Improved Inapproximability of VC Dimension and Littlestone’s Dimension via (Unbalanced) Biclique

Pasin Manurangsi

ITCS 2023 (to appear)

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Abstract

We study the complexity of computing (and approximating) VC Dimension and Littlestone's Dimension when we are given the concept class explicitly. We give a simple reduction from Maximum (Unbalanced) Biclique problem to approximating VC Dimension and Littlestone's Dimension. With this connection, we derive a range of hardness of approximation results and running time lower bounds. For example, under the (randomized) Gap-Exponential Time Hypothesis or the Strongish Planted Clique Hypothesis, we show a tight inapproximability result: both dimensions are hard to approximate to within a factor of o(log n) in polynomial-time. These improve upon constant-factor inapproximability results from [Manurangsi and Rubinstein, COLT 2017].

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Improved Inapproximability of VC Dimension and Littlestone’s Dimension via (Unbalanced) Biclique

Abstract

Research Areas

Meet the teams driving innovation

Defining the technology of today and tomorrow.

Philosophy

People

Teams

AI/ML Foundations & Capabilities

Algorithms & Optimization

Computing Paradigms

Responsible Human-Centric Technology

Science & Societal Impact

Projects

Publications

Resources

Shaping the future, together.

Student programs

Faculty programs

Conferences & events

Improved Inapproximability of VC Dimension and Littlestone’s Dimension via (Unbalanced) Biclique

Abstract

Research Areas

Meet the teams driving innovation

AI/ML Foundations  & Capabilities