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From Wikipedia, the free encyclopedia
This article is about classical machine learning of quantum systems. For machine learning enhanced by quantum computation, see quantum machine learning.
Part of a series of articles about
Quantum mechanics
Schrödinger equation
Background
Fundamentals
Experiments
Formulations
Equations
Interpretations
Advanced topics
Scientists

Applying classical methods of machine learning to the study of quantum systems is the focus of an emergent area of physics research. A basic example of this is quantum state tomography, where a quantum state is learned from measurement. [1] Other examples include learning Hamiltonians, [2] [3] learning quantum phase transitions, [4] [5] and automatically generating new quantum experiments. [6] [7] [8] [9] Classical machine learning is effective at processing large amounts of experimental or calculated data in order to characterize an unknown quantum system, making its application useful in contexts including quantum information theory, quantum technologies development, and computational materials design. In this context, it can be used for example as a tool to interpolate pre-calculated interatomic potentials [10] or directly solving the Schrödinger equation with a variational method. [11]

Applications of machine learning to physics

Noisy data

The ability to experimentally control and prepare increasingly complex quantum systems brings with it a growing need to turn large and noisy data sets into meaningful information. This is a problem that has already been studied extensively in the classical setting, and consequently, many existing machine learning techniques can be naturally adapted to more efficiently address experimentally relevant problems. For example, Bayesian methods and concepts of algorithmic learning can be fruitfully applied to tackle quantum state classification, [12] Hamiltonian learning, [13] and the characterization of an unknown unitary transformation. [14] [15] Other problems that have been addressed with this approach are given in the following list:

  • Identifying an accurate model for the dynamics of a quantum system, through the reconstruction of the Hamiltonian; [16] [17] [18]
  • Extracting information on unknown states; [19] [20] [21] [12] [22] [1]
  • Learning unknown unitary transformations and measurements; [14] [15]
  • Engineering of quantum gates from qubit networks with pairwise interactions, using time dependent [23] or independent [24] Hamiltonians.
  • Improving the extraction accuracy of physical observables from absorption images of ultracold atoms (degenerate Fermi gas), by the generation of an ideal reference frame. [25]

Calculated and noise-free data

Quantum machine learning can also be applied to dramatically accelerate the prediction of quantum properties of molecules and materials. [26] This can be helpful for the computational design of new molecules or materials. Some examples include

  • Interpolating interatomic potentials; [27]
  • Inferring molecular atomization energies throughout chemical compound space; [28]
  • Accurate potential energy surfaces with restricted Boltzmann machines; [29]
  • Automatic generation of new quantum experiments; [6] [7]
  • Solving the many-body, static and time-dependent Schrödinger equation; [11]
  • Identifying phase transitions from entanglement spectra; [30]
  • Generating adaptive feedback schemes for quantum metrology and quantum tomography. [31] [32]

Variational circuits

Variational circuits are a family of algorithms which utilize training based on circuit parameters and an objective function. [33] Variational circuits are generally composed of a classical device communicating input parameters (random or pre-trained parameters) into a quantum device, along with a classical Mathematical optimization function. These circuits are very heavily dependent on the architecture of the proposed quantum device because parameter adjustments are adjusted based solely on the classical components within the device. [34] Though the application is considerably infantile in the field of quantum machine learning, it has incredibly high promise for more efficiently generating efficient optimization functions.

Sign problem

Machine learning techniques can be used to find a better manifold of integration for path integrals in order to avoid the sign problem. [35]

Fluid dynamics

This section is an excerpt from Deep learning § Partial differential equations.
Physics informed neural networks have been used to solve partial differential equations in both forward and inverse problems in a data driven manner. [36] One example is the reconstructing fluid flow governed by the Navier-Stokes equations. Using physics informed neural networks does not require the often expensive mesh generation that conventional CFD methods relies on. [37] [38]

Physics discovery and prediction

See also: Laboratory robotics
Illustration of how an AI learns the basic fundamental physical concept of 'unchangeableness' [39]

A deep learning system was reported to learn intuitive physics from visual data (of virtual 3D environments) based on an unpublished approach inspired by studies of visual cognition in infants. [40] [39] Other researchers have developed a machine learning algorithm that could discover sets of basic variables of various physical systems and predict the systems' future dynamics from video recordings of their behavior. [41] [42] In the future, it may be possible that such can be used to automate the discovery of physical laws of complex systems. [41] Beyond discovery and prediction, "blank slate"-type of learning of fundamental aspects of the physical world may have further applications such as improving adaptive and broad artificial general intelligence.[ additional citation(s) needed] In specific, prior machine learning models were "highly specialised and lack a general understanding of the world". [40]

See also

References

  1. ^ a b Torlai, Giacomo; Mazzola, Guglielmo; Carrasquilla, Juan; Troyer, Matthias; Melko, Roger; Carleo, Giuseppe (May 2018). "Neural-network quantum state tomography". Nature Physics. 14 (5): 447–450. arXiv: 1703.05334. Bibcode: 2018NatPh..14..447T. doi: 10.1038/s41567-018-0048-5. ISSN  1745-2481. S2CID  125415859.
  2. ^ Cory, D. G.; Wiebe, Nathan; Ferrie, Christopher; Granade, Christopher E. (2012-07-06). "Robust Online Hamiltonian Learning". New Journal of Physics. 14 (10): 103013. arXiv: 1207.1655. Bibcode: 2012NJPh...14j3013G. doi: 10.1088/1367-2630/14/10/103013. S2CID  9928389.
  3. ^ Cao, Chenfeng; Hou, Shi-Yao; Cao, Ningping; Zeng, Bei (2020-02-10). "Supervised learning in Hamiltonian reconstruction from local measurements on eigenstates". Journal of Physics: Condensed Matter. 33 (6): 064002. arXiv: 2007.05962. doi: 10.1088/1361-648x/abc4cf. ISSN  0953-8984. PMID  33105109. S2CID  220496757.
  4. ^ Broecker, Peter; Assaad, Fakher F.; Trebst, Simon (2017-07-03). "Quantum phase recognition via unsupervised machine learning". arXiv: 1707.00663 [ cond-mat.str-el].
  5. ^ Huembeli, Patrick; Dauphin, Alexandre; Wittek, Peter (2018). "Identifying Quantum Phase Transitions with Adversarial Neural Networks". Physical Review B. 97 (13): 134109. arXiv: 1710.08382. Bibcode: 2018PhRvB..97m4109H. doi: 10.1103/PhysRevB.97.134109. ISSN  2469-9950. S2CID  125593239.
  6. ^ a b Krenn, Mario (2016-01-01). "Automated Search for new Quantum Experiments". Physical Review Letters. 116 (9): 090405. arXiv: 1509.02749. Bibcode: 2016PhRvL.116i0405K. doi: 10.1103/PhysRevLett.116.090405. PMID  26991161. S2CID  20182586.
  7. ^ a b Knott, Paul (2016-03-22). "A search algorithm for quantum state engineering and metrology". New Journal of Physics. 18 (7): 073033. arXiv: 1511.05327. Bibcode: 2016NJPh...18g3033K. doi: 10.1088/1367-2630/18/7/073033. S2CID  2721958.
  8. ^ Dunjko, Vedran; Briegel, Hans J (2018-06-19). "Machine learning & artificial intelligence in the quantum domain: a review of recent progress". Reports on Progress in Physics. 81 (7): 074001. arXiv: 1709.02779. Bibcode: 2018RPPh...81g4001D. doi: 10.1088/1361-6633/aab406. hdl: 1887/71084. ISSN  0034-4885. PMID  29504942. S2CID  3681629.
  9. ^ Melnikov, Alexey A.; Nautrup, Hendrik Poulsen; Krenn, Mario; Dunjko, Vedran; Tiersch, Markus; Zeilinger, Anton; Briegel, Hans J. (1221). "Active learning machine learns to create new quantum experiments". Proceedings of the National Academy of Sciences. 115 (6): 1221–1226. arXiv: 1706.00868. doi: 10.1073/pnas.1714936115. ISSN  0027-8424. PMC  5819408. PMID  29348200.
  10. ^ Behler, Jörg; Parrinello, Michele (2007-04-02). "Generalized Neural-Network Representation of High-Dimensional Potential-Energy Surfaces". Physical Review Letters. 98 (14): 146401. Bibcode: 2007PhRvL..98n6401B. doi: 10.1103/PhysRevLett.98.146401. PMID  17501293.
  11. ^ a b Carleo, Giuseppe; Troyer, Matthias (2017-02-09). "Solving the quantum many-body problem with artificial neural networks". Science. 355 (6325): 602–606. arXiv: 1606.02318. Bibcode: 2017Sci...355..602C. doi: 10.1126/science.aag2302. PMID  28183973. S2CID  206651104.
  12. ^ a b Sentís, Gael; Calsamiglia, John; Muñoz-Tapia, Raúl; Bagan, Emilio (2012). "Quantum learning without quantum memory". Scientific Reports. 2: 708. arXiv: 1106.2742. Bibcode: 2012NatSR...2E.708S. doi: 10.1038/srep00708. PMC  3464493. PMID  23050092.
  13. ^ Wiebe, Nathan; Granade, Christopher; Ferrie, Christopher; Cory, David (2014). "Quantum Hamiltonian learning using imperfect quantum resources". Physical Review A. 89 (4): 042314. arXiv: 1311.5269. Bibcode: 2014PhRvA..89d2314W. doi: 10.1103/physreva.89.042314. hdl: 10453/118943. S2CID  55126023.
  14. ^ a b Bisio, Alessandro; Chiribella, Giulio; D'Ariano, Giacomo Mauro; Facchini, Stefano; Perinotti, Paolo (2010). "Optimal quantum learning of a unitary transformation". Physical Review A. 81 (3): 032324. arXiv: 0903.0543. Bibcode: 2010PhRvA..81c2324B. doi: 10.1103/PhysRevA.81.032324. S2CID  119289138.
  15. ^ a b Jeongho; Junghee Ryu, Bang; Yoo, Seokwon; Pawłowski, Marcin; Lee, Jinhyoung (2014). "A strategy for quantum algorithm design assisted by machine learning". New Journal of Physics. 16 (1): 073017. arXiv: 1304.2169. Bibcode: 2014NJPh...16a3017K. doi: 10.1088/1367-2630/16/1/013017. S2CID  54494244.
  16. ^ Granade, Christopher E.; Ferrie, Christopher; Wiebe, Nathan; Cory, D. G. (2012-10-03). "Robust Online Hamiltonian Learning". New Journal of Physics. 14 (10): 103013. arXiv: 1207.1655. Bibcode: 2012NJPh...14j3013G. doi: 10.1088/1367-2630/14/10/103013. ISSN  1367-2630. S2CID  9928389.
  17. ^ Wiebe, Nathan; Granade, Christopher; Ferrie, Christopher; Cory, D. G. (2014). "Hamiltonian Learning and Certification Using Quantum Resources". Physical Review Letters. 112 (19): 190501. arXiv: 1309.0876. Bibcode: 2014PhRvL.112s0501W. doi: 10.1103/PhysRevLett.112.190501. ISSN  0031-9007. PMID  24877920. S2CID  39126228.
  18. ^ Wiebe, Nathan; Granade, Christopher; Ferrie, Christopher; Cory, David G. (2014-04-17). "Quantum Hamiltonian Learning Using Imperfect Quantum Resources". Physical Review A. 89 (4): 042314. arXiv: 1311.5269. Bibcode: 2014PhRvA..89d2314W. doi: 10.1103/PhysRevA.89.042314. hdl: 10453/118943. ISSN  1050-2947. S2CID  55126023.
  19. ^ Sasaki, Madahide; Carlini, Alberto; Jozsa, Richard (2001). "Quantum Template Matching". Physical Review A. 64 (2): 022317. arXiv: quant-ph/0102020. Bibcode: 2001PhRvA..64b2317S. doi: 10.1103/PhysRevA.64.022317. S2CID  43413485.
  20. ^ Sasaki, Masahide (2002). "Quantum learning and universal quantum matching machine". Physical Review A. 66 (2): 022303. arXiv: quant-ph/0202173. Bibcode: 2002PhRvA..66b2303S. doi: 10.1103/PhysRevA.66.022303. S2CID  119383508.
  21. ^ Sentís, Gael; Guţă, Mădălin; Adesso, Gerardo (2015-07-09). "Quantum learning of coherent states". EPJ Quantum Technology. 2 (1): 17. arXiv: 1410.8700. doi: 10.1140/epjqt/s40507-015-0030-4. ISSN  2196-0763. S2CID  6980007.
  22. ^ Lee, Sang Min; Lee, Jinhyoung; Bang, Jeongho (2018-11-02). "Learning unknown pure quantum states". Physical Review A. 98 (5): 052302. arXiv: 1805.06580. Bibcode: 2018PhRvA..98e2302L. doi: 10.1103/PhysRevA.98.052302. S2CID  119095806.
  23. ^ Zahedinejad, Ehsan; Ghosh, Joydip; Sanders, Barry C. (2016-11-16). "Designing High-Fidelity Single-Shot Three-Qubit Gates: A Machine Learning Approach". Physical Review Applied. 6 (5): 054005. arXiv: 1511.08862. Bibcode: 2016PhRvP...6e4005Z. doi: 10.1103/PhysRevApplied.6.054005. ISSN  2331-7019. S2CID  7299645.
  24. ^ Banchi, Leonardo; Pancotti, Nicola; Bose, Sougato (2016-07-19). "Quantum gate learning in qubit networks: Toffoli gate without time-dependent control". npj Quantum Information. 2: 16019. Bibcode: 2016npjQI...216019B. doi: 10.1038/npjqi.2016.19. hdl: 11858/00-001M-0000-002C-AA64-F.
  25. ^ Ness, Gal; Vainbaum, Anastasiya; Shkedrov, Constantine; Florshaim, Yanay; Sagi, Yoav (2020-07-06). "Single-exposure absorption imaging of ultracold atoms using deep learning". Physical Review Applied. 14 (1): 014011. arXiv: 2003.01643. Bibcode: 2020PhRvP..14a4011N. doi: 10.1103/PhysRevApplied.14.014011. S2CID  211817864.
  26. ^ von Lilienfeld, O. Anatole (2018-04-09). "Quantum Machine Learning in Chemical Compound Space". Angewandte Chemie International Edition. 57 (16): 4164–4169. doi: 10.1002/anie.201709686. PMID  29216413.
  27. ^ Bartok, Albert P.; Payne, Mike C.; Risi, Kondor; Csanyi, Gabor (2010). "Gaussian approximation potentials: The accuracy of quantum mechanics, without the electrons" (PDF). Physical Review Letters. 104 (13): 136403. arXiv: 0910.1019. Bibcode: 2010PhRvL.104m6403B. doi: 10.1103/PhysRevLett.104.136403. PMID  20481899. S2CID  15918457.
  28. ^ Rupp, Matthias; Tkatchenko, Alexandre; Müller, Klaus-Robert; von Lilienfeld, O. Anatole (2012-01-31). "Fast and Accurate Modeling of Molecular Atomization Energies With Machine Learning". Physical Review Letters. 355 (6325): 602. arXiv: 1109.2618. Bibcode: 2012PhRvL.108e8301R. doi: 10.1103/PhysRevLett.108.058301. PMID  22400967. S2CID  321566.
  29. ^ Xia, Rongxin; Kais, Sabre (2018-10-10). "Quantum machine learning for electronic structure calculations". Nature Communications. 9 (1): 4195. arXiv: 1803.10296. Bibcode: 2018NatCo...9.4195X. doi: 10.1038/s41467-018-06598-z. PMC  6180079. PMID  30305624.
  30. ^ van Nieuwenburg, Evert; Liu, Ye-Hua; Huber, Sebastian (2017). "Learning phase transitions by confusion". Nature Physics. 13 (5): 435. arXiv: 1610.02048. Bibcode: 2017NatPh..13..435V. doi: 10.1038/nphys4037. S2CID  119285403.
  31. ^ Hentschel, Alexander (2010-01-01). "Machine Learning for Precise Quantum Measurement". Physical Review Letters. 104 (6): 063603. arXiv: 0910.0762. Bibcode: 2010PhRvL.104f3603H. doi: 10.1103/PhysRevLett.104.063603. PMID  20366821. S2CID  14689659.
  32. ^ Quek, Yihui; Fort, Stanislav; Ng, Hui Khoon (2018-12-17). "Adaptive Quantum State Tomography with Neural Networks". arXiv: 1812.06693 [ quant-ph].
  33. ^ "Variational Circuits — Quantum Machine Learning Toolbox 0.7.1 documentation". qmlt.readthedocs.io. Retrieved 2018-12-06.
  34. ^ Schuld, Maria (2018-06-12). "Quantum Machine Learning 1.0". XanaduAI. Retrieved 2018-12-07.
  35. ^ Alexandru, Andrei; Bedaque, Paulo F.; Lamm, Henry; Lawrence, Scott (2017). "Deep Learning Beyond Lefschetz Thimbles". Physical Review D. 96 (9): 094505. arXiv: 1709.01971. Bibcode: 2017PhRvD..96i4505A. doi: 10.1103/PhysRevD.96.094505. S2CID  119074823.
  36. ^ Raissi, M.; Perdikaris, P.; Karniadakis, G. E. (2019-02-01). "Physics-informed neural networks: A deep learning framework for solving forward and inverse problems involving nonlinear partial differential equations". Journal of Computational Physics. 378: 686–707. Bibcode: 2019JCoPh.378..686R. doi: 10.1016/j.jcp.2018.10.045. ISSN  0021-9991. OSTI  1595805. S2CID  57379996.
  37. ^ Mao, Zhiping; Jagtap, Ameya D.; Karniadakis, George Em (2020-03-01). "Physics-informed neural networks for high-speed flows". Computer Methods in Applied Mechanics and Engineering. 360: 112789. Bibcode: 2020CMAME.360k2789M. doi: 10.1016/j.cma.2019.112789. ISSN  0045-7825. S2CID  212755458.
  38. ^ Raissi, Maziar; Yazdani, Alireza; Karniadakis, George Em (2020-02-28). "Hidden fluid mechanics: Learning velocity and pressure fields from flow visualizations". Science. 367 (6481): 1026–1030. Bibcode: 2020Sci...367.1026R. doi: 10.1126/science.aaw4741. PMC  7219083. PMID  32001523.
  39. ^ a b Piloto, Luis S.; Weinstein, Ari; Battaglia, Peter; Botvinick, Matthew (11 July 2022). "Intuitive physics learning in a deep-learning model inspired by developmental psychology". Nature Human Behaviour. 6 (9): 1257–1267. doi: 10.1038/s41562-022-01394-8. ISSN  2397-3374. PMC  9489531. PMID  35817932.
  40. ^ a b "DeepMind AI learns physics by watching videos that don't make sense". New Scientist. Retrieved 21 August 2022.
  41. ^ a b Feldman, Andrey (11 August 2022). "Artificial physicist to unravel the laws of nature". Advanced Science News. Retrieved 21 August 2022.
  42. ^ Chen, Boyuan; Huang, Kuang; Raghupathi, Sunand; Chandratreya, Ishaan; Du, Qiang; Lipson, Hod (July 2022). "Automated discovery of fundamental variables hidden in experimental data". Nature Computational Science. 2 (7): 433–442. doi: 10.1038/s43588-022-00281-6. ISSN  2662-8457. S2CID  251087119.
Retrieved from " https://en.wikipedia.org/?title=Machine_learning_in_physics&oldid=1221074382"
From Wikipedia, the free encyclopedia
This article is about classical machine learning of quantum systems. For machine learning enhanced by quantum computation, see quantum machine learning.
Part of a series of articles about
Quantum mechanics
Schrödinger equation
Background
Fundamentals
Experiments
Formulations
Equations
Interpretations
Advanced topics
Scientists

Applying classical methods of machine learning to the study of quantum systems is the focus of an emergent area of physics research. A basic example of this is quantum state tomography, where a quantum state is learned from measurement. [1] Other examples include learning Hamiltonians, [2] [3] learning quantum phase transitions, [4] [5] and automatically generating new quantum experiments. [6] [7] [8] [9] Classical machine learning is effective at processing large amounts of experimental or calculated data in order to characterize an unknown quantum system, making its application useful in contexts including quantum information theory, quantum technologies development, and computational materials design. In this context, it can be used for example as a tool to interpolate pre-calculated interatomic potentials [10] or directly solving the Schrödinger equation with a variational method. [11]

Applications of machine learning to physics

Noisy data

The ability to experimentally control and prepare increasingly complex quantum systems brings with it a growing need to turn large and noisy data sets into meaningful information. This is a problem that has already been studied extensively in the classical setting, and consequently, many existing machine learning techniques can be naturally adapted to more efficiently address experimentally relevant problems. For example, Bayesian methods and concepts of algorithmic learning can be fruitfully applied to tackle quantum state classification, [12] Hamiltonian learning, [13] and the characterization of an unknown unitary transformation. [14] [15] Other problems that have been addressed with this approach are given in the following list:

  • Identifying an accurate model for the dynamics of a quantum system, through the reconstruction of the Hamiltonian; [16] [17] [18]
  • Extracting information on unknown states; [19] [20] [21] [12] [22] [1]
  • Learning unknown unitary transformations and measurements; [14] [15]
  • Engineering of quantum gates from qubit networks with pairwise interactions, using time dependent [23] or independent [24] Hamiltonians.
  • Improving the extraction accuracy of physical observables from absorption images of ultracold atoms (degenerate Fermi gas), by the generation of an ideal reference frame. [25]

Calculated and noise-free data

Quantum machine learning can also be applied to dramatically accelerate the prediction of quantum properties of molecules and materials. [26] This can be helpful for the computational design of new molecules or materials. Some examples include

  • Interpolating interatomic potentials; [27]
  • Inferring molecular atomization energies throughout chemical compound space; [28]
  • Accurate potential energy surfaces with restricted Boltzmann machines; [29]
  • Automatic generation of new quantum experiments; [6] [7]
  • Solving the many-body, static and time-dependent Schrödinger equation; [11]
  • Identifying phase transitions from entanglement spectra; [30]
  • Generating adaptive feedback schemes for quantum metrology and quantum tomography. [31] [32]

Variational circuits

Variational circuits are a family of algorithms which utilize training based on circuit parameters and an objective function. [33] Variational circuits are generally composed of a classical device communicating input parameters (random or pre-trained parameters) into a quantum device, along with a classical Mathematical optimization function. These circuits are very heavily dependent on the architecture of the proposed quantum device because parameter adjustments are adjusted based solely on the classical components within the device. [34] Though the application is considerably infantile in the field of quantum machine learning, it has incredibly high promise for more efficiently generating efficient optimization functions.

Sign problem

Machine learning techniques can be used to find a better manifold of integration for path integrals in order to avoid the sign problem. [35]

Fluid dynamics

This section is an excerpt from Deep learning § Partial differential equations.
Physics informed neural networks have been used to solve partial differential equations in both forward and inverse problems in a data driven manner. [36] One example is the reconstructing fluid flow governed by the Navier-Stokes equations. Using physics informed neural networks does not require the often expensive mesh generation that conventional CFD methods relies on. [37] [38]

Physics discovery and prediction

See also: Laboratory robotics
Illustration of how an AI learns the basic fundamental physical concept of 'unchangeableness' [39]

A deep learning system was reported to learn intuitive physics from visual data (of virtual 3D environments) based on an unpublished approach inspired by studies of visual cognition in infants. [40] [39] Other researchers have developed a machine learning algorithm that could discover sets of basic variables of various physical systems and predict the systems' future dynamics from video recordings of their behavior. [41] [42] In the future, it may be possible that such can be used to automate the discovery of physical laws of complex systems. [41] Beyond discovery and prediction, "blank slate"-type of learning of fundamental aspects of the physical world may have further applications such as improving adaptive and broad artificial general intelligence.[ additional citation(s) needed] In specific, prior machine learning models were "highly specialised and lack a general understanding of the world". [40]

See also

References

  1. ^ a b Torlai, Giacomo; Mazzola, Guglielmo; Carrasquilla, Juan; Troyer, Matthias; Melko, Roger; Carleo, Giuseppe (May 2018). "Neural-network quantum state tomography". Nature Physics. 14 (5): 447–450. arXiv: 1703.05334. Bibcode: 2018NatPh..14..447T. doi: 10.1038/s41567-018-0048-5. ISSN  1745-2481. S2CID  125415859.
  2. ^ Cory, D. G.; Wiebe, Nathan; Ferrie, Christopher; Granade, Christopher E. (2012-07-06). "Robust Online Hamiltonian Learning". New Journal of Physics. 14 (10): 103013. arXiv: 1207.1655. Bibcode: 2012NJPh...14j3013G. doi: 10.1088/1367-2630/14/10/103013. S2CID  9928389.
  3. ^ Cao, Chenfeng; Hou, Shi-Yao; Cao, Ningping; Zeng, Bei (2020-02-10). "Supervised learning in Hamiltonian reconstruction from local measurements on eigenstates". Journal of Physics: Condensed Matter. 33 (6): 064002. arXiv: 2007.05962. doi: 10.1088/1361-648x/abc4cf. ISSN  0953-8984. PMID  33105109. S2CID  220496757.
  4. ^ Broecker, Peter; Assaad, Fakher F.; Trebst, Simon (2017-07-03). "Quantum phase recognition via unsupervised machine learning". arXiv: 1707.00663 [ cond-mat.str-el].
  5. ^ Huembeli, Patrick; Dauphin, Alexandre; Wittek, Peter (2018). "Identifying Quantum Phase Transitions with Adversarial Neural Networks". Physical Review B. 97 (13): 134109. arXiv: 1710.08382. Bibcode: 2018PhRvB..97m4109H. doi: 10.1103/PhysRevB.97.134109. ISSN  2469-9950. S2CID  125593239.
  6. ^ a b Krenn, Mario (2016-01-01). "Automated Search for new Quantum Experiments". Physical Review Letters. 116 (9): 090405. arXiv: 1509.02749. Bibcode: 2016PhRvL.116i0405K. doi: 10.1103/PhysRevLett.116.090405. PMID  26991161. S2CID  20182586.
  7. ^ a b Knott, Paul (2016-03-22). "A search algorithm for quantum state engineering and metrology". New Journal of Physics. 18 (7): 073033. arXiv: 1511.05327. Bibcode: 2016NJPh...18g3033K. doi: 10.1088/1367-2630/18/7/073033. S2CID  2721958.
  8. ^ Dunjko, Vedran; Briegel, Hans J (2018-06-19). "Machine learning & artificial intelligence in the quantum domain: a review of recent progress". Reports on Progress in Physics. 81 (7): 074001. arXiv: 1709.02779. Bibcode: 2018RPPh...81g4001D. doi: 10.1088/1361-6633/aab406. hdl: 1887/71084. ISSN  0034-4885. PMID  29504942. S2CID  3681629.
  9. ^ Melnikov, Alexey A.; Nautrup, Hendrik Poulsen; Krenn, Mario; Dunjko, Vedran; Tiersch, Markus; Zeilinger, Anton; Briegel, Hans J. (1221). "Active learning machine learns to create new quantum experiments". Proceedings of the National Academy of Sciences. 115 (6): 1221–1226. arXiv: 1706.00868. doi: 10.1073/pnas.1714936115. ISSN  0027-8424. PMC  5819408. PMID  29348200.
  10. ^ Behler, Jörg; Parrinello, Michele (2007-04-02). "Generalized Neural-Network Representation of High-Dimensional Potential-Energy Surfaces". Physical Review Letters. 98 (14): 146401. Bibcode: 2007PhRvL..98n6401B. doi: 10.1103/PhysRevLett.98.146401. PMID  17501293.
  11. ^ a b Carleo, Giuseppe; Troyer, Matthias (2017-02-09). "Solving the quantum many-body problem with artificial neural networks". Science. 355 (6325): 602–606. arXiv: 1606.02318. Bibcode: 2017Sci...355..602C. doi: 10.1126/science.aag2302. PMID  28183973. S2CID  206651104.
  12. ^ a b Sentís, Gael; Calsamiglia, John; Muñoz-Tapia, Raúl; Bagan, Emilio (2012). "Quantum learning without quantum memory". Scientific Reports. 2: 708. arXiv: 1106.2742. Bibcode: 2012NatSR...2E.708S. doi: 10.1038/srep00708. PMC  3464493. PMID  23050092.
  13. ^ Wiebe, Nathan; Granade, Christopher; Ferrie, Christopher; Cory, David (2014). "Quantum Hamiltonian learning using imperfect quantum resources". Physical Review A. 89 (4): 042314. arXiv: 1311.5269. Bibcode: 2014PhRvA..89d2314W. doi: 10.1103/physreva.89.042314. hdl: 10453/118943. S2CID  55126023.
  14. ^ a b Bisio, Alessandro; Chiribella, Giulio; D'Ariano, Giacomo Mauro; Facchini, Stefano; Perinotti, Paolo (2010). "Optimal quantum learning of a unitary transformation". Physical Review A. 81 (3): 032324. arXiv: 0903.0543. Bibcode: 2010PhRvA..81c2324B. doi: 10.1103/PhysRevA.81.032324. S2CID  119289138.
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