CN111611729B

CN111611729B - Resource management system based on environmental data acquisition

Info

Publication number: CN111611729B
Application number: CN202010685944.2A
Authority: CN
Inventors: 孙灵文; 栾恺; 董延朋; 孙安亲; 赵莲; 刘倩
Original assignee: Shandong Institute Of Science And Technology Development Strategy
Current assignee: Shandong Institute Of Science And Technology Development Strategy
Priority date: 2020-07-16
Filing date: 2020-07-16
Publication date: 2023-07-14
Anticipated expiration: 2040-07-16
Also published as: CN111611729A

Abstract

The invention relates to a resource management system based on environmental data acquisition, which comprises a data acquisition subsystem, a terrain simulation subsystem and a background processing subsystem; through the arrangement, the corresponding pollution monitoring information can be loaded in the terrain model in real time according to the constructed terrain, so that the corresponding pollution condition can be intuitively known, the manpower monitoring cost is greatly reduced, the response strategy can be intuitively obtained when the pollution exceeds the preset condition, and the problem of scheduling resource waste caused by artificial judgment is greatly reduced.

Description

Resource management system based on environmental data acquisition

Technical Field

The present invention relates to environmental resource management, and more particularly, to a resource management system based on environmental data collection.

Background

Urban environment resources are always an important ring for urban construction, are related to aspects of folk life, actual environment resources are extremely complex and finely divided, mainly relate to air environment quality, water area environment quality and mountain forest environment quality, and of course, urban environment management modes are that environmental workers are cleaned, urban health authorities are responsible for overall management, but are after all artificial management, particularly on water areas and mountain forests, the discovery of specific environmental problems is delayed due to too high inspection cost by manpower, and specific strategies are required to be formulated after the environmental problems are discovered, so that time and labor are consumed.

Disclosure of Invention

In view of the foregoing, it is an object of the present invention to provide a resource management system based on environmental data collection, so as to solve the above-mentioned problems.

In order to solve the technical problems, the technical scheme of the invention is as follows: the resource management system based on the environmental data acquisition comprises a data acquisition subsystem, a terrain simulation subsystem and a background processing subsystem;

the data acquisition subsystem comprises a water quality acquisition module, an air detection module and a surface pollution module, wherein the water quality acquisition module comprises a plurality of water quality detection units, and each water quality detection unit is respectively arranged at different positions corresponding to a detected area so as to acquire corresponding water quality detection information; the air detection module comprises a plurality of air quality detection units; the air quality detection units are arranged at different positions corresponding to the detected areas to acquire corresponding air quality information; the surface pollution module comprises a plurality of image acquisition units, the image acquisition units are arranged on surface pollution information of a corresponding area to be detected, the data acquisition subsystem acquires corresponding water quality detection information, air quality information and surface pollution information at intervals of a first preset time to generate acquisition data, and the acquisition data are sent to the terrain simulation subsystem;

the terrain simulation subsystem is used for configuring a terrain simulation model corresponding to a detected area, and the terrain simulation model reflects the terrain characteristics of the detected area; the terrain simulation subsystem is further configured with a dynamic loading strategy, the dynamic loading strategy comprises a loading step and a simulation step, the loading step loads corresponding coordinate positions in the terrain simulation model according to acquired acquisition data, and the simulation step comprises configuring simulation data for other coordinates of the terrain simulation model according to known distribution of the acquisition data in the terrain simulation model;

the background processing subsystem is configured with an abnormality analysis strategy, the abnormality analysis strategy is configured with a corresponding abnormality reference database, and the abnormality reference database comprises a plurality of abnormality references and response strategies; the anomaly analysis strategy sequentially judges whether the acquired data and the simulated data in the terrain simulation model accord with the corresponding anomaly references or not, and executes response instructions corresponding to the anomaly references when the acquired data and the simulated data exceed the anomaly references; and the background processing subsystem generates a response instruction according to the corresponding response strategy and executes the response instruction.

The technical effects of the invention are mainly as follows: through the arrangement, the corresponding pollution monitoring information can be loaded in the terrain model in real time according to the constructed terrain, so that the corresponding pollution condition can be intuitively known, the manpower monitoring cost is greatly reduced, the response strategy can be intuitively obtained when the pollution exceeds the preset condition, and the problem of scheduling resource waste caused by artificial judgment is greatly reduced.

Drawings

Fig. 1: the invention discloses a system architecture topological graph of a resource management system based on environmental data acquisition;

fig. 2: the invention discloses a terrain simulation model schematic diagram of a resource management system based on environmental data acquisition.

Reference numerals: 1. a terrain simulation model; 2. pollution value; 100. a data acquisition subsystem; 110. a water quality acquisition module; 120. an air detection module; 130. a surface pollution module; 200. a terrain simulation subsystem; 300. a background processing subsystem; 310. an anomaly reference database; 320. a pollution display database; 330. in response to the learning database.

Detailed Description

The following detailed description of the invention is provided in connection with the accompanying drawings to facilitate understanding and grasping of the technical scheme of the invention.

A resource management system based on environmental data acquisition, comprising a data acquisition subsystem 100, a terrain simulation subsystem 200 and a background processing subsystem 300; firstly, three systems and the purpose of the invention are basically described, the first part is a data acquisition module, the data acquisition subsystem 100 forms the data acquisition subsystem 100 through set hardware and a communication network, and is mainly used for replacing manual monitoring of pollution conditions and real-time analysis to acquire the latest pollution information, the terrain simulation subsystem 200 is a core technical point in the invention, firstly, simulation is carried out aiming at specific terrains, the specific terrains comprise height differences and coverage characteristics (river, vegetation, soil or rock), a three-dimensional characteristic view capable of being dataized is constructed, and the view has the functions of display output and characteristic analysis; the third part is a background processing subsystem 300, which aims to process the acquired data and update the terrain simulation model 1 in real time, and then intelligently analyze and output corresponding response strategies according to the quantized features on the terrain simulation model to feed back pollution conditions.

The data acquisition subsystem 100 comprises a water quality acquisition module 110, an air detection module 120 and a surface pollution module 130, wherein the water quality acquisition module 110 comprises a plurality of water quality detection units, and each water quality detection unit is respectively arranged at different positions corresponding to a detected area so as to acquire corresponding water quality detection information; the air detection module 120 includes a plurality of air quality detection units; the air quality detection units are arranged at different positions corresponding to the detected areas to acquire corresponding air quality information; the surface pollution module 130 includes a plurality of image acquisition units, the image acquisition units are arranged on surface pollution information corresponding to the area to be detected, the data acquisition subsystem 100 acquires corresponding water quality detection information, air quality information and surface pollution information every a first preset time to generate acquisition data, and the acquisition data are sent to the terrain simulation subsystem 200; the image acquisition units comprise a pollution positioning algorithm, the pollution positioning algorithm comprises background features and corresponding carry-over time which are configured corresponding to each image acquisition unit, the pollution positioning algorithm judges abnormal features in image information acquired in real time according to the background features and follows the abnormal features, and when the retention time of the abnormal features in the image information exceeds the preset carry-over time, corresponding surface pollution information is generated. The detection items of the water quality detection unit can be turbidity, PH value, heavy metal content, phosphorus content and the like, and can be realized by a water quality detector, and the air quality detection can be air humidity, dust density and the like, and can be realized by an air quality detector; the surface pollution module 130 is mainly configured to determine whether the surface has pollutants such as garbage by combining image acquisition and image recognition, so as to obtain pollution conditions of different positions by three methods above isomorphism.

The terrain simulation subsystem 200 is used for configuring a terrain simulation model 1 corresponding to a detected area, wherein the terrain simulation model 1 reflects the terrain characteristics of the detected area; the terrain simulation subsystem 200 is further configured with a dynamic loading strategy, the dynamic loading strategy comprising a loading step of loading in corresponding coordinate positions in the terrain simulation model 1 according to acquired acquisition data, and a simulation step of configuring simulation data for other coordinates of the terrain simulation model 1 according to known distribution of the acquisition data in the terrain simulation model 1; the input illustrates that firstly, the loading step is set, the loading step is generated according to the acquired data, and as the relative position of the corresponding detection unit in the terrain simulation model 1 is a known quantity, the coordinates corresponding to the acquired data can be loaded, but the pollution information of each coordinate needs to be constructed, the pollution quantity of other coordinates needs to be "deduced" according to the acquired coordinate quantity, and the pollution condition between two points can be calculated; in this way, the pollution condition can be updated in real time according to the content and presented in the terrain simulation model 1 of the terrain simulation subsystem 200. Referring to fig. 2, the terrain simulation model 1 is a middle part, and is a lower part after being loaded into a three-dimensional picture according to the terrain features, and the pollution value is the uppermost part according to the terrain simulation model 1, so that the pollution condition of each position can be known.

The background processing subsystem 300 is configured with an anomaly analysis strategy, the anomaly analysis strategy is configured with a corresponding anomaly reference database 310, and the anomaly reference database 310 comprises a plurality of anomaly references and response strategies; first, an anomaly reference and a response strategy are adopted, and in the same pollution display information, the colors of the display samples are different. The abnormal reference comprises a ground surface reference pollution value 2 and a reference ground surface pollution area, coordinates with the pollution value 2 higher than the ground surface reference pollution value 2 are screened, and when the area corresponding to the coordinates is larger than the reference ground surface pollution area, the abnormal reference is judged to be exceeded; and the abnormal reference comprises an air reference pollution value 2 and a reference air pollution area, coordinates with the pollution value 2 higher than the reference air pollution value 2 are screened, and when the area corresponding to the coordinates is larger than the reference air pollution area, the abnormal reference is judged to be exceeded. The abnormal reference comprises a pollution deepening reference value, a difference value between a pollution value 2 at the moment after each coordinate and the pollution value 2 at the moment before is calculated to be the pollution deepening value, and when the pollution deepening value is larger than the pollution deepening reference value, the abnormal reference is judged to be exceeded. The abnormal reference judges abnormal conditions, such as garbage on the earth surface, floaters in the air and exceeding a certain content of water quality, and corresponding processing modes, namely response strategies, are preset according to the conditions, are prestored in a corresponding abnormal reference database 310, so that a response result can be directly obtained once the abnormal conditions occur, human intervention is not needed, the background also comprises a display function, the display function displays a corresponding model diagram, the model reflects specific pollution conditions, and a user is helped to judge the pollution conditions more intuitively, and the method is realized by the following steps: the display policy is configured with a pollution display database 320, the pollution display database 320 stores pollution display information, the pollution display information uses a topography feature as an index, the pollution display information includes a display sample and a pollution value 2 corresponding to the display sample, the display policy includes screening the corresponding pollution display information according to the topography feature, calling the corresponding display sample according to the pollution value 2, loading the display sample into the topography simulation model 1 to obtain a display model, and the background processing subsystem 300 outputs the display model. The original pollution condition is displayed by calling a display sample, a terrain simulation model 1 corresponding to the terrain features is replaced in an image mode, a display model can be obtained, then the display model is intuitively output, the anomaly analysis strategy sequentially judges whether acquired data and simulated data in the terrain simulation model 1 accord with corresponding anomaly references or not, and when the acquired data and the simulated data exceed the anomaly references, a response instruction corresponding to the anomaly references is executed; the background processing subsystem 300 generates and executes a response instruction according to the corresponding response policy. The background processing subsystem 300 further comprises a numerical conversion strategy for quantifying the acquired data and the simulated data in the terrain simulation model 1 into pollution values 2, respectively. The background processing subsystem 300 is configured with a response learning database 330, the response learning database 330 stores a response instruction set, the response instruction set is written into the response learning database 330 in advance by the background, the response instruction set comprises a plurality of response instructions, the response instruction set takes a response strategy set as a first index, and when the obtained set of response strategies is the response strategy set, the first index is matched; the response instruction set takes the topographic feature set as a second index, and when the obtained topographic feature set is the topographic feature set, the second index is matched; the background processing subsystem 300 filters out the response instruction set output for which both the first index and the second index are matched. And when the first index or the second index is not matched, outputting the response strategy and the display model to a background terminal, waiting for the background terminal to feed back a response instruction set, and storing the response instruction set fed back by the background terminal to the learning database. When the first index or the second index is not matched, selecting the corresponding index according to the matching degree. While the response learning strategy is another key of the present invention, it should be noted that, in response to the problem that the learning database 330 solves the problem that multiple pollution situations are concurrent (which is a common phenomenon at present), in the problem that multiple situations are concurrent, because the complexity of the environment is relatively high, the final strategy is often formulated depending on human judgment, but the present solution extracts the core features, the first is the response strategy, because the response strategy is a necessary matter, and the available personnel, equipment, paths, modes, etc. need to be considered, the first index is determined according to the combination of the response strategies, and in this process, compared with the abnormal quantity corresponding to the abnormal reference, the data quantity may be increased, but in spite of the fact that the processing speed of the data storage quantity and the data processing speed is relatively high, because in the response strategy, the redundancy between each response strategy is relatively high in practice, the comparison efficiency can be greatly improved when processing, and in comparison, the error is relatively easy to correct data once the corresponding topography is considered, in order, and in this process, the relevant environmental features need to be considered, for example, the environmental factors need to be more than the environment is required to be established, and the relevant factors need to be output. It should be noted that, because the response instruction is preset by an expert, the situation that the index fails occurs, and then the background is needed to perform manual judgment and supplement is needed, and preferably, the background can make judgment faster by selecting the corresponding response instruction output by the background.

Of course, the above is only a typical example of the invention, and other embodiments of the invention are also possible, and all technical solutions formed by equivalent substitution or equivalent transformation fall within the scope of the invention claimed.

Claims

1. The resource management system based on environmental data acquisition is characterized in that: the system comprises a data acquisition subsystem, a terrain simulation subsystem and a background processing subsystem;

the background processing subsystem is configured with an abnormality analysis strategy, the abnormality analysis strategy is configured with a corresponding abnormality reference database, and the abnormality reference database comprises a plurality of abnormality references and response strategies; the anomaly analysis strategy sequentially judges whether the acquired data and the simulated data in the terrain simulation model accord with the corresponding anomaly references or not, and executes response instructions corresponding to the anomaly references when the acquired data and the simulated data exceed the anomaly references; the background processing subsystem generates a response instruction according to the corresponding response strategy and executes the response instruction;

the background processing subsystem further comprises a numerical conversion strategy, wherein the numerical conversion strategy is used for respectively quantifying collected data and simulated data in the terrain simulation model into pollution values;

the image acquisition units comprise a pollution positioning algorithm, wherein the pollution positioning algorithm comprises background features and corresponding carry-over time which are configured corresponding to each image acquisition unit, the pollution positioning algorithm judges abnormal features in image information acquired in real time according to the background features and follows the abnormal features, and when the retention time of the abnormal features in the image information exceeds the preset carry-over time, corresponding surface pollution information is generated;

the abnormal reference comprises a ground surface reference pollution value and a reference ground surface pollution area, coordinates with the pollution value higher than the ground surface reference pollution value are screened, and when the area corresponding to the coordinates is larger than the reference ground surface pollution area, the abnormal reference is judged to be exceeded;

the abnormal reference comprises a configured air reference pollution value and a reference air pollution area, coordinates with the pollution value higher than the reference air pollution value are screened, and when the area corresponding to the coordinates is larger than the reference air pollution area, the abnormal reference is judged to be exceeded;

the abnormal reference comprises a pollution deepening reference value, a difference value between a pollution value at the next moment and a pollution value at the previous moment of each coordinate is calculated to be the pollution deepening value, and when the pollution deepening value is larger than the pollution deepening reference value, the abnormal reference is judged to be exceeded;

the background processing subsystem is configured with a response learning database, the response learning database stores a response instruction group, the response instruction group is written into the response learning database in advance by the background, the response instruction group comprises a plurality of response instructions, the response instruction group takes a response strategy group as a first index, and when the obtained set of response strategies is the response strategy group, the first index is matched; the response instruction set takes the topographic feature set as a second index, and when the obtained topographic feature set is the topographic feature set, the second index is matched; the background processing subsystem screens the response instruction group output with the matched first index and second index;

and when the first index or the second index is not matched, outputting the response strategy and the display model to a background terminal, waiting for the background terminal to feed back a response instruction set, and storing the response instruction set fed back by the background terminal to the learning database.

2. A resource management system based on environmental data collection as claimed in claim 1, wherein: the background processing subsystem further comprises a display strategy, the display strategy is configured with a pollution display database, pollution display information is stored in the pollution display database, the pollution display information takes the terrain features as indexes, the pollution display information comprises display samples and pollution values corresponding to the display samples, the display strategy comprises screening the corresponding pollution display information according to the terrain features, calling the corresponding display samples according to the pollution values, loading the display samples into the terrain simulation model to obtain a display model, and the background processing subsystem outputs the display model.

3. A resource management system based on environmental data collection as claimed in claim 2, wherein: in the same pollution display information, the colors of the display samples are different.