Upper and Lower Bounds for the Linear Ordering Principle
Abstract
Korten and Pitassi (FOCS, 2024) defined a new complexity class L2P as the polynomial-time Turing closure of the Linear Ordering Principle. They put it between MA (Merlin--Arthur protocols) and S2P (the second symmetric level of the polynomial hierarchy). In this paper we sandwich L2P between PprMA and PprSBP. (The oracles here are promise problems, and SBP is the only known class between MA and AM.) The containment in PprSBP is proved via an iterative process that uses a prSBP oracle to estimate the average order rank of a subset and find the minimum of a linear order. Another containment result of this paper is PprO2P ⊂eq O2P (where O2P is the input-oblivious version of S2P). These containment results altogether have several byproducts: We give an affirmative answer to an open question posed by of Chakaravarthy and Roy (Computational Complexity, 2011) whether PprMA ⊂eq S2P, thereby settling the relative standing of the existing (non-oblivious) Karp-Lipton-style collapse results of Chakaravarthy and Roy (2011) and Cai (2007), We give an affirmative answer to an open question of Korten and Pitassi whether a Karp-Lipton-style collapse can be proven for L2P, We show that the Karp-Lipton-style collapse to PprOMA is actually better than both known collapses to PprMA due to Chakaravarthy and Roy (Computational Complexity, 2011) and to O2P also due to Chakaravarthy and Roy (STACS, 2006). Thus we resolve the controversy between previously incomparable Karp-Lipton collapses stemming from these two lines of research.
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.