Design of Carrier-Based Aircraft Operational Command Training System Based on LVC

doi:10.3969/j.issn.1009-086x.2024.01.017

Abstract

Abstract:

According to the high difficulty and risk in organizing the operational command training of carrier-based aircraft equipped with multiple arms， combined with the advantages of simulation training economy and safety， the carrier-based aircraft operational command training system is researched and designed，the overall frame structure of the carrier-based flight simulation training system is built， the technical principle is described，the function of each subsystem is introduced. The functions of "back to back" operational planning， multi-level force command and control， access to command information system， multi-dimensional situation display， confrontation effect evaluation and other auxiliary decision support are realized. Two application modes， "human-in-the-loop" and "human-out-of-the-loop"， are established， and the key technologies are analyzed， such as the use of injective extension technology to support the high-performance parallel simulation engine driver， the joint middleware technology based on interface programming and dynamic QoS， and the use of code reuse to achieve the integration of the engineering numerical model encapsulation.

Key words: carrier-based aircraft, operational command, simulation training, LVC（live virtual constructive）, flight simulator, joint operation

摘要：

针对舰载机实装多兵种作战指挥训练组织难度大、风险高等特点，考虑到飞行模拟训练经济型、安全性等优点，对舰载机作战指挥训练系统进行研究设计，搭建了系统整体框架，阐述了技术原理，介绍了各分系统的功能作用，实现了“背靠背”作战筹划、多层次兵力指挥控制、接入指挥信息系统实装、多维度态势展现、对抗效果评估等辅助决策支持等功能，建立了“人在环”和“人不在环”两种应用模式，最后对关键技术进行了分析，如采用注入式扩展技术以支撑高性能并行仿真引擎驱动，提出了基于接口的编程和动态QoS的联合中间件技术，利用代码重用方式实现工程数字模型封装集成等。

关键词: 舰载机, 作战指挥, 模拟训练, LVC, 飞行模拟器, 联合作战

CLC Number:

E926.392

Jianchao LIU, Fei DONG, Siyu JI, Qiong WU. Design of Carrier-Based Aircraft Operational Command Training System Based on LVC[J]. Modern Defense Technology, 2024, 52(1): 130-138.

刘剑超, 董斐, 姬嗣愚, 吴穹. 基于LVC的舰载机作战指挥训练系统设计[J]. 现代防御技术, 2024, 52(1): 130-138.

Figures/Tables 7

Fig. 1 Framework diagram of system

Fig. 2 Composition of system

Fig. 3 Application mode of "human-in-the-loop"

Fig. 4 Application mode of "human-out-of-the-loop"

Fig. 5 Structure of simulation engine

Fig. 6 Integration of digital model

Fig. 7 Process of data collection

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