The Quantum Complexity of Set Membership

Abstract. We study the quantum complexity of the static set membership problem: given a subset S (|S| ≤ n ) of a universe of size m ( >> n ), store it as a table, T: {0,1}r --> {0,1} , of bits so that queries of the form ``Is x in S ?'' can be answered. The goal is to use a small table and yet answer queries using few bit probes. This problem was considered recently by Buhrman et al. [BMRV], who showed lower and upper bounds for this problem in the classical deterministic and randomized models. In this paper we formulate this problem in the ``quantum bit probe model''. We assume that access to the table T is provided by means of a black box (oracle) unitary transform OT that takes the basis state | y,b > to the basis state | y,b\oplusT(y) > . The query algorithm is allowed to apply OT on any superposition of basis states. We show tradeoff results between space (defined as 2r ) and number of probes (oracle calls) in this model. Our results show that the lower bounds shown in [BMRV] for the classical model also hold (with minor differences) in the quantum bit probe model. These bounds almost match the classical upper bounds. Our lower bounds are proved using linear algebraic arguments.

• Publication year

  2000

• Venue

  Proceedings 41st Annual Symposium on Foundations of Computer Science

• Publication date

  2000-07-07

• Fields of study

  Mathematics, Physics, Computer Science

• Identifiers
  DOI 10.1007/s00453-002-0979-0arXiv quant-ph/0007021
• External record

  Open on Semantic Scholar

• Source metadata

  Semantic Scholar

• No claims are published for this paper.

• No concepts are published for this paper.

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