CN112529347B - Logistics data simulation method and device, electronic equipment and storage medium - Google Patents

Abstract

The embodiment of the application provides a logistics data simulation method, a device, electronic equipment and a storage medium, which are used for improving the processing efficiency of logistics planning. Applied to a simulation system, the simulation system having a simulation page, the method comprising: receiving logistics simulation parameters acquired through a parameter setting control in the simulation page; performing simulation processing according to the logistics simulation parameters to obtain corresponding logistics simulation results, wherein the logistics simulation results comprise nodes and node simulation information; and matching the logistics simulation result with the map of the simulation page to obtain simulation page data, wherein nodes in the logistics simulation result correspond to position points in the map of the simulation page. The visualized simulation page is used for carrying out the participating configuration and the simulation result display, so that the logistics simulation can be conveniently carried out, the accuracy is higher, the operation complexity is reduced, and the processing efficiency of logistics planning is improved.

Description

Logistics data simulation method and device, electronic equipment and storage medium

Technical Field

The present application relates to the field of computer technology, and in particular, to a method for simulating physical distribution data, a device for simulating physical distribution data, an electronic device, and a storage medium.

Background

In the logistics field, the routing generally refers to the sum of processing links from order acceptance to signing in, and is a process of tight connection and integration of processes including acceptance, ordering, picking, site operation, distribution, transportation (such as dry and branch transportation), sorting, dispatch, signing in and the like. Multiple types of nodes such as warehouse, distribution center, distribution site and the like in the logistics field can form a logistics network, logistics objects are transported among the nodes, and the routing process is realized based on the nodes

At present, the route planning usually depends on Excel for calculation and analysis, but with the increase of logistics demands, the expansion of logistics service range and the like, the efficiency of calculation and analysis through Excel is lower, and the service demands are difficult to meet.

And, route analysis results obtained through Excel calculation and analysis also need to take more time to check, modify, export data and the like, and the error rate of the results is higher.

Disclosure of Invention

The embodiment of the application provides a logistics data simulation method for improving the processing efficiency of logistics planning.

Correspondingly, the embodiment of the application also provides a logistics data simulation device, electronic equipment and a storage medium, which are used for guaranteeing the realization and the application of the system.

In order to solve the above problems, an embodiment of the present application discloses a method for simulating physical distribution data, which is applied to a simulation system, wherein the simulation system has a simulation page, and the method includes: receiving logistics simulation parameters acquired through a parameter setting control in the simulation page; performing simulation processing according to the logistics simulation parameters to obtain corresponding logistics simulation results, wherein the logistics simulation results comprise nodes and node simulation information; and matching the logistics simulation result with the map of the simulation page to obtain simulation page data, wherein nodes in the logistics simulation result correspond to position points in the map of the simulation page.

The embodiment of the application also discloses a logistics data simulation method, which comprises the following steps: displaying a simulation page, wherein the simulation page is provided with a parameter setting control, and a map is displayed on the simulation page; acquiring logistics simulation parameters through the parameter setting control, and sending the logistics simulation parameters; receiving simulation page data, wherein the simulation page data is determined according to a logistics simulation result of a logistics simulation parameter, and the logistics simulation result comprises position points and node simulation information; rendering the simulation page data, and displaying position points and node simulation information corresponding to the nodes in the simulation page.

The embodiment of the application also discloses a logistics data simulation device, which comprises: the parameter acquisition module is used for receiving the logistics simulation parameters acquired through the parameter setting control in the simulation page; the simulation module is used for performing simulation processing according to the logistics simulation parameters to obtain corresponding logistics simulation results, wherein the logistics simulation results comprise nodes and node simulation information; and the visualization processing module is used for matching the logistics simulation result with the map of the simulation page to obtain simulation page data, wherein nodes in the logistics simulation result correspond to position points in the map of the simulation page.

The embodiment of the application also discloses a logistics data simulation device, which comprises: the display module is used for displaying a simulation page, the simulation page is provided with a parameter setting control, and the simulation page is displayed with a map; rendering the simulation page data, and displaying position points corresponding to the nodes and node simulation information in the simulation page; the communication module is used for acquiring the logistics simulation parameters through the parameter setting control and sending the logistics simulation parameters; and receiving simulation page data, wherein the simulation page data is determined according to a logistics simulation result of the logistics simulation parameters, and the logistics simulation result comprises position points and node simulation information.

The embodiment of the application also discloses an electronic device, which comprises: a processor; and a memory having executable code stored thereon that, when executed, causes the processor to perform a method as described in one or more of the embodiments of the application.

Embodiments of the application also disclose one or more machine-readable media having executable code stored thereon that, when executed, cause a processor to perform a method as described in one or more of the embodiments of the application.

The embodiment of the application also discloses an electronic device, which comprises: a processor; and a memory having executable code stored thereon that, when executed, causes the processor to perform a method as described in one or more of the embodiments of the application.

Embodiments of the application also disclose one or more machine-readable media having executable code stored thereon that, when executed, cause a processor to perform a method as described in one or more of the embodiments of the application.

Compared with the prior art, the embodiment of the application has the following advantages:

in the embodiment of the application, the logistics simulation parameters can be received in the simulation page through the parameter setting control; then carrying out simulation processing according to the logistics simulation parameters to obtain a corresponding logistics simulation result, wherein the logistics simulation result comprises nodes and node simulation information; and determining the position points corresponding to the nodes in the map of the simulation page and displaying the node simulation information according to the logistics simulation result, and performing the participating configuration and the simulation result display through the visualized simulation page, so that the logistics simulation can be conveniently performed, the accuracy is higher, the operation complexity is reduced, and the processing efficiency of logistics planning is improved.

Drawings

FIG. 1A is a schematic diagram of a logistic data simulation process according to an embodiment of the present application;

FIG. 1B is a schematic diagram of an embodiment of the present application for importing data into a physical distribution simulation page;

FIG. 2 is an interactive schematic diagram of an embodiment of a method for simulating logistic data according to the present application;

fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8, fig. 9, fig. 10, fig. 11 are schematic diagrams of a logistic simulation page according to an embodiment of the present application;

FIG. 12 is an interactive schematic diagram of another embodiment of a logistic data simulation method of the present application;

FIG. 13 is an interactive schematic diagram of yet another embodiment of a logistic data simulation method of the present application;

FIG. 14 is a block diagram of an alternative embodiment of a logistic data simulation device according to the present application;

FIG. 15 is a block diagram of another embodiment of a physical distribution data simulator of the present application;

FIG. 16 is a block diagram of yet another embodiment of a physical distribution data simulator of the present application;

fig. 17 is a schematic structural diagram of an apparatus according to an embodiment of the present application.

Detailed Description

In order that the above-recited objects, features and advantages of the present application will become more readily apparent, a more particular description of the application will be rendered by reference to the appended drawings and appended detailed description.

The embodiment of the application can be applied to the field of logistics, and logistics is a process of organically combining functions of packaging, transportation, storage, loading and unloading, distribution, information processing and the like according to actual needs in the process of conveying a logistics object from a supply place (delivery place) to a receiving place (receiving place). A logistic object refers to an object of logistic processing such as a package, an unpackaged article to be transported, or the like.

The embodiment of the application provides a logistics simulation system which can simulate logistics related processing operations, such as a logistics routing process, so that the logistics routing simulation is more convenient, and for example, the routing simulation can be performed based on a starting point (a delivery place) and a destination point (a receiving place). And visual simulation pages can be provided, so that route simulation is more visual, operation is more convenient, operations such as adding, deleting, changing, checking and the like of a route line, operations such as timely lifting or lowering, new adding operations and withdrawal cost measurement and the like of bin or allocation can be performed through the simulation pages, simulation processing can be rapidly performed through dragging or deleting new adding nodes on the simulation pages, and required logistics simulation results are output.

As shown in the schematic diagram of the simulation process of the logistics data in fig. 1A. The database may store the logistics data, such as routing data (described in detail later), and the logistics data of the database may be imported to the server in step 100, so that the server may have basic data for performing the simulation process, and perform the preprocessing operation of the simulation process, and may perform the logistics simulation process.

The user can view the simulation page through the user equipment, and the user equipment can be various terminals with display equipment such as notebook computers, PC ends, mobile phones, tablet computers and the like. The logistic simulation parameters may then be set in the simulation page by the user device in step 102, so that the simulation page of the user device may receive the logistic simulation parameters, and then the user device may send the logistic simulation parameters to the server in step 104. After receiving the logistics simulation parameters, the server side can perform simulation processing according to the logistics simulation parameters to obtain a corresponding logistics simulation result, wherein the logistics simulation result comprises nodes and node simulation information, the logistics simulation result can be matched with a map of a simulation page to obtain simulation page data, the nodes in the logistics simulation result correspond to position points in the map of the simulation page, then the server side feeds back the page data corresponding to the simulation result to the user equipment in step 106, the user equipment can render and display the simulation page data in step 108, so that a user can view the simulation page through the display equipment of the user equipment, and the user equipment can zoom in one simulation page example of the simulation page displayed by the user equipment in FIG. 1A, wherein the simulation page example comprises two logistics lines with the same starting point (in the state of being distributed) and the same end point (in the cloud port of being distributed), and the user can adjust the logistics line based on the map by himself.

In the embodiment of the application, the simulation page can provide a data importing function, and can import logistics data by triggering a control of the data importing function. Wherein the routing data is data of a logistics process from receiving an order to distributing a logistics object into a user's hand, comprising: the commodity circulation order sign (such as commodity circulation bill number) of commodity circulation object, the commodity circulation service provider that provides commodity circulation service, the line data of each node of handling this commodity circulation object and the node processing data of each node, the type of node includes warehouse, dispatch center and delivery website, and wherein warehouse node can deposit commodity, can pack the constitution commodity circulation object and carry out the commodity circulation transportation after the user purchases commodity. The node processing data comprises node names, node position information, various information processed by the logistics object at the node, such as the starting time of the logistics object reaching the node and the ending time of the logistics object sent from the node, the processing time of the logistics object at the node is the time difference between the ending time and the starting time, the processing time of the logistics object between the two nodes is the ending time of the logistics object sent by the node at the previous stage and the starting time of the logistics object received by the node, and the node processing data can also comprise cost information of transportation of the logistics object between different nodes, a transportation service provider (such as a carrier) for providing transportation service, and the like.

According to the first page capable of providing the data importing function, the first page can be used for importing the routing data. The logistics data of the logistics provider can be imported according to a set rule, for example, the routing data is imported in batches based on a batch importing rule, for example, the data needing to be imported in batches is converted into a specified format and stored in a specified storage position, the specified storage position can be selected through a control on a first page, so that the batch data can be imported automatically, and the routing data can be imported according to other parameters of rules such as time, route and the like.

In other embodiments, the logistics data may also import historical single-volume data, where the single-volume data may be related data of processing logistics objects by each node, such as the number of processing logistics objects in a specified time, so that corresponding processing capability information of each node may be determined by the single-volume data. The number of orders (total amount of orders), the number of logistic objects (total number of objects or total parcel amount, etc.), the number of bus lines, etc. processed by the node in a specified time can be determined by the amount data.

The first page of the data importing apparatus as described in fig. 1B includes various controls of routing data to be imported, through which the importing of the routing data may be performed. In the example of 1, the time control is included, the time control can select time information of the logistics data to be imported, such as importing route data for one month, one quarter or one year, and the route data in the time parameter range can be imported by determining the corresponding time parameter through the time control. Based on the route data, the data of various logistics networks such as line data, node information and the like can be determined.

The data importing function also comprises other controls which can be used for performing simulation processing to control, wherein the daily flow control is used for determining the flow version of the route line, the flow version determines the rule of line statistics, each route line contained in the route data can be determined after the route data is selected through the time control, the information of the logistics objects processed by the route line can be further determined through the daily flow control, and if the daily flow version is used for determining the number of orders, the number of the logistics objects, the volume and the like processed according to the weekly calculation route line in the simulation processing. The single-quantity coefficient is a parameter of the simulation system corresponding to the single quantity, for example, the single quantity coefficient can be a multiple of the actual single quantity obtained by statistics of the imported data, if the single quantity calculated by simulation is 1.5 times, 2 times and the like of the actual single quantity, and if the single-quantity coefficient is 1 in fig. 1, the simulated single quantity is the same as the actual single quantity; the rule is used for determining the version of the rule, the rule content corresponding to the rule of different versions is different, the embodiment of the application can set corresponding rule content for each version of rule, including cost calculation rule, single-volume calculation rule, line calculation rule, operation rule of simulation page and the like, for example, display rule when single-volume of the route is overloaded, display color of different routes and the like, and can set different rule versions, so that different rules can be selected for simulation processing by setting the rule versions. Whereby simulation conditions of the simulation system may be set based on the simulation page, the simulation conditions comprising at least one of: flow conditions, single-quantity coefficients and rule versions corresponding to simulation rules

After receiving the imported data, the server can process the data to obtain various data of the logistics network, wherein the logistics network can correspond to a logistics service provider. The different logistics service providers can log in the system to automatically import data, and the system can also conduct data import, so that the logistics service providers can check own logistics network and conduct simulation processing after logging in.

In the embodiment of the application, the logistics data can be stored in a database, a storage system and other storage components, and the logistics data comprises basic information such as names, types, single quantities, parcel quantities, volumes and the like of warehouses, distribution centers and distribution sites; in the initialization process after the data is imported, the cost information of each line can be asynchronously calculated, and after the calculation is completed, the cost information is set in the cost field of the corresponding data in the storage component.

In the embodiment of the application, the processing can be performed on each node based on the imported logistics data, and the node information corresponding to each node is counted, wherein the node information comprises node names, position information, processable single-volume information, logistics object quantity information, volume information and the like, and the flow direction relationship between a transportation service provider associated with the node and other nodes. The relation among the nodes in the network, such as an allocation center corresponding to the warehouse, a distribution station corresponding to the allocation center, and the like, can also be determined.

The processing time of each node for processing the logistics object can be determined through each routing data, the processing time can be determined based on the starting time of each node for receiving the logistics object and the ending time of each node for sending out the logistics object, so that the statistical average processing time is taken as the processing time of the node, the processing time of different types of nodes can correspond to different things, for example, the processing time of a warehouse node is delivery time, the processing time of an allocation node can be allocation time, and the like.

The simulation page provided by the embodiment of the application can provide a map, so that each node of the logistics network is associated with a corresponding position point on the map, and the node information is associated with the corresponding position point on the map, and the node information can be displayed when the position point is checked in the page. The node information of each node is provided with position information, and the position point of the node on the map can be determined according to the position information, so that the position point is associated with the node, and the relevant simulation processing of the node in the simulation processing can be displayed in combination with the position point.

Receiving logistics simulation parameters in the simulation page through the parameter setting control; then carrying out simulation processing according to the logistics simulation parameters to obtain a corresponding logistics simulation result, wherein the logistics simulation result comprises nodes and node simulation information; determining the position points corresponding to the nodes in the map of the simulation page and displaying the node simulation information according to the logistics simulation result, and performing participating configuration and simulation result display through the visualized simulation page, so that logistics simulation can be conveniently performed, the accuracy is higher, the operation complexity is reduced, and the processing efficiency of logistics planning is improved

Referring to fig. 2, an interactive schematic diagram of an embodiment of a logistic data simulation method according to the present application is shown.

Step 202, the user side displays the simulation page, and obtains the logistics simulation parameters through the parameter setting control.

Step 204, the user side sends the logistic simulation parameters to the server side.

For a user side, a simulation page can be displayed, the simulation page is provided with a parameter setting control, and a map is displayed on the simulation page; and acquiring the logistics simulation parameters through the parameter setting control, and sending the logistics simulation parameters. And for the server, receiving the logistics simulation parameters acquired through the parameter setting control in the simulation page.

The simulation page is provided with a parameter setting control, the parameter setting control is used for setting the logistics simulation parameters, and different simulation processes can correspond to different parameter setting controls, so that a simulation user can set the simulation parameters in the parameter setting control of the simulation page, and the logistics simulation parameters can be received in the simulation page through the parameter setting control.

The parameter setting control may be a selection control, and after the parameter setting control is triggered, providing selectable logistic simulation parameters, and determining the selected logistic simulation parameters, for example, in one example, the parameter setting control may be triggered to display a drop-down menu, where options of the selectable logistic simulation parameters are provided. In other alternative embodiments, the parameter setting control may also be an input box, and a corresponding logistic simulation parameter may be input in the input box, or a corresponding logistic simulation parameter may be associated with the input box for selection by a user.

In an alternative embodiment, the logistic simulation parameter includes an aggregate display condition, where the aggregate display condition refers to a simulation condition for displaying a node, and the simulation condition may be set on a map to display the node. The aggregation display condition can be displayed for the node corresponding to the position point on the map, wherein the node can be displayed according to the line, the node type and the like, and aggregation can be understood as combining or independently displaying the position point. The polymeric display conditions include at least one of: bin presentation conditions, allocation presentation conditions, site presentation conditions, and line presentation conditions.

The bin display condition refers to a display condition of a node aiming at a warehouse type, for example, the bin display condition can be displayed based on a regional or provincial area division mode, and comprises national display, provincial display, municipal display and the like. The bin display conditions may also be set to not display or to display all of them, etc.

The allocation display condition refers to a display condition of a node aiming at an allocation center type, for example, the allocation display condition can be displayed based on a regional or provincial area division mode, and the bin display condition comprises national display, provincial display, municipal display and the like. The bin display conditions may also be set to not display or to display all of them, etc.

Site display conditions refer to display conditions of nodes aiming at the distribution site types, for example, the display conditions can be displayed based on a regional or provincial area division mode, and the bin display conditions comprise national display, provincial display, municipal display and the like. The bin display conditions may also be set to not display or to display all of them, etc.

The line display condition refers to a condition of displaying lines of a logistics network, wherein lines between nodes in the logistics network can form lines, such as from a warehouse to a distribution center and from one distribution center to another distribution center, so that the distribution center to a distribution site and the like, and the routing lines of one logistics object are also formed by the lines. Therefore, when the information of the nodes is displayed on the map of the simulation page through the position points, the connection lines between the nodes, namely the lines for displaying the nodes, can be displayed. The line display conditions can be not displayed or all displayed, and can also be displayed according to the level, wherein the level of the line is related to the node type, for example, the line between a warehouse and a distribution center is a primary line, the line between the distribution center and the distribution center is a secondary line, and the line between the distribution center and a site is tertiary information, so that the displayed line level can be selected according to the line display conditions, in addition, the line level can be set according to the type, the level of the displayed type and the level of the cross type can be selected, and the like.

As shown in fig. 3, 4, 5 and 6, in the simulation page, the upper menu bar of the simulation page displays the setting controls of each aggregation display condition, including the setting control of the bin display condition, the setting control of the allocation display condition, the setting control of the site display condition and the setting control of the line display condition. The simulation page also comprises other parameter setting controls, such as a control for changing data, through which the simulation data can be updated; help control, through which help information of the simulation system, such as a using method of the simulation system, common problems, and the like, can be checked; the system also comprises a control for viewing the history scheme, wherein the control can be used for viewing history information, including history data, history simulation scheme and the like; the control also includes a search box through which displayed location points, such as screening warehouses, distribution centers, distribution sites, etc., can be screened.

In the simulation page example shown in fig. 3, the allocation display condition is set to be aggregation in province, and allocation centers can be displayed according to province, wherein the allocation centers of Beijing, qinghai, sichuan, hubei, zhejiang, fujian and Guangdong are shown as corresponding position points on a map; and setting the line display conditions as all displays, and displaying the lines between the distribution centers by connecting lines among the position points.

In the simulation page examples shown in fig. 4, 5 and 6, the bin display condition is set to be in the city aggregation, the allocation display condition is set to be in the whole display, the site display condition is set to be in the city aggregation, and the line display condition is set to be in the whole display. The map of the simulation page displays position points corresponding to nodes such as warehouse, allocation, site and the like, lines among the nodes and the like.

Therefore, each aggregation display condition can be set as a logistics simulation parameter through the parameter setting control.

In further embodiments, the logistic simulation parameters include: sender location information and receiver location information. The information of the delivery place refers to the related information of the logistics object for starting the logistics process, and may be the delivery address of the logistics object, the area information of the delivery place, or the information of the starting node of the logistics object such as a warehouse and a distribution site corresponding to the delivery place. The receiving place information refers to information related to the end of the logistics processing of the logistics object, and can be a receiving address of the logistics object, or can be area information of the receiving place, or a delivery site corresponding to the receiving place. The sending place is the position where the logistics object is sent out, and the receiving place is the position where the logistics object is received. The logistics line can be determined based on the delivery place and the receiving place, and the logistics service of the logistics object can be realized based on the logistics line.

The parameter setting control can set the information of the delivery place and the information of the receiving place, so that the starting point (the node corresponding to the delivery place) and the ending point (the node corresponding to the receiving place) of the logistics line are determined. In the simulation page example shown in fig. 7, an origin may be selected as the sender information in the input box, where setting the range of the origin to the city of hangzhou, zhejiang province, providing optional warehouse nodes within the range of hangzhou, zhejiang province in the simulation page includes: a Hangzhou Xiaoshan storehouse 1, a Hangzhou Xiaoshan storehouse 2 and a Hangzhou Xiaoshan storehouse 3; the optional distribution center node includes: a Hangzhou Xiaoshan allocation 1, a Hangzhou Xiaoshan allocation 2, and a Hangzhou Xiaoshan allocation 3; the optional distribution site node includes: hangzhou western lake site 1, hangzhou western lake site 2, hangzhou western lake site 3, and Hangzhou western lake site 4. The Hangzhou Xiaoshan warehouse 1 was selected as the sender location information in the example of FIG. 7. The destination, namely the information of the receiving place can be configured, if the range of the receiving place is given, the node names of the warehouse, the distribution center and the distribution site contained in the range can be automatically displayed, so that the receiving place information can be conveniently selected.

In other embodiments, the logistics simulation parameters of the intermediate node of the logistics line can be set through the parameter setting control, so that the logistics line and the logistics line required by the setting can be adjusted.

And 206, performing simulation processing by the server according to the logistics simulation parameters to obtain a corresponding logistics simulation result, wherein the logistics simulation result comprises nodes and node simulation information.

And step 208, the server matches the logistics simulation result with the map of the simulation page to obtain simulation page data, wherein nodes in the logistics simulation result correspond to position points in the map of the simulation page.

Step 210, the server sends the simulated page data to the client.

And 212, rendering the simulation page data by the user side, and displaying the position points and the node simulation information corresponding to the nodes in the simulation page.

After the logistics simulation parameters are set through the parameter setting control, simulation processing can be performed based on the logistics simulation parameters, for example, simulation processing for each node in a logistics network, simulation processing for a logistics line and the like, and specific simulation processing operation can be determined according to the logistics simulation parameters, so that a corresponding logistics simulation result can be obtained. The physical distribution simulation result comprises nodes and node simulation information, and the physical distribution simulation method and the physical distribution simulation device provide visual physical distribution simulation, so that the simulation processing result comprises the nodes, and therefore the nodes can correspond to position points in a map of a simulation page and are convenient to display, and the node simulation information refers to simulation information corresponding to the nodes, such as names of all the nodes, position information, relations with other nodes and the like.

In an alternative embodiment, the logistic simulation parameters include aggregate presentation conditions; the logistics simulation result comprises: the polymerization reveals the results. And carrying out simulation processing on specific display conditions to obtain corresponding aggregation display results, wherein the aggregation display results can be results of aggregation display on nodes, such as a set of display warehouse nodes, a set of transfer center nodes and the like, and the conditions of the nodes and the lines to be displayed can be determined through the aggregation display conditions, so that the nodes and the lines are screened according to the conditions to obtain the corresponding aggregation display results.

In another optional embodiment, the logistic simulation parameter includes sender information and receiver information; the logistics simulation result comprises: and a logistics line from the sender to the receiver. For the simulation processing of the logistics line, corresponding sending place information and receiving place information can be set, so that a node corresponding to a starting point is determined based on the sending place information, a node corresponding to an end point is determined based on the receiving place information, then the logistics line can be simulated based on the node of the starting point and the node of the end point, and a corresponding logistics line is obtained, wherein line simulation information of the logistics line can be obtained through simulation, and the line simulation information comprises at least one of the following: route single amount information, route volume information, route distance information, route duration information, and route cost information. The route order quantity information refers to information of the order quantity which can be processed by the logistics line, and can be a range of the order quantity or the maximum order quantity, wherein the order can be a logistics order or a transaction order of a platform such as an electronic commerce and the like; the route volume information refers to the volume information of the logistics objects which can be processed by the logistics line, and can be a volume range or a maximum volume; the route distance information refers to a route distance corresponding to the logistics route, and the route distance can be an actual transportation distance; the route duration information refers to the duration of the physical distribution object processed by the physical distribution line, including the transportation time between different nodes, the processing time at each node, the total duration and the like, and the simulation information of the times can be determined based on the average processing duration of the physical distribution object corresponding to each node, the average transportation duration between the nodes and the like calculated by the historical data; route cost information refers to cost information of a logistics object processed in the logistics route, and can include transportation cost, labor cost, total cost and the like.

Therefore, different simulation processes can be performed according to different simulation demands, node information corresponding to each node can be obtained based on the imported historical data, and therefore processing such as node aggregation display and route simulation is performed based on the node information, and a logistics simulation result is obtained.

And 206, determining the position points corresponding to the nodes in the map of the simulation page and displaying the node simulation information according to the logistics simulation result.

The physical distribution simulation result is obtained through simulation processing, the position points corresponding to the nodes on the map of the simulation page in the physical distribution simulation result can be determined, display information corresponding to the position points and display information among the position points are determined based on the node simulation information, such as node information of names, addresses and the like of the nodes corresponding to the position points are displayed, and relationships among the nodes are displayed in a connecting mode.

In an alternative embodiment, the logistic simulation parameters include aggregate presentation conditions; the logistics simulation result comprises: polymerizing and displaying results; the server matches the logistics simulation result with the map of the simulation page, including: determining corresponding position points in a map of the simulation page according to the aggregation display result, and connecting the position points by using directed line segments; the user terminal displays the position points and the node simulation information corresponding to the nodes in the simulation page, and the method comprises the following steps: and displaying the position points connected through the directed line segments in the simulation page, wherein the position points correspond to the aggregation points corresponding to the aggregation display conditions. Determining the position point corresponding to the node in the map of the simulation page and displaying the node simulation information according to the logistics simulation result, wherein the method comprises the following steps: and determining corresponding position points in the map of the simulation page according to the aggregation display result, and connecting the position points by adopting directed line segments. The aggregation display result comprises a result of performing aggregation display on nodes and routes, nodes and node simulation information in the aggregation display result can be determined, the nodes can comprise nodes of types corresponding to the aggregation display conditions, the node simulation information can comprise aggregation node information, the aggregation node information is determined according to the aggregation display conditions, for example, at least one node group displayed in an aggregation mode, and the node group information comprises nodes contained in the node group, node information of each node and the like, and for the single display case, the node simulation information comprises the node information of the displayed nodes.

Therefore, the position point corresponding to the map of the simulation page of the node or the node group can be determined, for example, for each node, longitude and latitude information is determined according to the position information of the node, and the longitude and latitude information is matched with the position point on the map, for the node group, the geographic range can be determined according to the corresponding aggregation display condition, the geographic range is matched with the position point on the map according to the geographic range, if aggregation is performed by province, the province city or the central position of each province in the map is selected as the position point to display the node group, and if aggregation is performed by city, the central position of the city in the map is selected as the position point to display the node group. After the position points are determined, the position points can be marked in the map, and the corresponding node types such as a warehouse, a distribution center, a distribution site and the like can be marked on the position points.

In the diagram of each simulation page, the allocation center node (group) is identified by an icon with a 'minute'; the distribution site nodes (groups) are identified by icons with "stations"; warehouse nodes (groups) are identified by icons with "bins".

In the simulation page example shown in fig. 3, the allocation display condition is that the allocation center node is displayed according to the province, the warehouse node and the distribution site are set to be not displayed, and the allocation centers of Beijing, qinghai, sichuan, hubei, zhejiang, fujian and Guangdong are displayed as the corresponding position points on the map, and the displayed node group is marked as an allocation group; and setting the line display conditions as all displays, and displaying the lines between the distribution centers by connecting lines among the position points. The system comprises a transfer center, a transfer center and a transfer center, wherein the transfer center of Qinghai is provided with two transfer lines, one transfer line is used for transferring a logistics object from the transfer center of Qinghai to the transfer center of Beijing, and the other transfer line is used for transferring the logistics object from the transfer center of Qinghai to the transfer center of Hubei and then from the transfer center of Hubei to the transfer center of Beijing. In addition, the logistics objects are transported from the distribution center of Beijing to the distribution center of Guangzhou, and from the distribution center of Sichuan to the distribution centers of Hubei, zhejiang and Fujian, respectively, although fig. 3 is only an example of simulation, and other distribution centers and transportation flows may be included.

In the simulation page example shown in fig. 4, the bin display condition is set to be the city aggregation, the allocation display condition is set to be the whole display, the site display condition is set to be the city aggregation, and the line display condition is set to be the whole display. The map of the simulation page displays position points corresponding to nodes such as warehouse, allocation, site and the like, lines among the nodes and the like. The transportation route from the warehouse to the allocation center is a primary route, the transportation route between the allocation centers is a secondary route, and the transportation route from the allocation center to the site is a tertiary route. Wherein, warehouse and distribution site are according to the node group of city according to specific show condition.

In some optional embodiments, in a case that the location point is selected, a sub-window of the location point is displayed, where the sub-window displays aggregation point information corresponding to the location point, and the aggregation point information is related to the aggregation display condition. In the case of aggregate presentation, each node may be a single presentation or may present a group of nodes, and the nodes or the group of nodes may correspond to node information and group information, so that a corresponding location point may be selected by clicking, placing a mouse on a corresponding icon, or the like, and then a sub-window may be displayed around the corresponding location point, through which corresponding node information and/or group information, for example, for a single node, node information such as a name, location information, a volume, and a flow direction of the node may be displayed, and for a group of nodes, the number of nodes included in the group, the name of each node, the volume, and the like may be displayed, which are part of node simulation information obtained through simulation processing.

As shown in the simulation page example in fig. 5, on the basis of the simulation page in fig. 4, by clicking the warehouse node group in the southward city, 4 warehouse nodes in the southward city can be displayed through a sub-window, which are respectively: jiang Xiapu Luo Gecang, a sea crossing common bin, a north territory super bin and a south lake net win bin, and a single volume and a volume of the node group which can be processed.

In other examples, when the group information of the node group is displayed through the sub-window, the designated node is selected by clicking or the like, the node information of the designated node can also be displayed in a jump manner in the sub-window, the node group can be unfolded on the map to display each node in the node group, and a control for returning to the group can also be set in the sub-window. In the simulation page example shown in fig. 6, selecting the north-south collar bin of south Beijing can display a sub-window, and can display address information, and single volume, volume and flow information which can be processed by the super bin of north collar merchant, wherein the flow information can be flow information of a logistics partner.

In some other alternative embodiments, the logistic simulation parameters include sender information and receiver information; the logistics simulation result comprises: a logistics line from the delivery site to the collection site; the server matches the logistics simulation result with the map of the simulation page, and the method comprises the following steps: determining a position point corresponding to a node in the logistics line in a map of the simulation page according to the logistics line from the sender to the receiver; and connecting the position points in the map of the simulation page by adopting directed line segments so as to display the logistics line. The user terminal displays the position points and the node simulation information corresponding to the nodes in the simulation page, and the method comprises the following steps: and displaying position points connected through directed line segments in the simulation page, wherein the position points correspond to nodes in the logistics line. Determining the position point corresponding to the node in the map of the simulation page and displaying the node simulation information according to the logistics simulation result, wherein the method comprises the following steps: determining a position point corresponding to a node in the logistics line in a map of the simulation page according to the logistics line from the sender to the receiver; and connecting the position points in the map of the simulation page by adopting directed line segments so as to display the logistics line.

According to the simulation processing of the logistics line, through the set delivery place information and the set delivery receiving place information, the node of the delivery place corresponding to the starting point and the node of the receiving place corresponding to the receiving place can be determined, so that the simulation processing of the logistics line is performed based on the starting point and the receiving place, and the logistics line of the delivery place and the receiving place is obtained. Thereby displaying the logistics line on a map.

In some optional embodiments, line simulation information corresponding to the logistics line is displayed in the simulation page, where the line simulation information includes at least one of the following: route single amount information, route volume information, route distance information, route duration information, and route cost information. In the simulation page example shown in fig. 9, the logistics lines are displayed in the map, and specific logistics lines can be displayed through a sub-window, for example, the logistics lines from the Yangzhou to the salt city, and then to the site (in the Lianghong Kong city) are displayed. And line simulation information corresponding to the logistics line.

For each node on the commodity circulation line, the node information of the node can be displayed through a sub-window for the selected node, wherein the node information comprises the name, single quantity, parcel quantity, volume quantity, flow direction number and the like of the node. In addition, the node state determined by simulation can be displayed, for example, the state of a designated node is determined to be single-quantity overload by setting parameters such as single quantity, and the like, and the overload quantity can be obtained by simulation. In the simulation page example shown in fig. 8, node information and node status of the Yangzhou allocation are displayed, and a single overload of 20% of the Yangzhou allocation can be displayed.

In the case of overload of a logistics line or overload of the processing capacity of a node, overload refers to exceeding the processing capacity of the node and the line, and adjustment of the logistics line can also be automatically performed, for example, an intermediate node is adjusted for a single-quantity overload logistics line to adjust the logistics line. In an alternative embodiment, when the overload of the logistics line is determined according to the line simulation information, prompt information can be determined and displayed, for example, the overload line and/or the overload node can be prompted, simulation processing for adjusting the logistics line can be automatically performed, so that the adjusted simulation line is prompted, automatic recommendation of the line is performed, and the adjusted logistics line is displayed when the user confirms the adjustment.

In the simulation process of automatic adjustment of the logistics lines, one or more adjusted logistics lines can be obtained. And aiming at the condition of a plurality of adjusted logistics lines, the adjusted logistics lines can be screened based on the line simulation information, so that at least one adjusted logistics line is recommended.

In an optional embodiment of the present application, when it is determined that the overload occurs on the logistics line according to the line simulation information, a prompt message is determined, where the prompt message includes an overloaded line and/or an overloaded node. The prompt message further includes: line adjustment information; the method further comprises the steps of: and under the condition that the overload of the logistics line is determined according to the line simulation information, executing simulation processing for adjusting the logistics line, and determining the line adjustment information. Therefore, under the condition that the logistics line obtained through simulation is overloaded, the logistics line can be automatically adjusted and prompted, and a user can obtain the logistics line which is automatically adjusted. The prompt in the simulation page can be popped up and displayed in an independent window mode or displayed beside the overloaded logistics line, so that the overloaded logistics line in the simulation page is prompted, the prompt information can be synchronously displayed when the line simulation information is displayed, and the overloaded prompt information can be displayed in various modes for prompting.

In the embodiment of the application, node adjustment information of the logistics line can also be received in the simulation page; and adjusting the corresponding position points and the directed line segments between the position points in the map according to the node adjustment information. The nodes of the logistics line can be modified in the simulation page, so that the logistics line is modified, for example, a control for 'starting editing' is selected in a sub-window for displaying the logistics line, and the adjustment of the line is triggered. The method comprises the steps of displaying an adjusted route as an original route by default, wherein the original route is usually unchanged in starting point and end point, adjusting intermediate nodes on the basis of the original route, selecting intermediate nodes in a map, automatically adding the intermediate nodes into a logistics route, adjusting the intermediate nodes in the logistics route displayed by a sub-window, displaying other nodes of the intermediate nodes in the same type within a certain range on the map, facilitating route adjustment, and adjusting directed line segments among all position points of the logistics route according to the position points of the adjusted nodes in the map after determining one or more adjusted nodes, so that the adjusted logistics route is obtained, and carrying out simulation processing to obtain route simulation information of the adjusted logistics route and display the route simulation information.

As shown in fig. 9, the logistics line defaults to display the original logistics line, and then the logistics line can be adjusted, as shown in fig. 10, the salt city of the intermediate node is allocated from tin-free to Huaian, and then to salt city, so that the route is adjusted as follows: yangzhou allocation- > tin-free allocation- > Huai' an allocation- > Yangcheng south allocation- > site (Lianyong city).

In other embodiments, the multiple logistics lines (the starting point and the ending point are the same) obtained through simulation can be compared, so that the logistics lines can be conveniently adjusted, and therefore the multiple logistics lines can be compared according to the line simulation information, and the comparison result is determined; and displaying the comparison result in the simulation page. And comparing a plurality of logistics lines with the same starting point and end point according to line simulation information, and comparing the difference of the dimensions of single quantity, volume, distance, required time length, cost and the like which can be processed. As shown in fig. 10, the two logistics lines before and after adjustment are compared, so that a comparison result can be obtained: the single quantity is increased by 100 ten thousand, the distance is increased by 100km, the time length is increased by 200H, and the cost is reduced by 1K.

In the sub-window for displaying the logistics lines, a plurality of logistics lines can be displayed and distinguished by different numbers, for example, 6 lines are shown in fig. 11, the lines displayed on the map can be adjusted according to the selected line numbers, for example, the lines corresponding to the selected numbers are normally displayed, and for the logistics lines with no selected numbers, the lines are displayed on the map by setting gray scales, masks and the like, so that different logistics lines are distinguished.

In some alternative embodiments of the present application, the logistics objects are transported along a logistics route to circulate between different nodes until the user receives the logistics objects. During transportation, various factors may affect the normal execution of transportation. Such as weather conditions or other emergency conditions in the area of the logistics route, may result in the transportation of the logistics objects being affected. For example, the area corresponding to the nodes on the logistics line limits road or logistics transportation due to the event or various reasons, and if the area corresponding to the nodes on the logistics line encounters extreme weather such as heavy rain, snow storm, typhoon, etc., the path can be planned again under the condition, and the logistics line is adjusted to avoid the areas, so that the logistics objects can be transported normally. Thus, embodiments of the present application may trigger re-planning of the route based on specified events, including regional forbidden or restricted transportation events, weather events, and the like, to adjust the logistics route.

Optionally, weather information of positions corresponding to the nodes in the logistics line can also be obtained, and the logistics line is adjusted according to the weather information. Determining nodes contained in the logistics line and positions corresponding to the nodes, and inquiring weather information corresponding to the positions, wherein weather inquiry can be performed through a weather inquiry interface and the like. The weather information can comprise weather forecast information, weather early warning information and the like, wherein weather has certain timeliness, so that the logistics line can be periodically adjusted based on the weather information, the weather information corresponding to each position in the logistics line is acquired at regular time every day with 24 hours a day as a period, and then the logistics line is adjusted based on the weather information.

In a further optional embodiment, the adjusting the logistics line according to the weather information includes: analyzing the road condition information of the logistics line according to the weather information; and under the condition that the road condition information of the logistics line meets the adjustment condition, adjusting the nodes in the logistics line. According to the embodiment of the application, the time that the logistics object reaches each node every day, the time sent out by the nodes, the transportation time of the logistics object among the nodes and other information can be simulated, so that weather information such as weather forecast, early warning and the like of the corresponding position of the nodes in the time range can be obtained based on the time information, further more accurate weather information is obtained, whether the weather information meets the adjustment condition is detected, the adjustment condition is a condition affecting logistics transportation and comprises at least one of the early warning condition and the early warning condition, the weather warning information corresponding to the early warning condition can also be provided with the early warning condition, for example, the early warning condition comprises the early warning of storm, the early warning of typhoon, the early warning of fog and/or the early warning of road icing, and the like, the early warning condition can be determined according to the weather forecast information, and the early warning condition is set for the forecast information affecting logistics transportation, for example, the early warning condition is at least one of the following: if the weather information meets the adjustment conditions, the route from the starting point to the end point can be planned again, the logistics route can be adjusted, the position of the weather information meeting the adjustment conditions is adjusted, and the logistics route is adjusted to be the node corresponding to other positions, wherein the logistics route can be selected based on a certain regional range, such as the nodes of adjacent provinces and cities, the nodes of the corresponding regions can be selected for adjustment by combining the weather information, and the like. For example, a transportation road from Yangzhou to Yangzhou is sealed at a high speed due to heavy rain, the transportation road can be adjusted to a route from Yangzhou to Wuxi, to Huai-lan and then to Yangzhou, so that the logistics route is adjusted based on weather, roads and other conditions.

The simulation of the logistics line is generally determined based on the delivery place and the receiving place, however, the logistics transportation may be affected by the transported logistics object, the user corresponding to the logistics object, and the like, such as the transportation mode, the transportation speed, and the like, so that a switch, a control, and the like of a mixed scene can be set in the simulation system, and the adjustment of the logistics line can be performed by triggering the mixed scene, for example, the simulation adjustment is performed according to a certain proportion, such as 80% transportation is performed according to the original logistics line, and 20% real-time adjustment is performed according to the actual condition of the logistics object. Thus, in other embodiments of the present application, the logistics lines of the route simulation result may include logistics lines determined in various manners, such as determining logistics lines based on the place of delivery and the place of receipt, and in other cases, planning of the route may also be performed in combination with order information of the transported logistics object. The order can be a physical distribution order or a transaction order of an electronic commerce platform, and the information of the delivery place and the information of the receiving place can be obtained based on the order. And the order can also acquire priority information of the logistics object, wherein the priority information is determined according to at least one of the following parameters: the type of the logistics object and the user grade of the corresponding user of the logistics object can be set according to requirements, for example, general type, cold chain type and the like can be set according to transportation conditions, the logistics object is divided into express, logistics and the like according to logistics requirements, and priority information such as aging grade and the like corresponding to orders is further included, so that a logistics line of the logistics object can be adjusted according to the priority information.

The user of the logistics object can obtain order information, such as the user grade of a receiving user or a sending user of the logistics object, such as the user grade of a common user, a member user, a VIP member user and the like, so that the transportation time limit of the logistics object can be determined based on the user grade, and the logistics line of the logistics object can be adjusted based on the transportation time limit, for example, the transportation time limit of a high-grade user is shorter, so that the logistics line with shorter transportation time can be adjusted, and the logistics line with longer transportation time but low cost can be adjusted, such as the logistics line with longer transportation time limit of the common user. The order information may also include the type of the logistics object, such as fresh, etc., which needs cold chain transportation, so that the node supporting cold chain transportation may be determined, and the logistics line of the logistics object which needs cold chain transportation may be adjusted to the line formed by the nodes supporting cold chain transportation. For example, the type of the object corresponding to the order is a physical distribution time limit type, such as the current day, the next day, and the like, and the physical distribution line can be adjusted based on the time limit type.

For example, a logistics object from Qinghai to Beijing, a conventional logistics line is from a distribution center of Qinghai to a distribution center of Hubei, and then to a distribution center of Beijing; and for the logistics objects of the current day or the VIP users, the logistics objects can be directly sent to the distribution center of Beijing by the distribution center of Qinghai.

In other embodiments, the logistics object may have other requirements, such as a logistics object with a battery, a logistics object with a pneumatic device, etc., where the logistics object has certain requirements, such as a transportation mode only used for some logistics, etc., and an air transportation mode used for some logistics, etc., so that a transportation mode may be selected based on the requirements of the logistics object, whether the current logistics line is supported or not may be determined based on the transportation mode, and the nodes may be adjusted for the logistics line that does not support the transportation mode, so that the adjusted logistics line may support the transportation mode required by the logistics object, thereby completing the planning of the line.

E-commerce websites typically have some promotional activity that can promote the generation of a large number of trade orders, such that the volume of the stream is greatly increased over the time period of the promotion, which in turn can result in increased pressure on the stream's transportation. In order to better cope with the scene that various logistics objects such as sales promotion are greatly increased in a certain time, the simulation system of the embodiment of the application can also perform scene simulation of logistics pressure test (pressure measurement), and can collect logistics data of the sales promotion scene as a data basis to perform simulation of the pressure measurement scene. In the simulation process, the logistics simulation parameters of the pressure measurement scene can be set through the parameter setting control, wherein the simulation of the pressure measurement scene can be performed in full-network simulation, the pressure measurement simulation of the appointed logistics line can also be performed, the corresponding logistics simulation parameters can be set according to the requirements, the corresponding pressure test parameters can be determined, and the simulation can be determined to be full-network simulation or appointed route simulation. For example, the single quantity of transportation, the quantity, the volume quantity and the like of the logistics objects can be set in the pressure measurement scene, so that simulation processing can be performed based on the set logistics simulation parameters, one or more logistics lines are obtained and displayed in a simulation page. Wherein the logistic simulation parameters comprise pressure test parameters; the logistics simulation result comprises: the logistics line and the line simulation information of the logistics line; the matching the logistics simulation result with the map of the simulation page comprises the following steps: determining position points corresponding to nodes in the logistics line in a map of the simulation page; and connecting the position points in the map of the simulation page by adopting directed line segments, and determining display information of the directed line segments according to the line simulation information, wherein the display information comprises display information for reflecting the carrying capacity of the logistics line. The line simulation information of the logistics line in the pressure measurement scene can be determined through simulation processing, wherein the line simulation information comprises line single quantity information, line volume information, line distance information, line duration information, line cost information and the like, the carrying capacity of the line and the state of the nodes can be determined based on the single quantity, the volume and the like, and in the full-network simulation scene, the nodes can be superposed with the single quantity, the volume and the like of different lines to determine the node state. The state of the node can be judged based on the single quantity, the volume quantity and the like of the node simulation and the node threshold value of the node, such as overload, low load, normal and the like, and the overload threshold value can be set, if the single quantity, the volume quantity and the like of the node simulation reach the overload threshold value, the state of the node can be an overload state, and the state is beyond the capability of the node to process the logistics object, such as the condition of explosion bin and the like. After the position points corresponding to the nodes are determined in the map of the simulation page, the position points can be connected by adopting directed line segments, and the display information of the directed line segments can be determined according to the line simulation information, such as the carrying capacity of the logistics line represented by the colors and/or the thicknesses of the directed line segments. If the color, thickness, etc. of the directional line segments are set based on the carrying capacity, if the carrying capacity is larger, the line segments are darker, the line segments are thicker, etc., the node corresponding information can be displayed by combining the node states of the nodes, and whether the nodes are overloaded or not is displayed, etc.

Therefore, through simulation processing of the pressure measurement scene, the condition of logistics transportation in the scenes such as sales promotion and the like can be determined, and whether the condition of each logistics line in the whole network is overloaded, the overload degree and the like, and whether the conditions such as bin explosion and the like occur or not are determined. The simulation result can be used for analyzing the pressure measurement results of all nodes and logistics lines and analyzing improvement suggestions, such as adjusting the lines and increasing the capacity, so that the specific logistics scheduling suggestions can be provided for the pressure measurement scene, and the suggestion information is convenient for reasonably adjusting logistics conditions and arranging the capacity, manpower, lines and the like under the scenes of actual sales promotion and the like.

The embodiment of the application can determine the displayed position points based on the map range, the simulation requirement and the like displayed on the simulation page, and the display range of the map can also be determined according to the logistics simulation parameters.

On the basis of the embodiment, the embodiment also provides a logistics data simulation method, which can aggregate and display the nodes.

Referring to FIG. 12, an interactive schematic diagram of another embodiment of a logistic data simulation method of the present application is shown.

Step 1202, the user side displays a simulation page, and receives an aggregate display condition in the simulation page through the display setting control. The method comprises the steps that corresponding aggregation display conditions can be selected in display setting controls of a simulation page menu bar respectively, and the aggregation display conditions comprise at least one of the following: bin presentation conditions, allocation presentation conditions, site presentation conditions, and line presentation conditions.

In step 1204, the client sends the aggregate display condition to the server.

In step 1206, the server performs simulation processing according to the aggregation display condition to obtain a corresponding aggregation display result.

Step 1208, the server determines a corresponding position point in the map of the simulation page, and connects the position point with a directed line segment to obtain corresponding simulation page data.

In step 1210, the server sends the simulated page data to the client.

And 1212, rendering the simulated page data by the user side, and displaying the aggregation points connected by the directed line segments in the map of the simulated page.

Step 1214, displaying a sub-window of the location point, where the sub-window displays aggregation point information corresponding to the location point, where the aggregation point information is related to the aggregation display condition. The sub-window is displayed after the position points are selected, and the page data of the sub-window can be preset in the simulated page data so as to be directly displayed, or a selected event can be sent to the server after the aggregation points are selected so as to acquire the page data and render and display.

For the aggregation point of one node group, after one node in the node group is selected, node information of the node can be unfolded and displayed, and the node information is displayed in a map and displayed for each node in the node group, corresponding page data can be configured in simulated page data in advance, and after triggering, rendering and displaying are performed, or corresponding page data is obtained through interaction with a server side and is obviously displayed.

If the aggregation point comprises a plurality of node groups of the same type, the aggregation point information comprises group information of the node groups; if the aggregation point includes a single node, the aggregation point information includes node information of the node.

Thus, through the selection of the aggregation display condition, single nodes or node groups and corresponding aggregation point information can be displayed on the map of the simulation page. It is required to quickly edit and calculate the solution result through the simulation page according to the requirement.

In the visualized simulation page, the map can display the national logistics network visualization information mainly distributed by default, and the logistics network display form under each view angle is completed through the selection of the nodes, so that the display under multiple scenes is supported, and a user is assisted to quickly find the joints. When the node is displayed in the form of province, city and district aggregation, the node is moved to perform the selecting and unfolding operation. And the map scale can be reduced when the map is unfolded, so that the node separation visual analysis is realized, and different lines and different line states corresponding to different colors can be used.

On the basis of the embodiment, the embodiment also provides a logistics data simulation method, which can simulate a logistics line.

Referring to FIG. 13, an interaction diagram of yet another embodiment of a logistic data simulation method of the present application is shown.

In step 1302, the user side displays a simulation page, and receives the receiving part information and the receiving part information through the route setting control in the simulation page. Control inputs or selection start points, end points, etc. may be set up on the route of the simulation page menu bar.

In step 1304, the ue sends the sender information and receiver information to the server.

In step 1306, the server performs simulation processing on the logistics line according to the sending and receiving location information, so as to obtain the logistics line of the sending and receiving location.

Step 1308, the server determines a position point corresponding to a node in the logistics line in the map of the simulation page, and obtains corresponding simulation page data.

Step 1310, the server sends the simulated page data to the user terminal.

In step 1312, the user side renders the simulated page data, and displays the logistics line in the map of the simulated page.

In step 1314, the user side displays line simulation information corresponding to the logistics line in the simulation page, where the line simulation information includes at least one of the following: route single amount information, route volume information, route distance information, route duration information, and route cost information.

In step 1316, the user side receives node adjustment information for the physical distribution line in the simulation page.

In step 1318, the ue sends the node adjustment information to each server.

Step 1320, the server performs simulation processing according to the node adjustment information, and determines corresponding simulated page data.

In step 1322, the server sends the simulated page data to the client.

In step 1324, the user end renders the simulated page data and displays the adjusted logistics line.

Under the condition that the simulation page is provided with a plurality of logistics lines, the server side can also compare line simulation information of each logistics line to obtain a corresponding comparison result, so that the comparison result of the plurality of logistics lines is displayed on the user side, wherein the starting points and the ending points of the plurality of logistics lines are the same.

Therefore, the simulation processing of the logistics line can be carried out by setting the corresponding contact points of the starting point and the ending point, and each node in the logistics line and the transportation direction among the nodes are displayed on the map. The logistics lines can be adjusted and different logistics lines can be compared, so that logistics service providers and the like can be facilitated to adjust the logistics lines.

The embodiment of the application can also automatically adjust the logistics line based on various rules, thereby generating line adjustment information and displaying the adjusted logistics line on the map according to the line adjustment information.

In one example, weather information of positions corresponding to each node in the logistics line may be periodically obtained, and the logistics line may be adjusted according to the weather information. The road condition information of the logistics line in the period can be analyzed according to the weather information; and under the condition that the road condition information of the logistics line meets the adjustment condition, adjusting the nodes in the logistics line. Thus, line adjustment information of the adjusted logistics line is obtained, and then the adjusted logistics line is displayed on a map. The comparison information of the logistics lines before and after adjustment can be determined and displayed in the simulation page, for example, which section of the lines cannot be adjusted due to heavy rain, heavy snow and the like, and the time length, the cost comparison and the like before and after adjustment are prompted.

In another example, an adjustment control may be further provided in the simulation page, where the adjustment control is used to start a mixed scenario, where a part of the logistics lines of the order are determined according to a conventional simulation result, and the logistics lines of the other part of the order are adjusted based on the situation of the order, for example, the logistics lines are adjusted according to the type of the logistics object in the order, the user class of the user corresponding to the order (the receiving user, the sending user), and the like, and if the logistics object is specified in the order to be of a limit type such as a single day, a next day, and the like, the logistics lines can be adjusted by using these information as priority information, and then the adjusted logistics lines, and adjustment prompting information such as a proportion, an adjustment reason, and the like of the logistics line adjustment are displayed in the simulation page, so that the line selection of the logistics object under various different situations can be better known in the simulation page.

Therefore, the method can screen in a visual range, and the visual range is displayed by focusing the map through setting a start node, a plurality of passing points and an end node. The circuit can be regulated, the corresponding node can be selected, and meanwhile, the corresponding node is changed into a selectable frame, so that the instant multi-selection and counter-selection operation is realized, and the multi-selection/single-selection/counter-selection process of the circuit is completed. After selection, the corresponding lines and line simulation information appear in the left bullet layer (sub-window). After the line is selected and editing is started, each selection frame defaults to display the node information of the original line, and new nodes can be reselected in the selection frame to finish the line modification. The map on the right side can be adjusted in line while being modified, so that a user can be helped to check the actual geographical network details of the due line information. After editing, the viewing scheme can return to the original scheme, and the collection of all lines stored in the viewing scheme can be selected for re-editing, so that the convenience of operation is improved.

In the simulation process, the single quantity of the route line can be automatically obtained through simulation, if the electric quantity is changed, the system can display the node information of each node, and perform state early warning on the nodes, such as single quantity early warning and the like, so as to perform scientific decision for the route simulation.

The embodiment of the application can display nodes in dimensions such as province, city, district and the like, and can simulate and recommend transportation information such as vehicle types and the like based on single-volume, volume and the like obtained by simulation aiming at a logistics line, thereby being convenient for route selection.

The embodiment of the application can also display the connecting lines among the positions as different colors on the simulation page according to different addresses, aging and the like, thereby prompting the aging range, the transportation grade and the like. The data of allocation, site manpower and cost can be displayed according to the thermodynamic diagram of the order, the optimization of the areas, sites, manpower, cost and the like can be prompted, and the optimizable content can be displayed.

In the simulation process of each logistics line, overload conditions may occur in some logistics lines, nodes and the like, and the embodiment of the application can also prompt the overload conditions in the simulation page by displaying prompt information, displaying the overload conditions on the nodes of the logistics lines and the lines between the nodes, such as prompting the overload conditions by setting colors, thicknesses and the like of corresponding line segments of the lines, or displaying the overload conditions in the process of displaying description information of the nodes and line simulation information and the like. And the line is automatically adjusted according to overload conditions, and the adjusted logistics line can be automatically displayed and compared or displayed based on triggering of a user, so that the embodiment of the application is not limited.

Based on the above embodiments, the embodiments of the present application may further perform simulation of a pressure measurement scenario, by setting pressure test parameters in a simulation page, for example, may perform pressure measurement simulation based on an order amount and setting of order information, so that pressure measurement simulation of a whole network or a specified logistics line may be performed, and based on the pressure measurement simulation, a logistics line and line simulation information of the logistics line in the pressure measurement scenario may be obtained, so that a simulated logistics line and line simulation information of each logistics line may be displayed on a map, display information for representing a capacity of the logistics line may be displayed for the logistics line, such as whether each node is overloaded, etc., and a capacity may be prompted on a line segment between location points by color, thickness, etc., and may further provide a logistics scheduling suggestion in the pressure measurement scenario, such as an adjustment suggestion for each logistics line, a manual adjustment suggestion, etc.

For the logistics lines, the logistics lines can be displayed according to the dimensionalities of cost, traffic, aging and the like, the logistics lines are displayed according to the comparison information among different logistics lines, and the high-quality lines with balanced cost and aging can be determined and recommended through the comparison information.

It should be noted that, for simplicity of description, the method embodiments are shown as a series of acts, but it should be understood by those skilled in the art that the embodiments are not limited by the order of acts, as some steps may occur in other orders or concurrently in accordance with the embodiments. Further, those skilled in the art will appreciate that the embodiments described in the specification are presently preferred embodiments, and that the acts are not necessarily required by the embodiments of the application.

On the basis of the above embodiment, the present embodiment further provides a physical distribution processing device, which is applied to an electronic device of a server.

Referring to fig. 14, a block diagram of an embodiment of a physical distribution processing apparatus according to the present application may specifically include the following modules:

the parameter obtaining module 1402 is configured to receive the logistics simulation parameters obtained through the parameter setting control in the simulation page.

The simulation module 1404 is configured to perform simulation processing according to the logistics simulation parameters to obtain a corresponding logistics simulation result, where the logistics simulation result includes nodes and node simulation information.

And the visualization processing module 1406 is configured to match the physical distribution simulation result with the map of the simulation page to obtain simulation page data, where a node in the physical distribution simulation result corresponds to a position point in the map of the simulation page.

In summary, the logistic simulation parameters can be received in the simulation page through the parameter setting control; then carrying out simulation processing according to the logistics simulation parameters to obtain a corresponding logistics simulation result, wherein the logistics simulation result comprises nodes and node simulation information; determining the position points corresponding to the nodes in the map of the simulation page and displaying the node simulation information according to the logistics simulation result, and performing participating configuration and simulation result display through the visualized simulation page, so that logistics simulation can be conveniently performed, the accuracy is higher, the operation complexity is reduced, and the processing efficiency of logistics planning is improved

Referring to fig. 15, a block diagram of another embodiment of a physical distribution processing apparatus according to the present application is shown, and may specifically include the following modules:

the preprocessing module 1408 is configured to import the logistics data of the logistics provider according to a set rule.

The parameter obtaining module 1402 is configured to receive the logistics simulation parameters obtained through the parameter setting control in the simulation page.

The simulation module 1404 is configured to perform simulation processing according to the logistics simulation parameters to obtain a corresponding logistics simulation result, where the logistics simulation result includes nodes and node simulation information.

And the visualization processing module 1406 is configured to match the physical distribution simulation result with the map of the simulation page to obtain simulation page data, where a node in the physical distribution simulation result corresponds to a position point in the map of the simulation page.

In an alternative embodiment, the logistic simulation parameters include aggregate presentation conditions; the logistics simulation result comprises: polymerizing and displaying results; and the visualization processing module 1406 is configured to determine a corresponding location point in the map of the simulation page according to the aggregate display result, and connect the location point with a directional line segment.

The visualization processing module 1406 is further configured to determine a sub-window of the location point, where the sub-window displays aggregation point information corresponding to the location point, and the aggregation point information is related to the aggregation display condition.

If the aggregation point comprises a plurality of node groups of the same type, the aggregation point information comprises group information of the node groups; if the aggregation point includes a single node, the aggregation point information includes node information of the node. The polymeric display conditions include at least one of: bin presentation conditions, allocation presentation conditions, site presentation conditions, and line presentation conditions.

In another optional embodiment, the logistic simulation parameter includes sender information and receiver information; the logistics simulation result comprises: a logistics line from the delivery site to the collection site; the visualization processing module 1406 is configured to determine, according to the logistics line from the sender to the receiver, a location point corresponding to a node in the logistics line in the map of the simulation page; and connecting the position points in the map of the simulation page by adopting directed line segments so as to display the logistics line.

The parameter setting module 1402 is further configured to receive node adjustment information for the logistics line through the simulation page; the visualization processing module 1406 is further configured to adjust a directed line segment between a corresponding location point and a location point in the map according to the node adjustment information.

The visualization processing module 1406 is further configured to determine line simulation information corresponding to the logistics line, for display in the simulation page, where the line simulation information includes at least one of: route single amount information, route volume information, route distance information, route duration information, and route cost information.

The simulation module 1404 is further configured to compare a plurality of logistics lines according to the line simulation information, determine a comparison result, and display the comparison result in the simulation page, where start points and end points of the plurality of logistics lines are the same; the visualization processing module 1406 is further configured to determine a display of the comparison result in the simulation page.

The preprocessing module 1408 is further configured to set simulation conditions of a simulation system, where the simulation conditions include at least one of: flow conditions, single-quantity coefficients and rule versions, wherein the rule versions correspond to simulation rules.

The simulation module 1404 is further configured to periodically obtain weather information of a position corresponding to each node in the logistics line, and adjust the logistics line according to the weather information. Specifically, analyzing the road condition information of the logistics line in the period according to the weather information; and under the condition that the road condition information of the logistics line meets the adjustment condition, adjusting the nodes in the logistics line.

The simulation module 1404 is further configured to screen a logistics line of the logistics object according to the priority information, and adjust the logistics line of the logistics object. The sending place information and the receiving place information are determined according to order information of the logistics object; the simulation module 1404 is configured to determine priority information of the logistic object according to the order information, where the priority information is determined according to at least one of the following parameters: the type of the logistics object and the user grade of the user corresponding to the logistics object; and adjusting the logistics line of the logistics object according to the priority information.

The logistics simulation parameters comprise pressure test parameters; the logistics simulation result comprises: the logistics line and the line simulation information of the logistics line; the visualization processing module 1406 is configured to determine a location point corresponding to a node in the logistics line in a map of the simulation page; and connecting the position points in the map of the simulation page by adopting directed line segments, and determining display information of the directed line segments according to the line simulation information, wherein the display information comprises display information for reflecting the carrying capacity of the logistics line.

The simulation module 1404 is further configured to determine, when it is determined that the physical distribution line is overloaded according to the line simulation information, a prompt message, where the prompt message includes an overloaded line and/or an overloaded node.

The prompt message further includes: line adjustment information; the simulation module 1404 is further configured to perform simulation processing for adjusting the logistics line to determine the line adjustment information when it is determined that the logistics line is overloaded according to the line simulation information.

Referring to fig. 16, a block diagram of still another embodiment of a physical distribution processing apparatus according to the present application may specifically include the following modules:

The display module 1602 is configured to display a simulation page, where the simulation page has a parameter setting control, and the simulation page displays a map; and rendering the simulation page data, and displaying position points corresponding to the nodes and node simulation information in the simulation page.

The communication module 1604 is configured to obtain the logistics simulation parameters through the parameter setting control, and send the logistics simulation parameters; and receiving simulation page data, wherein the simulation page data is determined according to a logistics simulation result of the logistics simulation parameters, and the logistics simulation result comprises position points and node simulation information.

The display module 1602 is configured to display, in the simulation page, location points connected by directional line segments.

In an alternative embodiment, the logistic simulation parameters include aggregate presentation conditions; the logistics simulation result comprises: polymerizing and displaying results; and the position points correspond to the aggregation points corresponding to the aggregation display conditions.

The display module 1602 is further configured to display a sub-window of the location point, where the sub-window displays aggregation point information of an aggregation point corresponding to the location point, and the aggregation point information is related to the aggregation display condition; if the aggregation point comprises a plurality of node groups of the same type, the aggregation point information comprises group information of the node groups; if the aggregation point includes a single node, the aggregation point information includes node information of the node.

In another optional embodiment, the logistic simulation parameter includes sender information and receiver information; the logistics simulation result comprises: a logistics line from the delivery site to the collection site; and the position point corresponds to a node in the logistics line.

The communication module 1604 is further configured to receive node adjustment information for the logistics line in the simulation page; the display module 1602 is further configured to display the adjusted logistics line on the map.

The display module 1602 is further configured to display line simulation information corresponding to the logistics line in the simulation page, where the line simulation information includes at least one of: route single amount information, route volume information, route distance information, route duration information, and route cost information.

The display module 1602 is further configured to display a comparison result of the plurality of logistics lines when the simulation page has the plurality of logistics lines, where starting points and ending points of the plurality of logistics lines are the same.

In an optional embodiment, the logistics line is adjusted under the condition that the road condition information of the logistics line meets the adjustment condition, and the road condition information is determined according to periodically acquired weather information analysis.

In another optional embodiment, the display module 1602 is configured to display the adjusted logistics line on the map of the simulation page according to the trigger of the adjustment control; the logistics line is adjusted according to priority information, and the priority information is determined according to at least one of the following parameters: the type of the logistics object and the user grade of the corresponding user of the logistics object. The display module 1602 is further configured to display order information and/or priority information of the adjusted logistics line corresponding to the logistics object.

The logistics simulation parameters comprise pressure test parameters; the logistics simulation result comprises: the logistics line and the line simulation information of the logistics line; the display module 1602 is configured to display, in the map of the simulation page, a location point corresponding to a node in the logistics line, and a directional line segment between the location points, where the directional line segment reflects the capacity of the logistics line through color and/or thickness.

The display module 1602 is further configured to display a prompt message, where the prompt message includes an overloaded line and/or an overloaded node; the prompt information is determined under the condition that the logistics line is overloaded, and the condition that the logistics line is overloaded is determined according to the line simulation information.

In the simulation process, the single quantity of the route line can be automatically obtained through simulation, if the electric quantity is changed, the system can display the node information of each node, and perform state early warning on the nodes, such as single quantity early warning and the like, so as to perform scientific decision for the route simulation.

The embodiment of the application can display nodes in dimensions such as province, city, district and the like, and can simulate and recommend transportation information such as vehicle types and the like based on single-volume, volume and the like obtained by simulation aiming at a logistics line, thereby being convenient for route selection.

The embodiment of the application can also display the connecting lines among the positions as different colors on the simulation page according to different addresses, aging and the like, thereby prompting the aging range, the transportation grade and the like. The data of allocation, site manpower and cost can be displayed according to the thermodynamic diagram of the order, the optimization of the areas, sites, manpower, cost and the like can be prompted, and the optimizable content can be displayed.

For the logistics lines, the logistics lines can be displayed according to the dimensions of cost, traffic, aging and the like, the logistics lines are displayed according to the comparison information among different logistics lines, and the high-quality lines with balanced cost and aging can be determined and recommended through the comparison information.

The embodiment of the application also provides a non-volatile readable storage medium, in which one or more modules (programs) are stored, where the one or more modules are applied to a device, and the device can execute instructions (instructions) of each method step in the embodiment of the application.

Embodiments of the application provide one or more machine-readable media having instructions stored thereon that, when executed by one or more processors, cause an electronic device to perform a method as described in one or more of the above embodiments. In the embodiment of the application, the electronic equipment comprises terminal equipment, a server and the like.

Embodiments of the present disclosure may be implemented as an apparatus for performing a desired configuration using any suitable hardware, firmware, software, or any combination thereof, which may include a server (cluster), terminal device, or the like. Fig. 17 schematically illustrates an example apparatus 1700 that may be used to implement various embodiments described in the present disclosure.

For one embodiment, FIG. 17 illustrates an example apparatus 1700 having one or more processors 1702, a control module (chipset) 1704 coupled to at least one of the processor(s) 1702, a memory 1706 coupled to the control module 1704, a non-volatile memory (NVM)/storage device 1708 coupled to the control module 1704, one or more input/output devices 1710 coupled to the control module 1704, and a network interface 1712 coupled to the control module 1704.

The processor 1702 may include one or more single-core or multi-core processors, and the processor 1702 may include any combination of general-purpose or special-purpose processors (e.g., graphics processors, application processors, baseband processors, etc.). In some embodiments, the apparatus 1700 can be implemented as a server (cluster), a terminal device, or the like in an embodiment of the present application.

In some embodiments, the apparatus 1700 may include one or more computer-readable media (e.g., memory 1706 or NVM/storage 1708) having instructions 1714 and one or more processors 1702 combined with the one or more computer-readable media configured to execute the instructions 1714 to implement the modules to perform the actions described in this disclosure.

For one embodiment, the control module 1704 may include any suitable interface controller to provide any suitable interface to at least one of the processor(s) 1702 and/or any suitable device or component in communication with the control module 1704.

The control module 1704 may include a memory controller module to provide an interface to the memory 1706. The memory controller modules may be hardware modules, software modules, and/or firmware modules.

Memory 1706 may be used to load and store data and/or instructions 1714 for device 1700, for example. For one embodiment, memory 1706 may include any suitable volatile memory, such as, for example, a suitable DRAM. In some embodiments, memory 1706 may comprise double data rate type four synchronous dynamic random access memory (DDR 4 SDRAM).

For one embodiment, the control module 1704 may include one or more input/output controllers to provide interfaces to the NVM/storage 1708 and the input/output device(s) 1710.

For example, NVM/storage 1708 may be used to store data and/or instructions 1714. NVM/storage 1708 may include any suitable nonvolatile memory (e.g., flash memory) and/or may include any suitable nonvolatile storage device(s) (e.g., one or more Hard Disk Drives (HDDs), one or more Compact Disc (CD) drives, and/or one or more Digital Versatile Disc (DVD) drives).

NVM/storage 1708 may include storage resources that are logistically part of the device on which apparatus 1700 is installed, or which may be accessed by the device or may not be necessary as part of the device. For example, NVM/storage 1708 may be accessed over a network via input/output device(s) 1710.

The input/output device(s) 1710 may provide an interface for the apparatus 1700 to communicate with any other suitable device, and the input/output device 1710 may include a communication component, an audio component, a sensor component, and the like. The network interface 1712 may provide the device 1700 with an interface to communicate over one or more networks, and the device 1700 may wirelessly communicate with one or more components of a wireless network according to any of one or more wireless network standards and/or protocols, such as accessing a wireless network based on a communication standard, such as WiFi, 2G, 3G, 4G, 5G, etc., or a combination thereof.

For one embodiment, at least one of the processor(s) 1702 may be packaged together with logic of one or more controllers (e.g., memory controller modules) of the control module 1704. For one embodiment, at least one of the processor(s) 1702 may be packaged together with logic of one or more controllers of the control module 1704 to form a System In Package (SiP). For one embodiment, at least one of the processor(s) 1702 may be integrated on the same die as logic of one or more controllers of the control module 1704. For one embodiment, at least one of the processor(s) 1702 may be integrated on the same die as logic of one or more controllers of the control module 1704 to form a system on a chip (SoC).

In various embodiments, the apparatus 1700 may be, but is not limited to being: a server, a desktop computing device, or a mobile computing device (e.g., a laptop computing device, a handheld computing device, a tablet, a netbook, etc.), among other terminal devices. In various embodiments, the device 1700 may have more or fewer components and/or different architectures. For example, in some embodiments, the apparatus 1700 includes one or more cameras, a keyboard, a Liquid Crystal Display (LCD) screen (including a touch screen display), a non-volatile memory port, multiple antennas, a graphics chip, an Application Specific Integrated Circuit (ASIC), and a speaker.

The detection device can adopt a main control chip as a processor or a control module, sensor data, position information and the like are stored in a memory or an NVM/storage device, a sensor group can be used as an input/output device, and a communication interface can comprise a network interface.

The embodiment of the application also provides container equipment, which comprises: a processor; and a memory having executable code stored thereon that, when executed, causes the processor to perform a method as described in one or more of the embodiments of the application.

Embodiments of the application also provide one or more machine-readable media having stored thereon executable code that, when executed, causes a processor to perform a method as described in one or more of the embodiments of the application.

For the device embodiments, since they are substantially similar to the method embodiments, the description is relatively simple, and reference is made to the description of the method embodiments for relevant points.

In this specification, each embodiment is described in a progressive manner, and each embodiment is mainly described by differences from other embodiments, and identical and similar parts between the embodiments are all enough to be referred to each other.

Embodiments of the present application are described with reference to flowchart illustrations and/or block diagrams of methods, terminal devices (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing terminal device to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing terminal device, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

While preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the following claims be interpreted as including the preferred embodiment and all such alterations and modifications as fall within the scope of the embodiments of the application.

Finally, it is further noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or terminal that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or terminal. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article or terminal device comprising the element.

The above description of the present application provides a physical distribution data simulation method, a physical distribution data simulation device, an electronic device and a storage medium, and specific examples are applied to illustrate the principles and embodiments of the present application, and the above description of the examples is only used to help understand the method and core ideas of the present application; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in accordance with the ideas of the present application, the present description should not be construed as limiting the present application in view of the above.

Claims (33)

1. A method for simulating logistic data, the method being applied to a simulation system having a simulation page, the method comprising:

receiving logistics simulation parameters acquired through a parameter setting control in the simulation page, wherein the logistics simulation parameters comprise aggregation display conditions;

performing simulation processing according to the logistics simulation parameters to obtain corresponding logistics simulation results, wherein the logistics simulation results comprise nodes, node simulation information and aggregation display results;

matching the logistics simulation result with the map of the simulation page to obtain simulation page data, wherein nodes in the logistics simulation result correspond to position points in the map of the simulation page;

the matching the logistics simulation result with the map of the simulation page comprises the following steps:

determining corresponding position points in a map of the simulation page according to the aggregation display result, and connecting the position points by using directed line segments;

and under the condition that the position point is selected, determining a sub-window of the position point, wherein the sub-window displays aggregation point information corresponding to the position point, and the aggregation point information is related to the aggregation display condition.

2. The method according to claim 1, wherein if the aggregation point includes a node group of a plurality of nodes of the same type, the aggregation point information includes group information of the node group;

if the aggregation point includes a single node, the aggregation point information includes node information of the node.

3. The method of any one of claims 1-2, wherein the polymeric display conditions comprise at least one of: bin presentation conditions, allocation presentation conditions, site presentation conditions, and line presentation conditions.

4. The method of claim 1, wherein the logistic simulation parameters include sender-place information and receiver-place information; the logistics simulation result comprises: a logistics line from the delivery site to the collection site;

the matching the logistics simulation result with the map of the simulation page comprises the following steps:

determining a position point corresponding to a node in the logistics line in a map of the simulation page according to the logistics line from the sender to the receiver;

and connecting the position points in the map of the simulation page by adopting directed line segments so as to display the logistics line.

5. The method as recited in claim 4, further comprising:

Receiving node adjustment information of the logistics line through the simulation page;

and adjusting the corresponding position points and the directed line segments between the position points in the map according to the node adjustment information.

6. The method according to claim 4 or 5, further comprising:

determining line simulation information corresponding to the logistics line to display in the simulation page, wherein the line simulation information comprises at least one of the following: route single amount information, route volume information, route distance information, route duration information, and route cost information.

7. The method as recited in claim 6, further comprising:

and comparing the plurality of logistics lines according to the line simulation information, and determining a comparison result so as to display the comparison result in the simulation page, wherein the starting points and the ending points of the plurality of logistics lines are the same.

8. The method as recited in claim 1, further comprising:

and importing the logistics data of the logistics provider according to the set rules.

9. The method according to claim 1 or 8, further comprising:

setting simulation conditions of a simulation system, wherein the simulation conditions comprise at least one of the following: flow conditions, single-quantity coefficients and rule versions, wherein the rule versions correspond to simulation rules.

10. The method as recited in claim 4, further comprising:

and periodically acquiring weather information of the corresponding positions of all nodes in the logistics line, and adjusting the logistics line according to the weather information.

11. The method of claim 10, wherein said adjusting said logistics line in accordance with said weather information comprises:

analyzing the road condition information of the logistics line in the period according to the weather information;

and under the condition that the road condition information of the logistics line meets the adjustment condition, adjusting the nodes in the logistics line.

12. The method as recited in claim 4, further comprising:

and screening the logistics lines of the logistics objects according to the priority information, and adjusting the logistics lines of the logistics objects.

13. The method of claim 12, wherein the sender-side information and receiver-side information are determined based on order information of the logistic object;

the screening the logistics line of the logistics object according to the priority information and adjusting the logistics line of the logistics object comprises the following steps:

determining priority information of the logistics object according to the order information, wherein the priority information is determined according to at least one of the following parameters: the type of the logistics object and the user grade of the user corresponding to the logistics object;

And adjusting the logistics line of the logistics object according to the priority information.

14. The method of claim 1, wherein the logistic simulation parameters comprise pressure test parameters; the logistics simulation result comprises: the logistics line and the line simulation information of the logistics line;

the matching the logistics simulation result with the map of the simulation page comprises the following steps:

determining position points corresponding to nodes in the logistics line in a map of the simulation page;

and connecting the position points in the map of the simulation page by adopting directed line segments, and determining display information of the directed line segments according to line simulation information, wherein the display information comprises display information for reflecting the carrying capacity of the logistics line.

15. The method as recited in claim 14, further comprising:

and determining prompt information under the condition that the overload of the logistics line is determined according to the line simulation information, wherein the prompt information comprises the overloaded line and/or the overloaded node.

16. The method of claim 15, wherein the hint information further comprises: line adjustment information; the method further comprises the steps of:

And under the condition that the overload of the logistics line is determined according to the line simulation information, executing simulation processing for adjusting the logistics line, and determining the line adjustment information.

17. A method for simulating logistics data, the method comprising:

displaying a simulation page, wherein the simulation page is provided with a parameter setting control, and a map is displayed on the simulation page;

acquiring logistics simulation parameters through the parameter setting control, and sending the logistics simulation parameters, wherein the logistics simulation parameters comprise aggregation display conditions;

receiving simulation page data, wherein the simulation page data is determined according to a logistics simulation result of a logistics simulation parameter, and the logistics simulation result comprises position points, node simulation information and an aggregation display result;

rendering the simulation page data, and displaying position points and node simulation information corresponding to the nodes in the simulation page;

the displaying the position points and the node simulation information corresponding to the nodes in the simulation page comprises the following steps:

displaying position points connected through directed line segments in the simulation page, wherein the position points correspond to aggregation points corresponding to the aggregation display conditions;

And displaying a sub-window of the position point under the condition that the position point is selected, wherein the sub-window displays aggregation point information of an aggregation point corresponding to the position point, and the aggregation point information is related to the aggregation display condition.

18. The method as recited in claim 17, further comprising:

if the aggregation point comprises a plurality of node groups of the same type, the aggregation point information comprises group information of the node groups; if the aggregation point includes a single node, the aggregation point information includes node information of the node.

19. The method of claim 17, wherein the logistic simulation parameters include sender-place information and receiver-place information; the logistics simulation result comprises: a logistics line from the delivery site to the collection site; and the position point corresponds to a node in the logistics line.

20. The method as recited in claim 19, further comprising:

receiving node adjustment information of the logistics line in the simulation page;

and displaying the adjusted logistics line on the map.

21. The method according to claim 19 or 20, further comprising:

Displaying line simulation information corresponding to the logistics line in the simulation page, wherein the line simulation information comprises at least one of the following items: route single amount information, route volume information, route distance information, route duration information, and route cost information.

22. The method as recited in claim 21, further comprising:

and displaying comparison results of the plurality of logistics lines under the condition that the simulation page is provided with the plurality of logistics lines, wherein the starting points and the ending points of the plurality of logistics lines are the same.

23. The method of claim 20, wherein the logistics line is adjusted if the road condition information of the logistics line satisfies an adjustment condition, the road condition information being determined according to periodically acquired weather information analysis.

24. The method of claim 20, wherein displaying the adjusted logistics route on the map comprises:

displaying an adjusted logistics line on a map of the simulation page according to the trigger of the adjustment control;

the logistics line is adjusted according to priority information, and the priority information is determined according to at least one of the following parameters: the type of the logistics object and the user grade of the corresponding user of the logistics object.

25. The method as recited in claim 24, further comprising:

and displaying order information and/or priority information of the logistics objects corresponding to the adjusted logistics lines.

26. The method of claim 17, wherein the logistic simulation parameters comprise pressure test parameters; the logistics simulation result comprises: the logistics line and the line simulation information of the logistics line;

the displaying the position points and the node simulation information corresponding to the nodes in the simulation page comprises the following steps:

and displaying position points corresponding to the nodes in the logistics line and directed line segments among the position points in the map of the simulation page, wherein the directed line segments reflect the carrying capacity of the logistics line through colors and/or thicknesses.

27. The method as recited in claim 26, further comprising:

displaying prompt information, wherein the prompt information comprises an overloaded line and/or an overloaded node; the prompt information is determined under the condition that the logistics line is overloaded, and the condition that the logistics line is overloaded is determined according to the line simulation information.

28. A logistic data simulation device, the device comprising:

The parameter acquisition module is used for receiving the logistics simulation parameters acquired through the parameter setting control in the simulation page, wherein the logistics simulation parameters comprise aggregation display conditions;

the simulation module is used for performing simulation processing according to the logistics simulation parameters to obtain corresponding logistics simulation results, wherein the logistics simulation results comprise nodes, node simulation information and aggregation display results;

the visualization processing module is used for matching the logistics simulation result with the map of the simulation page to obtain simulation page data, wherein nodes in the logistics simulation result correspond to position points in the map of the simulation page;

the visual processing module is used for determining corresponding position points in the map of the simulation page according to the aggregation display result and connecting the position points by adopting directed line segments; and under the condition that the position point is selected, determining a sub-window of the position point, wherein the sub-window displays aggregation point information corresponding to the position point, and the aggregation point information is related to the aggregation display condition.

29. A logistic data simulation device, the device comprising:

the display module is used for displaying a simulation page, the simulation page is provided with a parameter setting control, and the simulation page is displayed with a map; rendering the simulation page data, and displaying position points corresponding to the nodes and node simulation information in the simulation page;

The communication module is used for acquiring logistics simulation parameters through the parameter setting control and sending the logistics simulation parameters, wherein the logistics simulation parameters comprise aggregation display conditions; receiving simulation page data, wherein the simulation page data is determined according to a logistics simulation result of a logistics simulation parameter, and the logistics simulation result comprises position points, node simulation information and an aggregation display result;

the display module is used for displaying position points connected through directed line segments in the simulation page, and the position points correspond to aggregation points corresponding to the aggregation display conditions; and displaying a sub-window of the position point under the condition that the position point is selected, wherein the sub-window displays aggregation point information of an aggregation point corresponding to the position point, and the aggregation point information is related to the aggregation display condition.

30. An electronic device, comprising: a processor; and

memory having executable code stored thereon that, when executed, causes the processor to perform the method of one or more of claims 1-16.

31. One or more machine readable media having executable code stored thereon that, when executed, causes a processor to perform the method of one or more of claims 1-16.

32. An electronic device, comprising: a processor; and

memory having executable code stored thereon that, when executed, causes the processor to perform the method of one or more of claims 17-27.

33. One or more machine readable media having executable code stored thereon that, when executed, causes a processor to perform the method of one or more of claims 17-27.