the geocode data of the mobile operation end;

the built-in management unit is used for comparing the field operation file with the standard operation file, sending an instruction for submitting the image file to the storage unit if the field operation file is consistent with the standard operation file, and sending a problem event instruction to the operation management end if the field operation file is not consistent with the standard operation file;

the remote management units are used for examining the image files and sending legal event instructions to the supervision terminal if the image files meet preset standards; and if the image file does not meet the preset standard, sending a problem event instruction to the operation management end.

In the invention, the monitoring end is a portable electronic device, the positioning module is a GPS positioning module, and the position data is longitude and latitude data.

In the invention, the mobile operation end is an urban operation vehicle, and the identification data is a license plate number.

In the invention, the identification set, the time set and the geocode set of at least one group of standard operation files all contain identification data, time data and geocode data of the field operation file, and then the field operation file is consistent with the standard operation file.

In the invention, the identification set comprises at least one piece of identification data, the time set comprises at least one piece of time data, and the geocode set comprises at least one piece of geocode data.

In the invention, the smart city supervision system further comprises a cooperative work unit, the cooperative work unit is connected with the storage unit and the plurality of remote management units, and the cooperative work unit is used for sending the image file to the corresponding remote management unit according to the identification data.

In the invention, the smart city supervision system further comprises an evaluation output unit, wherein the evaluation output unit acquires the problem event instructions of the built-in management unit and/or the remote management unit and counts the problem event instructions of different identification data.

A smart city supervision method is characterized by comprising the following steps:

the mobile operation end moves and operates in a preset area;

generating a plurality of groups of standard operation files, wherein the standard operation files consist of an identification set, a time set and a geocoding set which are mutually associated;

storing standard operation files of a plurality of mobile operation ends;

generating an image file, wherein the image file comprises identification data, time data and position data;

storing the image file;

storing the geographic coding data and the corresponding position data of a preset area;

extracting identification data, time data and position data from the image file, and calling a geocode library to generate a field operation file, wherein the field operation file comprises the identification data, the time data and the geocode data of the mobile operation end;

comparing the field operation file with the standard operation file, if the field operation file is consistent with the standard operation file, sending an instruction for submitting the image file to a storage unit, and if the field operation file is not consistent with the standard operation file, sending a problem event instruction to an operation management end;

examining the image file, and if the image file meets a preset standard, sending a legal event instruction to a supervision terminal; and if the image file does not meet the preset standard, sending a problem event instruction to the operation management end.

In the invention, the preset area is divided into a plurality of rectangular areas, each geocoded data represents a rectangular area, and the geocoded data comprises a coding serial number and boundary coordinates.

According to the intelligent city supervision system and method, the supervision end shoots the image file containing the mobile operation vehicle, the image file is firstly audited by the built-in management unit, and if the audit does not pass, the problem event instruction is directly output. If the audit is passed, the corresponding department performs image audit, so that the audit speed is improved.

Drawings

FIG. 1 is a block diagram of an embodiment of the smart city supervisor system of the present invention;

FIG. 2 is a block diagram of another embodiment of the smart city supervisor system of the present invention;

FIG. 3 is a schematic diagram of the usage of the smart city supervision system according to the present invention;

FIG. 4 is a schematic diagram of an image file according to the present invention;

fig. 5 is a flowchart of the smart city supervision system method according to the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention.

The smart city supervision system of the present invention as shown in fig. 1 comprises a plurality of mobile operation terminals, an operation management terminal, an operation database, a plurality of supervision terminals, a storage unit, a geocoding database, a data extraction unit, a built-in management unit and a remote management unit. The mobile operation end is generally an operation vehicle, and comprises a cleaning vehicle, a slag transport vehicle, a road maintenance vehicle and the like. The operation management terminal is a management terminal of a department where the operation vehicle is independently arranged. The supervision terminal can be a mobile phone of a user. The operation database, the storage unit, the data extraction unit and the built-in management unit can be accommodated in the same group of central servers, the central servers are respectively communicated with the operation management end, the supervision end, the geocode base and the remote management unit, and the communication mode can be 4G, 5G or broadband network. The remote management unit is an independent management terminal of a related department, such as a management terminal of an urban construction department, a management terminal of an environmental protection department, a management terminal of a fire protection department, a management terminal of a transportation department and the like, and different management terminals are used for checking whether image files in the authority range of the remote management unit accord with preset standards. Fig. 2 is an extended smart city supervision system, further having a cooperative work unit and an evaluation output unit. The cooperative work unit is used for synchronously managing the central server and the remote management unit and rapidly distributing image files managed by different departments. And the evaluation output unit is used for calling data of the built-in management unit and the remote management unit and outputting intuitive statistical data.

The application scenario of the intelligent city supervision system of the invention refers to fig. 3. The operation management terminal 06 of the environmental protection department records operation data of a certain cleaning vehicle and stores standard operation files in an operation database. The cleaning vehicle 01 is present near the road and the cleaning vehicle 01 directs debris into the underground sewer piping 02. The commercial and civilian handsets 03 capture this process and upload to the central server 04 (storage unit). The central server 04 (data extraction means) extracts data from the captured image file, and generates a field job file. The central server 04 (built-in management unit) performs a first comparison analysis to determine whether the cleaning vehicle 01 meets the time requirement and the position requirement of the standard job file. If the requirement is not met, the cleaning vehicle 01 is indicated to have abnormal operation, and a problem event is defined. If the requirements are met, the supervision department terminal 05 (remote management unit) of the cleaning department audits the image files, and if the cleaning vehicle 01 is found to lead sundries into the underground sewage pipeline, the problem events are defined, and the rectification requirements are sent. The image file is firstly audited by the built-in management unit, and if the audit is not passed, the problem event instruction is directly output. If the audit is passed, the corresponding department terminal checks the image, so that the processing speed is improved, the phenomenon of kicking the leather ball is avoided, and information is more effectively fed back to citizens.

The detailed structure of each part of the system is as follows. The mobile operation end moves and operates in a preset area. And the operation management terminal generates a plurality of groups of standard operation files, wherein the standard operation files consist of an identification set, a time set and a geocoding set which are mutually associated. The job management terminal is used for managing a plurality of mobile job terminals. The job management terminal distributes job contents to each mobile job terminal. The standard job file is used for recording the job data of each mobile job end. For example, slag transport vehicles with the license plate numbers of Shanghai A37231, A37232, A37257 and A37258 operate in the areas with geographic codes of 768295196129, 768295196130, 768295196131 and 768295196132 from 03 months, 15 days, 03 to 06 days and 22 to 23 days. The data structure of its standard job file is, for example, [ a37231, a37232, a37257, a 37258), (031503000600, 031522002300), (768295196129, 768295196130, 768295196131, 768295196132 ]. Generally, a plurality of slag trucks in the operation area can be contained, so that the identification set comprises at least one identification datum. A time set is typically a job time period, which typically includes at least one time datum (point-in-time datum). The work area may be multiple, and the geocode set includes at least one geocode data. And, since the location of the photograph taken may differ from the actual location of the slag car, the geocode set may be augmented around a central location.

The job database stores standard job files of a plurality of mobile job terminals. The various job management sides send standard job files to a remote job database.

The supervision terminal generates an image file, the supervision terminal comprises an image acquisition module, a time module and a positioning module, and the image file comprises identification data, time data and position data. The monitoring end is a portable electronic device such as a smart phone. An image acquisition module (camera) of the smart phone can capture image data, and the smart phone is provided with a GPS positioning module and provides longitude and latitude data of an image file. The time module of the smartphone may provide the time of capture of the image file.

The storage unit stores an image file. The storage unit may be a remote non-transitory storage device for receiving the data packet sent by the monitoring end.

The geocode library stores position data of a preset area and corresponding geocode data. The geocode library may be a map data service provided by a third party. And the third-party server sets a coding rule, and can obtain corresponding geocoded data according to any position data in the preset area. The present invention can be referred to the existing encoding methods, for example, CN201210130908.5, PCT/US2008/003798, etc. The preset area is divided into a plurality of rectangular areas, each geocoded data represents a rectangular area, and the geocoded data comprises a coding serial number and boundary coordinates.

The data extraction unit extracts identification data, time data, and position data from the image file. Referring to fig. 4, the image file has an image area 11 on the front, a time display area 12 in the lower right corner, and a position display area 13 in the lower left corner. The data extraction unit extracts identification data such as a license plate number 14 from the image area 11, extracts a shooting time from the time display area 12, and extracts a shooting position from the position display area 13. The data extraction unit is, for example, a character recognition system or software, and can recognize the time, license plate number, and position characters of a predetermined area. And the data extraction unit calls the geocode library, calls geocode data which are consistent with the position data from the geocode library, and finally generates a field operation file. The field operation file comprises identification data, time data and geographic coding data of the mobile operation end.

And the built-in management unit compares the field operation file with the standard operation file. If the field operation file is in accordance with the standard operation file, an instruction for submitting the image file is sent to the storage unit, and if the field operation file is not in accordance with the standard operation file, a problem event instruction is sent to the operation management terminal. Specifically, the identifier set, the time set, and the geocode set of at least one group of standard operation files all include identifier data, time data, and geocode data of the field operation file, and then the field operation file conforms to the standard operation file. And at least one item of the identification data, the time data and the geocoding data of the field operation file does not belong to the identification set, the time set and the geocoding set of the standard operation file, and the field operation file does not accord with the standard operation file.

The remote management units examine the image files and send legal event instructions to the supervision terminal if the image files meet preset standards; and if the image file does not meet the preset standard, sending a problem event instruction to the operation management end. The preset standard refers to the working requirements of a supervision department on the mobile operation ends of a slag transport vehicle and the like, such as dust height, sewage discharge, lane occupation and the like. An operator can judge whether the slag transport vehicle meets the requirements or not according to the image file, and if the slag transport vehicle does not meet the requirements, a problem event is output and the requirements are modified. And if the standard is met, outputting a legal event.

The cooperative work unit is connected with the storage unit and the plurality of remote management units, and the cooperative work unit is used for sending the image file to the corresponding remote management unit according to the identification data. The command center dispatchers dispatch different cases to different professional departments for processing aiming at specific case information, the professional departments acquire the information and process the cases, the information is fed back to the command center after the processing is finished, and the command center acquires the information and prepares to feed back the information to the supervision center. The data integration service comprising the operations of extraction, conversion, transmission, loading and the like is provided for interconnection and intercommunication among different databases of cross-region, cross-department and cross-application systems.

And the evaluation output unit acquires the problem event instructions of the built-in management unit and/or the remote management unit and counts the problem event instructions of different identification data. And through a post evaluation system, counting the historical data according to post operation, generating a data list of the working state and the effect of the post according to the pre-made evaluation requirement, and displaying the post evaluation effect in a table mode according to the pre-made evaluation standard. And calculating and counting the historical data according to unit areas through an area evaluation system to generate a data list of unit area city management effects, and visually displaying the unit area management effects according to different colors according to a pre-made grading standard.

As shown in fig. 5, the smart city supervision method of the present invention includes the following steps:

the mobile operation end moves and operates in a preset area.

And generating a plurality of groups of standard operation files, wherein the standard operation files consist of an identification set, a time set and a geocoding set which are mutually associated.

And storing standard job files of a plurality of mobile job terminals.

Generating an image file, wherein the image file comprises identification data, time data and position data;

the image file is stored.

And storing the geographic coding data of the preset area and the corresponding boundary coordinates. The preset area is divided into a plurality of rectangular areas, each geocoded data represents a rectangular area, and the geocoded data comprises a coding serial number and boundary coordinates.

And extracting identification data, time data and position data from the image file, and calling a geocode library to generate a field operation file, wherein the field operation file comprises the identification data, the time data and the geocode data of the mobile operation end.

And comparing the field operation file with the standard operation file, if the field operation file is consistent with the standard operation file, sending an instruction for submitting the image file to the storage unit, and if the field operation file is not consistent with the standard operation file, sending a problem event instruction to the operation management terminal.

Examining the image file, and if the image file meets a preset standard, sending a legal event instruction to a supervision terminal; and if the image file does not meet the preset standard, sending a problem event instruction to the operation management end.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (9)

1. A smart city supervision system, characterized by comprising:

the mobile operation ends are used for moving operation in a preset area;

the system comprises an operation management end, a time collection and a geocoding collection, wherein the operation management end is used for generating a plurality of groups of standard operation files, and each standard operation file consists of an identification collection, a time collection and a geocoding collection which are mutually associated;

the operation database is used for storing standard operation files of a plurality of mobile operation ends;

the system comprises a plurality of supervision terminals, a plurality of image processing modules and a plurality of image processing modules, wherein the supervision terminals are used for generating image files, each supervision terminal comprises an image acquisition module, a time module and a positioning module, and each image file comprises identification data, time data and position data;

a storage unit for storing image files;

the geographic coding library is used for storing geographic coding data of a preset area and corresponding position data;

the data extraction unit is used for extracting identification data, time data and position data from the image file and calling a geocode library to generate a field operation file, wherein the field operation file comprises the identification data, the time data and the geocode data of the mobile operation end;

the built-in management unit is used for comparing the field operation file with the standard operation file, sending an instruction for submitting the image file to the storage unit if the field operation file is consistent with the standard operation file, and sending a problem event instruction to the operation management end if the field operation file is not consistent with the standard operation file;

the remote management units are used for examining the image files and sending legal event instructions to the supervision terminal if the image files meet preset standards; and if the image file does not meet the preset standard, sending a problem event instruction to the operation management end.

2. The intelligent city supervision system according to claim 1, wherein the supervision terminal is a portable electronic device, the positioning module is a GPS positioning module, and the location data is latitude and longitude data.

3. The intelligent city supervision system according to claim 1, wherein the mobile operation terminal is a city operation vehicle, and the identification data is a license plate number.

4. The intelligent city supervision system according to claim 1, wherein the identification set, time set and geocode set of at least one set of standard operation files contain identification data, time data and geocode data of the field operation file, so that the field operation file is consistent with the standard operation file.

5. The intelligent city supervision system according to claim 4, wherein the identification set includes at least one identification data, the time set includes at least one time data, and the geocode set includes at least one geocode data.

6. The smart city supervision system according to claim 1, further comprising a cooperative unit connecting the storage unit and the plurality of remote management units, the cooperative unit being configured to send the image file to the corresponding remote management unit according to the identification data.

7. The smart city supervision system according to claim 1, further comprising an evaluation output unit, wherein the evaluation output unit obtains the problem event instructions of the built-in management unit and/or the remote management unit, and counts the problem event instructions of different identification data.

8. A smart city supervision method is characterized by comprising the following steps:

the mobile operation end moves and operates in a preset area;

generating a plurality of groups of standard operation files, wherein the standard operation files consist of an identification set, a time set and a geocoding set which are mutually associated;

storing standard operation files of a plurality of mobile operation ends;

generating an image file, wherein the image file comprises identification data, time data and position data;

storing the image file;

storing the geographic coding data and the corresponding position data of a preset area;

extracting identification data, time data and position data from the image file, and calling a geocode library to generate a field operation file, wherein the field operation file comprises the identification data, the time data and the geocode data of the mobile operation end;

comparing the field operation file with the standard operation file, if the field operation file is consistent with the standard operation file, sending an instruction for submitting the image file to a storage unit, and if the field operation file is not consistent with the standard operation file, sending a problem event instruction to an operation management end;

examining the image file, and if the image file meets a preset standard, sending a legal event instruction to a supervision terminal; and if the image file does not meet the preset standard, sending a problem event instruction to the operation management end.

9. The intelligent city supervision method according to claim 8, wherein the predetermined area is divided into a plurality of rectangular areas, each geocoded data represents a rectangular area, and the geocoded data comprises a coding sequence number and boundary coordinates.

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