Add to ORKG14 pagesWe extend the transfer theorem of [KP2007] to the complex field. That is, we investigate the links between the class VPSPACE of families of polynomials and the Blum-Shub-Smale model of computation over C. Roughly speaking, a family of polynomials is in VPSPACE if its coefficients can be computed in polynomial space. Our main result is that if (uniform, constant-free) VPSPACE families can be evaluated efficiently then the class PAR of decision problems that can be solved in parallel polynomial time over the complex field collapses to P. As a result, one must first be able to show that there are VPSPACE families which are hard to evaluate in order to separate P from NP over C, or even from PAR
In 1979, Valiant showed that the complexity class VPe of families with polynomially bounded formula ...
AbstractA P system is a natural computing model inspired by information processing in cells and cell...
5noThe decision problems solved in polynomial time by P systems with elementary active membranes are...
14 pagesWe extend the transfer theorem of [KP2007] to the complex field. That is, we investigate the...
AbstractWe extend the transfer theorem of [14] to the complex field. That is, we investigate the lin...
Abstract. We introduce a new class VPSPACE of families of polyno-mials. Roughly speaking, a family o...
Full version of the paper (appendices of the first version are now included in the text).We introduc...
In Valiant developed an algebraic analogue of the theory of NP-completeness for computations of po...
AbstractLet K be an algebraically closed field of characteristic 0. We show that constants can be re...
AbstractBlum et al. (1989) showed the existence of a NP-complete problem over the real closed fields...
In 1979 Valiant showed that the complexity class VPe of families with polynomially bounded formula s...
We show that P = PSPACE implies the collapse of the boolean polynomial hierarchy over any structure ...
We show that P = PSPACE implies the collapse of the boolean polynomial hierarchy over any structure ...
(eng) We show that P = PSPACE implies the collapse of the boolean polynomial hierarchy over any stru...
In 1979 Valiant showed that the complexity class VP_e of families with polynomially bounded formula ...
In 1979, Valiant showed that the complexity class VPe of families with polynomially bounded formula ...
AbstractA P system is a natural computing model inspired by information processing in cells and cell...
5noThe decision problems solved in polynomial time by P systems with elementary active membranes are...
14 pagesWe extend the transfer theorem of [KP2007] to the complex field. That is, we investigate the...
AbstractWe extend the transfer theorem of [14] to the complex field. That is, we investigate the lin...
Abstract. We introduce a new class VPSPACE of families of polyno-mials. Roughly speaking, a family o...
Full version of the paper (appendices of the first version are now included in the text).We introduc...
In Valiant developed an algebraic analogue of the theory of NP-completeness for computations of po...
AbstractLet K be an algebraically closed field of characteristic 0. We show that constants can be re...
AbstractBlum et al. (1989) showed the existence of a NP-complete problem over the real closed fields...
In 1979 Valiant showed that the complexity class VPe of families with polynomially bounded formula s...
We show that P = PSPACE implies the collapse of the boolean polynomial hierarchy over any structure ...
We show that P = PSPACE implies the collapse of the boolean polynomial hierarchy over any structure ...
(eng) We show that P = PSPACE implies the collapse of the boolean polynomial hierarchy over any stru...
In 1979 Valiant showed that the complexity class VP_e of families with polynomially bounded formula ...
In 1979, Valiant showed that the complexity class VPe of families with polynomially bounded formula ...
AbstractA P system is a natural computing model inspired by information processing in cells and cell...
5noThe decision problems solved in polynomial time by P systems with elementary active membranes are...