We present proof labeling schemes for graphs with bounded pathwidth that can decide any graph property expressible in monadic second-order (MSO) logic using O(logn)-bit vertex labels. Examples of such properties include planarity, Hamiltonicity, k-colorability, H-minor-freeness, admitting a perfect matching, and having a vertex cover of a given size. Our proof labeling schemes improve upon a recent result by Fraigniaud, Montealegre, Rapaport, and Todinca (Algorithmica 2024), which achieved the same result for graphs of bounded treewidth but required O(log2n)-bit labels. Our improved label size O(logn) is optimal, as it is well-known that any proof labeling scheme that accepts paths and rejects cycles requires labels of size Ω(logn). Our result implies that graphs with pathwidth at most k can be certified using O(logn)-bit labels for any fixed constant k. Applying the Excluding Forest Theorem of Robertson and Seymour, we deduce that the class of F-minor-free graphs can be certified with O(logn)-bit labels for any fixed forest F, thereby providing an affirmative answer to an open question posed by Bousquet, Feuilloley, and Pierron (Journal of Parallel and Distributed Computing 2024).
@article{arxiv.2502.00676,
title = {Optimal local certification on graphs of bounded pathwidth},
author = {Dan Alden Baterisna and Yi-Jun Chang},
journal= {arXiv preprint arXiv:2502.00676},
year = {2025}
}