Qiskit: An open-source framework for quantum computing G Aleksandrowicz, T Alexander, P Barkoutsos, L Bello, Y Ben-Haim, ... Accessed on: Mar 16, 61, 2019 | 960* | 2019 |
Qiskit pulse: programming quantum computers through the cloud with pulses T Alexander, N Kanazawa, DJ Egger, L Capelluto, CJ Wood, ... Quantum Science and Technology 5 (4), 044006, 2020 | 172 | 2020 |
Qiskit backend specifications for openqasm and openpulse experiments DC McKay, T Alexander, L Bello, MJ Biercuk, L Bishop, J Chen, JM Chow, ... arXiv preprint arXiv:1809.03452, 2018 | 139 | 2018 |
OpenQASM 3: A broader and deeper quantum assembly language A Cross, A Javadi-Abhari, T Alexander, N De Beaudrap, LS Bishop, ... ACM Transactions on Quantum Computing 3 (3), 1-50, 2022 | 128 | 2022 |
QInfer: Statistical inference software for quantum applications C Granade, C Ferrie, I Hincks, S Casagrande, T Alexander, J Gross, ... Quantum 1, 5, 2017 | 51 | 2017 |
Qiskit: An open-source framework for quantum computing (2021) MDS Anis, H Abraham, RA AduOffei, G Agliardi, M Aharoni, IY Akhalwaya, ... SUPPLEMENTARY INFORMATION I. ALGORITHMS II. A RELAXATION BOUND (| E| 2+ 1 9 …, 2021 | 45 | 2021 |
Encoding a magic state with beyond break-even fidelity RS Gupta, N Sundaresan, T Alexander, CJ Wood, ST Merkel, MB Healy, ... Nature 625 (7994), 259-263, 2024 | 17 | 2024 |
Programming physical quantum systems with pulse-level control KN Smith, GS Ravi, T Alexander, NT Bronn, ARR Carvalho, ... Frontiers in Physics 10, 900099, 2022 | 8 | 2022 |
Hamiltonian learning with online Bayesian experiment design in practice I Hincks, T Alexander, M Kononenko, B Soloway, DG Cory arXiv preprint arXiv:1806.02427, 2018 | 8 | 2018 |
OpenPulse: Software for Experimental Physicists in Quantum Computing L Capelluto, T Alexander Bulletin of the American Physical Society 65, 2020 | 5 | 2020 |
Summary: Chicago Quantum Exchange (CQE) Pulse-level Quantum Control Workshop KN Smith, GS Ravi, T Alexander, NT Bronn, A Carvalho, A Cervera-Lierta, ... arXiv preprint arXiv:2202.13600, 2022 | 4 | 2022 |
Visualizing arbitrary pulse shapes and schedules in quantum computing applications P Nation, N Kanazawa, TA Alexander US Patent 10,536,224, 2020 | 4 | 2020 |
NMR study of optically hyperpolarized phosphorus donor nuclei in silicon P Gumann, H Haas, S Sheldon, L Zhu, R Deshpande, T Alexander, ... Physical Review B 98 (18), 180405, 2018 | 3 | 2018 |
Representing the operation of a quantum computing device over time P Nation, N Kanazawa, TA Alexander US Patent 11,704,455, 2023 | 1 | 2023 |
Quantum state measurement logic facilitating a quantum state measurement backend process JJ Ruedinger, TA Alexander, DC McKay US Patent App. 17/018,480, 2022 | 1 | 2022 |
Mapping conditional execution logic to quantum computing resources JJ Ruedinger, TA Alexander, DC McKay US Patent App. 17/018,507, 2022 | 1 | 2022 |
Visualizing arbitrary pulse shapes and schedules in quantum computing applications P Nation, N Kanazawa, TA Alexander US Patent 10,790,912, 2020 | 1 | 2020 |
Centralized control of execution of quantum program S Willenborg, A Wack, T Alexander, JJ Ruedinger, B Johnson, ... US Patent 11,740,901, 2023 | | 2023 |
Above Bandgap Hyperpolarization Mechanism in Isotopically Purified Silicon and Optimal Bayesian Experiment Design for Estimation T Alexander University of Waterloo, 2018 | | 2018 |
Optical Hyperpolarization of Phosphorus Donor Nuclei and Bound Exciton Capture Rates in Isotopically Purified Silicon H Haas, R Deshpande, T Alexander, D Cory APS March Meeting Abstracts 2018, R21. 008, 2018 | | 2018 |