IBM Quantum Platform
Type of site
Cloud-based quantum computing
OwnerIBM
URLquantum-computing.ibm.com
RegistrationRequired
LaunchedMay 2016; 8 years ago (2016-05)
Current statusActive

IBM Quantum Platform (previously known as IBM Quantum Experience) is an online platform allowing public and premium access to cloud-based quantum computing services provided by IBM. This includes access to a set of IBM's prototype quantum processors, a set of tutorials on quantum computation, and access to an interactive textbook. As of February 2021, there are over 20 devices on the service, six of which are freely available for the public. This service can be used to run algorithms and experiments, and explore tutorials and simulations around what might be possible with quantum computing.

IBM's quantum processors are made up of superconducting transmon qubits, located in dilution refrigerators at the IBM Research headquarters at the Thomas J. Watson Research Center. Users interact with a quantum processor through the quantum circuit model of computation. Circuits can be created either graphically with the Quantum Composer, or programmatically with the Jupyter notebooks of the Quantum Lab. Circuits are created using Qiskit and can be compiled down to OpenQASM for execution on real quantum systems.

History

IBM Quantum Composer

Screenshot showing the result of running a GHZ state experiment using the IBM Quantum Composer

The Quantum Composer is a graphic user interface (GUI) designed by IBM to allow users to construct various quantum algorithms or run other quantum experiments. Users may see the results of their quantum algorithms by either running it on a real quantum processor or by using a simulator. Algorithms developed in the Quantum Composer are referred to as a "quantum score", in reference to the Quantum Composer resembling a musical sheet.[8]

The composer can also be used in scripting mode, where the user can write programs in the OpenQASM-language instead. Below is an example of a very small program, built for IBMs 5-qubit computer. The program instructs the computer to generate a quantum state , a 3-qubit GHZ state, which can be thought of as a variant of the Bell state, but with three qubits instead of two. It then measures the state, forcing it to collapse to one of the two possible outcomes, or . 

include "qelib1.inc"
qreg q[5];                // allocate 5 qubits (set automatically to |00000>)
creg c[5];                // allocate 5 classical bits

h q[0];                   // Hadamard-transform qubit 0
cx q[0], q[1];            // conditional pauli X-transform (ie. "CNOT") of qubits 0 and 1
                          // At this point we have a 2-qubit Bell state (|00> + |11>)/sqrt(2)

cx q[1], q[2];            // this expands entanglement to the 3rd qubit

measure q[0] -> c[0];     // this measurement collapses the entire 3-qubit state
measure q[1] -> c[1];     // therefore qubit 1 and 2 read the same value as qubit 0
measure q[2] -> c[2];

Every instruction in the QASM language is the application of a quantum gate, initialization of the chips registers to zero or measurement of these registers.

Usage

References

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  2. ^ "IBM Quantum Experience Update". Archived from the original on 2019-01-29. Retrieved 2017-04-06.
  3. ^ "Quantum computing gets an API and SDK". 2017-03-06.
  4. ^ "Beta access our upgrade to the IBM QX". Archived from the original on 2019-01-31. Retrieved 2017-05-19.
  5. ^ "Now Open: Get quantum ready with new scientific prizes for professors, students and developers". IBM. 2018-01-14.
  6. ^ "IBM Unveils Beta of Next Generation Quantum Development Platform". IBM. 2021-02-10.
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  10. ^ "QX Community papers". Archived from the original on 2019-03-22. Retrieved 2018-05-24.
  11. ^ "Research of the IBM Quantum Hub at the University of Melbourne". 20 April 2021.
  12. ^ Rundle, R. P.; Tilma, T.; Samson, J. H.; Everitt, M. J. (2017). "Quantum state reconstruction made easy: a direct method for tomography". Physical Review A. 96 (2): 022117. arXiv:1605.08922. Bibcode:2017PhRvA..96b2117R. doi:10.1103/PhysRevA.96.022117.
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  14. ^ Huffman, Emilie; Mizel, Ari (29 March 2017). "Violation of noninvasive macrorealism by a superconducting qubit: Implementation of a Leggett-Garg test that addresses the clumsiness loophole". Physical Review A. 95 (3): 032131. arXiv:1609.05957. Bibcode:2017PhRvA..95c2131H. doi:10.1103/PhysRevA.95.032131.
  15. ^ Deffner, Sebastian (23 September 2016). "Demonstration of entanglement assisted invariance on IBM's Quantum Experience". Heliyon. 3 (11): e00444. arXiv:1609.07459. doi:10.1016/j.heliyon.2017.e00444. PMC 5683883. PMID 29159322.
  16. ^ Huang, He-Liang; Zhao, You-Wei; Li, Tan; Li, Feng-Guang; Du, Yu-Tao; Fu, Xiang-Qun; Zhang, Shuo; Wang, Xiang; Bao, Wan-Su (9 December 2016). "Homomorphic Encryption Experiments on IBM's Cloud Quantum Computing Platform". Frontiers of Physics. 12 (1): 120305. arXiv:1612.02886. Bibcode:2017FrPhy..12l0305H. doi:10.1007/s11467-016-0643-9. S2CID 17770053.
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  18. ^ Fedortchenko, Serguei (8 July 2016). "A quantum teleportation experiment for undergraduate students". arXiv:1607.02398 [quant-ph].
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  20. ^ Li, Rui; Alvarez-Rodriguez, Unai; Lamata, Lucas; Solano, Enrique (23 November 2016). "Approximate Quantum Adders with Genetic Algorithms: An IBM Quantum Experience". Quantum Measurements and Quantum Metrology. 4 (1): 1–7. arXiv:1611.07851. Bibcode:2017QMQM....4....1L. doi:10.1515/qmetro-2017-0001. S2CID 108291239.
  21. ^ Hebenstreit, M.; Alsina, D.; Latorre, J. I.; Kraus, B. (11 January 2017). "Compressed quantum computation using the IBM Quantum Experience". Phys. Rev. A. 95 (5): 052339. arXiv:1701.02970. doi:10.1103/PhysRevA.95.052339. S2CID 118958024.
  22. ^ Alsina, Daniel; Latorre, José Ignacio (11 July 2016). "Experimental test of Mermin inequalities on a five-qubit quantum computer". Physical Review A. 94 (1): 012314. arXiv:1605.04220. Bibcode:2016PhRvA..94a2314A. doi:10.1103/PhysRevA.94.012314. S2CID 119189277.
  23. ^ Linke, Norbert M.; Maslov, Dmitri; Roetteler, Martin; Debnath, Shantanu; Figgatt, Caroline; Landsman, Kevin A.; Wright, Kenneth; Monroe, Christopher (28 March 2017). "Experimental comparison of two quantum computing architectures". Proceedings of the National Academy of Sciences. 114 (13): 3305–3310. arXiv:1702.01852. Bibcode:2017PNAS..114.3305L. doi:10.1073/pnas.1618020114. PMC 5380037. PMID 28325879.
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  25. ^ Steiger, Damian; Haner, Thomas; Troyer, Matthias (2018). "ProjectQ: An Open Source Software Framework for Quantum Computing". Quantum. 2: 49. arXiv:1612.08091. Bibcode:2018Quant...2...49S. doi:10.22331/q-2018-01-31-49. S2CID 6758479.
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  27. ^ Caicedo-Ortiz, H. E.; Santiago-Cortés, E. (2017). "Construyendo compuertas cuánticas con IBM's cloud quantum computer" [Building quantum gates with IBM’s cloud quantum computer] (PDF). Journal de Ciencia e Ingeniería (in Spanish). 9: 42–56. doi:10.46571/JCI.2017.1.7.

External links

IBM
Quantum information science
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