Quantum Amplitude Amplification and Estimation

Abstract

Consider a Boolean function : X \0,1\ that partitions set X between its good and bad elements, where x is good if (x)=1 and bad otherwise. Consider also a quantum algorithm A such that A |0= Σx∈ X αx |x is a quantum superposition of the elements of X, and let a denote the probability that a good element is produced if A |0 is measured. If we repeat the process of running A, measuring the output, and using to check the validity of the result, we shall expect to repeat 1/a times on the average before a solution is found. *Amplitude amplification* is a process that allows to find a good x after an expected number of applications of A and its inverse which is proportional to 1/a, assuming algorithm A makes no measurements. This is a generalization of Grover's searching algorithm in which A was restricted to producing an equal superposition of all members of X and we had a promise that a single x existed such that (x)=1. Our algorithm works whether or not the value of a is known ahead of time. In case the value of a is known, we can find a good x after a number of applications of A and its inverse which is proportional to 1/a even in the worst case. We show that this quadratic speedup can also be obtained for a large family of search problems for which good classical heuristics exist. Finally, as our main result, we combine ideas from Grover's and Shor's quantum algorithms to perform amplitude estimation, a process that allows to estimate the value of a. We apply amplitude estimation to the problem of *approximate counting*, in which we wish to estimate the number of x∈ X such that (x)=1. We obtain optimal quantum algorithms in a variety of settings.

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