AbstractWe prove that some central problems in computational linear algebra are in the complexity class RNC1 that is solvable by uniform families of probabilistic boolean circuits of logarithmic depth and polynomial size. In particular, we first show that computing the solution of n × n linear systems in the form x = Bx + c, with |B|∞ ≤ 1 − n−k, k = O(1), in the fixed precision model (i.e., computing d = O(1) digits of the result) is in RNC1 ; then we prove that the case of general n × n linear systems Ax = b, with both |A|∞ and |b|∞ bounded by polynomials in n, can be reduced to the special case mentioned before
The following problems related to linear systems are studied: finding a diophantine solution; findin...
We characterize the complexity of some natural and important problems in linear algebra. In particul...
© Richard Ryan Williams; licensed under Creative Commons License CC-BY 33rd Computational Complexity...
We prove that some central problems in computational linear algebra are in the complexity class RNC1...
AbstractWe prove that some central problems in computational linear algebra are in the complexity cl...
International audienceWe present an interactive probabilistic proof protocol that certifies in (log ...
In this thesis, we study small, yet important, circuit complexity classes within NC1, such as ACC0 a...
In this thesis, we study small, yet important, circuit complexity classes within NC^1, such as ACC^0...
At its core, much of Computational Complexity is concerned with combinatorial objects and structures...
At its core, much of Computational Complexity is concerned with combinatorial objects and structures...
Analysis of condition number for random matrices originated in the works of von Neumann and Turing o...
Algebraic natural proofs were recently introduced by Forbes, Shpilka and Volk (Proc. of the 49th Ann...
In their paper on the ''chasm at depth four'', Agrawal and Vinay have shown that polynomials in m va...
A simple randomized algorithm is given for finding an integer solution to a system of linear Diophan...
A fundamental problem in computer science is to find all the common zeroes of m quadratic poly-nomia...
The following problems related to linear systems are studied: finding a diophantine solution; findin...
We characterize the complexity of some natural and important problems in linear algebra. In particul...
© Richard Ryan Williams; licensed under Creative Commons License CC-BY 33rd Computational Complexity...
We prove that some central problems in computational linear algebra are in the complexity class RNC1...
AbstractWe prove that some central problems in computational linear algebra are in the complexity cl...
International audienceWe present an interactive probabilistic proof protocol that certifies in (log ...
In this thesis, we study small, yet important, circuit complexity classes within NC1, such as ACC0 a...
In this thesis, we study small, yet important, circuit complexity classes within NC^1, such as ACC^0...
At its core, much of Computational Complexity is concerned with combinatorial objects and structures...
At its core, much of Computational Complexity is concerned with combinatorial objects and structures...
Analysis of condition number for random matrices originated in the works of von Neumann and Turing o...
Algebraic natural proofs were recently introduced by Forbes, Shpilka and Volk (Proc. of the 49th Ann...
In their paper on the ''chasm at depth four'', Agrawal and Vinay have shown that polynomials in m va...
A simple randomized algorithm is given for finding an integer solution to a system of linear Diophan...
A fundamental problem in computer science is to find all the common zeroes of m quadratic poly-nomia...
The following problems related to linear systems are studied: finding a diophantine solution; findin...
We characterize the complexity of some natural and important problems in linear algebra. In particul...
© Richard Ryan Williams; licensed under Creative Commons License CC-BY 33rd Computational Complexity...