English

Advice Coins for Classical and Quantum Computation

Quantum Physics 2011-01-28 v1 Computational Complexity

Abstract

We study the power of classical and quantum algorithms equipped with nonuniform advice, in the form of a coin whose bias encodes useful information. This question takes on particular importance in the quantum case, due to a surprising result that we prove: a quantum finite automaton with just two states can be sensitive to arbitrarily small changes in a coin's bias. This contrasts with classical probabilistic finite automata, whose sensitivity to changes in a coin's bias is bounded by a classic 1970 result of Hellman and Cover. Despite this finding, we are able to bound the power of advice coins for space-bounded classical and quantum computation. We define the classes BPPSPACE/coin and BQPSPACE/coin, of languages decidable by classical and quantum polynomial-space machines with advice coins. Our main theorem is that both classes coincide with PSPACE/poly. Proving this result turns out to require substantial machinery. We use an algorithm due to Neff for finding roots of polynomials in NC; a result from algebraic geometry that lower-bounds the separation of a polynomial's roots; and a result on fixed-points of superoperators due to Aaronson and Watrous, originally proved in the context of quantum computing with closed timelike curves.

Keywords

Cite

@article{arxiv.1101.5355,
  title  = {Advice Coins for Classical and Quantum Computation},
  author = {Scott Aaronson and Andrew Drucker},
  journal= {arXiv preprint arXiv:1101.5355},
  year   = {2011}
}

Comments

23 pages, 2 figures

R2 v1 2026-06-21T17:17:58.916Z