CN110675688A - True-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system - Google Patents
True-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system Download PDFInfo
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- CN110675688A CN110675688A CN201910948365.XA CN201910948365A CN110675688A CN 110675688 A CN110675688 A CN 110675688A CN 201910948365 A CN201910948365 A CN 201910948365A CN 110675688 A CN110675688 A CN 110675688A
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Abstract
A virtual-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system is characterized in that a task planning and planning generation module is respectively connected with a plurality of local real aircraft platforms, a plurality of other local real aircraft platforms, a plurality of local full-mission flight simulators and real air platform equipment access devices, a multi-domain equipment access device is respectively connected with a task planning and planning generation module, a plurality of local real aircraft platforms and real air platform equipment access devices, the real air platform equipment access devices are respectively connected with the local real aircraft platforms and the local full-mission flight simulators, an airborne virtual opponent simulation generation module and an airborne virtual threat environment generation module are arranged in each local real aircraft platform, a ground virtual opponent simulation generation module is arranged in each local full-mission flight simulator, therefore, the real and virtual co-fusion space-ground integrated tactical training is realized, and the training cost is effectively reduced.
Description
Technical Field
The invention relates to the technical field of information systems, in particular to a true-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system.
Background
At present, internationally, the military mainly develops research of a test, integration and combat training system with real virtual synthesis, the system connects real airplanes, ACMI pod, simulators and the like in active service of the military through active tactics or information data chains such as LINK16, SADL and the like to implement test or combat training, and more, multi-military-force multi-union combat training is developed from a battle-level layer, if the military uses the system in red-flag military, but the system has the defects that: 1) the tactical skill training requirement of a pilot from a flight school to a real fighter cannot be met; 2) the system is only constructed for the active service/in-research equipment of the American army and cannot be directly transplanted to the application of the American army. How to construct a set of real and virtual combined tactical training system enables flight trainees to start tactical skill training from zero foundation to really become a fighter, and the current international exploration stage is also available. At present, domestic air combat training almost completely depends on real equipment, real and virtual fusion air-ground integrated training capacity is not formed, and the real and virtual fusion air-ground integrated tactical training equipment is blank.
Disclosure of Invention
The technical problem to be solved by the invention is to provide a true-virtual co-fusion reconfigurable space-ground integrated multi-domain tactical training system, so as to solve the problems in the background art.
The technical problem solved by the invention is realized by adopting the following technical scheme:
a virtual-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system comprises a task planning and planning generation module, a multi-domain equipment access device, a plurality of other regional real aircraft platforms, a plurality of local real aircraft platforms, a real air platform equipment access device and a plurality of local full-task flight simulators, wherein the task planning and planning generation module is respectively connected with the local real aircraft platforms, the other regional real aircraft platforms, the local full-task flight simulators and the real air platform equipment access device, a task planning module and a planning generation module are arranged in the task planning and planning generation module, the multi-domain equipment access device is respectively connected with the task planning and planning generation module, the local real aircraft platforms and the real air platform equipment access device, and the real air platform equipment access device is respectively connected with the local real aircraft platforms, the local real air platform equipment access device, The ground full-task flight simulators are connected, meanwhile, the real aircraft platforms are connected with one another, the ground full-task flight simulators are connected with one another, an airborne virtual opponent simulation generation module and an airborne virtual threat environment generation module are arranged in each real aircraft platform, and a ground virtual opponent simulation generation module is arranged in each ground full-task flight simulator.
In the invention, a task monitoring module is also arranged in the task planning and scenario generation module.
In the invention, the local field of each local field full-mission flight simulator is connected through Ethernet, and the external field is connected through a command private network; and the system is connected with a real aerial platform through a high-speed low-delay training link or a weapon cooperative link.
In the invention, local aerial platforms of each local real aircraft platform and aerial and ground simulators are interconnected and intercommunicated through a high-speed low-delay training link or a weapon cooperative link.
In the invention, each real aircraft platform is provided with an airborne air-air communication module, and the communication bandwidth of the airborne air-air communication module is not less than 2 Mbps.
In the invention, each local real aircraft platform is provided with an airborne air-ground communication module, and the communication bandwidth of the airborne air-ground communication module is not less than 2 Mbps.
In the invention, each ground full-mission flight simulator is provided with a ground-air communication module used for being connected with a corresponding ground real aircraft platform.
In the invention, each local full-mission flight simulator is provided with a ground communication module used for being connected with a corresponding local real aircraft platform.
Has the advantages that:
1) the invention effectively gets through the training channel between the aerial real airplane and the ground simulator, and carries out the empty and empty tactical training by flexibly and rapidly networking;
2) the invention provides a channel for the joint air-space and air-surface tactical training of the real airplanes and ground simulators among troops in different regions;
3) the invention greatly reduces the difficulty of air combat, particularly middle-distance air combat training, short-distance air support training, combined training group training among different troops and airspace coordination difficulty, ensures that the training which can be developed by spending a large amount of manpower and material resources at ordinary times is daily, and effectively reduces the training cost;
4) the invention can greatly shorten the culture period from zero base to the growth of the flight trainee into the fighter with the fighting capability.
Drawings
FIG. 1 is a schematic diagram of the connection according to the preferred embodiment of the present invention.
Detailed Description
In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further explained below by combining the specific drawings.
Referring to fig. 1, the real-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system comprises a task planning and scenario generation module 1, a task planning module 2, a scenario generation module 3, a task monitoring module 4, a multi-domain equipment access device 5, a real aircraft platform 6 of a different regional troops, a real aircraft platform 7 of a different regional troops, a real aircraft platform 8 of a local region, an airborne virtual opponent simulation generation module 9 of a local region, an airborne virtual threat environment generation module 10 of a airborne virtual threat environment of a local region, an airborne air-ground communication module 11 of a local region, an airborne air-ground communication module 12 of a airborne air-ground communication module of a local region, a airborne air-ground communication module 13 of a local region, an airborne air-ground communication module 14 of a local region, an airborne air-ground communication module 15 of a local region, an airborne virtual threat environment generation module 16 of a airborne virtual opponent of a B airborne region, an airborne virtual threat environment, An A ground virtual opponent simulation generation module 20, an A ground-air communication module 21, an A ground communication module 22, a B ground full-mission flight simulator 23, a B ground-air communication module 24, a B ground communication module 25 and a B ground virtual opponent simulation generation module 26, wherein the mission planning and planning generation module 1 is respectively connected with the A local real aircraft platform 8, the B local real aircraft platform 13, the A ground full-mission flight simulator 19, the B ground full-mission flight simulator 23 and the real air platform equipment access device 18, a mission planning module 2, a planning generation module 3 and a mission monitoring module 4 are arranged in the mission planning and planning generation module 1, the multi-domain equipment access device 5 is respectively connected with the mission planning and planning generation module 1, the A other regional army real aircraft platforms 6, the B other regional army real aircraft platforms 7 and the real air platform equipment access device 18, the real aerial platform equipment access device 18 is respectively connected with a local real aircraft platform 8, a local real aircraft platform 13, a ground full-mission flight simulator 19 and a ground full-mission flight simulator 23, the local real aircraft platform 13 is connected with the local real aircraft platform 8, the ground full-mission flight simulator 23 is connected with the ground full-mission flight simulator 19, the local real aircraft platform 8 is provided with an airborne virtual opponent simulation generation module 9, an airborne virtual threat environment generation module 10, an airborne air-air communication module 11 and an airborne air-ground communication module 12, the local real aircraft platform 13 is provided with an airborne air-air communication module 14, an airborne air-ground communication module 15, an airborne virtual opponent simulation generation module 16 and a airborne virtual threat environment generation module 17, the ground full-mission flight simulator 19 is provided with an airborne virtual opponent simulation generation module 20, a ground virtual opponent simulation generation module 20 and a ground virtual opponent simulation generation module 17, The ground-air communication module A21 and the ground-ground communication module A22, and the ground full-mission flight simulator B23 is provided with a ground-air communication module B24, a ground-ground communication module B25 and a ground virtual opponent simulation generation module B26;
the A ground full-mission flight simulator 19 and the B ground full-mission flight simulator 23 are connected through the Ethernet in the field, and the external field is connected through a command private network; the device is connected with a real aerial platform through a high-speed low-delay training link or a weapon cooperative link;
the A field real airplane platform 8 and the B field real airplane platform 13 are interconnected and intercommunicated between the air platforms of the field and the ground simulator through a training link or a weapon cooperative link with high speed and low time delay;
the functional sub-modules of the mission planning module 2, the scenario generation module 3, the mission monitoring module 4 and the like in the mission planning and scenario generation module 1 are used for planning, directing and monitoring control of tactical missions;
the real aerial platform equipment access device 18 comprises an access sub-module of a local real aerial platform (such as a local real airplane platform 8 and a local real airplane platform 13 in the A and B in the attached drawings) and an access sub-module of real aerial platforms of other regions (such as an army real airplane platform 6 in other regions in the A and an army real airplane platform 7 in other regions in the B in the attached drawings), and is mainly used for data interaction between ground equipment and aerial equipment;
the A airborne air-air communication module 11 and the B airborne air-air communication module 14 are used for providing data interaction of space-time positions, postures, sensors, weapons, virtual opponents, sensors, weapons and the like between the A local real aircraft platform 8 and the B local real aircraft platform 13, the communication bandwidth is not less than 2Mbps, and the time delay is millisecond order;
the A airborne air-ground communication module 12 and the B airborne air-ground communication module 15 mainly achieve information interaction between the A local real aircraft platform 8 and the B local real aircraft platform 13 and information interaction between the A ground full-task flight simulator 19 and the B ground full-task flight simulator 23 such as space-time position and the like, communication bandwidth is not less than 2Mbps, and time delay is millisecond-level;
the A airborne virtual opponent simulation generation module 9 and the B airborne virtual opponent simulation generation module 16 are fused in an aircraft avionics system in an embedded mode, are used for generating a virtual intelligent opponent, a sensor and a weapon thereof, and have certain human-like antagonism;
the ground full-task flight simulator A19 and the ground full-task flight simulator B23 can realize flight similar to a real airplane, and have semi-physical environments for simulating various airborne sensors and operations, various airborne weapons, external hanging management and other task systems of the airplane;
the A ground-air communication module 21 and the B ground-air communication module 24 mainly realize the data interaction of the A ground full-mission flight simulator 19 and the B ground full-mission flight simulator 23 with the real airplane platform A8 and the real airplane platform B13, such as space-time position, attitude, sensor, weapon, virtual opponent, sensor, weapon and the like;
the A-ground communication module 22 and the B-ground communication module 25 mainly realize high-speed low-delay data interaction among the mission planning and scenario generation module 1, the mission planning module 2, the scenario generation module 3, the mission monitoring module 4, the A-ground full-mission flight simulator 19, the B-ground full-mission flight simulator 23 and the real air platform equipment access device 18;
the ground virtual opponent simulation generation module A20 and the ground virtual opponent simulation generation module B26 are fused in the ground simulator in an embedded mode, so that a virtual air intelligent opponent and a virtual air/ground threat environment can be generated, and the intelligent opponent and the threat environment both have antagonism with different intelligent levels.
The foregoing shows and describes the general principles and broad features of the present invention and advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.
Claims (8)
1. A virtual-virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system is characterized by comprising a task planning and planning generation module, a multi-domain equipment access device, a plurality of other regional real aircraft platforms, a plurality of local real aircraft platforms, a real air platform equipment access device and a plurality of local full-task flight simulators, wherein the task planning and planning generation module is respectively connected with the plurality of local real aircraft platforms, the plurality of other regional real aircraft platforms, the plurality of local full-task flight simulators and the real air platform equipment access device, a task planning module and a planning generation module are arranged in the task planning and planning generation module, the multi-domain equipment access device is respectively connected with the task planning and planning generation module, the plurality of local real aircraft platforms and the real air platform equipment access device, the real aerial platform equipment access device is respectively connected with a plurality of local real aircraft platforms and a plurality of local full-mission flight simulators, the local real aircraft platforms are connected with one another, the local full-mission flight simulators are connected with one another, an airborne virtual opponent simulation generation module and an airborne virtual threat environment generation module are arranged in each local real aircraft platform, and a ground virtual opponent simulation generation module is arranged in each local full-mission flight simulator.
2. The system for real-virtual co-fusion reconfigurable space-ground integrated multi-domain tactical training according to claim 1, wherein a task monitoring module is further arranged in the task planning and scenario generation module.
3. The real virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system of claim 1, wherein the local field of each local site full mission flight simulator is connected through Ethernet, and the external field is connected through a command private network.
4. The real virtual co-fusion reconfigurable space-ground integrated multi-domain tactical training system of claim 1, wherein the local aerial platforms of each local real aircraft platform and the aerial and ground simulators are interconnected and intercommunicated through high-speed low-delay training links or weapon cooperative links.
5. The real virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system of claim 1, wherein an airborne air-air communication module is provided in each local real aircraft platform, and the communication bandwidth of the airborne air-air communication module is not less than 2 Mbps.
6. The real virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system of claim 1, wherein an airborne air-ground communication module is provided in each local real aircraft platform, and the communication bandwidth of the airborne air-ground communication module is not less than 2 Mbps.
7. The real virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system of claim 1, wherein each local full-mission flight simulator is provided with an air-ground communication module for connecting with a corresponding local real airplane platform.
8. The real virtual co-fusion reconfigurable air-ground integrated multi-domain tactical training system of claim 1, wherein each local full-mission flight simulator is provided with a ground communication module for connecting with a corresponding local real airplane platform.
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
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| CN115294820A (en) * | 2022-07-13 | 2022-11-04 | 陕西千山航空电子有限责任公司 | Flight mission training computer with master-slave structure |
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Inventor after: Zhang Hong Inventor after: Liu Yaoqin Inventor after: Wang Jun Inventor after: Huang Chaoqiang Inventor after: Liu Chun Inventor after: Li Wei Inventor after: Li Zhigang Inventor after: Yu Kui Inventor after: Zhao Pingjun Inventor after: Teng Jianfang Inventor after: Yu Fuzhang Inventor after: Chen Ying Inventor before: Liu Chun Inventor before: Liu Yaoqin Inventor before: Wang Jun Inventor before: Huang Chaoqiang Inventor before: Zhang Hong Inventor before: Li Wei Inventor before: Li Zhigang Inventor before: Yu Kui Inventor before: Zhao Pingjun Inventor before: Teng Jianfang Inventor before: Yu Fuzhang Inventor before: Chen Ying |
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