6533b82afe1ef96bd128b99a

RESEARCH PRODUCT

Quantum search of spatial regions

Andris AmbainisScott Aaronson

subject

Holographic principleDiscrete mathematicsQuantum PhysicsComputational complexity theoryFOS: Physical sciencesComputer Science::Software EngineeringGraph theoryGeneral Relativity and Quantum Cosmology (gr-qc)Unitary matrixUpper and lower boundsGeneral Relativity and Quantum CosmologyCombinatoricsHypercubeQuantum Physics (quant-ph)Black hole thermodynamicsQuantum computerMathematics

description

Can Grover's algorithm speed up search of a physical region - for example a 2-D grid of size sqrt(n) by sqrt(n)? The problem is that sqrt(n) time seems to be needed for each query, just to move amplitude across the grid. Here we show that this problem can be surmounted, refuting a claim to the contrary by Benioff. In particular, we show how to search a d-dimensional hypercube in time O(sqrt n) for d at least 3, or O((sqrt n)(log n)^(3/2)) for d=2. More generally, we introduce a model of quantum query complexity on graphs, motivated by fundamental physical limits on information storage, particularly the holographic principle from black hole thermodynamics. Our results in this model include almost-tight upper and lower bounds for many search tasks; a generalized algorithm that works for any graph with good expansion properties, not just hypercubes; and relationships among several notions of `locality' for unitary matrices acting on graphs. As an application of our results, we give an O(sqrt(n))-qubit communication protocol for the disjointness problem, which improves an upper bound of Hoyer and de Wolf and matches a lower bound of Razborov.

yearjournalcountryeditionlanguage
2003-03-0944th Annual IEEE Symposium on Foundations of Computer Science, 2003. Proceedings.
https://doi.org/10.1109/sfcs.2003.1238194