P?=NP as minimization of degree 4 polynomial, integration or Grassmann number problem, and new graph isomorphism problem approaches

Abstract

While the P vs NP problem is mainly approached form the point of view of discrete mathematics, this paper proposes reformulations into the field of abstract algebra, geometry, fourier analysis and of continuous global optimization - which advanced tools might bring new perspectives and approaches for this question. The first one is equivalence of satisfaction of 3-SAT problem with the question of reaching zero of a nonnegative degree 4 multivariate polynomial (sum of squares), what could be tested from the perspective of algebra by using discriminant. It could be also approached as a continuous global optimization problem inside [0,1]n, for example in physical realizations like adiabatic quantum computers. However, the number of local minima usually grows exponentially. Reducing to degree 2 polynomial plus constraints of being in \0,1\n, we get geometric formulations as the question if plane or sphere intersects with \0,1\n. There will be also presented some non-standard perspectives for the Subset-Sum, like through convergence of a series, or zeroing of ∫02π Πi ( ki) d fourier-type integral for some natural ki. The last discussed approach is using anti-commuting Grassmann numbers θi, making (A · diag(θi))n nonzero only if A has a Hamilton cycle. Hence, the P assumption implies exponential growth of matrix representation of Grassmann numbers. There will be also discussed a looking promising algebraic/geometric approach to the graph isomorphism problem -- tested to successfully distinguish strongly regular graphs with up to 29 vertices.