AbstractWe investigate the phenomenon of depth-reduction in commutative and non-commutative arithmetic circuits. We prove that in the commutative setting, uniform semi-unbounded arithmetic circuits of logarithmic depth are as powerful as uniform arithmetic circuits of polynomial degree (and unrestricted depth); earlier proofs did not work in the uniform setting. This also provides a unified proof of the circuit characterizations of the class LOGCFL and its counting variant #LOGCFL.We show that AC1 has no more power than arithmetic circuits of polynomial size and degree nO(log log n) (improving the trivial bound of nO(log n)). Connections are drawn between TC1 and arithmetic circuits of polynomial size and degree.Then we consider non-commuta...
Classical results of Brent, Kuck and Maruyama (IEEE Trans. Computers 1973) and Brent (JACM 1974) sho...
We say that a circuit C over a field F {functionally} computes a polynomial P in F[x_1, x_2, ..., x_...
. We prove that constant depth circuits of size n log O(1) n over the basis AND, OR, PARITY are ...
AbstractWe investigate the phenomenon of depth-reduction in commutative and non-commutative arithmet...
We investigate the phenomenon of depth-reduction in commutative and non-commutative arithmetic circu...
We investigate the phenomenon of depth-reduction in commutative and non-commutative arithmetic circu...
) Eric Allender Department of Computer Science Princeton University 35 Olden Street Princeton, NJ...
We show that proving mildly super-linear lower bounds on non-commutative arithmetic circuits implies...
In their paper on the ''chasm at depth four'', Agrawal and Vinay have shown that polynomials in m va...
In this paper, we show that there is a family of polynomials P_n, where P_n is a polynomial in n var...
We show an almost cubic lower bound on the size of any depth three arithmetic circuit computing an e...
Shpilka and Wigderson (CCC 99) had posed the problem of proving exponential lower bounds for (nonhom...
Proving lower bounds for arithmetic circuits is a problem of fundamental importance in theoretical c...
We establish new separations between the power of monotone and general (non-monotone) Boolean circui...
AbstractConsider an arithmetic expression of lengthninvolving only the operations {+,×} and non-nega...
Classical results of Brent, Kuck and Maruyama (IEEE Trans. Computers 1973) and Brent (JACM 1974) sho...
We say that a circuit C over a field F {functionally} computes a polynomial P in F[x_1, x_2, ..., x_...
. We prove that constant depth circuits of size n log O(1) n over the basis AND, OR, PARITY are ...
AbstractWe investigate the phenomenon of depth-reduction in commutative and non-commutative arithmet...
We investigate the phenomenon of depth-reduction in commutative and non-commutative arithmetic circu...
We investigate the phenomenon of depth-reduction in commutative and non-commutative arithmetic circu...
) Eric Allender Department of Computer Science Princeton University 35 Olden Street Princeton, NJ...
We show that proving mildly super-linear lower bounds on non-commutative arithmetic circuits implies...
In their paper on the ''chasm at depth four'', Agrawal and Vinay have shown that polynomials in m va...
In this paper, we show that there is a family of polynomials P_n, where P_n is a polynomial in n var...
We show an almost cubic lower bound on the size of any depth three arithmetic circuit computing an e...
Shpilka and Wigderson (CCC 99) had posed the problem of proving exponential lower bounds for (nonhom...
Proving lower bounds for arithmetic circuits is a problem of fundamental importance in theoretical c...
We establish new separations between the power of monotone and general (non-monotone) Boolean circui...
AbstractConsider an arithmetic expression of lengthninvolving only the operations {+,×} and non-nega...
Classical results of Brent, Kuck and Maruyama (IEEE Trans. Computers 1973) and Brent (JACM 1974) sho...
We say that a circuit C over a field F {functionally} computes a polynomial P in F[x_1, x_2, ..., x_...
. We prove that constant depth circuits of size n log O(1) n over the basis AND, OR, PARITY are ...