CN116681264B

CN116681264B - Power-saving command scheduling system and method

Info

Publication number: CN116681264B
Application number: CN202310943806.3A
Authority: CN
Inventors: 朱炯; 来益博; 谭年熊; 乐全明; 陈高辉; 张伟峰; 樊立波; 韩荣杰; 罗少杰; 郑伟彦; 王渊龙; 孙全; 孙智卿; 郭大琦; 陈炜; 唐铁英; 周艳; 黄江宁; 冯雪; 江崇熙
Original assignee: Beijing Youhao Technology Co ltd; Zhejiang Dayou Industrial Co ltd Hangzhou Science And Technology Development Branch; Hangzhou Power Supply Co of State Grid Zhejiang Electric Power Co Ltd; Hangzhou Vango Technologies Inc
Current assignee: Beijing Youhao Technology Co ltd; Zhejiang Dayou Industrial Co ltd Hangzhou Science And Technology Development Branch; Hangzhou Power Supply Co of State Grid Zhejiang Electric Power Co Ltd; Hangzhou Vango Technologies Inc
Priority date: 2023-07-31
Filing date: 2023-07-31
Publication date: 2023-10-20
Anticipated expiration: 2043-07-31
Also published as: CN116681264A

Abstract

The invention discloses a power-saving command scheduling system and a method, wherein the system comprises a monitoring video module, an online monitoring module, a task inspection module, a course information module and a task allocation module; the course information module calculates electricity-keeping importance coefficients according to the risk coefficients, the personnel number coefficients and the public opinion attention coefficients of the events; the task distribution module calculates a task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event; calculating a matrix matching value of the electric team according to the executor matrix; calculating the matching degree of the electricity-saving team and the electricity-saving task according to the task risk coefficient and the matrix matching value of the electricity-saving task; and allocating the electricity-saving team with the highest matching degree for the electricity-saving task to execute the electricity-saving task. According to the method, the task risk is determined according to the nature of the event and the importance and difficulty of the electricity-saving task, a proper electricity-saving team is allocated for the electricity-saving task to execute the electricity-saving task, and the emergency command efficiency is remarkably improved.

Description

Power-saving command scheduling system and method

Technical Field

The invention relates to the technical field of power systems, in particular to a power-saving command scheduling system and a power-saving command scheduling method.

Background

In recent years, more and more large-scale events are correspondingly held in large cities in China, more scientific and stricter requirements are required for power guarantee work for holding the large-scale events, and how to guarantee the large-scale events to avoid large-area power failure accidents caused by weather and geographic disasters, external damage and the like becomes a problem that each power guarantee task must be completed.

The traditional power guarantee mode uses a flattened management mode to manage and control power-saving equipment and guarantee resources, and power-saving tasks are executed by distribution personnel based on human management experience.

Disclosure of Invention

Based on the method, the system and the method for power-saving command scheduling can determine the task risk according to the nature of the event and the importance and difficulty of the power-saving task, and allocate a proper power-saving team to perform the power-saving task by combining the comprehensive quality of the power-saving team, so that the emergency command efficiency is remarkably improved.

In order to achieve the above purpose, the embodiment of the invention provides a power-saving command scheduling system, which comprises a monitoring terminal and a command scheduling terminal; the monitoring terminal at least comprises a monitoring video module, an online monitoring module and a task inspection module; the command scheduling terminal at least comprises a course information module and a task allocation module;

The competition course information module is used for calculating the electricity-keeping importance coefficient of the competition according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient of the competition; the electricity-keeping importance coefficient is positively correlated with the risk coefficient, the personnel number coefficient and the public opinion attention coefficient respectively;

the task allocation module comprises a task risk calculation unit, a team matching value calculation unit and a task allocation unit;

the task risk calculation unit is used for calculating the task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event; the target event is an event associated with the electricity-keeping task, and the task risk coefficient is positively correlated with the task importance level, the task difficulty and the electricity-keeping importance coefficient respectively;

the team matching value calculation unit is used for:

acquiring all electric protection teams within a preset electric protection range; wherein each of the electricity protection teams comprises at least one electricity protection person;

acquiring the position information, the current working state, the acceptance degree and the working age of the electricity-retaining personnel for the temporary emergency task, and constructing a executive matrix;

Calculating a matrix matching value of each electric protection team according to the executor matrix;

the task allocation unit is configured to allocate an electricity-saving team to the electricity-saving task, and includes:

calculating the matching degree of each electricity-saving team and the electricity-saving task according to the task risk coefficient of the electricity-saving task and the matrix matching value;

and distributing the electricity-retaining team with the highest matching degree for the electricity-retaining task to execute the electricity-retaining task.

As an improvement of the above scheme, the monitoring video module is configured to select a target video for playing according to a preset carousel rule or by responding to a user operation by accessing a substation video, a transmission line video, a distribution room video and a task field distribution ball video;

the online monitoring module is used for displaying the transmission line alarm data, the transformer substation alarm data and the distribution room alarm data in a set layer window of a front end interface of the system in a rolling way; the layer window is set to be a semitransparent window;

the task inspection module is used for rolling and displaying the acquired task inspection information on the front-end interface; the task inspection information at least comprises a task name, an inspection object, an inspection team, a contact way, task creation time, task processing state and task details.

As an improvement of the above solution, the course information module is specifically configured to, before calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient of the event:

determining a risk degree estimation coefficient of each occasion according to the risk level of each occasion of the event; wherein the risk level is positively correlated with the risk estimation coefficient; adding the risk estimation coefficients of all the occasions of the event to obtain a risk coefficient of the event;

determining a personnel number coefficient of each occasion according to the number of event activities of each occasion; the larger the personnel number coefficient is, the more the corresponding event activity number is; adding the number coefficients of all the scenes of the event to obtain the personnel number coefficient of the event;

determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion relation coefficient is, the higher the corresponding public opinion attention is; and adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event.

As an improvement of the above solution, the task risk calculation unit is specifically configured to:

Determining the electricity-keeping level of the target branch library according to the electricity-keeping level of the electricity-keeping equipment associated with the target branch library, determining the electricity-keeping number of the target branch library according to the electricity-keeping level of the target branch library, and adding all the electricity-keeping numbers of the target branch library to obtain the electricity-keeping coefficient of the target venue; the target stadium is a stadium associated with the electricity-keeping task, the target stadium comprises a plurality of target sub-stadiums, and the electricity-keeping level and the electricity-keeping coefficient of the target sub-stadiums are positively correlated;

determining range coefficients of the target museums according to the range of the power supply circuit related to the target museums, and adding the range coefficients of all the target museums to obtain the range coefficients of the target venues; wherein the power supply line range is positively correlated with the range coefficient;

determining task density coefficients of the target branch pavilion according to task execution time of the target branch pavilion, and adding the task density coefficients of all the target branch pavilions to obtain the task density coefficients of the target venue;

adding the electricity-keeping coefficient of the target venue, the range coefficient of the target venue and the task density coefficient of the target venue, and dividing the added value by three to obtain the task importance level of the electricity-keeping task;

Determining task difficulties of the target sub-museums according to the guaranteed man-vehicle scale of the target sub-museums, and adding the task difficulties of all the target sub-museums to obtain the task difficulties of the electricity-saving task; wherein, the scale of the guaranteed man-vehicle is positively correlated with the task difficulty;

multiplying the task importance level, the task difficulty and the electricity-keeping importance coefficient of the target event to obtain a task risk coefficient of the electricity-keeping task; the target event is an event associated with the electricity-keeping task.

As an improvement of the above solution, the obtaining the location information, the current working state, the acceptance degree for the temporary emergency task, and the working age of the electricity-protecting person, so as to construct a executor matrix specifically includes:

acquiring position information of the electricity-protecting personnel to be used for calculating the estimated arrival time of the electricity-protecting personnel to the electricity-protecting site, and determining a first matrix score according to the estimated arrival time; wherein the higher the first matrix score, the shorter the corresponding predicted arrival time;

determining a second matrix score according to the current working state of the electricity-retaining person; the current working state comprises an executing task state and a non-executing task state, and the second matrix score of the executing task state is smaller than the second matrix score of the non-executing task state;

Determining a third matrix score according to the acceptance degree of the electricity-retaining personnel for the temporary emergency task; wherein the degree of reception is positively correlated with the third matrix score;

determining a fourth matrix score according to the work age of the electricity-retaining person; wherein, the higher the fourth matrix score, the longer the corresponding working age;

and constructing an executive matrix according to the first matrix score, the second matrix score, the third matrix score and the fourth matrix score of all electricity-retaining persons.

As an improvement of the above solution, the task allocation unit is further configured to:

when a plurality of electricity-saving tasks exist in the task pool, determining a first score according to the task time of the electricity-saving task per se for each electricity-saving task; the task time is a issuing time or a deadline, and the first score is lower when the task time is earlier;

determining a second score according to the task type of the self electricity-retaining task aiming at each electricity-retaining task; the task types comprise a rush-repair task, a duty task and a patrol task, wherein the second score of the rush-repair task is smaller than that of the duty task, and the second score of the duty task is smaller than that of the patrol task;

Determining a third score according to the number of fault devices of the power-saving tasks per se according to each power-saving task;

calculating the total score of all electricity-keeping tasks according to the first score, the second score and the third score;

priority ordering is carried out on all electricity-keeping tasks according to the total score; wherein the higher the total score, the lower the corresponding priority.

when a plurality of electricity-saving tasks exist in the task pool, distributing electricity-saving teams for each electricity-saving task in sequence according to the order of priority from high to low; and each electricity-retaining task corresponds to the assigned electricity-retaining team one by one.

As an improvement of the above scheme, the system adopts a heterogeneous multi-core processor for data processing, wherein the heterogeneous multi-core processor comprises a digital signal processor core.

As an improvement of the scheme, the state registers of the system are static random access memories, and the number of the state registers is flexibly configured by software programming of the heterogeneous multi-core processor.

As an improvement of the above solution, the heterogeneous multi-core processor is integrated with a plurality of processors, and configures each of the processors, the bus host, the peripheral devices and the memory areas with a resource domain identifier, packages the monitor bus signal and limits access, and controls the processors and the starting from the previous host controller to the respective corresponding peripheral devices and memory areas.

As an improvement of the above solution, the power-saving command and dispatch system further includes:

the bullet screen alarm module is used for rolling and playing the acquired alarm information on a front page of the front end interface in a bullet window mode;

and the alarm pushing module is used for determining abnormal equipment according to the on-line monitoring data, generating abnormal prompt information and performing voice broadcasting.

the task mode generation module is used for determining a target treatment scheme according to the electricity-retaining task based on the corresponding relation between a preset task and the treatment scheme; generating a task list according to the target processing scheme and the distributed electricity-retaining team;

the task issuing module is used for responding to a task distribution instruction of a task initiator and issuing a task according to the task list;

and the task feedback module is used for responding to a task feedback instruction and feeding the acquired feedback information of the electricity-retaining task back to the task initiator.

As an improvement of the above scheme, the task assigning module should follow the following principles when performing task assigning:

the task initiator can issue the electricity-protecting task to all lower related organizations in the command system;

The received organization of the power conservation task may forward the task to its lower level.

As an improvement of the above scheme, the electricity protection commanding and dispatching system comprises an assistance dispatch module for:

when a temporary electricity-keeping task is created, displaying a task configuration progress bar on the front-end interface;

after the temporary electricity-keeping task configuration is completed, a temporary electricity-keeping task list and a corresponding electricity-keeping team are popped up on the front-end interface, and whether to dispatch the task is inquired through voice;

responding to a task dispatching instruction input by a user voice, and dispatching the task according to the electricity-keeping task list and the corresponding electricity-keeping team;

and responding to a task non-dispatching instruction input by the user voice, and continuously displaying a temporary electricity-keeping task list and a corresponding electricity-keeping team on the front-end interface until the task dispatching instruction is received.

As an improvement of the above scheme, the electricity-protection commanding and dispatching system comprises an execution result feedback module for:

responding to a query instruction input by voice, and calling information to be displayed associated with the query instruction to display based on a map of a geographic information system and a power grid.

As an improvement of the above solution, the execution result feedback module is specifically configured to:

Responding to a voice input 'generate an upper power supply traceability map' instruction of an austenite center stadium, and generating a power supply path step by step upwards from an austenite center on a geographic information interface according to a principle that a voltage level is dynamically traced upwards from low to high to trace the power supply path; based on the power supply path, tracing a graph of the power grid by taking a user as a starting point, and determining a tracing route and a tracing direction;

responding to the instruction of the voice input about how to operate the related line, and calling the electricity-saving bulletin information; based on a geographic information system and a map of a power grid, generating a relevant line electricity-protection inspection brief according to the electricity-protection brief information and performing voice broadcasting;

responding to a voice input instruction of requesting to call one line of the line A, automatically calling one line of the line A by the system, and briefly broadcasting an outline;

responding to voice input 'digital twin patrol of the B transformer substation', switching the picture of the front-end interface to a B digital twin view angle of the transformer substation, and completing automatic patrol of the transformer substation;

and responding to the voice input 'automatic negative feedback regulation action immersive guarantee mode' instruction, and selecting a power supply path to automatically patrol, introduce voice, display popup, dispatch a task or interact on site.

As an improvement of the above solution, the execution result feedback module is further configured to:

acquiring progress inquiry problems associated with the inquiry instructions and inquiring a user through voice in the process of calling the information to be displayed associated with the inquiry instructions to display;

after the information to be displayed is displayed, inquiring whether the user performs negative feedback adjustment or not by voice;

and according to the negative feedback operation input by the user, adjusting voice broadcasting information, voice broadcasting frequency or task granularity.

In order to solve the same technical scheme, the embodiment of the invention also provides a power-saving command scheduling method which is adapted to the power-saving command scheduling system and comprises the following steps:

calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient of the event; the electricity-keeping importance coefficient is positively correlated with the risk coefficient, the personnel number coefficient and the public opinion attention coefficient respectively;

calculating a task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event; the target event is an event associated with the electricity-keeping task, and the task risk coefficient is positively correlated with the task importance level, the task difficulty and the electricity-keeping importance coefficient respectively;

As an improvement of the above solution, the course information module, before calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient of the event, the method further includes:

As an improvement of the above solution, the calculating the task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event includes:

As an improvement of the above scheme, the electricity protection commanding and dispatching method further includes:

As an improvement of the scheme, the state registers of the system are static random access memories, and the number of the state registers is flexibly configured by software programming of a processor.

rolling and playing the acquired alarm information on a front page of the front end interface in a popup window mode;

And determining abnormal equipment according to the on-line monitoring data, generating abnormal prompt information and performing voice broadcasting.

determining a target treatment scheme according to the electricity-keeping task based on the corresponding relation between the preset task and the treatment scheme; generating a task list according to the target processing scheme and the distributed electricity-retaining team;

responding to a task distribution instruction of a task initiator, and assigning tasks according to the task list;

and responding to a task feedback instruction, and feeding the acquired feedback information of the electricity-retaining task back to the task initiator.

As an improvement of the above scheme, the following principles are followed when performing task dispatch:

As an improvement of the above solution, the responding to the query command input by voice, based on a map of the geographic information system and the power grid, calls the information to be displayed associated with the query command to display, includes:

Compared with the prior art, the electricity-protecting command dispatching system and method disclosed by the embodiment of the invention comprise the following steps: the monitoring video module is used for selecting a target video to play according to a preset carousel rule or by responding to user operation by accessing a transformer substation video, a transmission line video, a power distribution room video and a task field distribution ball video; the online monitoring module is used for displaying the transmission line alarm data, the transformer substation alarm data and the distribution room alarm data in a set layer window of a front end interface of the system in a rolling way; the layer window is set to be a semitransparent window; the task inspection module is used for rolling and displaying the acquired task inspection information on the front-end interface; the task inspection information at least comprises a task name, an inspection object, an inspection team, a contact way, task creation time, task processing state and task details; the course information module is used for: determining a risk degree estimation coefficient of each occasion according to the risk level of each occasion of the event; wherein the risk level is positively correlated with the risk estimation coefficient; adding the risk estimation coefficients of all the occasions of the event to obtain a risk coefficient of the event; determining a personnel number coefficient of each occasion according to the number of event activities of each occasion; the larger the personnel number coefficient is, the more the corresponding event activity number is; adding the number coefficients of all the scenes of the event to obtain the personnel number coefficient of the event; determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion relation coefficient is, the higher the corresponding public opinion attention is; adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event; calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient; the electricity-keeping importance coefficient is positively correlated with the risk coefficient, the personnel number coefficient and the public opinion attention coefficient respectively; the bullet screen alarm module is used for rolling and playing the acquired alarm information on a front page of the front end interface in a bullet window mode; the task allocation module comprises a task risk calculation unit, a team matching value calculation unit and a task allocation unit; the task risk calculation unit is used for calculating the task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event; the target event is an event associated with the electricity-keeping task, and the task risk coefficient is positively correlated with the task importance level, the task difficulty and the electricity-keeping importance coefficient respectively; the team matching value calculation unit is used for: acquiring all electric protection teams within a preset electric protection range; wherein each of the electricity protection teams comprises at least one electricity protection person; acquiring the position information, the current working state, the acceptance degree and the working age of the electricity-retaining personnel for the temporary emergency task, and constructing a executive matrix; calculating a matrix matching value of each electric protection team according to the executor matrix; the task allocation unit is configured to allocate an electricity-saving team to the electricity-saving task, and includes: calculating the matching degree of each electricity-saving team and the electricity-saving task according to the task risk coefficient of the electricity-saving task and the matrix matching value; and distributing the electricity-retaining team with the highest matching degree for the electricity-retaining task to execute the electricity-retaining task. Therefore, the embodiment of the invention determines the task risk according to the nature of the event and the importance and difficulty of the electricity-saving task, and distributes the proper electricity-saving team for the electricity-saving task by combining the comprehensive quality of the electricity-saving team, thereby reducing the emergency command difficulty and improving the emergency command efficiency.

Drawings

In order to more clearly illustrate the technical solutions of the present invention, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a technical scheme roadmap of a power conservation strategy of a power conservation command and dispatch system according to an embodiment of the invention;

fig. 2 is a flow chart of a power-saving command scheduling method according to an embodiment of the invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. 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 provides a power-saving commanding and dispatching system, which comprises a monitoring terminal and a commanding and dispatching terminal; the monitoring terminal at least comprises a monitoring video module, an online monitoring module and a task inspection module; the command scheduling terminal at least comprises a course information module and a task allocation module;

The monitoring video module is used for accessing a transformer substation video, a transmission line video, a power distribution room video and a task field distribution control ball video, and selecting a target video to play according to a preset carousel rule or by responding to user operation;

the on-line monitoring module is used for displaying the transmission line monitoring data, the transformer substation monitoring data and the distribution room monitoring data in a rolling manner on a set layer window of a front end interface of the system; the layer window is set to be a semitransparent window;

the task inspection module is used for rolling and displaying the acquired task inspection information on the front-end interface; the task inspection information at least comprises a task name, an inspection object, an inspection team, a contact way, task creation time, task processing state and task details;

the course information module is used for:

Determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion relation coefficient is, the higher the corresponding public opinion attention is; adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event;

calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient; the electricity-keeping importance coefficient is positively correlated with the risk coefficient, the personnel number coefficient and the public opinion attention coefficient respectively;

The team matching value calculation unit is used for:

For example, referring to the technical scheme roadmap of the power-on policy of the power-on commanding and dispatching system shown in fig. 1, first, major activity information creation and intelligent task distribution algorithm design are performed.

1. Create of critical activity information

The major activity information creation comprises monitoring video module creation, online monitoring module creation, task patrol item module creation, course information module creation, barrage alarm module creation and major alarm information barrage.

1.1 monitoring video Module creation

The system is connected with a transformer substation video, a transmission line video, a distribution room video and a task field distribution ball video, video pictures of important electricity-protecting places are configured for each professional video point location to conduct carousel, and meanwhile clicking of the self-selection point location is supported to view details of the video pictures.

1.2 on-line monitoring Module creation

The front end (front end interface) of the system map is overlapped with a semitransparent window in the form of a layer, and alarm data of professional online monitoring of a transmission line, a transformer substation and a power distribution room are displayed in a rolling mode, wherein the alarm data comprise statistical data, detail data, alarm data and the like such as wire fairings, icing monitoring, microclimate monitoring, tower inclination monitoring, wind deflection monitoring, image online monitoring and the like.

1.3 creation of task tour Module

The system scrolls and displays task inspection result information (task inspection information) recorded by the APP on site, wherein the task inspection result information comprises task names, task types, inspection objects, inspection teams, team leader names, contact information, task creation time, task processing states and task details (materials such as site photos).

1.4 course importance model creation (course information Module)

The mobile terminal can maintain and display the event scheduling information, and the event scheduling information is acquired in real time by docking the 'sub-fortune online'. Initializing and acquiring the full amount of event activity information by maintaining 'sub-fortune online'; when the arrangement of the event activities changes, related personnel update the event names, the event risk coefficients, the number of event audience personnel, the network audience rating, the related stadium IDs and names, stadium guarantee teams, team leader information, stadium guarantee task information and the like in real time through the system.

The system estimates the importance of the event according to the risk W (x) of the event, the number of personnel involved in the event P (x) and the public opinion rebroadcasting coefficient S (x) to help determine the electricity-keeping importance coefficient Q (x) of the event

Determining the risk coefficient of the event:

determining the risk level of each occasion according to the standard of the table, thereby determining the risk estimation coefficient of each occasion, and calculating the risk coefficient of the occasion as follows

Wherein W (x) represents a risk coefficient, n represents the total number of events, and W represents a risk estimation coefficient corresponding to a single event;

(II) the event involves the determination of a person number coefficient (person number coefficient):

wherein P (x) represents the personnel number coefficient of the event, and P represents the personnel number coefficient of the corresponding single-field event

(III) determining a public opinion attention coefficient of the event:

s (x) represents a public opinion attention coefficient of the event; s represents the public opinion attention coefficient of the corresponding single event;

(IV) determining a power-saving importance coefficient F (X):

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1.5, important alarm information barrage (barrage alarm module)

For the MOC (Main Operations Centre, main operation center) information of the sub-congregation, important emergencies, various alarms and accident tripping information, the system adopts a popup window mode to scroll and play on the front page, and important information details can be clicked and checked.

2. Intelligent task distribution algorithm

2.1 task risk factor simulation (task risk calculation means)

The system determines the task risk coefficient of the electricity-keeping task according to the electricity-keeping importance coefficient of the event, the task importance level of the electricity-keeping task and the task difficulty.

2.2 task executor matrix matching (team matching value calculation unit)

And calling the data of all professionals meeting the conditions reaching the site in the current system task range (preset electricity protection range). And calling the personnel positioning and track tracking in the moving range in a real-time tracking mode of the mobile terminal, thereby obtaining the execution personnel matrix-predicted arrival time.

(1) The system creates a patrol point in an indoor environment, generates a two-dimensional code, and simultaneously establishes a corresponding relation with a patrol specialty, and automatically judges what type of specialty type personnel is needed in a place related to a current electricity-keeping task;

(2) The system automatically provides a personnel file scanning function in the inspection process, and records parameters such as personnel working age, whether emergency tasks are received or not and the like;

(3) When the patrol task is submitted, whether the personnel is currently in a state of executing the task or not is confirmed;

(4) The system calculates a matrix matching value of each team (electricity-retaining team) in the current selectable task pool according to the matrix score, selects a task execution team according to a screening method of the matrix matching value from high to low, and executes next task assignment;

(5) The matrix match value G (x) is the sum of the matrix scores corresponding to the current team. The respective position information, the current operating state, the acceptance degree for the temporary emergency task, and the matrix score corresponding to the work age are shown in the following table.

2.3 task distribution Algorithm

The system regularly generates all the point-to-task of the current day of electricity-protecting team according to the requirement, and sends the point-to-task to the mobile terminal APP of each electricity-protecting team leader after confirmation by the commander, and feeds back the point-to-task to the system after finishing the point-to-task of the team leader and synchronizes to the system.

The system automatically generates all client side teams and power grid side teams corresponding to the venue to the tasks according to the schedule of the event, confirms the tasks by a commander, and sends the tasks to the mobile terminal APP of each electric team leader, feeds back the team leader to the system after finishing the team leader to the system, and synchronizes to the system.

The core of the task distribution algorithm comprises:

and determining whether the current team is the task most suitable for the task according to the ranking of the risk factors, the team matrix and the task distribution matching degree in the respective data, wherein the distributed tasks correspond to the teams one by one. The current electricity-retaining team can get the next task to be executed after the current task is completed. Specifically, the matching degree a (x) of each team with the current corresponding task:

For example, as shown in the following table, for a scenario of a plurality of tasks of a single team Wu Duiying, the matching degree of the team with different tasks is calculated, and the result with the highest matching degree is selected to assign the team the most suitable task.

Taking team K as an example, G (1) in the table represents the matrix matching value of team K for task 1, G (2) represents the matrix matching value of team K for task 2, G (3) represents the matrix matching value of team A for task 3, G #) The matrix matching value of the team K for the task N is indicated, and if R (1) ×g (1) < R (2) ×g (2) < R (3) <. & lt R (N) ×g (N), it can be known that the nth matching scheme is the optimal choice for solving the current problem, and the system will automatically issue the task N with the risk factor R (N) to the electricity-retaining team involved in the nth team matrix matching value.

In one embodiment, the task risk calculation unit is specifically configured to:

The first step is to define the level Ln (special level, special level correlation, first level correlation, second level correlation, third level total 7 power-keeping levels) according to the power-keeping line, respectively corresponding to each power-keeping user, and define a highest power-keeping level, that is, the highest level in the power-keeping levels corresponding to all users, so as to facilitate tracing the user and the activity according to the equipment. The current transformer substation totally relates to 3 superfine lines and 2 primary lines, and then belongs to the superfine transformer substation. The current transformer substation totally relates to 3 special-grade related lines and 2 primary lines, and then belongs to the primary transformer substation. The current transformer substation totally relates to 3 primary circuits and 2 secondary circuits, and then belongs to the primary transformer substation. ( Important electricity-protecting substations and lines in the following table: all the station line nodes in the main power supply line in the current electricity protection activity can directly influence the power supply activity of the electricity protection place if the station line is unexpected, so the station line nodes are defined as important electricity protection substations and lines. On the basis, the important electricity-keeping transformer substation and the circuit are internally divided into special grade, special grade correlation, first grade correlation, second grade correlation and third grade according to the electricity-keeping grade )

Determining the user electricity protection level of each target branch pavilion according to the above table, finding out corresponding coefficients, and adding the electricity protection coefficients of each target branch pavilion to obtain the electricity protection coefficients of the target venue;

second, the scope of electricity-keeping tasks (provincial level, municipal level, administrative district level, stadium building level) is determined

And determining the range coefficient of the target sub-stadium through the table, for example, when the current electricity-protecting activity of the target sub-stadium is highest and relates to a trans-provincial power supply line, the corresponding coefficient is 4, and adding the range coefficients of all the target sub-stadium to obtain the range coefficient of the target stadium.

Third, determining the electricity-keeping task density (task occurrence density brought by different stages of peace war, standby war, temporary war and battle-breaking war)

Determining task density coefficients of a target stadium through the table, and adding the task density coefficients of all the target stadium to obtain the task density coefficients of the target stadium;

fourth, determining a task importance level I (X) of the electricity-keeping task:

wherein, the liquid crystal display device comprises a liquid crystal display device,representing the electricity retention number of the target venue, +.>Representing the electricity retention number of the target venue, +.>Representing the range coefficients of the target venue.

Fifthly, determining the command difficulty (task difficulty) of the electricity-keeping task:

determining the task difficulty of each target stadium according to the table, and adding to obtain the task difficulty of the target stadium:

Multiplying the task importance level, the task difficulty and the electricity-keeping importance coefficient to obtain a task risk coefficient:

in one embodiment, the obtaining the location information, the current working state, the acceptance degree for the temporary emergency task, and the working age of the electricity-protecting person is used for constructing a executor matrix, and specifically includes:

In one embodiment, the task allocation unit is further configured to:

Illustratively, in the "2.3 task distribution algorithm", in addition to the core algorithm, it further includes:

1. electricity-keeping task distribution-intelligent electricity-keeping

The electricity-keeping task mainly comprises the following elements: an electricity-keeping team, an electricity-keeping target, an electricity-keeping execution process, a task execution result and an electricity-keeping task risk, wherein:

1. an electricity protection team: a specific executor of the electricity-keeping task.

2. Electricity-protecting target: and the entity equipment to be protected by the protection team.

3. Starting point: the point at which the power conservation target begins to perform a task, such as a parking spot or workstation.

4. The task execution process comprises the following steps: critical nodes that must be passed under the power conservation task, rather than general nodes that perform actions. The task execution process here is often a business-related node. For example, factors such as the number of points on duty, the type of equipment involved, etc. in the distribution room in the user stadium affect the task execution process parameters.

5. Task execution results: the final execution result of the electricity-saving task is usually the result parameters such as equipment status, inspection times, failure rate and the like.

6. The actions are performed: and distributing actions according to the tasks planned by the factors according to the electricity-keeping task risks.

Each power-preserving task comprises a power-preserving target, and the power-preserving target starts from a starting point and can reach one or more task execution results through one or more task execution processes. And selecting the security point for the electricity-retaining task of the multiple nodes.

2. System hierarchy

The task allocation unit of the electricity-keeping task is divided into two layers, namely, an upper layer business constraint definition and a lower layer core matching algorithm. The traffic constraints are defined as follows:

1. power conservation task distribution-business constraints

Core influencing parameters: business and professional intimate association degree

Business constraints involve a large number of different scenarios, requiring different business requirements to be met, and are relatively complex.

For example, when the task is dispatched, the task to be done may be of different types, some tasks are more urgent, priority is higher, and first task is needed; some tasks have higher waiting cost, so a certain number of teams are required to be reserved for the time, and when the tasks are issued, personnel can be immediately allocated to perform electricity protection; there may be different specialized types of idle teams, with some specialized teams being able to perform only certain types of tasks.

2. Power conservation task distribution-task constraints

Core influencing parameters: task priority

The priorities of different tasks are different, and the following indexes can be used for measuring:

(1) Task issue/deadline: in the current non-empty task pool, different tasks have different issuing time or cut-off time, and generally, the cut-off time is preferentially considered, and the earlier the priority is, the higher the cut-off time is; when the deadline is unknown, the issue time is considered.

(2) Task type: tasks are divided according to types, and include power transmission, power transformation, power distribution tasks and the like.

In general, the priorities of different task types meet the requirements of rush repair task > duty task > inspection task, and the sequence is mainly configured according to actual conditions.

(3) Queuing conditions: taking the rush-repair task as an example, equipment faults may occur in a plurality of power distribution rooms, and a higher priority is required to be adopted for issuing the power distribution professional task, so that the priority of the power distribution room rush-repair task is higher than that of other patrol or on duty tasks.

3. Task matching distribution mechanism

For each task, a comprehensive score can be given according to the index of the task to evaluate the priority of the task; the lower the score, the higher the priority.

For a single index, the corresponding score of each task is defined to be between 0 and 1, and the score is configurable. For example, for an index of task type, two tasks occur in the same time period, and the scores of the task indexes are 0.5,0.8 respectively, and the former task is represented as a preceding task. Should be given priority to currently available teams to execute.

The task types belong to category indexes, and indexes of the type of quantity (task corresponds to the queuing quantity of the tasks in the power distribution room) or time (task deadline) are sorted according to values, and then a score is fitted by the sorting. For example, assuming that the set of tasks is a, B, C, D, E for a total of 5 tasks with deadlines B, C, a, E, D in ascending order, then A, B, C, D, E corresponds to a score of:

Similarly, deadlines also affect the order in which tasks are distributed.

In one embodiment, the task allocation unit is further configured to: when a plurality of electricity-saving tasks exist in the task pool, distributing electricity-saving teams for each electricity-saving task in sequence according to the order of priority from high to low; and each electricity-retaining task corresponds to the assigned electricity-retaining team one by one.

In one embodiment, the system employs a heterogeneous multi-core processor for data processing, the heterogeneous multi-core processor comprising a digital signal processor core.

It can be understood that, in combination with the technical scheme roadmap of the power-on policy of the power-on commanding and dispatching system shown in fig. 1, the technical route further includes application of heterogeneous processors, so as to enhance task allocation and processing efficiency. Heterogeneous multi-core processors contain a general purpose host process and accelerator. Heterogeneous multi-core processors can use different types of processor cores to complete different types of tasks, if the parallelism of the tasks is high, numerous reduced accelerators are used for accelerating, otherwise, powerful general-purpose main processors are used for running.

The heterogeneous multi-core processor is integrated with a plurality of processors, each processor, the bus host, the peripheral equipment and the memory area are configured with a resource domain identifier, the monitoring bus signal is packaged and access is limited, and the processors and the slave master controllers are controlled to be started to the corresponding peripheral equipment and the memory area respectively.

In one embodiment, the status registers of the system are static random access memories, and the number of the status registers is flexibly configured by software programming of the processor. Specifically, the control status registers may be implemented in SRAM (status register, static Random Access Memory), the number of which may be flexibly configured by Cortex-M33 or other processor core software programming.

In one embodiment, the method further comprises:

the alarm pushing module is used for determining abnormal equipment according to the on-line monitoring data, generating abnormal prompt information and performing voice broadcasting;

a task mode generation module for: determining a target treatment scheme according to the electricity-keeping task based on the corresponding relation between the preset task and the treatment scheme; generating a task list according to the target processing scheme and the distributed electricity-retaining team;

the task issuing module is used for responding to a task distribution instruction of a task initiator and distributing the task according to the task list;

In one embodiment, the task assigning module, when performing task assignment, follows the following principles:

Specifically, in connection with fig. 1, the technical route further includes task model creation, specifically including:

(1) Alarm pushing module: according to the existing online monitoring data, after detecting the abnormality or failure of the equipment, carrying out voice broadcasting on the information;

(2) A task mode generation module: determining a power-saving task according to the alarm content, matching a disposal plan, and automatically generating a task list (comprising the alarm content, disposal measures, the affiliated battlefield and the affiliated team);

(3) Task model circulation: the on-site command part can send the task to the battlefield, the team command part and the team at the same time, and the battlefield or the team command part can transfer the task to other organizations or teams, and each level of organization or each level of organization respectively feeds back to the task initiator according to the received task. The principle is as follows:

a. the task initiator can issue tasks to all lower related organizations (war zone, team command part and team) in the command system;

b. the received organizational tasks may forward the tasks to a lower level (battlefield, team director, team);

c. The received task is fed back only to the task initiator.

The voice interaction function is realized aiming at the abnormal alarm information, and the dispatch of the abnormal fault related task list is realized through voice instruction input. When the temporary electricity-keeping task is issued, the system searches for a supporting team, and the system and the commander perform voice interaction and confirm issuing to issue the task once in an interaction way.

In one embodiment, the method further comprises an assistance dispatch module for:

Specifically, in conjunction with fig. 1, the technical route further includes task intelligent generation and assignment, specifically includes intelligent voice-assisted assignment and task streamline reporting.

1. Intelligent voice-assisted dispatch list

(1) When the temporary electricity-keeping task is created, automatically configuring the template task and recommending support personnel, synchronously displaying a temporary label in the system, and displaying a progress bar in automatic configuration of the task.

(2) After the automatic configuration of the system is completed, the configured electricity-keeping task list and the information of the suggested support team are popped up on a large screen, voice inquiry is carried out, the temporary electricity-keeping task is created and searched for the suggested support team, and whether the electricity-keeping task is dispatched or not is judged.

(3) When the commander answers: when the information is sent to the system, the system automatically executes the operation of the dispatch task and displays the information of the responsible person of the electricity-keeping task; if the commander answers: and the task is manually issued later or temporarily not issued, i.e. the task is not dispatched, the system stays in the task configuration interface, and the task and personnel can be continuously configured.

2. Task streamline reporting

The streamline reporting is limited to reporting to the upper command part by the command parts of each level, and can not be reported across levels. Each team commander and war zone commander report information such as zero report, daily report, dynamic information and the like to the superior commander through a PC or APP every day.

In one embodiment, the method further comprises an execution result feedback module for:

In one embodiment, the execution result feedback module is specifically configured to:

responding to voice input 'digital twin patrol of the B transformer substation', switching the picture of the front-end interface to a digital twin view angle of the transformer substation, and completing automatic patrol of the B transformer substation;

In one embodiment, the execution result feedback module is further configured to:

Illustratively, in connection with fig. 1, after the task is dispatched, the execution result of the task is checked, such as asking whether the task is dispatched, the task execution progress is checked by voice, negative feedback adjustment is performed based on the task execution result, and the task execution result is archived. Specifically, the system is based on a map of a Zhejiang power GIS and a power grid, and is switched to a result voice correction mode for improving the control fineness of the power-saving command and improving the display effect. The mode is based on a graph of a power grid, the power protection path is dynamically traced from low to high gradually according to voltage levels, power protection data are displayed in a carousel mode, and the power protection service is inquired and prompted by an AI. More specifically, the system is responsible for a graph of a power grid, overlapping the node progress of the power-saving negative feedback regulation action task, dynamically broadcasting data such as video-saving images, online monitoring, inspection results, team tracks and the like in a carousel mode, carrying out voice broadcasting, splitting the negative feedback regulation action task into professional tasks, and sending an APP end of a field person to be rechecked by the field person.

(1) Negative feedback regulation behavior initiation:

a. the method comprises the steps that a command of generating an upper power supply traceability map of an austenite center stadium is issued through voice, a power supply path is generated step by step upwards from the austenite center by a system geographic information interface, a map geographical map of a power grid is traced by taking a user as a starting point, and a tracing route and direction are selected;

b. the system generates a relevant line electricity-protecting inspection brief report and performs voice broadcasting by calling system electricity-protecting brief report information through voice sending an instruction of how to run relevant lines;

c. the system automatically calls the line one book of the A line and briefly broadcasts the outline by sending an instruction of calling the line one book of the A line through voice;

d. the voice is issued to 'digital twin inspection for the B transformer substation', the picture is switched to the digital twin view angle of the transformer substation, and the inspection for the B transformer substation is completed through automatic inspection;

e. the automatic negative feedback regulation behavior immersion type guarantee mode can be started, and one power supply path is selected for automatic inspection, voice introduction, popup window display, task assignment and field interaction.

(2) Negative feedback regulation behavior reminding: in the negative feedback regulation action process, AI inquires whether a task work order is issued or not through a sound box, reminds whether the task work order is connected with a site or not, broadcasts once after one node rechecks, and inquires whether the negative feedback regulation action is carried out on an untraced line after the whole process is finished.

(3) Negative feedback regulation behavior configuration: the voice of the broadcasting task, the frequency of the broadcasting task, the granularity (comprehensive/quick/custom) of the task and the like can be set.

Referring to a flow chart of a power-saving command scheduling method shown in fig. 2, an embodiment of the present invention provides a power-saving command scheduling method, including:

s1, determining a risk degree estimation coefficient of each occasion according to the risk level of each occasion of the event; wherein the risk level is positively correlated with the risk estimation coefficient; adding the risk estimation coefficients of all the occasions of the event to obtain a risk coefficient of the event;

s2, determining a personnel number coefficient of each occasion according to the number of event activities of each occasion; the larger the personnel number coefficient is, the more the corresponding event activity number is; adding the number coefficients of all the scenes of the event to obtain the personnel number coefficient of the event;

s3, determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion relation coefficient is, the higher the corresponding public opinion attention is; adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event;

S4, calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient; the electricity-keeping importance coefficient is positively correlated with the risk coefficient, the personnel number coefficient and the public opinion attention coefficient respectively;

s5, calculating a task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event; the target event is an event associated with the electricity-keeping task, and the task risk coefficient is positively correlated with the task importance level, the task difficulty and the electricity-keeping importance coefficient respectively;

s6, acquiring all the electricity-protecting teams within a preset electricity-protecting range; wherein each of the electricity protection teams comprises at least one electricity protection person;

s7, acquiring the position information, the current working state, the acceptance degree of the temporary emergency task and the working age of the electricity-retaining personnel, and constructing a executive matrix;

s8, calculating a matrix matching value of each electric protection team according to the executor matrix;

s9, calculating the matching degree of each electricity-retaining team and the electricity-retaining task according to the task risk coefficient of the electricity-retaining task and the matrix matching value;

And S10, distributing an electricity-retaining team with the highest matching degree for the electricity-retaining task to execute the electricity-retaining task.

In one embodiment, the calculating the task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event includes:

In one embodiment, the method further comprises:

In one embodiment, the method further comprises: when a plurality of electricity-saving tasks exist in the task pool, distributing electricity-saving teams for each electricity-saving task in sequence according to the order of priority from high to low; and each electricity-retaining task corresponds to the assigned electricity-retaining team one by one.

In one embodiment, the control status registers may be implemented in SRAM, the number of which may be flexibly configured by Cortex-M33 or other processor core software programming.

In one embodiment, the method further comprises:

determining abnormal equipment according to the on-line monitoring data, generating abnormal prompt information and performing voice broadcasting;

In one embodiment, the following principles are followed when performing a task assignment:

In one embodiment, the method further comprises:

In one embodiment, the responding to the query command input by voice, based on a graph of the geographic information system and the power grid, calls the information to be displayed associated with the query command to display, and includes:

In one embodiment, the method further comprises:

It should be noted that, the working process of the power-saving command scheduling method may refer to the working process of the power-saving command scheduling system in the foregoing embodiment, which is not described herein.

Compared with the prior art, the electricity-protecting command dispatching system and method disclosed by the embodiment of the invention comprise the following steps: determining a risk degree estimation coefficient of each occasion according to the risk level of each occasion of the event; wherein the risk level is positively correlated with the risk estimation coefficient; adding the risk estimation coefficients of all the occasions of the event to obtain a risk coefficient of the event; determining a personnel number coefficient of each occasion according to the number of event activities of each occasion; the larger the personnel number coefficient is, the more the corresponding event activity number is; adding the number coefficients of all the scenes of the event to obtain the personnel number coefficient of the event; determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion relation coefficient is, the higher the corresponding public opinion attention is; adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event; calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient; the electricity-keeping importance coefficient is positively correlated with the risk coefficient, the personnel number coefficient and the public opinion attention coefficient respectively; the bullet screen alarm module is used for rolling and playing the acquired alarm information on a front page of the front end interface in a bullet window mode; calculating a task risk coefficient of the electricity-saving task according to the task importance level and the task difficulty of the electricity-saving task and the electricity-saving importance coefficient of the target event; the target event is an event associated with the electricity-keeping task, and the task risk coefficient is positively correlated with the task importance level, the task difficulty and the electricity-keeping importance coefficient respectively; acquiring all electric protection teams within a preset electric protection range; wherein each of the electricity protection teams comprises at least one electricity protection person; acquiring the position information, the current working state, the acceptance degree and the working age of the electricity-retaining personnel for the temporary emergency task, and constructing a executive matrix; calculating a matrix matching value of each protection team according to the executor matrix; calculating the matching degree of each electricity-saving team and the electricity-saving task according to the task risk coefficient of the electricity-saving task and the matrix matching value; and distributing the electricity-retaining team with the highest matching degree for the electricity-retaining task to execute the electricity-retaining task. Therefore, the embodiment of the invention determines the task risk according to the nature of the event and the importance and difficulty of the electricity-saving task, and combines the comprehensive quality of the electricity-saving team to allocate the proper electricity-saving team for the electricity-saving task without manually allocating the electricity-saving task, thereby reducing the difficulty of emergency command and improving the efficiency of emergency command.

While the foregoing is directed to the preferred embodiments of the present invention, it will be appreciated by those skilled in the art that changes and modifications may be made without departing from the principles of the invention, such changes and modifications are also intended to be within the scope of the invention.

Claims

1. The electricity-retaining commanding and dispatching system is characterized by comprising a monitoring terminal and a commanding and dispatching terminal; the monitoring terminal at least comprises a monitoring video module, an online monitoring module and a task inspection module; the command scheduling terminal at least comprises a course information module and a task allocation module;

The team matching value calculation unit is used for:

distributing an electricity-retaining team with highest matching degree for the electricity-retaining task to execute the electricity-retaining task;

the course information module is specifically configured to, before calculating a power conservation importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient of the event:

determining a risk degree estimation coefficient of each occasion according to the risk level of each occasion of the event; wherein the risk level is positively correlated with the risk estimation coefficient; adding the risk estimation coefficients of all the occasions of the event to obtain a risk coefficient of the event; the hazard classes include high potential hazards, medium potential hazards, lower potential hazards, and little or no hazards;

determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion attention coefficient is, the higher the corresponding public opinion attention is; adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event; the public opinion concerns comprise public opinion high concerns, public opinion medium concerns, public opinion low concerns and public opinion extremely low concerns;

the team matching value calculating unit is configured to obtain location information, a current working state, an acceptance degree for a temporary emergency task, and a working age of the electricity-retaining person, so as to construct a executor matrix, and includes:

determining a third matrix score according to the acceptance degree of the electricity-retaining personnel for the temporary emergency task; wherein the acceptance level is positively correlated with the third matrix score;

constructing an executive matrix according to the first matrix score, the second matrix score, the third matrix score and the fourth matrix score of all electricity-retaining persons;

the team matching value calculating unit is configured to calculate a matrix matching value of each of the electricity-retaining teams according to the executor matrix, and includes: for each electric protection team, adding a first matrix score, the second matrix score, the third matrix score and the fourth matrix score of the electric protection team associated with the electric protection team in the executor matrix to obtain the matrix matching value;

The task allocation unit is configured to calculate, according to the task risk coefficient of the electricity-saving task and the matrix matching value, a matching degree between each electricity-saving team and the electricity-saving task, and includes: and multiplying the task risk coefficient with the matrix matching value of each electricity-protecting team to obtain the matching degree of each electricity-protecting team and the electricity-protecting task.

2. The power conservation command scheduling system of claim 1, wherein,

the monitoring video module is used for selecting a target video to play according to a preset carousel rule or by responding to user operation by accessing a transformer substation video, a transmission line video, a power distribution room video and a task field distribution ball video;

3. The power conservation command scheduling system according to claim 1, wherein the task risk calculation unit is specifically configured to:

determining the electricity-keeping level of the target branch library according to the electricity-keeping level of the electricity-keeping equipment associated with the target branch library, determining the electricity-keeping number of the target branch library according to the electricity-keeping level of the target branch library, and adding the electricity-keeping numbers of all the target branch libraries to obtain the electricity-keeping coefficient of the target venue; the target stadium is a stadium associated with the electricity-keeping task, the target stadium comprises a plurality of target sub-stadiums, and the electricity-keeping level and the electricity-keeping coefficient of the target sub-stadiums are positively correlated;

multiplying the task importance level, the task difficulty and the electricity-keeping importance coefficient of the target event to obtain a task risk coefficient of the electricity-keeping task; wherein the target event is an event associated with the electricity-saving task;

the determining the task density coefficient of the target sub-gallery according to the task execution time of the target sub-gallery includes: when the task execution time of the target sub-stadium is 'the task which lasts 3 days before the current electricity-saving activity competition to the end of the activity', the task density coefficient of the target sub-stadium is 4, when the task execution time of the target sub-stadium is 'the task which lasts 5-3 days before the current electricity-saving activity competition to the end of the activity', the task density coefficient of the target sub-stadium is 3, when the task execution time of the target sub-stadium is 'the task which lasts 7-5 days before the current electricity-saving activity competition to the end of the activity', the task density coefficient of the target sub-stadium is 2, and when the task execution time of the target sub-stadium is 'the task which happens before the current electricity-saving activity for one week', the task density coefficient of the target sub-stadium is 1.

4. The power conservation command scheduling system of claim 1, wherein the task allocation unit is further to:

5. The power conservation command scheduling system of claim 1 or 4 wherein the task allocation unit is further to:

6. The power conservation command scheduling system of claim 1, wherein the system employs heterogeneous multi-core processors for data processing, the heterogeneous multi-core processors comprising digital signal processor cores.

7. The power conservation command scheduling system of claim 6, wherein the status register of the system is a static random access memory, the number of status registers being flexibly configured by software programming of the heterogeneous multi-core processor.

8. The power save command and dispatch system of claim 6 or 7, wherein the heterogeneous multi-core processor is integrated with a plurality of processors, and wherein each of the processors, bus master, peripheral and memory regions is configured with a resource domain identifier, wherein monitor bus signals are packetized and access restricted, and wherein the processors and slave master controllers are controlled to boot to respective corresponding peripheral and memory regions.

9. The power conservation command scheduling system of claim 1, wherein the power conservation command scheduling system further comprises:

10. The power conservation command scheduling system of claim 1, wherein the power conservation command scheduling system further comprises:

the task mode generation module is used for determining a target treatment scheme according to the electricity-retaining task based on the corresponding relation between a preset task and the treatment scheme; generating a task list according to the target treatment scheme and the distributed electricity-retaining team;

11. The power conservation command scheduling system of claim 10 wherein the task assigning module, when executing task assigning, follows the following principle:

all lower related organizations in the task initiation direction command system issue the electricity-protecting task;

And the received organization of the electricity-keeping task transfers the task to the subordinate of the electricity-keeping task.

12. The power conservation command scheduling system of claim 1, wherein the power conservation command scheduling system comprises an assistance dispatch module for:

13. The power conservation command scheduling system of claim 1, wherein the power conservation command scheduling system comprises an execution result feedback module for:

14. The power conservation command scheduling system of claim 13, wherein the execution result feedback module is specifically configured to:

15. The power conservation command scheduling system of claim 13 or 14, wherein the execution result feedback module is further configured to:

16. A power-saving command scheduling method adapted to the power-saving command scheduling system according to any one of claims 1 to 15, comprising:

before calculating the electricity-keeping importance coefficient of the event according to the risk coefficient, the personnel number coefficient and the public opinion attention coefficient of the event, the method further comprises the following steps:

Determining a public opinion attention coefficient of each occasion according to the public opinion attention of each occasion of the event; the larger the public opinion attention coefficient is, the higher the corresponding public opinion attention is; adding the public opinion attention coefficients of all the scenes of the event to obtain the public opinion attention coefficient of the event;

the step of obtaining the position information, the current working state, the acceptance degree and the working age of the electricity-retaining personnel for the temporary emergency task, so as to construct a executive matrix, comprises the following steps:

the calculating the matrix matching value of each of the electric protection teams according to the executives matrix comprises the following steps: for each electric protection team, adding a first matrix score, the second matrix score, the third matrix score and the fourth matrix score of the electric protection team associated with the electric protection team in the executor matrix to obtain the matrix matching value;

the calculating the matching degree of each power saving team and the power saving task according to the task risk coefficient of the power saving task and the matrix matching value comprises the following steps: and multiplying the task risk coefficient with the matrix matching value of each electricity-protecting team to obtain the matching degree of each electricity-protecting team and the electricity-protecting task.

17. The power conservation command scheduling method of claim 16, wherein the calculating the task risk coefficient of the power conservation task according to the task importance level and the task difficulty of the power conservation task and the power conservation importance coefficient of the target event comprises:

18. The power conservation command scheduling method of claim 16, wherein the power conservation command scheduling method further comprises:

19. The power conservation command scheduling method of claim 16 or 18 wherein the power conservation command scheduling method further comprises:

20. The power conservation command scheduling method of claim 16, wherein the system employs a heterogeneous multi-core processor for data processing, the heterogeneous multi-core processor comprising a digital signal processor core.

21. The power conservation command scheduling method of claim 20, wherein the status register of the system is a static random access memory, and the number of the status registers is flexibly configured by software programming of a processor.

22. The power save command and dispatch method of claim 20 or 21, wherein the heterogeneous multi-core processor is integrated with a plurality of processors, and each of the processors, bus master, peripheral and memory regions is configured with a resource domain identifier, and monitor bus signals are packetized and access restricted, controlling the processors and starting from a previous master to the respective corresponding peripheral and memory region.

23. The power conservation command scheduling method of claim 16, wherein the power conservation command scheduling method further comprises:

24. The power conservation command scheduling method of claim 16, wherein the power conservation command scheduling method further comprises:

determining a target treatment scheme according to the electricity-keeping task based on the corresponding relation between the preset task and the treatment scheme; generating a task list according to the target treatment scheme and the distributed electricity-retaining team;

25. The power conservation command scheduling method of claim 24, wherein the following principles are followed when performing the task dispatch:

26. The power conservation command scheduling method of claim 16, wherein the power conservation command scheduling method further comprises:

27. The power conservation command scheduling method of claim 16, wherein the power conservation command scheduling method further comprises:

28. The power conservation command scheduling method of claim 27, wherein the responding to the query command input by voice, based on a graph of a geographic information system and a power grid, retrieving information to be displayed associated with the query command for display comprises:

29. The power conservation command scheduling method of claim 27 or 28 wherein the power conservation command scheduling method further comprises: