CN117453841A - Three-dimensional geographic information large-model-assisted chess deduction system and method - Google Patents

Abstract

The invention provides a three-dimensional geographic information large-model-assisted chess deduction system and method, which can simulate and analyze geographic environment more accurately and comprehensively through the steps of task setting, map construction, force deployment, action simulation, intelligent decision, command control and fight assessment, improve fight efficiency and decision accuracy, and provide rapid simulation support for a modern combined fight system. The method integrates a plurality of technical fields of three-dimensional geographic information, model construction, artificial intelligence and the like, can more accurately express the vertical dimension of the geographic space, provides more comprehensive space analysis and simulation, enhances decision support capability, and improves the accuracy and comprehensiveness of the deduction of the chess. The invention can be applied to the fields of urban planning, military strategy and emergency management, and the like, and has wide application prospect and important practical value. The invention aims to assist the deduction of the chess by utilizing a three-dimensional geographic large model.

Description

Three-dimensional geographic information large-model-assisted chess deduction system and method

Technical Field

The invention relates to the field of a chess deduction system, in particular to a chess deduction system and method assisted by a three-dimensional geographic information large model.

Background

A chess deduction system belongs to the technical field of military simulation. Military simulation techniques are the process and results of simulating and reproducing military operations such as warfare, combat operations, weapon systems, and the like using computers and related software tools. The chess deduction system is a software system for military war deduction and decision analysis in a computer environment. The method helps military decision makers, commanders and researchers evaluate the effect of military operations, test tactics and strategies and train military personnel through modeling and simulating war rules and war environments, thereby providing tools for decision support and war exercise. So the development is urgent and necessary.

The chess deduction system combines knowledge and methods in the technical fields of computer science, mathematical modeling, artificial intelligence, virtual reality and the like. The system can simulate elements such as the geographic environment, the topography, the weapon system, the weapon deployment, the action instruction and the like of a battlefield, and can display possible results of the battlefield action in a calculation and prediction mode. The goal of the chess deduction system is to provide evaluation and decision support for military decisions, help military directors and decision makers to make more effective combat plans and military strategies, and improve combat effectiveness and decision accuracy.

With the continuous development of Geographic Information Systems (GIS), computer graphics and other technologies, in the chess deduction method, the three-dimensional geographic update can provide more accurate and comprehensive geographic environment simulation and analysis.

Computer chess deduction systems are now mainly divided into two categories, military and commercial. However, the simulation environments of the two deduction systems are basically consistent, the local battlefield environment is simulated based on the two-dimensional plane geographic image, the real-time display of the three-dimensional situation cannot be realized, the utilization of the height information is insufficient, the fight details such as the hit position of the fight unit and the like are ignored, the function is single, the space fight simulation is extremely unfavorable, and then the fight command is influenced. In addition, the two parties of the fight mainly interact with each other for people, the fight model development is mainly based on a two-dimensional fight space and a digital fight unit, the fight space lacks reality, the fight unit lacks related complex modeling, and the integral visualization capability is poor and the gap between the actual fight process is larger; the existing simulation platform has limited combat setting quantity and is not easy to modify, and the process of setting up a new setting environment is complicated, which is not beneficial to the rapid simulation of a modern combined combat system on emergencies.

In summary, the invention of a method for deducting a chess based on the assistance of a three-dimensional geographic large model is urgent and necessary.

Disclosure of Invention

The invention provides a soldier chess deduction system and a soldier chess deduction method assisted by a three-dimensional geographic information large model, which are used for solving the problems of improvement of accuracy of geographic expression of the three-dimensional geographic information large model (3D GIS), comprehensiveness of spatial analysis, enhancement of decision support, improvement of virtual reality experience and the like.

According to a first aspect of the invention, the technical scheme adopted by the invention is as follows: a soldier chess deduction system based on three-bit geographic information large model assistance comprises the following modules:

the map construction module is used for constructing a three-dimensional geographic large model, and comprises information such as topography, landform and the like of the earth surface;

the task setting module is used for compiling a combat assumption on combat targets, combat force data, combat rules and combat task sequences to obtain initialization parameters;

the weapon force deployment module is used for deploying weapon forces, and deploying weapon forces of different types at different positions of the three-dimensional geographic big model according to the combat plan;

the action simulation module is used for simulating actions of the forces and simulating action routes and attack directions of the forces according to the information of the positions, the terrains and the like of different types of forces on the three-dimensional geographic large model;

the intelligent decision module is used for automatically generating an optimal decision suggestion according to situation information of action simulation and transmitting the optimal decision suggestion to the command control module;

the command control module is used for commanding and controlling the process of deduction of the soldier chess, and comprises the steps of setting a combat plan, adjusting the deployment of the forces and adjusting combat evaluation;

and the combat evaluation module is used for evaluating combat results, and evaluating combat results of parties such as combat loss, occupied areas and the like according to simulated combat conditions.

Preferably, in the process of constructing a three-dimensional geographic large model, a satellite remote sensing technology or an aerial photography technology is adopted to acquire topographic and geomorphic data, and GIS software is utilized to perform data processing and modeling; then, a three-dimensional geographic information model is established, a three-dimensional model of terrain, water system and road elements is established through GIS software, and texture mapping and illumination simulation are carried out; and finally combining the three-dimensional geographic information model with the rules of the chess, taking the three-dimensional geographic information model as a basic environment for the deduction of the chess, and setting terrain barriers and enemy defending facilities according to the rules of the chess.

Preferably, the task setting module sets a combat target, combat rules and combat task sequences based on combat; wherein the combat target comprises destroying important military facilities of enemy, occupying important battle fields of enemy and protecting important targets of own; the combat rules include equipment usage rules and combat action rules.

Preferably, in the task setting module, the situation of simulated combat required by the user, including the information of the geographic environment, the forces, equipment and combat targets of the two parties, is determined by determining the task targets and the combat data, and then a corresponding combat plan is compiled.

Preferably, the force deployment module automatically sets the arms and equipment thereof according to actual war scenes and strategy requirements, including designing force deployment, combat actions and tactical strategies with different types and scales; the weapon species comprise infantry, artillery, industrial soldier and armored soldier; equipment includes weapons, ammunition, armored vehicles, aircraft, and is adapted and evolved according to corresponding tactical and strategic requirements.

Preferably, the operation simulation module is used for simulating and analyzing military operations in a virtual environment; comprises simulating force action, obtaining real-time combat conditions, and adjusting execution decisions;

and the method can simulate the action route, attack direction and the like of the weapon according to the position and terrain information of different types of weapon on the three-dimensional geographic large model, and make decisions and adjust strategies according to the real-time updated war condition information.

Preferably, the intelligent decision module is used for providing real-time feedback and analysis functions, analyzing and evaluating decisions, and providing corresponding suggestions and guidance to optimize strategic decisions.

Preferably, the command control module is used for simulating and analyzing military operations in a virtual environment, can acquire feedback in real time, and then accurately controls the trend of the chess in real time to assist a user to conduct command; and the trend of the chess can be controlled according to different army deployment and strategies and simulated combat results to obtain different results.

Preferably, the combat evaluation module is further capable of evaluating combat results of the parties such as combat losses and occupied areas according to simulated combat conditions by collecting simulation data and then performing combat evaluation, and provides real-time feedback and analysis functions.

According to a second aspect of the invention, the technical scheme adopted by the invention is as follows: a soldier chess deduction method based on three-bit geographic information large model assistance comprises the following steps:

obtaining geographic information, establishing a three-dimensional geographic information model and training the model; collecting geographic information data, constructing a three-dimensional geographic information large model of a terrain multi-element, and integrating the generated three-dimensional geographic information large model into a chess deduction system;

setting combat targets, combat rules and combat task parameters in a task setting module, and transmitting task initialization parameters to a chess deduction system after the parameters are adjusted;

the method comprises the steps of respectively designing the force deployment, simulating the force action, optimizing strategic decision and controlling the trend of the chess through a force deployment module, an action simulation module, an intelligent decision module and a command control module, and sequentially connecting each module of a chess deduction system into the chess deduction system;

and (3) performing fight evaluation, transmitting fight data of the fight chess generated by simulation to a fight evaluation module, and performing comprehensive evaluation on the performances of each module of the fight chess deduction system and evaluation on both sides of the fight chess deduction.

Compared with the prior art, the invention has the following advantages and beneficial effects:

1. more accurate geographical representation: conventional two-dimensional maps and planar Geographic Information Systems (GIS) can only provide a planar view of the earth's surface, while three-dimensional geographic information large models can present the vertical dimension of geographic space in a more accurate manner. By presenting the geographic data in a three-dimensional form, the real conditions of the topography, the land feature and the ground feature can be better reflected, and more accurate and visual geographic expression is provided.

2. More comprehensive spatial analysis: the three-dimensional geographic information large model allows for more comprehensive analysis and simulation in space. By combining the geographic data with the vertical dimension, more accurate visual analysis can be performed, including topography analysis, flow simulation, visual field analysis, and the like. These analyses are important in the areas of urban planning, emergency response, environmental assessment, etc.

3. Enhancing decision support: the three-dimensional geographic information large model can provide more visual and comprehensive geographic information and help a decision maker to make a more intelligent decision. For example, in urban planning, three-dimensional models may be used to evaluate the impact of buildings, roads, and infrastructure on urban landscape and landscapes. In military strategy and emergency management, three-dimensional models may be used to evaluate the impact of a geographic environment on army operations and disaster handling.

4. Promote virtual reality experience: with the rapid development of Virtual Reality (VR) and Augmented Reality (AR) technologies, three-dimensional geographic information large models provide the basis for creating realistic virtual environments. By combining geographic data with virtual reality technology, an interactive virtual reality experience can be created.

In summary, the three-dimensional geographic information large model has the advantages of providing accurate geographic expression, comprehensive spatial analysis, enhancing decision support, improving virtual reality experience and the like. These advantages drive the wide application and development of three-dimensional geographic information large models in various fields.

Drawings

FIG. 1 is a flow chart of a soldier chess deduction system module assisted by a three-dimensional geographic information large model provided by an embodiment of the invention;

FIG. 2 is a general flow chart of a soldier chess deduction system assisted by a three-dimensional geographic information large model provided by the embodiment of the invention;

FIG. 3 is a flow chart of three-dimensional geographic large model construction provided by an embodiment of the invention;

fig. 4 is a flowchart of a method for deriving a soldier chess assisted by a three-dimensional geographic information large model according to an embodiment of the invention.

Detailed Description

The invention will now be described in further detail with reference to the drawings and examples.

In order to facilitate the understanding and practice of the invention, those of ordinary skill in the art will now make further details with reference to the drawings and examples, it being understood that the examples described herein are for the purpose of illustration and explanation only and are not intended to limit the invention thereto.

Please see fig. 1 for a flow chart of a module of a chess deduction system assisted by a three-dimensional geographic information large model, and fig. 2 for a general flow chart of a chess deduction system assisted by a three-dimensional geographic information large model; referring to fig. 1 and 2, the embodiment of the invention provides a three-dimensional geographic information large model-assisted chess deduction system, which comprises the following modules:

module 1: the map construction module is used for constructing a three-dimensional geographic large model comprising the topography and landform information of the earth surface;

preferably, the map building module generally includes data collection, data preprocessing, data integration, map symbolization, mapping, map updating functions. The modules may vary with the particular application and requirements. For example, for military strategies, task performers may add specific data analysis and processing functions to change the direction of operation of the module.

The map building module, which involves collecting environmental data and converting these data into map information that can be understood and used by a computer program. In the map construction module, data are collected to train a geographic model, geographic information of the region is collected according to the needed geographic environment information, and a corresponding three-dimensional map is constructed. The method comprises the following specific steps: in the process of acquiring three-dimensional geographic information data, acquiring topographic and geomorphic data by adopting a satellite remote sensing technology or an aerial photography technology, and performing data processing and modeling by utilizing GIS software; then, a three-dimensional geographic information model is established, a three-dimensional model of elements such as terrain, water system and road is established through GIS software, and texture mapping and illumination simulation are carried out to enhance the sense of reality of the model; finally, after the three-dimensional geographic information large model is successfully established, the three-dimensional geographic information model is combined with the chess rules, the three-dimensional geographic information model is used as a basic environment for the deduction of the chess, and elements such as terrain barriers, enemy defending facilities and the like are set according to the chess rules, so that the real battlefield situation can be better understood and dealt with.

Module 2: the task setting module is used for editing and obtaining initialization parameters based on the fight target, fight force data, fight rules and fight task sequences;

preferably, the task setting module can define and describe the background, target, environmental condition, participant, resource and other relevant information of the task when planning, executing and evaluating the task, and the task setting module is a plan and prediction performed by the chess deduction system before executing the task, and aims to provide detailed information required by task execution, so that a task executor can be helped to comprehensively understand the background and meaning of the task.

The task setting module is an important component part in the chess deduction system and can set a fight target, a fight rule and a fight task sequence based on fight, wherein the fight target comprises destroying important military facilities of enemy, occupying important battle areas of enemy, protecting important targets of own side and the like; the combat rules include equipment usage rules, combat action rules, and the like. The module provides a foundation and framework for simulating combat so that a user can practice and train in a virtual environment. In the module, the scene of simulated combat required by a user is determined by determining task targets and combat data, which may include information such as geographical environment, forces of both enemy parties, equipment, combat targets and the like. And then a corresponding combat plan is compiled.

Module 3: and the weapon force deployment module. Deploying the forces by using a force deployment module, and deploying different types of forces at different positions of the three-dimensional geographic large model according to the combat plan;

preferably, the force deployment module is a software module or system for planning and optimizing force distribution and deployment of the army. The system can help military commanders and planners to effectively use the army resources under different tasks and situations, and has advantages in battlefields. The army deployment module generally comprises functions of battlefield information analysis, army demand assessment, army distribution and scheduling, combat effectiveness simulation, real-time information updating, integrated decision support and the like. The weapon force deployment module aims to realize reasonable distribution and deployment of weapon force by utilizing the self function, and ensure that army can effectively execute various combat tasks. By using the module, the combat effectiveness can be improved, the risk can be reduced, and the advantage of a battlefield can be realized.

The weapon power deployment module can automatically set weapon types and equipment thereof according to actual war scenes and strategic demands, wherein the weapon types comprise infantry, artillery, industrial soldier, armored soldier and the like, and the equipment comprises weapons, ammunition, armored vehicles, airplanes and the like and can be adjusted and evolved according to corresponding tactical and strategic demands. The intelligent management system mainly has the following three functions of designing different types and scales of force deployment, combat actions and tactical strategies, and the force deployment module can well combine deployment requirements with decisions through the three functions, so that the accuracy of decisions and the accuracy of deployment allocation are greatly improved.

Module 4: the action simulation module simulates actions of the forces through the action simulation module, and simulates action routes, attack directions and the like of the forces according to the position, the terrain and other information of different types of forces on the three-dimensional geographic large model;

preferably, the action simulation module is a software module or system for simulating and evaluating various action plans and tactical schemes. It provides a virtual environment in which different combat actions can be simulated and exercised and the effects and feasibility of which are evaluated. The operation simulation module plays an important role in the fields of military training, tactical planning, decision support and the like. The action simulation module generally includes: virtual environment, units and forces, combat action simulation, firepower support and combat effect simulation, visualization and real-time feedback, data analysis and evaluation, and the like. By using the action simulation module, the army can train, drill and evaluate in real time in the virtual environment to improve the combat capability and decision making effect. It can help commanders and tactical planners verify and optimize various tactical schemes and provide decision support and training opportunities. The use of an action simulation module can greatly reduce the risk and cost of actual actions and improve army readiness and response capability.

The operation simulation module is used for simulating and analyzing military operations in the virtual environment. The system may be used for military training, military exercises, tactical planning, and educational purposes so that military personnel can practice and evaluate various tactics and operations in a simulated environment. The module has the following three main functions: simulating the action of force, obtaining real-time combat conditions and adjusting execution decisions. This module is very important for military decisions, tactical planning, and educational training, as it allows military personnel to simulate various situations in a virtual environment, reducing risk and cost on an actual battlefield, and improving the ability to cope with complex situations. In addition, they can also be used in military research and military exercises to evaluate the effectiveness of new tactics, weapons and strategies based on information such as the location and topography of different types of forces on a three-dimensional geographic large model, simulate the course of action and direction of attack of forces, etc., and make decisions and adjust strategies based on real-time updated tactical information.

Module 5: the intelligent decision module is used for automatically generating an optimal decision suggestion according to situation information of the existing action simulation and transmitting the optimal decision suggestion to the command control module;

preferably, the intelligent decision module utilizes artificial intelligence and machine learning techniques to assist in the module or system of decision-making processes. It can analyze large amounts of data, intelligence, and information, providing real-time insight, predictions, and suggestions required by a decision maker to support more accurate, rapid, and intelligent decisions. By using intelligent decision-making modules, a decision maker can better utilize data and information, quickly identify key factors from complex environments, understand potential impacts, and make informed decisions based on data-driven insight. The intelligent decision-making module plays an important role in various fields such as enterprise management, finance, risk management, medical treatment, military and the like, and improves the accuracy, efficiency and effect of decision-making.

The intelligent decision module is a key component for supporting an intelligent system, software or robot to make decisions in specific tasks. These modules typically rely on Artificial Intelligence (AI) and machine learning techniques to process large amounts of information, analyze context, and formulate optimal action plans. The module performs strategic assessment and optimizes strategic decisions to achieve intelligent decision functions by providing real-time feedback. Real-time feedback and analysis functions can be provided to analyze and evaluate decisions and provide corresponding suggestions and guidance.

And (6) module 6: and the command control module is used for commanding and controlling the process of deduction of the soldier chess, including resetting a combat plan, adjusting the deployment of the forces of the soldiers, adjusting combat evaluation and the like.

Preferably, the command control module directs technical modules for commanding and controlling tasks, operations or systems. It can be used in various fields to support the decision maker or director to conduct effective command and control. By using the command control module, a director can better organize and coordinate executors, resources and tasks, and realize efficient execution of tasks and precise control of command. Especially in military operations, the command control module plays a key role, and the efficiency and the effect of command and control are improved.

The command control module is used for simulating and analyzing military operations in a virtual environment. Such systems are commonly used for military training, military exercises, tactical planning, and educational purposes so that military personnel can practice and evaluate various tactics and operations in a simulated environment. Aims to assist commanders and decision makers in managing resources, performing tasks and making critical decisions in complex environments. The module can acquire feedback in real time, and then accurately control the trend of the chess in real time, so as to assist a user in commanding. And the trend of the chess can be controlled according to different army deployment and strategies and simulated combat results to obtain different results.

Module 7: and a combat evaluation module. And (3) evaluating the fight result through a fight evaluation module, and evaluating the fight results of the fight loss, the occupied area and the like of each party according to the simulated fight condition.

Preferably, the combat evaluation module is a technical module for evaluating combat actions and combat effects. It is intended to provide quantitative and qualitative assessment of combat processes and outcomes to support the director and decision maker in making tactical and strategic decisions. Combat evaluation modules play a critical role in military operations. The system can help a director to know the actual situation and effect of a battle, evaluate the effectiveness of the strategy and tactics, and make optimization and adjustment. Through the combat evaluation module, a director can better know and control the battlefield module, and accuracy and effect of combat decision are improved.

The combat evaluation module is used for evaluating combat processes, results and effectiveness. The aim is to provide a comprehensive and accurate assessment of combat actions, to support command decisions, to improve combat strategies and tactics, and to provide empirical training for future combat actions. The module can collect simulation data and then perform fight evaluation, so that not only can the real-time data analysis of a battlefield be provided, the commander can be guided to make quick and intelligent decisions, the fight efficiency and the fight success rate can be improved to the greatest extent, but also the fight results of fight loss, occupied areas and the like of each party can be evaluated according to the simulated fight situation, and the real-time feedback and analysis functions can be provided.

The chess deduction system provided by the embodiment of the invention can set different combat tasks according to different geographic environments and combat targets, so as to meet different combat environments; further, different difficulty levels and campaign modes can be set according to different user requirements and interests so as to meet player requirements of different levels.

According to a second aspect of the present invention, an embodiment of the present invention provides a method for deriving a chess game based on assistance of a three-dimensional geographic information large model, please refer to fig. 3, which is a flowchart of a method for deriving a chess game based on assistance of a three-dimensional geographic information large model, as shown in fig. 3, the method includes the following steps:

step 1: obtaining geographic information, establishing a three-dimensional geographic information model and training the model; then, collecting more geographic information data, constructing a complex three-dimensional geographic information large model comprising a plurality of terrain elements, and perfectly integrating the generated model into a chess deduction system;

preferably, in step 1, the three-dimensional geographic construction module is used to acquire geographic information, including acquisition of geographic position data, establishment of a three-dimensional geographic information model and training of the model. Subsequently, more extensive geographic information data collection is actively underway to build a complex three-dimensional geographic information large model comprising terrain multiple elements. The three-dimensional geographic large model aims to reflect the real geographic situation as perfectly as possible, and comprises a plurality of key elements such as topography, geomorphology and the like. And finally, perfectly integrating the generated complex three-dimensional geographic information large model into a chess deduction system to ensure that the system can provide the most accurate and practical geographic information support in the chess deduction and decision process. Such optimization helps to improve the performance and efficiency of the system.

FIG. 4 is a flow chart for constructing a three-dimensional geographic large model, which is provided by the embodiment of the invention, wherein the process of constructing the three-dimensional geographic large model comprises the steps of acquiring topographic and geomorphic data by adopting a satellite remote sensing technology or an aerial photography technology, and carrying out data processing and modeling by utilizing GIS software; then, a three-dimensional geographic information model is established, a three-dimensional model of terrain, water system and road elements is established through GIS software, and texture mapping and illumination simulation are carried out; and finally combining the three-dimensional geographic information model with the rules of the chess, taking the three-dimensional geographic information model as a basic environment for the deduction of the chess, and setting terrain barriers and enemy defending facilities according to the rules of the chess.

Step 2: defining combat targets, rules and task parameters, and transmitting task initialization parameters to a chess deduction system after adjusting the parameters in a task setting module so as to enable the system to carry out accurate military simulation and decision;

preferably, in step 2, after explicitly defining the combat objectives, rules and mission parameters, the user first carefully adjusts these parameters in the mission setting module, including but not limited to factors such as the force ratio of the enemy party, the weaponry, the topography and the topography, etc., to ensure that the outcome of the combat deduction is as close as possible to the real battlefield situation. After the adjustment of the parameters is completed, the task initialization parameters are transmitted to the chess deduction system. This provides the system with the data base required for accurate military simulations and decisions. The module has the advantage of ensuring that the system can realize more accurate simulation and decision-making based on well-defined targets and rules and well-regulated task parameters when performing chess deduction and decision-making. This helps to improve the practicality and feasibility of the chess system.

Step 3: the chess deduction is carried out, and different stages of chess deduction are completed through a series of key modules, including a weapon power deployment module, an action simulation module, an intelligent decision module and a command control module. This covers planning of the deployment of forces, simulation of actions, fine tuning of strategic decisions, and real-time mastering of the action of the chess. And then, the chess deduction modules are sequentially integrated into a chess deduction system, so that the overall process of chess deduction is realized. The purpose of this procedure is to provide a highly accurate and controllable environment that supports military strategies and tactical decisions to assist the military decision maker in making an informed choice.

Preferably, in step 3, a series of key modules such as a force deployment module, an action simulation module, an intelligent decision module and a command control module are orderly utilized, covering military operations in different stages. This includes strategy-level force deployment planning, real-time action simulation, fine tuning of tactical and strategic decisions, and real-time chess action monitoring. Then, the chess deduction modules are integrated into a chess deduction system according to a given sequence, so that the whole course simulation of chess deduction is realized. The core goal of this process is to provide a highly accurate and controlled environment for military decision makers to assist them in making informed decisions. The method has the advantages that the method can ensure that the chess deduction system can comprehensively support the needs of military strategies and tactical decisions, provide accurate simulation and real-time mastery conditions, and further help decision makers to make more intelligent choices.

Step 4: and finally, performing fight evaluation, and transmitting fight data of the chess generated by simulation to comprehensively evaluate the performances of the modules, and simultaneously evaluating participants of each party deduced by the chess. This helps to provide insight and control in understanding battlefield situations deeply, thereby improving the accuracy and effectiveness of combat decisions. This key step is to ensure the effectiveness and practicality of the chess deduction system, helping to improve the decision making process of military strategies and tactics.

Preferably, in the fourth step, the fight evaluation module transmits fight data of the chess generated by previous simulation to comprehensively evaluate the performance of each module, and simultaneously evaluate participants of each party deduced by the chess. The key step aims at deeply understanding the battlefield situation and providing key insight and actual control so as to improve the accuracy and effect of the battle decision. This key step is an important link to ensure the effectiveness and practicality of the chess deduction system, helping to improve the decision making process of military strategies and tactics to ensure that more intelligent decisions can be made in the real world.

In summary, according to the method for deducing the soldiers with the assistance of the three-dimensional geographic information large model, provided by the embodiment of the invention, through the steps of task setting, map construction, army deployment, action simulation, intelligent decision making, command control and fight assessment, the geographic environment can be simulated and analyzed more accurately and comprehensively, the fight efficiency and the decision accuracy are improved, and the support of quick simulation is provided for a modern combined fight system. The method integrates a plurality of technical fields of three-dimensional geographic information, model construction, artificial intelligence and the like, can more accurately express the vertical dimension of the geographic space, provides more comprehensive space analysis and simulation, enhances decision support capability, and improves the accuracy and comprehensiveness of the deduction of the chess. The invention can be applied to the fields of urban planning, military strategy and emergency management, and the like, and has wide application prospect and important practical value.

It is noted that each module/step described in this application may be split into more modules/steps, or two or more modules/steps or portions of the operations of the modules/steps may be combined into new modules/steps, as needed for implementation, to achieve the objects of the invention.

It will be readily understood by those skilled in the art that the foregoing description is only of the preferred embodiments of the invention and is not intended to limit the invention, but any modifications, equivalents, improvements or modifications made within the spirit and principles of the invention are intended to be included within the scope of the invention.

Claims (10)

1. A three-dimensional geographic information large model auxiliary chess deduction system is characterized in that: comprising the following steps:

the map construction module is used for constructing a three-dimensional geographic large model; including topography and topography information of the earth's surface;

the task setting module is used for compiling a combat assumption on combat targets, combat force data, combat rules and combat task sequences to obtain initialization parameters;

the weapon force deployment module is used for deploying weapon forces, and deploying weapon forces of different types at different positions of the three-dimensional geographic big model according to the combat plan;

the action simulation module is used for simulating actions of the forces and simulating action routes and attack directions of the forces according to the information of the positions, the terrains and the like of different types of forces on the three-dimensional geographic large model;

the intelligent decision module is used for automatically generating an optimal decision suggestion according to situation information of action simulation and transmitting the optimal decision suggestion to the command control module;

the command control module is used for commanding and controlling the process of deduction of the soldier chess, and comprises the steps of setting a combat plan, adjusting the deployment of the forces and adjusting combat evaluation;

and the combat evaluation module is used for evaluating combat results, and evaluating combat results of parties such as combat loss, occupied areas and the like according to simulated combat conditions.

2. The system for deducing the chess with the assistance of the large three-dimensional geographic information model according to claim 1, wherein the map construction module acquires the data of the topography and the relief by adopting a satellite remote sensing technology or an aerial photography technology and performs data processing and modeling by utilizing GIS software in the process of constructing the large three-dimensional geographic information model; then, a three-dimensional geographic information model is established, a three-dimensional model of terrain, water system and road elements is established through GIS software, and texture mapping and illumination simulation are carried out; and finally combining the three-dimensional geographic information model with the rules of the chess, taking the three-dimensional geographic information model as a basic environment for the deduction of the chess, and setting terrain barriers and enemy defending facilities according to the rules of the chess.

3. The system for three-dimensional geographic information large model aided chess deduction according to claim 1, wherein the task setting module sets a combat target, combat rules and combat task sequences based on combat; wherein the combat target comprises destroying important military facilities of enemy, occupying important battle fields of enemy and protecting important targets of own; the combat rules include equipment usage rules and combat action rules.

4. A three-dimensional geographic information large-model aided chess deduction system according to claim 3, wherein in the task setting module, the scene of simulated combat required by a user, including the information of the geographic environment, the forces of both enemy and the equipment and the combat target, is determined through the determination of task targets and combat data, and then a corresponding combat plan is compiled.

5. The system for the development of the chess assisted by the large three-dimensional geographic information model according to claim 1, wherein the force deployment module is used for automatically setting the types and equipment of the chess according to actual war scenes and strategic requirements, and comprises the steps of designing force deployment, combat actions and tactical strategies with different types and scales; the weapon species comprise infantry, artillery, industrial soldier and armored soldier; equipment includes weapons, ammunition, armored vehicles, aircraft, and is adapted and evolved according to corresponding tactical and strategic requirements.

6. The system for three-dimensional geographic information large model aided chess deduction according to claim 1, wherein said action simulation module is used for simulating and analyzing military actions in a virtual environment; comprises simulating force action, obtaining real-time combat conditions, and adjusting execution decisions;

and the method can simulate the action route, attack direction and the like of the weapon according to the position and terrain information of different types of weapon on the three-dimensional geographic large model, and make decisions and adjust strategies according to the real-time updated war condition information.

7. The system of claim 1, wherein the intelligent decision module is configured to provide real-time feedback and analysis, analyze and evaluate decisions, and provide corresponding advice and guidance to optimize strategic decisions.

8. The system for deducing the chess with the assistance of the large three-dimensional geographic information model according to claim 1, wherein the command control module is used for simulating and analyzing military operations in a virtual environment, and can acquire feedback in real time, accurately control the trend of the chess in real time and assist a user to command; and the trend of the chess can be controlled according to different army deployment and strategies and simulated combat results to obtain different results.

9. The system for the deduction of the soldiers chess assisted by the large three-dimensional geographic information model according to claim 1, wherein the combat evaluation module is used for collecting simulation data and then carrying out combat evaluation, and can be used for evaluating combat losses, occupied areas and other combat results of all parties according to simulated combat conditions and providing real-time feedback and analysis functions.

10. A method for three-dimensional geographic information large model-aided chess deduction for the chess deduction system of claim 1, the method comprising the steps of:

obtaining geographic information, establishing a three-dimensional geographic information model and training the model; collecting geographic information data, constructing a three-dimensional geographic information large model of a terrain multi-element, and integrating the generated three-dimensional geographic information large model into a chess deduction system;

setting combat targets, combat rules and combat task parameters in a task setting module, and transmitting task initialization parameters to a chess deduction system after the parameters are adjusted;

the method comprises the steps of respectively designing the force deployment, simulating the force action, optimizing strategic decision and controlling the trend of the chess through a force deployment module, an action simulation module, an intelligent decision module and a command control module, and sequentially connecting each module of a chess deduction system into the chess deduction system;

and (3) performing fight evaluation, transmitting fight data of the fight chess generated by simulation to a fight evaluation module, and performing comprehensive evaluation on the performances of each module of the fight chess deduction system and evaluation on both sides of the fight chess deduction.