CN117649197A - Visual intelligent monitoring data security control substation system and process thereof - Google Patents

Abstract

The invention relates to the technical field of urban security, in particular to a visual intelligent monitoring data security control substation system and a process thereof, wherein the visual intelligent monitoring data security control substation system comprises a control terminal, a receiving layer, a monitoring layer and a scheduling layer; the control terminal is a main control terminal of the system and is used for sending out an execution command; the invention can automatically match the number of the police-out personnel of the fire station according to the analysis of the basic information of the alarm event, effectively improve the police-out efficiency of the fire station after receiving the alarm event, and can also decide whether the subsequent police-out support is needed or not and the number of the police-out personnel again based on the event site data feedback of the police-out personnel after the police-out, thereby effectively improving the processing efficiency and the processing reliability of the alarm event.

Description

Visual intelligent monitoring data security control substation system and process thereof

Technical Field

The invention relates to the technical field of urban security, in particular to a visual intelligent monitoring data security control substation system and a process thereof.

Background

The fire control is to eliminate hidden danger and prevent disaster, and the narrow meaning of the fire control is that in the early stage of people's understanding: (putting out) the meaning of a fire;

the responsibility range of fire control includes: natural disasters such as fires, dangerous chemical leaks, road traffic accidents, earthquakes, building collapse, major safety production accidents, air accidents, explosions and terrorist events, mass distress events, paddy fields and dry land, weather, geological disasters, forests, grassland fires and the like, mine and water accidents, major environmental pollution, nuclear and radiation accidents, sudden public health events and the like.

In the patent of application number 202211251253.7, a visual intelligent monitoring data security control system is disclosed, its characterized in that: the system comprises a plurality of image acquisition devices, a data processing center, a data access port and a data storage unit; the image acquisition equipment comprises access control equipment arranged at each access of the cell and high-definition cameras arranged on roads and buildings in the cell, and is used for acquiring real-time image data in the cell and transmitting the image data to the data processing center; the data processing center comprises an image processing unit, a face recognition unit and a permission setting module, wherein the image processing unit is used for recognizing a face in image data after processing the image data, classifying and storing the face and related data into a data storage unit, and the permission setting module is used for setting different access permissions according to the face data; the data access ports comprise access ports installed in the home of each owner, management ports installed in property and query ports installed in public security institutions in jurisdictions; for accessing data in the data storage unit according to its own access rights.

The application aims at solving the problems: because the community has complex population sources and strong mobility, larger requirements are put forward on community security monitoring work, in order to cope with the change of social development, cameras are generally installed in a monitoring area to monitor the monitoring site in a video mode, monitoring staff can master the actual conditions of multiple places at the same time by observing on-site image information in front of a television wall, and the workload of security monitoring staff is reduced.

The fire department plays a vital role in the development of urban security work;

however, when a security accident occurs in a city, in the process of correspondingly processing the security accident by a fire department, the specific information of the security accident is often obtained by relying on a mode that a fire operator answers an alarm call, so that a certain amount of fire resources are configured to process the security accident, the fire resources required by the security accident processing cannot be absolutely met in a one-time alarm discharging mode of the fire resource configuration, further, secondary scheduling of the fire resources is required, the secondary scheduling coordination efficiency is poor, and when the security accident is serious, and a plurality of fire stations are required to cooperatively process the security accident, the scheduling coordination effect and efficiency are further reduced, so that the security accident processing effect is affected.

Disclosure of Invention

Aiming at the defects existing in the prior art, the invention provides a visual intelligent monitoring data security control substation system and a process thereof, and solves the technical problems in the background art.

In order to achieve the above purpose, the invention is realized by the following technical scheme:

in a first aspect, a visual intelligent monitoring data security control substation system comprises a control terminal, a receiving layer, a monitoring layer and a scheduling layer;

the control terminal is a main control terminal of the system and is used for sending out an execution command;

the method comprises the steps that basic information of an event is received through a receiving layer, urban fire resources are stored through the receiving layer, basic information of the event is analyzed in the receiving layer, the number of police personnel is configured based on analysis results, a monitoring layer collects on-site event development situation of the event in real time, whether on-duty personnel are scheduled to give an alarm or not is judged based on the event development situation, when the decision result is NO, the operation of the monitoring layer is refreshed, when the decision result is yes, the operation of a scheduling layer is triggered, the on-duty personnel are scheduled to give an alarm, and after the scheduling is completed, the operation of the monitoring layer is skipped again;

the monitoring layer comprises an acquisition module, an evaluation module and a decision module, wherein the acquisition module is used for acquiring event actual information of an event occurrence site, the evaluation module is used for receiving the event actual information of the event occurrence site acquired by the acquisition module, the event actual information of the event occurrence site is used for evaluating event development situation of the event occurrence site, and the decision module is used for receiving the event development situation in the evaluation module and deciding the operation logic of the monitoring layer and the scheduling layer based on the event development situation;

the event development situation of the event scene is expressed as follows:

wherein: f (f) _swot Developing a situation for an event on an event scene; IMMD (IMMD) ₀ The actual emergency degree of the police; IMMD is the emergency degree of police; h is a _s The information entropy is the actual information of the event; [ f (epsilon)]Calculating an accurate function for the event development situation of the event scene;

wherein,middle sigma _x 、σ _y Estimating standard deviation for coordinates of the event impact region (x, y); ρ is the correlation between the size of the event impact area and the personnel concentration of the event occurrence site; z is an event level, where the event level z is manually set by a user at a system end, and the monitoring layer and scheduling layer operation logic includes: monitoring refreshing operation of the layer; the monitoring layer jumps to the operation of the scheduling layer, the jump is triggered after the operation of the scheduling layer is finished, the monitoring layer is controlled to operate again, f _swot Not less than 1, if the decision result of the decision module is yes, controlling the monitoring layer to jump to the scheduling layer operation, triggering the jump after the scheduling layer operation is finished, f _swot And less than 1, if the decision result of the decision module is NO, controlling the refreshing operation of the monitoring layer.

Further, the receiving layer comprises an analysis module, a storage module and a configuration module, wherein the analysis module is used for receiving the audio data of the alarm telephone, performing text conversion on the audio data, analyzing the emergency degree of the alarm based on the text conversion result, the storage module is used for receiving the text conversion result of the audio data in the analysis module and the emergency degree analysis result of the alarm, uploading urban fire-fighting resource data, storing the text conversion result of the audio data, the emergency degree analysis result of the alarm and the urban fire-fighting resource data, and the configuration module is used for acquiring the emergency degree analysis result of the alarm and configuring the number of police based on the emergency degree analysis result of the alarm;

the alarm telephone is received by a firefighter on duty, after the firefighter on duty receives the alarm telephone, the basic information of the scene where the event occurs is queried in real time, the recording of the alarm telephone is the audio data word conversion target, and the basic information query content of the scene where the event occurs is as follows: the number of trapped people, the occurrence position of the event and whether the event has the property of further development deterioration, and the urban fire-fighting resource data comprise: fire station location information, the number of personnel currently on duty at the fire station.

Furthermore, the emergency degree is calculated by the following formula:

wherein: IMMD is the emergency degree of police; m is the number of trapped people; mu is the weight; chi is the dispersion degree of trapped people; θ is the flow of people at the event occurrence position; g is the number of urban fire stations; g _ing The number of fire stations in the current alarm state;the average value of the fire-fighting on-duty personnel is the average value;

wherein mu is more than or equal to 1, the weight mu is set based on whether the event has the property of further development and deterioration in the basic information of the event occurrence site, the event has the property of development and deterioration, the faster the development and deterioration speed is, the larger the weight mu value is, the event has the property of development and deterioration, the slower the development and deterioration speed is, the smaller the weight mu value is, and the event does not have the property of development and deterioration, namely the weight mu value is 1.

Still further, the alarm number configuration logic in the configuration module is expressed as: when the value of the weight mu applied to the emergency degree of the warning situation is 1, the value of the weight mu applied to the emergency degree of the warning situation is downward and rounded, and when the value of the weight mu applied to the emergency degree of the warning situation is not 1, the value of the weight mu applied to the emergency degree of the warning situation is upward and rounded;

the alarm person quantity in the operation configuration of the configuration module is synchronously fed back to the storage module, and the corresponding alarm condition emergency degree analysis results in the storage module are matched and stored.

Further, the information entropy h of the event actual information _s The method comprises the following steps:

wherein: h is a _s E (0, 1); c is the total amount of event levels; x is x _qz An index value of the q-th event level z; (lnc) ^-1 Representing the information entropy coefficient;

wherein, the actual emergency degree IMMD of the alert ₀ The solving mode of the (E) is the same as that of the alarm emergency IMMD, and the IMMD is used for solving the emergency IMMD ₀ When the alarm is obtained, the applied m, mu, chi and theta are manually edited by the first police on-duty personnel.

Further, the dispatching layer comprises a selection module, a configuration module and a jump module, wherein the selection module is used for receiving an operation result of the decision module, triggering operation when the operation result of the decision module is yes, selecting a fire station as an on-duty personnel dispatching alarm-out target for dispatching alarm-out, the configuration module is used for obtaining and configuring the number of alarm-out personnel when the fire station selected in the selection module dispatches alarm-out, and the jump module is used for monitoring the operation state of the configuration module, triggering the jump after the operation of the configuration module is finished, so that the system returns to the operation stage of the monitoring layer again;

the configuration module is used for configuring the number of the police-out personnel and dispatching the police-out personnel to give an alarm when the number of the police-out personnel is smaller than the total number of the police-out personnel in the fire station, and is used for dispatching all the police-out personnel in the fire station selected by the selection module and the rest police-out personnel in the fire station for giving an alarm last time when the number of the police-out personnel is larger than the total number of the police-out personnel in the fire station.

Still further, the fire station selection logic in the selection module is expressed as:

wherein:selecting a fitness level for a fire station; d is the linear distance between the fire station and the event occurrence site; alpha is the total amount of on-duty personnel in the fire station; v (v) _e Is an empirical value of the fire station; lambda is the current alarm-out path unobstructed rate;

wherein the fire station selected by the selection module is operated each time isFire station with highest value v _e Is obeyed by the value of (v), the more the fire station gives out police at the moment _e The smaller the value, the conversely, v _e Setting logic with larger value, wherein a target fire station which is the first to alarm for an event in the system is the fire station which is closest to the event occurrence site and is not currently alarming.

Further, after the selection module selects the fire station and gives an alarm, the on-duty personnel newly giving the alarm executes the alarm actual emergency IMMD again ₀ When obtaining, editing the values of m, mu, χ and θ, and based on the obtained IMMD ₀ Calculating the number of police dispatch personnel configured by the configuration module;

the alarm person quantity obtaining logic configured in the configuration module is as follows:

(IMMD ₀ ×1.1+1)-(IMMD×1.1+1)；

after the event is alerted twice in succession, when the system jumps to the dispatch layer to run, the number of alerted personnel configured in the configuration module is changed Into (IMMD) _0-1 ×1.1+1)-(IMMD ₀ X 1.1+1), wherein IMMD is _0-1 When the alarm is sent out for the third time, after the on-duty personnel newly sent out send out the alarm again edit the values of m, mu, χ and theta, the actual emergency degree of the alarm is obtained, (IMMD) _0-2 、IMMD _0-3 、IMMD _0-4 A.+ -.), and so on.

Furthermore, the control terminal is electrically connected with an analysis module through a medium, the analysis module is electrically connected with a storage module and a configuration module through the medium, the configuration module is electrically connected with an acquisition module through the medium, the acquisition module is electrically connected with an evaluation module and a decision module through the medium, the decision module is electrically connected with a selection module through the medium, and the selection module is electrically connected with the configuration module and a jump module through the medium.

In a second aspect, a process for security control substation of visual intelligent monitoring data includes the following steps:

step 1: uploading urban fire control resource data, and collecting basic information of an alarm event in real time;

step 11: an emergency degree analysis stage of the basic information of the alarm event;

step 2: a first configuration stage of an alarm person based on basic information of an alarm event;

step 3: analyzing the emergency degree of the event based on the actual information of the event occurrence site;

step 4: the emergency degree analysis result of the two events is applied to evaluate the event development situation of the event scene;

step 5: deciding whether to execute the police dispatch operation of the on-duty personnel of the fire station according to the event development situation of the event scene;

step 51: step 5, if the decision result is NO, executing step jump, and jumping to the capturing 1 for executing again;

step 6: step 5, if the decision result is yes, the selection of the fire station and the number of the new police on-duty personnel are obtained;

step 61: selecting logic and solving a limiting stage of the logic;

step 7: and the output stage of the fire station selection result and the number of the new police on-duty personnel to obtain the result.

Compared with the prior art, the technical proposal provided by the invention has the following advantages that

The beneficial effects are that:

1. the invention provides a visual intelligent monitoring data security control substation system, which can collect basic information of an alarm event in a city in the running process, so that the number of alarm personnel in a fire station is automatically matched according to analysis of the basic information of the alarm event, the alarm efficiency of the fire station after the alarm event is received is effectively improved, and whether the subsequent alarm is needed to be re-carried out or not and the number of the re-alarm personnel are also determined based on event site data feedback of the alarm personnel after the alarm is carried out, so that the processing efficiency and the processing reliability of the alarm event are effectively improved.

2. In the system, in the running process, the system provides a digitalized visual event dynamic monitoring effect for a system end user through calculating the emergency degree of the police and the time development situation of the event scene, and is beneficial to the management and manual scheduling of the fire control resource by the fire station management background.

3. In the system operation stage, when the alarm event requiring the alarm is reconfigured, the fire station can be selected through the appointed fire station selection logic, and after the fire station is selected, the appointed number of alarm personnel are configured, so that the alarm force of the alarm event can be matched in an automatic mode, and the alarm event is more timely and stable.

4. The invention provides a visual intelligent monitoring data security control substation process, which can further maintain the stability of system operation by executing steps in the process method, and further provides system operation logic in the executing process of the steps in the process method, so that the system loaded with the method is more reliable and has better robustness in the operation process.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present invention and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a schematic diagram of a visual intelligent monitoring data security control substation system;

FIG. 2 is a schematic flow chart of a process of a visual intelligent monitoring data security control substation;

FIG. 3 is a schematic diagram showing the system application phase operation logic according to the present invention;

FIG. 4 is a diagram illustrating a first phase of a demonstration of a continuous selection logic application of a fire station upon occurrence of an event in accordance with the present invention;

fig. 5 is a diagram illustrating a second phase of a demonstration of a continuous selection logic application of a fire station upon occurrence of an event in accordance with the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention more clear, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. It will be apparent that the described embodiments are some, but not all, embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

The invention is further described below with reference to examples.

Example 1:

the visual intelligent monitoring data security control substation system of the embodiment, as shown in fig. 1, comprises a control terminal, a receiving layer, a monitoring layer and a scheduling layer;

the control terminal is a main control terminal of the system and is used for sending out an execution command;

the method comprises the steps that basic information of an event is received through a receiving layer, urban fire resources are stored through the receiving layer, basic information of the event is analyzed in the receiving layer, the number of police personnel is configured based on analysis results, a monitoring layer collects on-site event development situation of the event in real time, whether on-duty personnel are scheduled to give an alarm or not is judged based on the event development situation, when the decision result is NO, the operation of the monitoring layer is refreshed, when the decision result is yes, the operation of a scheduling layer is triggered, the on-duty personnel are scheduled to give an alarm, and after the scheduling is completed, the operation of the monitoring layer is skipped again;

the monitoring layer comprises an acquisition module, an evaluation module and a decision module, wherein the acquisition module is used for acquiring event actual information of an event occurrence site, the evaluation module is used for receiving the event actual information of the event occurrence site acquired by the acquisition module, the event actual information of the event occurrence site is used for evaluating event development situation of the event occurrence site, and the decision module is used for receiving the event development situation in the evaluation module and deciding the operation logic of the monitoring layer and the scheduling layer based on the event development situation;

the event development situation at the event site is expressed as:

wherein: f (f) _swot Developing a situation for an event on an event scene; IMMD (IMMD) ₀ The actual emergency degree of the police; IMMD is the emergency degree of police; h is a _s The information entropy is the actual information of the event; [ f (epsilon)]Calculating an accurate function for the event development situation of the event scene;

wherein,middle sigma _x 、σ _y Estimating standard deviation for coordinates of the event impact region (x, y); ρ is the correlation between the size of the event impact area and the personnel concentration of the event occurrence site; z is an event level, the event level z is manually set by a user at a system end, and the operation logic of the monitoring layer and the scheduling layer comprises: monitoring refreshing operation of the layer; the monitoring layer jumps to the operation of the scheduling layer, the jump is triggered after the operation of the scheduling layer is finished, the monitoring layer is controlled to operate again, f _swot Not less than 1, if the decision result of the decision module is yes, controlling the monitoring layer to jump to the scheduling layer operation, triggering the jump after the scheduling layer operation is finished, f _swot The method comprises the steps that 1, a decision module decides whether a result is negative, and refreshing operation of a monitoring layer is controlled;

the receiving layer comprises an analysis module, a storage module and a configuration module, wherein the analysis module is used for receiving alarm telephone audio data, carrying out text conversion on the audio data, analyzing the alarm emergency degree based on text conversion results, the storage module is used for receiving the audio data text conversion results and the alarm emergency degree analysis results in the analysis module, uploading urban fire control resource data, storing the audio data text conversion results, the alarm emergency degree analysis results and the urban fire control resource data, and the configuration module is used for obtaining the alarm emergency degree analysis results and configuring the number of police based on the alarm emergency degree analysis results;

the alarm telephone is received by a firefighter on duty, after the firefighter on duty receives the alarm telephone, the basic information of the scene where the event occurs is queried in real time, the recording of the alarm telephone is the audio data word conversion target, and the basic information query content of the scene where the event occurs is as follows: the number of trapped people, the occurrence position of the event and whether the event has the property of further development deterioration, and the urban fire-fighting resource data comprise: fire station location information, the number of current on-duty personnel of the fire station;

the emergency degree is calculated by the following formula:

wherein: IMMD is the emergency degree of police; m is the number of trapped people; mu is the weight; chi is the dispersion degree of trapped people; θ is the flow of people at the event occurrence position; g is the number of urban fire stations; g _ing The number of fire stations in the current alarm state;the average value of the fire-fighting on-duty personnel is the average value;

wherein mu is more than or equal to 1, the weight mu is set based on whether the event has the property of further development and deterioration in the basic information of the event occurrence site, the event has the property of development and deterioration, the faster the development and deterioration speed is, the larger the weight mu value is, the event has the property of development and deterioration, the slower the development and deterioration speed is, the smaller the weight mu value is, and the event does not have the property of development and deterioration, namely the weight mu value is 1;

information entropy h of event actual information _s The method comprises the following steps:

wherein: h is a _s E (0, 1); c is the total amount of event levels; x is x _qz An index value of the q-th event level z; (ln c) ^-1 Representing the information entropy coefficient;

wherein, the actual emergency degree IMMD of the alert ₀ The solving mode of the (E) is the same as that of the alarm emergency IMMD, and the IMMD is used for solving the emergency IMMD ₀ When solving, the applied m, mu, χ and θ are manually edited by the first police on-duty personnel;

the scheduling layer comprises a selection module, a configuration module and a jump module, wherein the selection module is used for receiving the operation result of the decision module, triggering operation when the operation result of the decision module is yes, selecting a fire station as an on-duty personnel scheduling alarm-out target for scheduling alarm-out, the configuration module is used for obtaining and configuring the number of alarm-out personnel when the fire station selected in the selection module performs scheduling alarm-out, and the jump module is used for monitoring the operation state of the configuration module, triggering the jump after the operation of the configuration module is finished, so that the system returns to the operation stage of the monitoring layer;

the configuration module is used for synchronously comparing the number of the police-out personnel obtained in the operation stage of the configuration module with the total number of the police-out personnel in the fire station selected by the selection module, when the number of the police-out personnel obtained is smaller than the total number of the police-out personnel in the fire station, the configuration module is used for configuring the number of the police-out personnel and dispatching the police-out personnel to give out the police, and when the number of the police-out personnel obtained is larger than the total number of the police-out personnel in the fire station, the configuration module is used for dispatching all the police-out personnel in the fire station selected by the selection module and the rest police-out personnel in the fire station for giving the police-out last time;

the control terminal is electrically connected with an analysis module through a medium, the analysis module is electrically connected with a storage module and a configuration module through the medium, the configuration module is electrically connected with a collection module through the medium, the collection module is electrically connected with an evaluation module and a decision module through the medium, the decision module is electrically connected with a selection module through the medium, and the selection module is electrically connected with the configuration module and a jump module through the medium.

In the embodiment, the analysis module operates to receive alarm telephone audio data, perform text conversion on the audio data, analyze alarm emergency degree based on text conversion results, the storage module receives text conversion results and alarm emergency degree analysis results of the audio data in the analysis module, uploads urban fire-fighting resource data, stores the text conversion results, the alarm emergency degree analysis results and the urban fire-fighting resource data, the configuration module operates at a later stage to obtain alarm emergency degree analysis results, configures the number of police personnel based on the alarm emergency degree analysis results, the acquisition module synchronizes event actual information of an event occurrence site, the evaluation module receives the event actual information of the event occurrence site acquired by the acquisition module in real time, the method comprises the steps that actual information of an event occurrence site event is used for evaluating the event development situation of the event occurrence site event, a decision module further receives the event development situation in an evaluation module, a decision monitoring layer and a scheduling layer operation logic are based on the event development situation, a selection module simultaneously receives the decision module operation result, when the decision module operation result is yes, the operation is triggered, a fire station is selected as an on-duty personnel scheduling police-out target for scheduling police-out, the number of police-out personnel when the police-out is scheduled out of the fire station selected in the selection module is obtained and configured by a configuration module, finally, the operation state of the configuration module is monitored through a skip module, and after the operation of the configuration module is finished, skip is triggered, so that the system returns to the monitoring layer operation stage again;

through the recorded alarm emergency degree calculation formula, digital visual alarm emergency degree reading conditions are brought to a system background user, and necessary data support is provided for solving the event development situation of an event scene;

referring to FIG. 3, the application and operating logic of the system of the present embodiment is shown;

referring to fig. 4 and 5, the operation logic of the continuous dispatch of fire station personnel is further illustrated by fig. 4 and 5.

Example 2:

on the aspect of implementation, on the basis of embodiment 1, this embodiment further specifically describes a visual intelligent monitoring data security control substation system in embodiment 1 with reference to fig. 2:

the alarm number configuration logic in the configuration module is expressed as: when the value of the weight mu applied to the emergency degree of the warning situation is 1, the value of the weight mu applied to the emergency degree of the warning situation is downward and rounded, and when the value of the weight mu applied to the emergency degree of the warning situation is not 1, the value of the weight mu applied to the emergency degree of the warning situation is upward and rounded;

the alarm personnel quantity in the operation configuration of the configuration module is synchronously fed back to the storage module, and the corresponding alarm condition emergency analysis results in the storage module are matched and stored.

Through the arrangement, when the number of police personnel is configured for the event for the first time for the operation of the configuration module in the system, further configuration number solving logic is provided.

As shown in fig. 1, the fire station selection logic in the selection module is represented as:

wherein:selecting a fitness level for a fire station; d is the linear distance between the fire station and the event occurrence site; alpha is the total amount of on-duty personnel in the fire station; v (v) _e Is an empirical value of the fire station; lambda is the current alarm-out path unobstructed rate;

wherein the fire station selected by the selection module is operated each time isFire station with highest value v _e Is obeyed by the value of (v), the more the fire station gives out police at the moment _e The smaller the value, the conversely, v _e Setting logic with larger value, wherein a target fire station for first warning of an event in the system is a fire station closest to the event occurrence site and not currently warning。

Through the arrangement, when the fire station is selected for the operation of the dispatching layer in the system, appointed fire station selection logic is provided, the fire station selected by the dispatching layer is ensured to be more in line with the event-amplified alarm condition.

As shown in fig. 1, after selecting a fire station and alerting, the selection module re-executes the alert actual emergency IMMD by the newly alerted on-duty personnel ₀ When obtaining, editing the values of m, mu, χ and θ, and based on the obtained IMMD ₀ Calculating the number of police dispatch personnel configured by the configuration module;

the alarm person quantity obtaining logic configured in the configuration module is as follows:

(IMMD ₀ ×1.1+1)-(IMMD×1.1+1)；

after the event is alerted twice in succession, when the system jumps to the dispatch layer to run, the number of alerted personnel configured in the configuration module is changed Into (IMMD) _0-1 ×1.1+1)-(IMMD ₀ X 1.1+1), wherein IMMD is _0-1 When the alarm is sent out for the third time, after the on-duty personnel newly sent out send out the alarm again edit the values of m, mu, χ and theta, the actual emergency degree of the alarm is obtained, (IMMD) _0-2 、IMMD _0-3 、IMMD _0-4 A.+ -.), and so on.

Through the arrangement, further police dispatch personnel quantity configuration logic after the fire station selection is provided, and the quantity of on-duty personnel in the fire station for the police dispatch for the event is ensured to meet the event rescue requirement.

Example 3:

on the aspect of implementation, on the basis of embodiment 1, this embodiment further specifically describes a visual intelligent monitoring data security control substation system in embodiment 1 with reference to fig. 2:

a visual intelligent monitoring data security control substation process comprises the following steps:

step 1: uploading urban fire control resource data, and collecting basic information of an alarm event in real time;

step 11: an emergency degree analysis stage of the basic information of the alarm event;

step 2: a first configuration stage of an alarm person based on basic information of an alarm event;

step 3: analyzing the emergency degree of the event based on the actual information of the event occurrence site;

step 4: the emergency degree analysis result of the two events is applied to evaluate the event development situation of the event scene;

step 5: deciding whether to execute the police dispatch operation of the on-duty personnel of the fire station according to the event development situation of the event scene;

step 51: step 5, if the decision result is NO, executing step jump, and jumping to the capturing 1 for executing again;

step 6: step 5, if the decision result is yes, the selection of the fire station and the number of the new police on-duty personnel are obtained;

step 61: selecting logic and solving a limiting stage of the logic;

step 7: and the output stage of the fire station selection result and the number of the new police on-duty personnel to obtain the result.

In summary, the system in the above embodiment can collect basic information of an alarm event occurring in a city in the running process, so that the number of alarm personnel in a fire station is automatically matched according to analysis of the basic information of the alarm event, the alarm efficiency of the fire station after receiving the alarm event is effectively improved, whether the subsequent alarm is needed to be carried out again or not is determined based on event site data feedback of the alarm personnel after the alarm is carried out, and the number of the alarm personnel is further increased, and the processing efficiency and the processing reliability of the alarm event are effectively improved. The system provides a digitalized visual event dynamic monitoring effect for a system end user through calculation of the emergency degree of the police and the time development situation of the event scene, and is beneficial to management and manual scheduling of fire control resources by a fire station management background; meanwhile, in the operation stage of the system, when the alarm event needing to be amplified is reconfigured by the alarm personnel, the fire station can be selected through the appointed fire station selection logic, and after the fire station is selected, the appointed number of alarm personnel are configured, so that the amplified alarm force of the alarm event can be matched in an automatic mode, and the amplified alarm event is more timely and stable; in addition, the process method provided in the embodiment can further maintain the stability of the operation of the system, and in the execution process of the steps of the process method, the system operation logic is further provided, so that the system loaded with the process is more reliable and has better robustness in the operation process.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. The visual intelligent monitoring data security control substation system is characterized by comprising a control terminal, a receiving layer, a monitoring layer and a scheduling layer;

the control terminal is a main control terminal of the system and is used for sending out an execution command;

the method comprises the steps that basic information of an event is received through a receiving layer, urban fire resources are stored through the receiving layer, basic information of the event is analyzed in the receiving layer, the number of police personnel is configured based on analysis results, a monitoring layer collects on-site event development situation of the event in real time, whether on-duty personnel are scheduled to give an alarm or not is judged based on the event development situation, when the decision result is NO, the operation of the monitoring layer is refreshed, when the decision result is yes, the operation of a scheduling layer is triggered, the on-duty personnel are scheduled to give an alarm, and after the scheduling is completed, the operation of the monitoring layer is skipped again;

the monitoring layer comprises an acquisition module, an evaluation module and a decision module, wherein the acquisition module is used for acquiring event actual information of an event occurrence site, the evaluation module is used for receiving the event actual information of the event occurrence site acquired by the acquisition module, the event actual information of the event occurrence site is used for evaluating event development situation of the event occurrence site, and the decision module is used for receiving the event development situation in the evaluation module and deciding the operation logic of the monitoring layer and the scheduling layer based on the event development situation;

the event development situation of the event scene is expressed as follows:

wherein: f (f) _swot Developing a situation for an event on an event scene; IMMD (IMMD) ₀ The actual emergency degree of the police; IMMD is the emergency degree of police; h is a _s The information entropy is the actual information of the event; [ f (epsilon)]Calculating an accurate function for the event development situation of the event scene;

wherein,middle sigma _x 、σ _y Estimating standard deviation for coordinates of the event impact region (x, y); ρ is the correlation between the size of the event impact area and the personnel concentration of the event occurrence site; z is an event level, where the event level z is manually set by a user at a system end, and the monitoring layer and scheduling layer operation logic includes: monitoring refreshing operation of the layer; the monitoring layer jumps to the operation of the scheduling layer, the jump is triggered after the operation of the scheduling layer is finished, the monitoring layer is controlled to operate again, f _swot Not less than 1, if the decision result of the decision module is yes, controlling the monitoring layer to jump to the scheduling layer operation, triggering the jump after the scheduling layer operation is finished, f _swot And less than 1, if the decision result of the decision module is NO, controlling the refreshing operation of the monitoring layer.

2. The visual intelligent monitoring data security control substation system according to claim 1, wherein the receiving layer comprises an analysis module, a storage module and a configuration module, the analysis module is used for receiving alarm telephone audio data, performing text conversion on the audio data, analyzing alarm emergency degree based on text conversion results, the storage module is used for receiving the text conversion results of the audio data in the analysis module and the alarm emergency degree analysis results, uploading urban fire resource data, storing the text conversion results of the audio data, the alarm emergency degree analysis results and the urban fire resource data, and the configuration module is used for obtaining alarm emergency degree analysis results and configuring the number of police based on the alarm emergency degree analysis results;

the alarm telephone is received by a firefighter on duty, after the firefighter on duty receives the alarm telephone, the basic information of the scene where the event occurs is queried in real time, the recording of the alarm telephone is the audio data word conversion target, and the basic information query content of the scene where the event occurs is as follows: the number of trapped people, the occurrence position of the event and whether the event has the property of further development deterioration, and the urban fire-fighting resource data comprise: fire station location information, the number of personnel currently on duty at the fire station.

3. The visualized intelligent monitoring data security control substation system according to claim 2, wherein the alarm condition emergency degree is calculated by the following formula:

wherein: IMMD is the emergency degree of police; m is the number of trapped people; mu is the weight; chi is the dispersion degree of trapped people; θ is the flow of people at the event occurrence position; g is the number of urban fire stations; g _ing The number of fire stations in the current alarm state;the average value of the fire-fighting on-duty personnel is the average value;

wherein mu is more than or equal to 1, the weight mu is set based on whether the event has the property of further development and deterioration in the basic information of the event occurrence site, the event has the property of development and deterioration, the faster the development and deterioration speed is, the larger the weight mu value is, the event has the property of development and deterioration, the slower the development and deterioration speed is, the smaller the weight mu value is, and the event does not have the property of development and deterioration, namely the weight mu value is 1.

4. The visualized intelligent monitoring data security control substation system according to claim 2, wherein the alarm number configuration logic in the configuration module is expressed as: when the value of the weight mu applied to the emergency degree of the warning situation is 1, the value of the weight mu applied to the emergency degree of the warning situation is downward and rounded, and when the value of the weight mu applied to the emergency degree of the warning situation is not 1, the value of the weight mu applied to the emergency degree of the warning situation is upward and rounded;

the alarm person quantity in the operation configuration of the configuration module is synchronously fed back to the storage module, and the corresponding alarm condition emergency degree analysis results in the storage module are matched and stored.

5. The visualized intelligent monitoring data security control substation system according to claim 1, wherein the information entropy h of the event actual information _s The method comprises the following steps:

wherein: hs E (0, 1); c is the total amount of event levels; x is x _qz An index value of the q-th event level z; (lnc) ^-1 Representing the information entropy coefficient;

wherein, the actual emergency degree IMMD of the alert ₀ The solving mode of the (E) is the same as that of the alarm emergency IMMD, and the IMMD is used for solving the emergency IMMD ₀ When the alarm is obtained, the applied m, mu, chi and theta are manually edited by the first police on-duty personnel.

6. The visualized intelligent monitoring data security control substation system according to claim 1, wherein the dispatching layer comprises a selection module, a configuration module and a jump module, the selection module is used for receiving an operation result of the decision module, triggering operation when the operation result of the decision module is yes, selecting a fire station as an on-duty personnel dispatching alarm-out target for dispatching alarm-out, the configuration module is used for obtaining and configuring the number of the alarm-out personnel when dispatching the alarm-out is carried out on the fire station selected in the selection module, the jump module is used for monitoring the operation state of the configuration module, triggering jump after the operation of the configuration module is finished, and enabling the system to return to the operation stage of the monitoring layer;

the configuration module is used for configuring the number of the police-out personnel and dispatching the police-out personnel to give an alarm when the number of the police-out personnel is smaller than the total number of the police-out personnel in the fire station, and is used for dispatching all the police-out personnel in the fire station selected by the selection module and the rest police-out personnel in the fire station for giving an alarm last time when the number of the police-out personnel is larger than the total number of the police-out personnel in the fire station.

7. The visual intelligent monitoring data security control substation system according to claim 6, wherein the fire station selection logic in the selection module is expressed as:

wherein:selecting a fitness level for a fire station; d is the linear distance between the fire station and the event occurrence site; alpha is the total amount of on-duty personnel in the fire station; v (v) _e Is an empirical value of the fire station; lambda is the current alarm-out path unobstructed rate;

wherein the fire station selected by the selection module is operated each time isFire station with highest value v _e Is obeyed by the value of (v), the more the fire station gives out police at the moment _e The smaller the value, the conversely, v _e Setting logic with larger value, wherein a target fire station which is the first to alarm for an event in the system is the fire station which is closest to the event occurrence site and is not currently alarming.

8. A visual intelligent monitoring data security control as claimed in claim 6The substation system is characterized in that after the selection module selects the fire station and gives an alarm, the on-duty personnel newly giving the alarm executes the alarm actual emergency IMMD again ₀ When obtaining, editing the values of m, mu, χ and θ, and based on the obtained IMMD ₀ Calculating the number of police dispatch personnel configured by the configuration module;

the alarm person quantity obtaining logic configured in the configuration module is as follows:

(IMMD ₀ ×1.1+1)-(IMMD×1.1+1)；

after the event is alerted twice in succession, when the system jumps to the dispatch layer to run, the number of alerted personnel configured in the configuration module is changed Into (IMMD) _0-1 ×1.1+1)-(IMMD ₀ X 1.1+1), wherein IMMD is _0-1 When the alarm is sent out for the third time, after the on-duty personnel newly sent out send out the alarm again edit the values of m, mu, χ and theta, the actual emergency degree of the alarm is obtained, (IMMD) _0-2 、IMMD _0-3 、IMMD _0-4 A.+ -.), and so on.

9. The visualized intelligent monitoring data security control substation system according to claim 1, wherein the control terminal is electrically connected with an analysis module through a medium, the analysis module is electrically connected with a storage module and a configuration module through the medium, the configuration module is electrically connected with an acquisition module through the medium, the acquisition module is electrically connected with an evaluation module and a decision module through the medium, the decision module is electrically connected with a selection module through the medium, and the selection module is electrically connected with the configuration module and a jump module through the medium.

10. A process for implementing a visual intelligent monitoring data security control substation system according to any one of claims 1 to 9, comprising the following steps:

step 1: uploading urban fire control resource data, and collecting basic information of an alarm event in real time;

step 11: an emergency degree analysis stage of the basic information of the alarm event;

step 2: a first configuration stage of an alarm person based on basic information of an alarm event;

step 3: analyzing the emergency degree of the event based on the actual information of the event occurrence site;

step 4: the emergency degree analysis result of the two events is applied to evaluate the event development situation of the event scene;

step 5: deciding whether to execute the police dispatch operation of the on-duty personnel of the fire station according to the event development situation of the event scene;

step 51: step 5, if the decision result is NO, executing step jump, and jumping to the capturing 1 for executing again;

step 6: step 5, if the decision result is yes, the selection of the fire station and the number of the new police on-duty personnel are obtained;

step 61: selecting logic and solving a limiting stage of the logic;

step 7: and the output stage of the fire station selection result and the number of the new police on-duty personnel to obtain the result.