2 code implementations • 8 Dec 2022 • Nils Quetschlich, Lukas Burgholzer, Robert Wille
Any quantum computing application, once encoded as a quantum circuit, must be compiled before being executable on a quantum computer.
no code implementations • 3 Dec 2020 • Lukas Burgholzer, Robert Wille, Richard Kueng
In this work, we consider error detection via simulation for reversible circuit architectures.
Hardware Architecture Emerging Technologies
1 code implementation • 14 Nov 2020 • Lukas Burgholzer, Richard Kueng, Robert Wille
Verification of quantum circuits is essential for guaranteeing correctness of quantum algorithms and/or quantum descriptions across various levels of abstraction.
Quantum Physics Emerging Technologies
2 code implementations • 4 Sep 2020 • Lukas Burgholzer, Rudy Raymond, Robert Wille
In this paper, we propose an efficient scheme for quantum circuit equivalence checking---specialized for verifying results of the IBM Qiskit quantum circuit compilation flow.
Quantum Circuit Equivalence Checking Quantum Physics
1 code implementation • 17 Apr 2020 • Lukas Burgholzer, Robert Wille
Experimental evaluations confirm that the resulting methodology allows one to conduct equivalence checking dramatically faster than ever before--in many cases just a single simulation run is sufficient.
Quantum Circuit Equivalence Checking Quantum Physics Emerging Technologies
1 code implementation • 3 Jul 2019 • Robert Wille, Lukas Burgholzer, Alwin Zulehner
By this, we do not only provide a method that maps quantum circuits to IBM's QX architectures with a minimal number of SWAP and H operations, but also show by experimental evaluation that the number of operations added by IBM's heuristic solution exceeds the lower bound by more than 100% on average.
Quantum Circuit Mapping Quantum Physics