CN112456261B - Wisdom garden management system based on internet - Google Patents

Abstract

The invention discloses an intelligent park management system based on the Internet, which utilizes a data acquisition module to acquire the operation information of elevators and the working information of employees in a park; receiving and processing the operation information and the working information by using an information processing module to obtain data processing information; receiving and analyzing the data processing information by using an information analysis module to obtain data analysis information; planning a route between the staff and the elevator by using a planning module according to the data analysis information to obtain planning information; receiving planning information by using a display navigation module, and displaying and navigating; the elevator scheduling method and the elevator scheduling system are used for solving the problems that the staff cannot be matched with floors reached by the staff according to the real-time running state of the elevator in a park during the peak period of work, so that the staff spend more time to queue up for getting on the elevator before work, the work is late, and the recommended elevator accuracy is poor due to the fact that the staff cannot achieve different floors for targeted recommendation and navigation.

Description

Wisdom garden management system based on internet

Technical Field

The invention relates to the technical field of intelligent management, in particular to an intelligent park management system based on the Internet.

Background

The management of the park is all-around and multi-level management, and the problems of step-by-step monitoring and management of projects, companies, various industries and various departments, adaptation and risk control of different market environments, resource integration and coordination problems caused by professional division and refinement and the like are all challenges faced by the park in the management. The intelligent park is established to help the park to establish a unified organization management coordination framework, a business management platform and an internal and external service operation platform in the aspect of informatization; a unified working flow, a cooperation mechanism, a scheduling mechanism and a sharing mechanism need to be established, a tightly-connected whole is formed by integrating a cloud platform and taking the cloud platform as a hub, and the benefits of high efficiency, cooperation, interaction and the whole are obtained; 2, establishing 2 large services and 2 large management systems of unified emergency management and daily management, internal and external services; and a unified comprehensive management platform is established, and a park comprehensive management service system is established according to application requirements of safety, environmental protection, emergency, energy, economy, offices of parks and enterprises and the like.

Patent publication No. CN105129552B discloses an elevator management system that enables selection of a desired destination floor from a plurality of destination floors without taking extra time and effort. The elevator management system comprises: a reading device provided in a landing shared by a plurality of elevators; a display device provided corresponding to the landing; a detection device provided corresponding to the landing; and a control device that, when the reading device reads information from the tag, selects an elevator from the plurality of elevators that is assigned to each of the plurality of pieces of destination floor information corresponding to the information, causes the display device to display information indicating the assigned elevator, selects an elevator from the elevators corresponding to each of the plurality of pieces of destination floor information based on the position of the user detected by the detection device, and releases the assignment of an elevator other than the selected elevator.

The existing intelligent park management system based on the internet has the following defects: the elevator scheduling method has the advantages that during the peak working hours in the park, the elevator cannot be matched with floors reached by staff according to the real-time running state of the elevator, so that the staff spend more time before working to queue up for the elevator and the elevator is late to work, and the elevator cannot be subjected to targeted recommendation and navigation according to different floors reached by different staff and the accuracy of the recommended elevator is poor.

Disclosure of Invention

The invention aims to provide an intelligent park management system based on the Internet, and the technical problems to be solved by the invention are as follows:

how to solve in the prior art scheme during the park during peak period of working can not match with the floor that the staff reached according to the real-time running state of elevator for staff consumes more time to queue up to go to the elevator before working and leads to the problem of late arrival to working, and can not reach the not good problem of elevator accuracy that the pertinence was recommended and the navigation leads to recommending according to different staff.

The purpose of the invention can be realized by the following technical scheme: an intelligent park management system based on the Internet comprises a data acquisition module, a data transmission module, an information processing module, an information analysis module, a planning module and a display navigation module;

the data acquisition module is used for acquiring the operation information of the elevator and the working information of the staff in the park, the operation information comprises the operation position data, the carrying data, the operation time data, the stay time data and the stay floor data of the elevator, the working information comprises the working floor data, the moving position data and the weight data of the staff, and the operation information and the working information are sent to the information processing module through the data transmission module;

the information processing module is used for receiving and processing the operation information and the working information to obtain data processing information and sending the data processing information to the information analysis module;

the information analysis module is used for receiving and analyzing the data processing information to obtain data analysis information and sending the data analysis information to the planning module; the specific analysis steps include:

the method comprises the following steps: acquiring an operation sorting set and an inosculation sorting set in the data processing information;

step two: using formulas

Acquiring a matching coefficient between the running sorting set and the anastomotic sorting set; where ki is expressed as a matching coefficient, δ is expressed as a preset matching correction factor, Q _yx Expressed as a running value, Q, in a running ordered set _wh Expressed as a matching value in the matching ordered set;

step three: the matching coefficients are sorted in a descending order, the matching coefficient with the largest value is obtained and marked as the optimal matching coefficient;

step four: obtaining the running elevator corresponding to the running value in the running sorting set according to the optimal matching coefficient, and marking the running elevator as a recommended elevator;

step five: combining the matching coefficients in descending order, the marked optimal matching coefficients and the marked recommended elevators to obtain data analysis information;

the planning module plans the route between the staff and the elevator according to the data analysis information to obtain planning information, and sends the planning information to the display navigation module through the data transmission module;

the display navigation module is used for receiving planning information and carrying out display and navigation;

the data transmission module is used for transmitting data among the modules.

Preferably, the information processing module is configured to receive and process the operation information and the working information to obtain data processing information, and the specific steps include:

s21: acquiring running position data, carrying data, running time data, stopping time data and stopping floor data of the elevator in the running information;

s22: marking run position data as W _i I =1,2.. N, the maximum accommodated mass in the carrying data is marked as Z1, the loaded mass in the carrying data is marked as Z2, the running time length of each floor up and down of the elevator in the running time data is marked as T0, the stopping time length of the elevator at each floor in the stopping data is marked as Ti, and i =1,2.. N;

s23: setting different floor preset values for different floors, matching the data of the staying floor with all the floors to obtain corresponding floor preset values, marking the corresponding floor preset values as L0, accumulating the floor preset values between the data of the staying floor and the ground to obtain interval floor values, and marking the interval floor values as Li, wherein i =1,2.. N;

s24: obtaining the running value of the elevator by using a formula;

s25: performing descending order arrangement on the plurality of operation values to obtain an operation order arrangement set;

s26: acquiring working floor data, mobile position data and weight data in the working information;

s27: matching the data of the working floors with all floors to obtain corresponding floor preset values, marking the floor preset values as LP, accumulating the floor preset values between the working floors and the ground to obtain fixed floor values, marking the floor preset values as LP0, and marking the weight data as Z3;

s28: marking the moving position data as WY, setting the entrance and exit of the garden building as the center of a circle, the length of the garden building as the abscissa, the width of the garden building as the ordinate and the preset distance value as the coordinate interval to establish a coordinate system, and utilizing a distance formula

Obtaining distance data between the mobile position data and the operation position data of the elevator;

wherein, WY _x Expressed as abscissa, W, in the employee's mobile position data _ix Expressed as abscissa, WY, of the operating position data of the elevator _y Expressed as ordinate, W, in the employee's mobile position data _iy An ordinate represented as operating position data of the elevator;

s29: acquiring an inosculation value of the employee by using a formula;

s210: and performing descending order arrangement on the plurality of coincidence values to obtain a coincidence ordering set, and combining the operation ordering set and the coincidence ordering set to obtain data processing information.

Preferably, the operating values of the elevator are obtained by means of a formula, which is:

wherein Q _yx Expressed as an operation value, mu is expressed as a preset elevator correction factor, a1, a2, a3 and a4 are all expressed as different proportionality coefficients, and a1<a2<a3<a4。

Preferably, the matching value of the employee is obtained by using a formula, wherein the formula is as follows:

wherein Q _wh Expressed as an agreement value, eta is expressed as a preset staff information correction factor, b1 and b2 are expressed as different proportionality coefficients, and b1<b2。

Preferably, the planning module plans the route between the employee and the elevator according to the data analysis information, and the specific steps include:

s51: obtaining the recommended elevator running position in the data analysis information by using a distance formula

Obtaining a distance difference D between the recommended elevator and the mobile position of the employee;

wherein, WY _x Expressed as the abscissa, WT, of the mobile position of the staff _x Abscissa, WY, expressed as the travel position of the recommended elevator _y Expressed as the ordinate, WT, of the employee's mobile position _y A ordinate representing the operating position of the recommended elevator;

s52: the method comprises the steps of obtaining the moving speed of an employee and marking the moving speed as v0, and obtaining the moving time t0 when the employee reaches a recommended elevator according to a formula t0= D/v 0;

s53: acquiring the running height, the number of loaded people and the height of each floor of a recommended elevator, marking the running height as h, the height of each floor as c, the number of loaded people as r, and acquiring the reaching time of the recommended elevator reaching the ground by using a formula T1= h x T0/c + r x Ti; wherein T0 represents the running time of the recommended elevator passing through each floor, and Ti represents the stay time of the recommended elevator on each floor;

s54: and combining the distance difference, the moving time and the reaching time to obtain planning information.

Preferably, the display navigation module is configured to receive planning information and perform display and navigation, and includes: the distance difference, the moving time and the reaching time in the planning information are obtained, the expected time point when the employee reaches the recommended elevator is displayed according to the moving time, the expected time point when the recommended elevator reaches the ground is displayed according to the reaching time, and the employee is navigated to the position of the recommended elevator according to the distance difference.

The invention has the beneficial effects that:

in the aspects disclosed by the invention, the operation information of the elevator and the working information of the staff in the park are acquired by using a data acquisition module, wherein the operation information comprises the operation position data, the carrying data, the operation time data, the stay time data and the stay floor data of the elevator, and the working information comprises the working floor data, the moving position data and the weight data of the staff; by collecting and processing the operation information of the elevator and the working information of the staff, data support is provided for the accuracy and the high efficiency of elevator recommendation of the staff;

receiving and processing the operation information and the working information by using an information processing module to obtain data processing information;

receiving and analyzing the data processing information by using an information analysis module to obtain data analysis information; the running information and the working information are processed and analyzed, so that the running conditions of different elevators can be obtained and different employees can be accurately recommended, and the accuracy of matching the elevators for different employees is improved by comprehensively considering the running position data, the carrying data, the running time data, the staying floor data and the working floor data, the moving position data and the weight data in the running information;

planning a route between the staff and the elevator by using a planning module according to the data analysis information to obtain planning information, and sending the planning information to a display navigation module through a data transmission module;

the display navigation module is used for receiving planning information and displaying and navigating the planning information, so that the problems that the staff cannot be matched with floors reached by the staff according to the real-time running state of the elevator in the park at the peak working hours, the staff spend more time before working to queue up to get to the elevator and cause the delay to work are solved, and the problems that the staff cannot reach different floors according to different staff to carry out targeted recommendation and navigation, so that the accuracy of the recommended elevator is poor are solved.

Drawings

The invention is further described below with reference to the accompanying drawings.

Fig. 1 is a schematic block diagram of an internet-based intelligent campus management system according to the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

Referring to fig. 1, the present invention is an internet-based intelligent park management system, which includes a data acquisition module, a data transmission module, an information processing module, an information analysis module, a planning module, and a display navigation module;

the data acquisition module is used for acquiring operation information of an elevator and working information of staff in a park, the operation information comprises operation position data, carrying data, operation time data, stay time data and stay floor data of the elevator, the working information comprises the working floor data, moving position data and weight data of the staff, and the operation information and the working information are sent to the information processing module through the data transmission module;

the information processing module is used for receiving and processing the operation information and the working information to obtain data processing information and sending the data processing information to the information analysis module; the method comprises the following specific steps:

acquiring running position data, carrying data, running time data, stopping time data and stopping floor data of the elevator in the running information;

marking run position data as W _i N, marking the maximum contained mass in the carried data as Z1, the loaded mass in the carried data as Z2, and the elevator in the run-time data as Z2The running time of each floor above and below is marked as T0, the stopping time of the elevator on each floor in the stopping data is marked as Ti, and i =1,2.. N;

setting different floor preset values for different floors, matching the data of the staying floor with all the floors to obtain corresponding floor preset values, marking the corresponding floor preset values as L0, accumulating the floor preset values between the data of the staying floor and the ground to obtain interval floor values, and marking the interval floor values as Li, wherein i =1,2.. N;

obtaining the running value of the elevator by using a formula; the formula is:

wherein Q is _yx Expressed as an operating value, mu as a preset elevator correction factor, a1, a2, a3, a4 each expressed as a different scaling factor, and a1<a2<a3<a4；

Performing descending order arrangement on the plurality of operation values to obtain an operation order arrangement set;

acquiring working floor data, mobile position data and weight data in the working information;

matching the data of the working floors with all floors to obtain corresponding floor preset values, marking the floor preset values as LP, accumulating the floor preset values between the working floors and the ground to obtain fixed floor values, marking the floor preset values as LP0, and marking the weight data as Z3;

marking the moving position data as WY, setting the entrance and exit of the garden building as the center of a circle, the length of the garden building as the abscissa, the width of the garden building as the ordinate and the preset distance value as the coordinate interval to establish a coordinate system, and utilizing a distance formula

Obtaining distance data between the mobile position data and the operation position data of the elevator;

wherein, WY _x Expressed as abscissa, W, in the employee's mobile position data _ix Expressed as abscissa, WY, of the operating position data of the elevator _y Expressed as ordinate, W, in the employee's mobile position data _iy An ordinate represented as operating position data of the elevator;

obtaining the coincidence value of the employee by using a formula; the formula is:

wherein Q _wh Expressed as a coincidence value, eta is expressed as a preset staff information correction factor, b1 and b2 are expressed as different scale factors, and b1<b2；

Performing descending order arrangement on the plurality of coincidence values to obtain a coincidence ordering set, and combining the operation ordering set and the coincidence ordering set to obtain data processing information;

the information analysis module is used for receiving and analyzing the data processing information to obtain data analysis information and sending the data analysis information to the planning module; the specific analysis steps include:

acquiring a running sequencing set and an aggregation sequencing set in data processing information;

using formulas

Acquiring a matching coefficient between the running sorting set and the anastomotic sorting set; where ki is expressed as a matching coefficient, δ is expressed as a preset matching correction factor, Q _yx Expressed as a running value, Q, in a running ordered set _wh Expressed as a matching value in the matching ordered set;

the matching coefficients are sorted in a descending order, the matching coefficient with the largest value is obtained and marked as the optimal matching coefficient;

obtaining the running elevator corresponding to the running value in the running sorting set according to the optimal matching coefficient, and marking the running elevator as a recommended elevator;

combining the matching coefficients in descending order, the marked optimal matching coefficients and the marked recommended elevators to obtain data analysis information;

the planning module plans the route between the staff and the elevator according to the data analysis information to obtain planning information, and sends the planning information to the display navigation module through the data transmission module; the method comprises the following specific steps:

obtaining the recommended elevator running position in the data analysis information by using a distance formula

Obtaining a distance difference D between the recommended elevator and the mobile position of the employee;

wherein, WY _x Expressed as the abscissa of the employee's mobile position, WT _x Abscissa, WY, expressed as the travel position of the recommended elevator _y Expressed as the ordinate, WT, of the employee's mobile position _y An ordinate representing the travel position of the recommended elevator;

the method comprises the steps of obtaining the moving speed of an employee and marking the moving speed as v0, and obtaining the moving time t0 when the employee reaches a recommended elevator according to a formula t0= D/v 0;

acquiring the running height, the number of people loaded and the height of each floor of a recommended elevator, marking the running height as h, the height of each floor as c, the number of people loaded as r, and acquiring the reaching time of the recommended elevator reaching the ground by using a formula T1= h T0/c + r Ti; wherein T0 represents the running time of the recommended elevator passing through each floor, and Ti represents the stay time of the recommended elevator on each floor;

combining the distance difference, the moving time and the reaching time to obtain planning information;

the display navigation module is used for receiving planning information and performing display and navigation; the method comprises the following steps: obtaining distance difference, moving time and reaching time in the planning information, displaying a predicted time point when the employee reaches the recommended elevator according to the moving time, displaying a predicted time point when the recommended elevator reaches the ground according to the reaching time, and navigating the employee to the position of the recommended elevator according to the distance difference;

the data transmission module is used for transmitting data among the modules;

the above formulas are all obtained by collecting a large amount of data and performing software simulation, and the formula is selected to be close to the true value, and the coefficients in the formulas are set by the person skilled in the art according to the actual situation.

The working principle of the invention is as follows: the method comprises the steps that a data acquisition module is used for acquiring operation information of an elevator and working information of staff in a park, wherein the operation information comprises operation position data, carrying data, operation time data, stay time data and stay floor data of the elevator, and the working information comprises the working floor data, moving position data and weight data of the staff and is sent to an information processing module through a data transmission module;

the information processing module is used for receiving and processing the operation information and the working information to obtain the operation position data, the carrying data, the operation time data, the staying time data and the staying floor data of the elevator in the operation information; marking run position data as W _i I =1,2.. N, the maximum accommodated mass in the carrying data is marked as Z1, the loaded mass in the carrying data is marked as Z2, the running time length of each floor up and down of the elevator in the running time data is marked as T0, the stopping time length of the elevator at each floor in the stopping data is marked as Ti, i =1,2.. N; setting different floor preset values for different floors, matching the data of the staying floor with all the floors to obtain corresponding floor preset values, marking the corresponding floor preset values as L0, accumulating the floor preset values between the data of the staying floor and the ground to obtain interval floor values, and marking the interval floor values as Li, wherein i =1,2.. N; obtaining the running value of the elevator by using a formula; the formula is:

wherein Q is _yx Expressed as an operating value, mu as a preset elevator correction factor, a1, a2, a3, a4 each expressed as a different scaling factor, and a1<a2<a3<a4；

Performing descending order arrangement on the plurality of operation values to obtain an operation order arrangement set; acquiring working floor data, mobile position data and weight data in the working information; matching the data of the working floor with all floors to obtain corresponding floor pre-treatmentSetting and marking the value as LP, accumulating the preset values of the floors between the working floor and the ground to obtain a fixed floor value and marking the fixed floor value as LP0, and marking the weight data as Z3; marking the moving position data as WY, setting the entrance and exit of the garden building as the center of a circle, the length of the garden building as the abscissa, the width of the garden building as the ordinate and the preset distance value as the coordinate interval to establish a coordinate system, and utilizing a distance formula

Obtaining distance data between the mobile position data and the operation position data of the elevator; wherein, WY _x Expressed as abscissa, W, in the employee's mobile position data _ix Abscissa, WY, expressed as running position data of the elevator _y Expressed as ordinate, W, in the employee's mobile position data _iy An ordinate represented as operating position data of the elevator; acquiring an inosculation value of the employee by using a formula; the formula is:

wherein Q _wh Expressed as an agreement value, eta is expressed as a preset staff information correction factor, b1 and b2 are expressed as different proportionality coefficients, and b1<b2; performing descending order arrangement on the plurality of coincidence values to obtain a coincidence ordering set, and combining the operation ordering set and the coincidence ordering set to obtain data processing information;

receiving and analyzing the data processing information by using an information analysis module, and acquiring a running sorting set and an aggregation sorting set in the data processing information; using a formula

Acquiring a matching coefficient between the running sorting set and the inosculating sorting set; where ki is expressed as a matching coefficient, δ is expressed as a preset matching correction factor, Q _yx Expressed as a running value, Q, in a running ordered set _wh Expressed as a fitness value in a ranked set of fitness; arranging a plurality of matching coefficients in descending order to obtain the value with the maximum valueMatching the coefficients and marking as optimal matching coefficients; obtaining the running elevator corresponding to the running value in the running sorting set according to the optimal matching coefficient, and marking the running elevator as a recommended elevator; combining the matching coefficients in descending order, the marked optimal matching coefficients and the marked recommended elevators to obtain data analysis information;

planning the route between the staff and the elevator by using a planning module according to the data analysis information, acquiring the operation position of the recommended elevator in the data analysis information, and using a distance formula

Obtaining a distance difference D between the recommended elevator and the mobile position of the employee;

wherein, WY _x Expressed as the abscissa of the employee's mobile position, WT _x Abscissa, WY, expressed as the travel position of the recommended elevator _y Expressed as the ordinate of the employee's mobile position, WT _y A ordinate representing the operating position of the recommended elevator; the method comprises the steps of obtaining the moving speed of an employee and marking the moving speed as v0, and obtaining the moving time t0 when the employee reaches a recommended elevator according to a formula t0= D/v 0; acquiring the running height, the number of people loaded and the height of each floor of a recommended elevator, marking the running height as h, the height of each floor as c, the number of people loaded as r, and acquiring the reaching time of the recommended elevator reaching the ground by using a formula T1= h T0/c + r Ti; wherein T0 represents the running time of the recommended elevator passing through each floor, and Ti represents the stay time of the recommended elevator on each floor; combining the distance difference, the moving time and the reaching time to obtain planning information;

receiving planning information by using a display navigation module, and displaying and navigating: obtaining distance difference, moving time and reaching time in the planning information, displaying a predicted time point when the employee reaches the recommended elevator according to the moving time, displaying a predicted time point when the recommended elevator reaches the ground according to the reaching time, and navigating the employee to the position of the recommended elevator according to the distance difference;

transmitting data among the modules by using a data transmission module;

compared with the prior art, the invention has the advantages that in each aspect, the data acquisition module is used for acquiring the operation information of the elevator and the work information of the staff in the park, the operation information comprises the operation position data, the carrying data, the operation time data, the stay time data and the stay floor data of the elevator, and the work information comprises the work floor data, the moving position data and the weight data of the staff; by collecting and processing the operation information of the elevator and the working information of the staff, data support is provided for the accuracy and the high efficiency of elevator recommendation of the staff;

receiving and processing the operation information and the working information by using an information processing module to obtain data processing information;

receiving and analyzing the data processing information by using an information analysis module to obtain data analysis information; the running information and the working information are processed and analyzed, so that the running conditions of different elevators can be obtained and different employees can be accurately recommended, and the accuracy of matching the elevators for different employees is improved by comprehensively considering the running position data, the carrying data, the running time data, the staying floor data and the working floor data, the moving position data and the weight data in the running information;

planning a route between the staff and the elevator by using a planning module according to the data analysis information to obtain planning information, and sending the planning information to a display navigation module through a data transmission module;

the display navigation module is used for receiving planning information and displaying and navigating the planning information, so that the problems that the staff cannot be matched with floors reached by the staff according to the real-time running state of the elevator in the park at the peak working hours, the staff spend more time before working to queue up to get to the elevator and cause the delay to work are solved, and the problems that the staff cannot reach different floors according to different staff to carry out targeted recommendation and navigation, so that the accuracy of the recommended elevator is poor are solved.

In the embodiments provided by the present invention, it should be understood that the disclosed system and method can be implemented in other ways. For example, the above-described embodiments are merely illustrative, and for example, the division of the modules is only one logical functional division, and other divisions may be realized in practice.

The modules described as separate parts may or may not be physically separate, and parts displayed as modules may or may not be physical modules, may be located in one place, or may be distributed on a plurality of network modules. Some or all of the modules may be selected according to actual needs to achieve the purpose of the method of the embodiment.

In addition, functional modules in the embodiments of the present invention may be integrated into one processing module, or each module may exist alone physically, or two or more modules are integrated into one module. The integrated module can be realized in a hardware form, and can also be realized in a form of hardware and a software functional module.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference signs in the claims shall not be construed as limiting the claim concerned.

Furthermore, it is to be understood that the word "comprising" does not exclude other modules or steps, and the singular does not exclude the plural. A plurality of modules or means recited in the system claims may also be implemented by one module or means in software or hardware. The terms second, etc. are used to denote names, but not any particular order.

Finally, it should be noted that the above examples are only intended to illustrate the technical process of the present invention and not to limit the same, and although the present invention has been described in detail with reference to the preferred embodiments, it will be understood by those skilled in the art that modifications or equivalent substitutions may be made to the technical process of the present invention without departing from the spirit and scope of the technical process of the present invention.

Claims (3)

1. An intelligent park management system based on the Internet is characterized by comprising a data acquisition module, a data transmission module, an information processing module, an information analysis module, a planning module and a display navigation module;

the data acquisition module is used for acquiring operation information of an elevator and working information of staff in a park, the operation information comprises operation position data, carrying data, operation time data, stay time data and stay floor data of the elevator, the working information comprises the working floor data, moving position data and weight data of the staff, and the operation information and the working information are sent to the information processing module through the data transmission module;

the information processing module is used for receiving and processing the operation information and the working information to obtain data processing information and sending the data processing information to the information analysis module;

the information analysis module is used for receiving and analyzing the data processing information to obtain data analysis information and sending the data analysis information to the planning module; the specific analysis steps include:

the method comprises the following steps: acquiring a running sequencing set and an aggregation sequencing set in data processing information;

step two: using formulas

Acquiring a matching coefficient between the running sorting set and the inosculating sorting set; where ki is expressed as a matching coefficient, δ is expressed as a preset matching correction factor, Q _yx Expressed as a running value, Q, in a running ordered set _wh Expressed as a fitness value in a ranked set of fitness;

step three: the matching coefficients are sorted in a descending order, the matching coefficient with the largest value is obtained and marked as the optimal matching coefficient;

step four: obtaining running elevators corresponding to the running values in the running sorting set according to the optimal matching coefficient, and marking the running elevators as recommended elevators;

step five: combining the matching coefficients in descending order, the marked optimal matching coefficients and the marked recommended elevators to obtain data analysis information;

the planning module plans the route between the staff and the elevator according to the data analysis information to obtain planning information, and sends the planning information to the display navigation module through the data transmission module;

the display navigation module is used for receiving planning information and carrying out display and navigation;

the data transmission module is used for transmitting data among the modules;

the information processing module is used for receiving and processing the operation information and the working information to obtain data processing information, and the specific steps comprise:

s21: acquiring running position data, carrying data, running time data, stopping time data and stopping floor data of the elevator in the running information;

s22: marking run position data as W _i I =1,2.. N, the maximum accommodated mass in the carrying data is marked as Z1, the loaded mass in the carrying data is marked as Z2, the running time length of each floor up and down of the elevator in the running time data is marked as T0, the stopping time length of the elevator at each floor in the stopping data is marked as Ti, and i =1,2.. N;

s23: setting different floor preset values for different floors, matching the data of the staying floor with all the floors to obtain corresponding floor preset values, marking the corresponding floor preset values as L0, accumulating the floor preset values between the data of the staying floor and the ground to obtain interval floor values, and marking the interval floor values as Li, wherein i =1,2.. N;

s24: obtaining the running value of the elevator by using a formula;

s25: performing descending order arrangement on the plurality of operation values to obtain an operation order arrangement set;

s26: acquiring working floor data, mobile position data and weight data in the working information;

s27: matching the data of the working floors with all floors to obtain corresponding floor preset values, marking the floor preset values as LP, accumulating the floor preset values between the working floors and the ground to obtain fixed floor values, marking the floor preset values as LP0, and marking the weight data as Z3;

s28: marking the moving position data as WY, setting the entrance and exit of the garden building as the center of a circle, the length of the garden building as the abscissa, the width of the garden building as the ordinate and the preset distance value as the coordinate interval to establish a coordinate system, and utilizing a distance formula

Obtaining distance data between the mobile position data and the operation position data of the elevator;

wherein, WY _x Expressed as abscissa, W, in the employee's mobile position data _ix Expressed as abscissa, WY, of the operating position data of the elevator _y Expressed as ordinate, W, in the employee's mobile position data _iy An ordinate represented as operating position data of the elevator;

s29: obtaining the coincidence value of the employee by using a formula;

s210: performing descending order arrangement on the plurality of coincidence values to obtain a coincidence ordering set, and combining the operation ordering set and the coincidence ordering set to obtain data processing information;

the operation value of the elevator is obtained by using a formula, wherein the formula is as follows:

wherein Q is _yx Expressed as an operating value, mu as a preset elevator correction factor, a1, a2, a3, a4 each expressed as a different scaling factor, and a1<a2<a3<a4；

Obtaining the coincidence value of the employee by using a formula, wherein the formula is as follows:

wherein Q is _wh Expressed as an agreement value, eta is expressed as a preset staff information correction factor, b1 and b2 are expressed as different proportionality coefficients, and b1<b2。

2. The internet-based intelligent campus management system of claim 1 wherein said planning module plans the route between the employees and the elevators based on the data analysis information, the specific steps including:

s51: obtaining the recommended elevator running position in the data analysis information by using a distance formula

Obtaining a distance difference D between the recommended elevator and the mobile position of the employee;

wherein, WY _x Expressed as the abscissa, WT, of the mobile position of the staff _x Abscissa, WY, expressed as the travel position of the recommended elevator _y Expressed as the ordinate, WT, of the employee's mobile position _y A ordinate representing the operating position of the recommended elevator;

s52: the method comprises the steps of obtaining the moving speed of an employee and marking the moving speed as v0, and obtaining the moving time t0 when the employee reaches a recommended elevator according to a formula t0= D/v 0;

s53: acquiring the running height, the number of people loaded and the height of each floor of a recommended elevator, marking the running height as h, the height of each floor as c, the number of people loaded as r, and acquiring the reaching time of the recommended elevator reaching the ground by using a formula T1= h T0/c + r Ti; wherein T0 represents the running time of the recommended elevator passing through each floor, and Ti represents the stay time of the recommended elevator on each floor;

s54: and combining the distance difference, the moving time and the reaching time to obtain planning information.

3. The internet-based intelligent campus management system of claim 1 wherein said display navigation module is adapted to receive planning information and to display and navigate, comprising: the distance difference, the moving time and the reaching time in the planning information are obtained, the expected time point when the employee reaches the recommended elevator is displayed according to the moving time, the expected time point when the recommended elevator reaches the ground is displayed according to the reaching time, and the employee is navigated to the position of the recommended elevator according to the distance difference.

Images