English

Non-Boolean Quantum Amplitude Amplification and Quantum Mean Estimation

Quantum Physics 2021-02-10 v1

Abstract

This paper generalizes the quantum amplitude amplification and amplitude estimation algorithms to work with non-boolean oracles. The action of a non-boolean oracle UφU_\varphi on an eigenstate x|x\rangle is to apply a state-dependent phase-shift φ(x)\varphi(x). Unlike boolean oracles, the eigenvalues exp(iφ(x))\exp(i\varphi(x)) of a non-boolean oracle are not restricted to be ±1\pm 1. Two new oracular algorithms based on such non-boolean oracles are introduced. The first is the non-boolean amplitude amplification algorithm, which preferentially amplifies the amplitudes of the eigenstates based on the value of φ(x)\varphi(x). Starting from a given initial superposition state ψ0|\psi_0\rangle, the basis states with lower values of cos(φ)\cos(\varphi) are amplified at the expense of the basis states with higher values of cos(φ)\cos(\varphi). The second algorithm is the quantum mean estimation algorithm, which uses quantum phase estimation to estimate the expectation ψ0Uφψ0\langle\psi_0|U_\varphi|\psi_0\rangle, i.e., the expected value of exp(iφ(x))\exp(i\varphi(x)) for a random xx sampled by making a measurement on ψ0|\psi_0\rangle. It is shown that the quantum mean estimation algorithm offers a quadratic speedup over the corresponding classical algorithm. Both algorithms are demonstrated using simulations for a toy example. Potential applications of the algorithms are briefly discussed.

Keywords

Cite

@article{arxiv.2102.04975,
  title  = {Non-Boolean Quantum Amplitude Amplification and Quantum Mean Estimation},
  author = {Prasanth Shyamsundar},
  journal= {arXiv preprint arXiv:2102.04975},
  year   = {2021}
}

Comments

36 pages, 16 figures

R2 v1 2026-06-23T22:59:24.554Z