Years and Authors of Summarized Original Work
1998; Brassard, Høyer, Tapp
Problem Definition
A function F is said to be r-to-one if every element in its image has exactly r distinct preimages.
- Input ::
-
an r-to-one function F.
- Output ::
-
x1 and x2 such that F(x1) = F(x2).
Key Results
The algorithm presented here finds collisions in arbitrary r-to-one functions F after only \(O(\root{3}\of{\mbox{ $N/r$}}\,)\) expected evaluations of F. The algorithm uses the function as a black box, that is, the only thing the algorithm requires is the capacity to evaluate the function. Again assuming the function is given by a black box, the algorithm is optimal [1], and it is more efficient than the best possible classical algorithm which has query complexity \(\varOmega (\sqrt{N/r})\). The result is stated precisely in the following theorem and corollary.
Theorem 1
Given an r-to-one function F:X→Y with r ≥ 2 and an integer 1 ≤ k ≤ N = |X|, algorithmCollision(F,k) returns a collision after an expected...
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Aaronson S, Shi Y (2004) Quantum lower bounds for the collision and the element distinctness problems. J ACM (JACM) 51(4):595–605
Brassard G, Høyer P, Tapp A (1998) Quantum algorithm for the collision problem. In: 3rd Latin American theoretical informatics symposium (LATIN’98). LNCS, vol 1380. Springer, Berlin, pp 163–169
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Brassard, G., Høyer, P., Tapp, A. (2016). Quantum Algorithm for the Collision Problem. In: Kao, MY. (eds) Encyclopedia of Algorithms. Springer, New York, NY. https://doi.org/10.1007/978-1-4939-2864-4_304
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