Deep Reinforcement Learning Based Systems for Safety Critical Applications in Aerospace
- URL: http://arxiv.org/abs/2412.16489v1
- Date: Sat, 21 Dec 2024 05:17:55 GMT
- Title: Deep Reinforcement Learning Based Systems for Safety Critical Applications in Aerospace
- Authors: Abedin Sherifi,
- Abstract summary: Recent advancements in artificial intelligence (AI) applications within aerospace have demonstrated substantial growth.
As High Performance Computing platforms continue to evolve, they are expected to replace current flight control or engine control computers.
This shift will allow real-time AI applications, such as image processing and defect detection, to be seamlessly integrated into monitoring systems.
- Score: 0.0
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- Abstract: Recent advancements in artificial intelligence (AI) applications within aerospace have demonstrated substantial growth, particularly in the context of control systems. As High Performance Computing (HPC) platforms continue to evolve, they are expected to replace current flight control or engine control computers, enabling increased computational capabilities. This shift will allow real-time AI applications, such as image processing and defect detection, to be seamlessly integrated into monitoring systems, providing real-time awareness and enhanced fault detection and accommodation. Furthermore, AI's potential in aerospace extends to control systems, where its application can range from full autonomy to enhancing human control through assistive features. AI, particularly deep reinforcement learning (DRL), can offer significant improvements in control systems, whether for autonomous operation or as an augmentative tool.
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