We study the classical problem of approximating a non-decreasing function $f: \mathcal{X} \to \mathcal{Y}$ in $L^p(\mu)$ norm by sequentially querying its values, for known compact real intervals $\mathcal{X}$, $\mathcal{Y}$ and a known probability measure $\mu$ on $\mathcal{X}$. For any function~$f$ we characterize the minimum number of evaluations of $f$ that algorithms need to guarantee an approximation $\hat{f}$ with an $L^p(\mu)$ error below $\epsilon$ after stopping. Unlike worst-case results that hold uniformly over all $f$, our complexity measure is dependent on each specific function $f$. To address this problem, we introduce GreedyBox, a generalization of an algorithm originally proposed by Novak (1992) for numerical integration. ...
We consider the problem of learning monotone Boolean functions over under the uniform distributi...
. When we approximate a continuous nondecreasing function f in [\Gamma1; 1], we wish sometimes that...
A function f is d-resilient if all its Fourier coefficients of degree at most d are zero, i.e. f is ...
We study the classical problem of approximating a non-decreasing function $f: \mathcal{X} \to \mathc...
AbstractThis paper investigates the relationship between approximation error and complexity. A varie...
This paper investigates the relationship between approximation error and complexity. A variety of co...
AbstractIn contrast to linear schemes, nonlinear approximation techniques allow for dimension indepe...
Much work has been done on learning various classes of “simple ” monotone functions under the unifor...
textabstractWe show that every algorithm for testing n-variate Boolean functions for monotonicity ha...
This thesis studies computational complexity in concrete models of computation. We draw on a range o...
AbstractThe approximation of integrals of monotone functions of d variables is studied. Algorithms u...
We give an algorithm that learns any monotone Boolean function f: f1; 1gn! f1; 1g to any constant ac...
We give a poly(log(n),1/epsilon)-query adaptive algorithm for testing whether an unknown Boolean fun...
© Ronitt Rubinfeld and Arsen Vasilyan. The noise sensitivity of a Boolean function f : {0, 1}n → {0,...
We give an algorithm that learns any monotone Boolean function f: {−1, 1}n → {−1, 1} to any constant...
We consider the problem of learning monotone Boolean functions over under the uniform distributi...
. When we approximate a continuous nondecreasing function f in [\Gamma1; 1], we wish sometimes that...
A function f is d-resilient if all its Fourier coefficients of degree at most d are zero, i.e. f is ...
We study the classical problem of approximating a non-decreasing function $f: \mathcal{X} \to \mathc...
AbstractThis paper investigates the relationship between approximation error and complexity. A varie...
This paper investigates the relationship between approximation error and complexity. A variety of co...
AbstractIn contrast to linear schemes, nonlinear approximation techniques allow for dimension indepe...
Much work has been done on learning various classes of “simple ” monotone functions under the unifor...
textabstractWe show that every algorithm for testing n-variate Boolean functions for monotonicity ha...
This thesis studies computational complexity in concrete models of computation. We draw on a range o...
AbstractThe approximation of integrals of monotone functions of d variables is studied. Algorithms u...
We give an algorithm that learns any monotone Boolean function f: f1; 1gn! f1; 1g to any constant ac...
We give a poly(log(n),1/epsilon)-query adaptive algorithm for testing whether an unknown Boolean fun...
© Ronitt Rubinfeld and Arsen Vasilyan. The noise sensitivity of a Boolean function f : {0, 1}n → {0,...
We give an algorithm that learns any monotone Boolean function f: {−1, 1}n → {−1, 1} to any constant...
We consider the problem of learning monotone Boolean functions over under the uniform distributi...
. When we approximate a continuous nondecreasing function f in [\Gamma1; 1], we wish sometimes that...
A function f is d-resilient if all its Fourier coefficients of degree at most d are zero, i.e. f is ...