Search

CN-121436606-B - Environment-friendly control and management platform operation method for accessing mass monitoring terminals

CN121436606BCN 121436606 BCN121436606 BCN 121436606BCN-121436606-B

Abstract

The application discloses an operation method of an environment-friendly management and control platform accessed by a mass monitoring terminal, and relates to the technical field of data calculation; the method comprises the steps of calculating to obtain historical state weights of various points at the same moment every day based on pollution intensity, time difference between various environmental monitoring data at different moments and the last pollution moment and the ratio of pollution occurrence of various points at the same moment in the historical moment, calculating to obtain real-time triggering weights of various environmental monitoring data corresponding to various points based on the integral pollution level corresponding to the pollution intensity and the pollution intensity trend, calculating to obtain pollution weights of different points at the current moment based on the historical state weights and the real-time triggering weights, and determining real-time bandwidth allocation proportion of various monitoring terminals based on the pollution weights.

Inventors

  • FANG CHEN
  • LIANG DU
  • YANG JIE

Assignees

  • 北京易玖智能科技有限公司

Dates

Publication Date
20260512
Application Date
20251231

Claims (8)

  1. 1. An operation method of an environment-friendly management and control treatment platform accessed by a mass monitoring terminal is characterized by comprising the following steps: Environmental monitoring data of different points reported by each monitoring terminal in the environmental protection management platform are obtained, and pollution intensity of the environmental monitoring data of different types is determined; based on the pollution intensity, the time difference between different times and the last pollution existing time of various environmental monitoring data and the duty ratio of pollution of each point in the historical time at the same time every day, the historical state weights of each time of different points are calculated, and the method specifically comprises the following steps: Calculating to obtain historical pollution discharge evaluation values of all points based on the pollution intensity and the time difference between different moments and the last moment of pollution existence of various environmental monitoring data; Calculating the repetition rate of pollution of different points at each moment based on the proportion of pollution of each point at the same moment in each day in the historical moment; Based on the repetition rate and the historical pollution discharge evaluation value, calculating to obtain historical state weights of different points at all moments, wherein the historical state weights The calculation mode of (2) is as follows: ; Wherein: a historical blowdown evaluation value representing the ith point, Indicating the repetition rate of pollution at the ith point in time at the (r) th point, Representing a preset repetition rate threshold; Based on the overall pollution level and the pollution intensity trend corresponding to the pollution intensity, calculating to obtain the real-time trigger weight of the environmental monitoring data of different types corresponding to each point location, wherein the real-time trigger weight comprises the following specific steps: Selecting all moments in a preset time period before the current moment as trigger lengths; For any point location, determining a first average value of pollution intensity of various environmental monitoring data of the current point location; Determining the overall pollution level of the environmental monitoring data of different types corresponding to each point location based on the difference value between the first average value and a preset pollution threshold value; calculating to obtain a pollution intensity trend value based on the difference between the pollution intensity at any time in the triggering length and the average value of the pollution intensity before the adjacent time at the current time; Calculating a real-time trigger weight of the environmental monitoring data of different types corresponding to each point location based on a normalized value of a product between the overall pollution level and the pollution intensity trend value, wherein the real-time trigger weight The calculation mode of (2) is as follows: ; wherein: a first average of all pollution intensities over the trigger length for the kth class data representing the ith point, Representing a preset contamination threshold for the kth class of data, Indicating the length of the trigger is indicated, Represents the pollution intensity of the kth class data at the ith point in the trigger length at the ith moment, The average value of pollution intensity of the kth class data representing the ith point position at the l-1 moment before the triggering length, Indicating the overall contamination level of the current trigger length, A pollution intensity trend value is represented; based on the historical state weight and the real-time triggering weight, calculating pollution weights of different points at the current moment, The pollution weight The calculation mode of (2) is as follows: ; Wherein, the Represents the historical state weight of the ith point in time at the (r) th moment, All surrounding points representing the ith point are at the real-time trigger weights at the current time, The weight maximum value of the real-time triggering weight of all kinds of environment monitoring data of the ith point location; and determining the real-time bandwidth allocation proportion of each monitoring terminal based on the pollution weight, so as to dynamically allocate the uploading bandwidth of each monitoring terminal based on the real-time bandwidth allocation proportion, and stably transmitting the environment monitoring data.
  2. 2. The method for operating an environmental protection management and control platform accessed by a mass monitoring terminal according to claim 1, wherein the calculating to obtain the historical pollution discharge evaluation value of each point location based on the pollution intensity and the time difference between the different time and the previous pollution existing time of each environmental monitoring data comprises: Determining a first ratio between the time difference between different moments of various environmental monitoring data and the last moment of pollution and the pollution intensity; And carrying out summation and averaging processing on the first ratio according to the total time corresponding to all the environmental monitoring data, and calculating to obtain the historical pollution discharge evaluation value of each point.
  3. 3. The method for operating an environmental protection management and control platform accessed by a mass monitoring terminal according to claim 1, wherein the calculating the repetition rate of pollution of different points at each time based on the proportion of pollution of each point at the same time every day in the historical time comprises: For any point location, determining a first day of environment monitoring data transmitted by the current point location in a historical time period and a pollution intensity maximum value of various environment monitoring data of the current point location at different times of day; Determining the proportion of the pollution occurrence ratio of each point in the historical moment at the same moment every day based on the maximum pollution intensity and the first days; and determining the repetition rate of pollution at different points at each moment based on the normalized value of the duty ratio.
  4. 4. The method for operating an environmental protection management and control platform accessed by a mass monitoring and control terminal according to claim 1, wherein the calculating the historical state weights of different points at different moments based on the repetition rate and the historical pollution discharge evaluation value comprises: comparing the repetition rate of all the moments of each point location with a preset repetition rate threshold value, and marking the corresponding moment of the repetition rate larger than the preset repetition rate threshold value as high-demand moment; Determining an adjustment coefficient of the historical pollution discharge evaluation value based on a difference value between the repetition rate of the high-demand time and a preset repetition rate threshold; and calculating the historical state weights of different points at different moments based on the normalized value of the product between the adjustment coefficient and the historical pollution discharge evaluation value.
  5. 5. The method for operating an environmental protection management and control platform accessed by a mass monitoring terminal according to claim 1, wherein the calculating the pollution weights of different points based on the historical state weights and the real-time trigger weights comprises: For any point location, determining the real-time trigger weights of all the point locations in a preset range around the current point location at the current moment and the maximum weight value of the real-time trigger weights of all the environmental monitoring data of the current point location; and calculating pollution weights of different points at the current moment based on the product among the historical state weights, the real-time triggering weights and the maximum weights.
  6. 6. The method for operating an environmental protection management and control platform accessed by a mass monitoring and control terminal according to claim 1, wherein after calculating the real-time trigger weight of different types of environmental monitoring data corresponding to each point location based on the overall pollution level and the pollution intensity trend corresponding to the pollution intensity, the method further comprises: Comparing the real-time trigger weight with a preset trigger threshold, and if the real-time trigger weight is larger than the preset trigger threshold, mobilizing a monitoring terminal to shoot the point corresponding to the real-time trigger weight; when the monitoring terminal shoots that emission behaviors exist at any point, performing gain processing on the real-time trigger weight of the current point to obtain the real-time trigger weight after gain; The pollution weights of different points at the current moment are calculated based on the historical state weights and the real-time triggering weights, and the pollution weights comprise: and calculating pollution weights of different points at the current moment based on the historical state weights and the gained real-time trigger weights.
  7. 7. The method for operating an environmental protection management and control platform accessed by mass monitoring and control terminals according to claim 1, wherein the determining the real-time bandwidth allocation proportion of each monitoring and control terminal based on the pollution weight comprises: For any monitoring terminal, calculating a second average value of pollution weights of all points acquired by the current monitoring terminal, and taking the second average value as an allocation evaluation value of the current monitoring terminal; and calculating the real-time bandwidth allocation proportion of each monitoring terminal based on the ratio between the allocation evaluation value and the sum of the allocation evaluation values of each monitoring terminal.
  8. 8. The method for operating an environmental protection management and control platform accessed by mass monitoring and control terminals according to claim 1, wherein after the step of determining the real-time bandwidth allocation proportion of each monitoring and control terminal based on the pollution weight, the method further comprises: and if the pollution influence range of any point is determined to exceed the preset range threshold, the environment treatment equipment is mobilized to carry out linkage pollution treatment, and the pollution influence degree of each point is timely restrained.

Description

Environment-friendly control and management platform operation method for accessing mass monitoring terminals Technical Field The invention relates to the technical field of data calculation, in particular to an operation method of an environment-friendly management and control treatment platform accessed by a mass monitoring terminal. Background Along with the maturity of technologies such as thing networking, cloud computing, artificial intelligence, environmental protection management and control administering platform begins to digital, intelligent, integration conversion, large-scale, multiple class deployment is at factory and peripheral monitoring supervisory equipment, such as air micro-station, quality of water monitoring station, VOC (volatile organic compound)/TSP (total suspended particulate matter) monitor, noise monitor, high definition video camera etc. are the basis that the platform realized the universe perception, environmental protection management and control administering platform can carry out relevance, complementation and combination from different terminals, different grade data (such as sensor data, video data, meteorological data), finally realizes accurate pollution control and collaborative management. However, the data management of the mass monitoring terminals is a key challenge for the operation of the environmental protection management platform, and due to the huge number of terminals, when the data transmission quality of each terminal cannot be ensured, the problems of data loss or disorder and the like may be caused. Disclosure of Invention In order to solve the technical problem that data loss or disorder can be caused when the data transmission quality of each terminal cannot be guaranteed due to the huge number of terminals in the related art, the invention provides an operation method of an environment-friendly management and control platform for accessing a large number of monitoring terminals. The adopted technical scheme is as follows: Environmental monitoring data of different points reported by each monitoring terminal in the environmental protection management platform are obtained, and pollution intensity of the environmental monitoring data of different types is determined; based on the pollution intensity, the time difference between different time points and the last time point when the pollution exists of various environmental monitoring data and the proportion of pollution occurrence of each point in the historical time point at the same time point every day, calculating to obtain the historical state weight of each time point of different point; Based on the overall pollution level and the pollution intensity trend corresponding to the pollution intensity, calculating to obtain the real-time trigger weight of the different types of environment monitoring data corresponding to each point location; Based on the historical state weight and the real-time trigger weight, calculating to obtain pollution weights of different points at the current moment; and determining the real-time bandwidth allocation proportion of each monitoring terminal based on the pollution weight, so as to dynamically allocate the uploading bandwidth of each monitoring terminal based on the real-time bandwidth allocation proportion, and stably transmitting the environment monitoring data. In one possible implementation manner of the present application, based on pollution intensity, time difference between different time points of various environmental monitoring data and the last time point of pollution occurrence and duty ratio of each point in the historical time point at the same time point every day, historical state weights of each time point of different point positions are calculated, including: Calculating to obtain historical pollution discharge evaluation values of all points based on the pollution intensity and the time difference between different moments and the last moment of pollution existence of various environmental monitoring data; Calculating the repetition rate of pollution of different points at each moment based on the proportion of pollution of each point at the same moment in each day in the historical moment; and calculating historical state weights of different points at different moments based on the repetition rate and the historical pollution discharge evaluation value. In one possible implementation manner of the present application, based on the pollution intensity and the time difference between the different time and the previous time of the pollution existence of various environmental monitoring data, the historical pollution discharge evaluation value of each point is calculated, including: Determining a first ratio of the time difference between different moments of various environmental monitoring data and the last moment of pollution and the pollution intensity; And carrying out summation and average processing on the first ratio according to t