The study of self-testing and self-correcting programs leads to the search for robust characterizations of functions. Here we make this notion precise and show such a characterization for polynomials. From this characterization, we get the following three applications: First, we can construct simple and efficient self-testers for polynomial functions. Secondly, it provides results in the area of coding theory, by giving extremely fast and efficient error-detecting schemes for some well known codes. Thirdly, this error-detection scheme plays a crucial role in recent results on hardness of approximating some NP-optimization problems
We continue the investigation of locally testable codes, i.e., error-correcting codes for whom membe...
In analogy with the regularity lemma of Szemerédi [Sze75], regularity lemmas for polynomials shown ...
This thesis presents a practical means for determining checking polynomials for the fault tolerant c...
The study of self-testing/correcting programs was introduced in [8] in order to allow one to use pro...
. We investigate self-testing programs with relative error by allowing error terms proportional to ...
Suppose P is a program designed to compute a function f defined on a group G. The task of self-testi...
The idea of self-testing/correcting programs, introduced in [BLR90], is a powerful tool for attacki...
We formalize the notion and initiate the investigation of approximate testing for arbitrary forms of...
Given a function f mapping n-variate inputs from a nite eld F into F, we consider the task of recons...
We present simple, self-contained proofs of correctness for algorithms for linearity testing and pro...
This dissertation is a study of special types of error correcting codes and their applications. It ...
AbstractSuppose someone gives us an extremely fast program P that we can call as a black box to comp...
The definition of the class NP [Coo71, Lev73] highlights the problem of verification of proofs as on...
AbstractIn this paper, robust semi-definite programs are considered with the goal of verifying wheth...
We study locally correctable and locally testable codes in the high rate regime. The tradeoff betwee...
We continue the investigation of locally testable codes, i.e., error-correcting codes for whom membe...
In analogy with the regularity lemma of Szemerédi [Sze75], regularity lemmas for polynomials shown ...
This thesis presents a practical means for determining checking polynomials for the fault tolerant c...
The study of self-testing/correcting programs was introduced in [8] in order to allow one to use pro...
. We investigate self-testing programs with relative error by allowing error terms proportional to ...
Suppose P is a program designed to compute a function f defined on a group G. The task of self-testi...
The idea of self-testing/correcting programs, introduced in [BLR90], is a powerful tool for attacki...
We formalize the notion and initiate the investigation of approximate testing for arbitrary forms of...
Given a function f mapping n-variate inputs from a nite eld F into F, we consider the task of recons...
We present simple, self-contained proofs of correctness for algorithms for linearity testing and pro...
This dissertation is a study of special types of error correcting codes and their applications. It ...
AbstractSuppose someone gives us an extremely fast program P that we can call as a black box to comp...
The definition of the class NP [Coo71, Lev73] highlights the problem of verification of proofs as on...
AbstractIn this paper, robust semi-definite programs are considered with the goal of verifying wheth...
We study locally correctable and locally testable codes in the high rate regime. The tradeoff betwee...
We continue the investigation of locally testable codes, i.e., error-correcting codes for whom membe...
In analogy with the regularity lemma of Szemerédi [Sze75], regularity lemmas for polynomials shown ...
This thesis presents a practical means for determining checking polynomials for the fault tolerant c...