Title :
Computational Complexity of Quantum Satisfiability
Author :
Herrmann, Christian ; Ziegler, Martin
Author_Institution :
Math. Dept., Tech. Univ. of Darmstadt, Darmstadt, Germany
Abstract :
Quantum logic generalizes, and in dimension one coincides with, Boolean propositional logic. We introduce the weak and strong satisfiability problem for quantum logic formulas, and show both NP-complete in dimension two as well. For higher-dimensional spaces Rd and Cd with d≥3 fixed, on the other hand, we show the problem to be complete for the nondeterministic Blum-Shub-Smale model of real computation. This provides a unified view on both Turing and real BSS complexity theory, and adds (a perhaps more natural and combinatorially flavoured) one to the still sparse list of NPR-complete problems, mostly pertaining to real algebraic geometry. Our proofs rely on (a careful examination of) works by John von Neumannas well as contributions by Hagge et. al (2005,2007,2009). We finally investigate the problem over Indefinite finite dimensions and relate it to NON-commutative semi algebraic geometry.
Keywords :
Boolean algebra; Turing machines; computability; computational complexity; geometry; quantum computing; Boolean prepositional logic; NP-complete problem; Turing theory; algebraic geometry; computational complexity; noncommutative semialgebraic geometry; nondeterministic Blum-Shub-Smale model; quantum logic; quantum satisfiability; real BSS complexity theory; Complexity theory; Computational modeling; Hilbert space; Polynomials; Quantum computing; Quantum mechanics; Turing machines;
Conference_Titel :
Logic in Computer Science (LICS), 2011 26th Annual IEEE Symposium on
Conference_Location :
Toronto, ON
Print_ISBN :
978-1-4577-0451-2
Electronic_ISBN :
1043-6871
DOI :
10.1109/LICS.2011.8
