Multi-task Combinatorial Optimization: Adaptive Multi-modality Knowledge Transfer by an Explicit Inter-task Distance (2305.12807v1)

Abstract: Scheduling problems are often tackled independently, and rarely solved by leveraging the commonalities across problems. Lack of awareness of this inter-task similarity could impede the search efficacy. A quantifiable relationship between scheduling problems is to-date rather unclear, how to leverage it in combinatorial optimization remains largely unknown, and its effects on search are also undeterminable. This paper addresses these hard questions by delving into quantifiable useful inter-task relationships and, through leveraging the explicit relationship, presenting a speed-up algorithm. After deriving an analytical inter-task distance metric to quantitatively reveal latent similarity across scheduling problems, an adaptive transfer of multi-modality knowledge is devised to promptly adjust the transfer in forms of explicit and implicit knowledge in response to heterogeneity in the inter-task discrepancy. For faintly related problems with disappearing dependences, a problem transformation function is suggested with a matching-feature-based greedy policy, and the function projects faintly related problems into a latent space where these problems gain similarity in a way that creates search speed-ups. Finally, a multi-task scatter search combinatorial algorithm is formed and a large-scale multi-task benchmark is generated serving the purposes of validation. That the algorithm exhibits dramatic speed-ups of 2~3 orders of magnitude, as compared to direct problem solving in strongly related problems and 3 times faster in weakly related ones, suggests leveraging commonality across problems could be successful.