215 research outputs found
Circuit Lower Bounds, Help Functions, and the Remote Point Problem
We investigate the power of Algebraic Branching Programs (ABPs) augmented
with help polynomials, and constant-depth Boolean circuits augmented with help
functions. We relate the problem of proving explicit lower bounds in both these
models to the Remote Point Problem (introduced by Alon, Panigrahy, and Yekhanin
(RANDOM '09)). More precisely, proving lower bounds for ABPs with help
polynomials is related to the Remote Point Problem w.r.t. the rank metric, and
for constant-depth circuits with help functions it is related to the Remote
Point Problem w.r.t. the Hamming metric. For algebraic branching programs with
help polynomials with some degree restrictions we show exponential size lower
bounds for explicit polynomials
On the relation between the WRT invariant and the Hennings invariant
The purpose of this note is to provide a simple relation between the
Witten-Reshetikhin-Turaev SO(3) invariant and the Hennings invariant of
3-manifolds associated to quantum sl_2.Comment: 14 pages, 1 figur
Arithmetic Circuits and the Hadamard Product of Polynomials
Motivated by the Hadamard product of matrices we define the Hadamard product
of multivariate polynomials and study its arithmetic circuit and branching
program complexity. We also give applications and connections to polynomial
identity testing. Our main results are the following. 1. We show that
noncommutative polynomial identity testing for algebraic branching programs
over rationals is complete for the logspace counting class \ceql, and over
fields of characteristic the problem is in \ModpL/\Poly. 2.We show an
exponential lower bound for expressing the Raz-Yehudayoff polynomial as the
Hadamard product of two monotone multilinear polynomials. In contrast the
Permanent can be expressed as the Hadamard product of two monotone multilinear
formulas of quadratic size.Comment: 20 page
A Near-Optimal Depth-Hierarchy Theorem for Small-Depth Multilinear Circuits
We study the size blow-up that is necessary to convert an algebraic circuit
of product-depth to one of product-depth in the multilinear
setting.
We show that for every positive
there is an explicit multilinear polynomial on variables
that can be computed by a multilinear formula of product-depth and
size , but not by any multilinear circuit of product-depth and
size less than . This result is tight up to the
constant implicit in the double exponent for all
This strengthens a result of Raz and Yehudayoff (Computational Complexity
2009) who prove a quasipolynomial separation for constant-depth multilinear
circuits, and a result of Kayal, Nair and Saha (STACS 2016) who give an
exponential separation in the case
Our separating examples may be viewed as algebraic analogues of variants of
the Graph Reachability problem studied by Chen, Oliveira, Servedio and Tan
(STOC 2016), who used them to prove lower bounds for constant-depth Boolean
circuits
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