Adnan Ahmad, Rawan Amjad, Amna Basharat, Asma Ahmad Farhan, Ali Ezad Abbas
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引用次数: 0
摘要
本研究提出了一种针对地基防空(GBAD)环境的智能决策支持系统,该环境由地面上需要保护以抵御敌方空中威胁的防御资产(DA)组成。火控官负责评估威胁,并分配最合适的武器来消除威胁。然而,决策过程很容易出错,造成资源浪费并危及 DA 保护。为解决这一问题,本研究提出了一种混合方法,将知识驱动的模糊推理系统与机器学习模型相结合,以优化资源分配,同时在决策过程中纳入专家知识。由于从多个雷达获得的感测数据可能不完整或不正确,因此采用基于模糊知识图谱的系统进行数据融合,并将其提供给连接的模块。通过将最重要的参数(如防御资产的活力和威胁得分)纳入威胁评估,对特征选择进行了优化。这些子系统的结果通过地理信息系统可视化,可实时绘制 GBAD 环境地图,并在用户友好的网络界面上显示结果。所提议的系统经过了严格的测试和评估,最终形成了一个高效、准确的武器分配模型,RMSE 值低至 0.037。总之,该智能决策支持系统为优化 GBAD 环境中的决策过程提供了有效的解决方案,可显著提高伤残军人的防护能力。
Fuzzy knowledge based intelligent decision support system for ground based air defence
This research proposes an Intelligent Decision Support System for Ground-Based Air Defense (GBAD) environments, which consist of Defended Assets (DA) on the ground that require protection from enemy aerial threats. A Fire Control Officer is responsible for assessing threats and assigning the most appropriate weapon to neutralize them. However, the decision-making process can be prone to errors, risking resource wastage and endangering DA protection. To address this problem, this research proposes a hybrid approach that combines a knowledge-driven fuzzy inference system with machine learning models to optimize resource allocation while incorporating expert knowledge in the decision-making process. Since sensory data obtained from multiple radars may be incomplete or incorrect, a fuzzy knowledge graph-based system is used for data fusion and providing it to the connected modules. Feature selection is optimized by including the most important parameters, such as the vitality of defended assets and threat score, in the threat evaluation. The results from these subsystems are visualized using a Geographical Information System, allowing for real-time mapping of the GBAD environment and displaying the results in a user-friendly web interface. The proposed system has undergone rigorous testing and evaluation, resulting in an efficient and accurate weapon assignment model with a low RMSE value of 0.037. Overall, this Intelligent Decision Support System provides an effective solution for optimizing decision-making processes in GBAD environments and can significantly improve DA protection.
期刊介绍:
The purpose of JAIHC is to provide a high profile, leading edge forum for academics, industrial professionals, educators and policy makers involved in the field to contribute, to disseminate the most innovative researches and developments of all aspects of ambient intelligence and humanized computing, such as intelligent/smart objects, environments/spaces, and systems. The journal discusses various technical, safety, personal, social, physical, political, artistic and economic issues. The research topics covered by the journal are (but not limited to):
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