A UCB-based Tree Search Approach to Joint Verification-Correction Strategy for Large Scale Systems
April 02, 2022 Β· Declared Dead Β· π IEEE Transactions on Systems, Man, and Cybernetics: Systems
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Authors
Peng Xu, Xinwei Deng, Alejandro Salado
arXiv ID
2204.00925
Category
cs.SE: Software Engineering
Cross-listed
eess.SY
Citations
6
Venue
IEEE Transactions on Systems, Man, and Cybernetics: Systems
Last Checked
4 months ago
Abstract
Verification planning is a sequential decision-making problem that specifies a set of verification activities (VA) and correction activities (CA) at different phases of system development. While VAs are used to identify errors and defects, CAs also play important roles in system verification as they correct the identified errors and defects. However, current planning methods only consider VAs as decision choices. Because VAs and CAs have different activity spaces, planning a joint verification-correction strategy (JVCS) is still challenging, especially for large-size systems. Here we introduce a UCB-based tree search approach to search for near-optimal JVCSs. First, verification planning is simplified as repeatable bandit problems and an upper confidence bound rule for repeatable bandits (UCBRB) is presented with the optimal regret bound. Next, a tree search algorithm is proposed to search for feasible JVCSs. A tree-based ensemble learning model is also used to extend the tree search algorithm to handle local optimality issues. The proposed approach is evaluated on the notional case of a communication system.
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