Publication: Quantum Versus Classical Learnability
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Date
2001
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Institute of Electrical and Electronics Engineers (IEEE)
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Servedio, Rocco A. and Steven J. Gortler. 2001. Quantum versus classical learnability. In Computational complexity: Proceedings of the 16th IEEE conference on computational complexity, June 18-21, 2001, Chicago, Illinois, ed. IEEE Conference on Computational Complexity, 138-148. Also published as Equivalences and separations between quantum and classical learnability. 2004. SIAM Journal on Computing 33(5): 1067-1092.
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Abstract
Motivated by work on quantum black-box query complexity, we consider quantum versions of two well-studied models of learning Boolean functions: Angluin's (1988) model of exact learning from membership queries and Valiant's (1984) Probably Approximately Correct (PAC) model of learning from random examples. For each of these two learning models we establish a polynomial relationship between the number of quantum versus classical queries required for learning. Our results provide an interesting contrast to known results which show that testing black-box functions for various properties can require exponentially more classical queries than quantum queries. We also show that under a widely held computational hardness assumption there is a class of Boolean functions which is polynomial-time learnable in the quantum version but not the classical version of each learning model; thus while quantum and classical learning are equally powerful from an information theory perspective, they are different when viewed from a computational complexity perspective.
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