A Framework for Distributed Quantum Queries in the CONGEST Model
- URL: http://arxiv.org/abs/2202.10969v2
- Date: Fri, 17 Jun 2022 15:36:21 GMT
- Title: A Framework for Distributed Quantum Queries in the CONGEST Model
- Authors: Joran van Apeldoorn, Tijn de Vos
- Abstract summary: We give a general framework for implementing quantum query algorithms in Quantum CONGEST.
We generalize the protocol for the distributed Deutsch-Jozsa problem.
We also give quantum speedups for the problems of cycle detection and computation.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The Quantum CONGEST model is a variant of the CONGEST model, where messages
consist of $O(\log(n))$ qubits. We give a general framework for implementing
quantum query algorithms in Quantum CONGEST, using the concept of
parallel-queries. We apply our framework for distributed quantum queries in two
settings: when data is distributed over the network, and graph theoretical
problems where the network defines the input. The first is slightly unusual in
CONGEST but our results follow almost directly. The second is more traditional
for the CONGEST model but here we require some classical CONGEST steps to get
our results.
In the setting with distributed data, we show how a network can schedule a
meeting in one of $k$ dates using $\tilde{O}(\sqrt{kD}+D)$ rounds, with $D$ the
network diameter. We also give an algorithm for element distinctness: if all
nodes together hold a list of $k$ numbers, they can find a duplicate in $\tilde
O(k^{2/3}D^{1/3}+D)$ rounds. We also generalize the protocol for the
distributed Deutsch-Jozsa problem from the two-party setting considered in
[arXiv:quant-ph/9802040] to general networks, giving a novel separation between
exact classical and exact quantum protocols in CONGEST.
When the input is the network structure itself, we almost directly recover
the $O(\sqrt{nD})$ round diameter computation algorithm of Le Gall and Magniez
[arXiv:1804.02917]. We also compute the radius in the same number of rounds,
and give an $\epsilon$-additive approximation of the average eccentricity in
$\tilde{O}(D+D^{3/2}/\epsilon)$ rounds. Finally, we give quantum speedups for
the problems of cycle detection and girth computation. We detect whether a
graph has a cycle of length at most $k$ in $O(k+(kn)^{1/2-1/\Theta(k)})$
rounds. For girth computation we give an $\tilde{O}(g+(gn)^{1/2-1/\Theta(g)})$
round algorithm for graphs with girth $g$, beating the known classical lower
bound.
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