Omar Shehab scite author profile

Omar Shehab

3Publications

91Citation Statements Received

84Citation Statements Given

How they've been cited

109

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Affiliations

IBM Research - Thomas J. Watson Research Center, University of Maryland, Baltimore County, Southern States University

Publications

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Experimental quantum annealing: case study involving the graph isomorphism problem

Zick

Shehab

French

2015

Sci Rep

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Quantum annealing is a proposed combinatorial optimization technique meant to exploit quantum mechanical effects such as tunneling and entanglement. Real-world quantum annealing-based solvers require a combination of annealing and classical pre- and post-processing; at this early stage, little is known about how to partition and optimize the processing. This article presents an experimental case study of quantum annealing and some of the factors involved in real-world solvers, using a 504-qubit D-Wave Two machine and the graph isomorphism problem. To illustrate the role of classical pre-processing, a compact Hamiltonian is presented that enables a reduced Ising model for each problem instance. On random N-vertex graphs, the median number of variables is reduced from N2 to fewer than N log2 N and solvable graph sizes increase from N = 5 to N = 13. Additionally, error correction via classical post-processing majority voting is evaluated. While the solution times are not competitive with classical approaches to graph isomorphism, the enhanced solver ultimately classified correctly every problem that was mapped to the processor and demonstrated clear advantages over the baseline approach. The results shed some light on the nature of real-world quantum annealing and the associated hybrid classical-quantum solvers.

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The Lomonaco–kauffman Conjecture

Kuriya

Shehab

2014

J. Knot Theory Ramifications

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Toward convergence of effective-field-theory simulations on digital quantum computers

et al. 2019

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We report results for simulating an effective field theory to compute the binding energy of the deuteron nucleus using a hybrid algorithm on a trapped-ion quantum computer. Two increasingly complex unitary coupled-cluster ansaetze have been used to compute the binding energy to within a few percent for successively more complex Hamiltonians. By increasing the complexity of the Hamiltonian, allowing more terms in the effective field theory expansion and calculating their expectation values, we present a benchmark for quantum computers based on their ability to scalably calculate the effective field theory with increasing accuracy. Our result of E4 = −2.220 ± 0.179MeV may be compared with the exact Deuteron ground-state energy −2.224MeV. We also demonstrate an error mitigation technique using Richardson extrapolation on ion traps for the first time. The error mitigation circuit represents a record for deepest quantum circuit on a trapped-ion quantum computer.

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Omar Shehab

Experimental quantum annealing: case study involving the graph isomorphism problem

The Lomonaco–kauffman Conjecture

Toward convergence of effective-field-theory simulations on digital quantum computers

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