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Main Author: Sarwar, Mir Md Sajid
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.09578
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author Sarwar, Mir Md Sajid
author_facet Sarwar, Mir Md Sajid
contents The recent advancement in artificial intelligence (AI) technologies facilitates a paradigm shift toward automation. Autonomous systems are fully or partially replacing manually crafted ones. At the core of these systems is automated planning. With the advent of powerful planners, automated planning is now applied to many complex and safety-critical domains, including smart energy grids, self-driving cars, warehouse automation, urban and air traffic control, search and rescue operations, surveillance, robotics, and healthcare. There is a growing need to generate explanations of AI-based systems, which is one of the major challenges the planning community faces today. The thesis presents a comprehensive study on explainable artificial intelligence planning (XAIP) for hybrid systems that capture a representation of real-world problems closely.
format Preprint
id arxiv_https___arxiv_org_abs_2604_09578
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Explainable Planning for Hybrid Systems
Sarwar, Mir Md Sajid
Artificial Intelligence
I.2; F.0
The recent advancement in artificial intelligence (AI) technologies facilitates a paradigm shift toward automation. Autonomous systems are fully or partially replacing manually crafted ones. At the core of these systems is automated planning. With the advent of powerful planners, automated planning is now applied to many complex and safety-critical domains, including smart energy grids, self-driving cars, warehouse automation, urban and air traffic control, search and rescue operations, surveillance, robotics, and healthcare. There is a growing need to generate explanations of AI-based systems, which is one of the major challenges the planning community faces today. The thesis presents a comprehensive study on explainable artificial intelligence planning (XAIP) for hybrid systems that capture a representation of real-world problems closely.
title Explainable Planning for Hybrid Systems
topic Artificial Intelligence
I.2; F.0
url https://arxiv.org/abs/2604.09578