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Main Authors: Pal, Koyena, Kadioglu, Serdar
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.15448
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author Pal, Koyena
Kadioglu, Serdar
author_facet Pal, Koyena
Kadioglu, Serdar
contents Foundational optimization embeddings have recently emerged as powerful pre-trained representations for mixed-integer programming (MIP) problems. These embeddings were shown to enable cross-domain transfer and reduce reliance on solver-generated labels. In this work, we investigate whether such representations generalize beyond optimization to decision problems, focusing on Boolean satisfiability (SAT). We adapt the foundational optimization architecture to SAT by mapping CNF formulas into the same bipartite constraint-variable graph representation used for MIPs. This allows direct reuse of the pre-trained embedding model without architectural changes or supervised fine-tuning. Our results show that these embeddings capture structural regularities in SAT instances and support unsupervised tasks such as instance clustering and distribution identification. We demonstrate, for the first time, that foundational optimization embeddings can transfer to constraint satisfaction domains. Our findings is a step toward a unified representational framework for both optimization and decision problems.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15448
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Transfer Learning from Foundational Optimization Embeddings to Unsupervised SAT Representations
Pal, Koyena
Kadioglu, Serdar
Machine Learning
Artificial Intelligence
Logic in Computer Science
Foundational optimization embeddings have recently emerged as powerful pre-trained representations for mixed-integer programming (MIP) problems. These embeddings were shown to enable cross-domain transfer and reduce reliance on solver-generated labels. In this work, we investigate whether such representations generalize beyond optimization to decision problems, focusing on Boolean satisfiability (SAT). We adapt the foundational optimization architecture to SAT by mapping CNF formulas into the same bipartite constraint-variable graph representation used for MIPs. This allows direct reuse of the pre-trained embedding model without architectural changes or supervised fine-tuning. Our results show that these embeddings capture structural regularities in SAT instances and support unsupervised tasks such as instance clustering and distribution identification. We demonstrate, for the first time, that foundational optimization embeddings can transfer to constraint satisfaction domains. Our findings is a step toward a unified representational framework for both optimization and decision problems.
title Transfer Learning from Foundational Optimization Embeddings to Unsupervised SAT Representations
topic Machine Learning
Artificial Intelligence
Logic in Computer Science
url https://arxiv.org/abs/2604.15448