On the Approximability of Parameterized Minimum Monotone Satisfying Assignment
Abstract
The parameterized Minimum Monotone Satisfying Assignment (k-MMSA) problem asks whether a monotone Boolean circuit admits a satisfying assignment of Hamming weight at most k. The MMSA hierarchy is defined by allowing a bounded number of alternations between AND and OR gates in the circuit. While the polynomial-time approximability of the MMSA hierarchy has been studied extensively, much less is known in the parameterized setting. In particular, k-MMSA2 is the well-known k-SetCover problem, whose parameterized inapproximability lies in the polylog(n) regime. In contrast, k-MMSA4 captures k-MinLabel, for which known lower bounds give poly(n) inapproximability. Sandwiched by k-MMSA2 and k-MMSA4, the inapproximability of k-MMSA3 remained comparatively unexplored. In this paper, we give an FPT-time O(2k n)-approximation algorithm for k-MMSA3, suggesting that in the fixed-parameter regime, the third level of MMSA remains surprisingly close to the second level. Complementing this algorithm, we also give an FPT-time gap-preserving reduction from k-MMSA3 to k-MMSA2. Thus, stronger inapproximability for k-MMSA3 would imply new hardness for k-MMSA2, potentially offering a route around the current barriers for the latter problem. Revisiting Marx's reduction from k-MMSAt to gap k-MMSAt+2, we also show that k-MMSA4 admits no no(1)-factor FPT approximation unless W[2]=FPT, and no nO(1/k)-factor approximation running in no(k) time under ETH. These results separate the parameterized approximability behavior of the third and fourth levels and clarify where stronger inapproximability enters the k-MMSA hierarchy.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.