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Optimized compiler for Distributed Quantum Computing

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arxiv 2112.14139 v1 pith:2JYGOC6B submitted 2021-12-28 quant-ph cs.ET

Optimized compiler for Distributed Quantum Computing

classification quant-ph cs.ET
keywords computingdistributedquantumtimedistributionentanglementformulationgiven
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Practical distributed quantum computing requires the development of efficient compilers, able to make quantum circuits compatible with some given hardware constraints. This problem is known to be tough, even for local computing. Here, we address it on distributed architectures. As generally assumed in this scenario, telegates represent the fundamental remote (inter-processor) operations. Each telegate consists of several tasks: i) entanglement generation and distribution, ii) local operations, and iii) classical communications. Entanglement generations and distribution is an expensive resource, as it is time-consuming and fault-prone. To mitigate its impact, we model an optimization problem that combines running-time minimization with the usage of that resource. Specifically, we provide a parametric ILP formulation, where the parameter denotes a time horizon (or time availability); the objective function count the number of used resources. To minimize the time, a binary search solves the subject ILP by iterating over the parameter. Ultimately, to enhance the solution space, we extend the formulation, by introducing a predicate that manipulates the circuit given in input and parallelizes telegates' tasks.

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