Extreme dimensionality reduction with quantum modeling
Effective and efficient forecasting relies on identification of the relevant information contained in past observations-the predictive features-and isolating it from the rest. When the future of a process bears a strong dependence on its behavior far into the past, there are many such features to st...
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sg-ntu-dr.10356-1488402021-05-22T09:16:30Z Extreme dimensionality reduction with quantum modeling Elliott, Thomas J. Yang, Chengran Binder, Felix C. Garner, Andrew J. P. Thompson, Jayne Gu, Mile School of Physical and Mathematical Sciences Science::Physics Science::Mathematics::Applied mathematics::Information theory Quantum Algorithms Quantum Channels Effective and efficient forecasting relies on identification of the relevant information contained in past observations-the predictive features-and isolating it from the rest. When the future of a process bears a strong dependence on its behavior far into the past, there are many such features to store, necessitating complex models with extensive memories. Here, we highlight a family of stochastic processes whose minimal classical models must devote unboundedly many bits to tracking the past. For this family, we identify quantum models of equal accuracy that can store all relevant information within a single two-dimensional quantum system (qubit). This represents the ultimate limit of quantum compression and highlights an immense practical advantage of quantum technologies for the forecasting and simulation of complex systems. 2021-05-22T09:16:30Z 2021-05-22T09:16:30Z 2020 Journal Article Elliott, T. J., Yang, C., Binder, F. C., Garner, A. J. P., Thompson, J. & Gu, M. (2020). Extreme dimensionality reduction with quantum modeling. Physical Review Letters, 125(26), 260501-. https://dx.doi.org/10.1103/PhysRevLett.125.260501 1079-7114 https://hdl.handle.net/10356/148840 10.1103/PhysRevLett.125.260501 33449713 2-s2.0-85099156343 26 125 260501 en NRF2017-NRF-ANR004 Physical Review Letters © 2020 American Physical Society (APS). All rights reserved. |
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Science::Physics Science::Mathematics::Applied mathematics::Information theory Quantum Algorithms Quantum Channels Elliott, Thomas J. Yang, Chengran Binder, Felix C. Garner, Andrew J. P. Thompson, Jayne Gu, Mile Extreme dimensionality reduction with quantum modeling |
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Effective and efficient forecasting relies on identification of the relevant information contained in past observations-the predictive features-and isolating it from the rest. When the future of a process bears a strong dependence on its behavior far into the past, there are many such features to store, necessitating complex models with extensive memories. Here, we highlight a family of stochastic processes whose minimal classical models must devote unboundedly many bits to tracking the past. For this family, we identify quantum models of equal accuracy that can store all relevant information within a single two-dimensional quantum system (qubit). This represents the ultimate limit of quantum compression and highlights an immense practical advantage of quantum technologies for the forecasting and simulation of complex systems. |
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School of Physical and Mathematical Sciences |
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School of Physical and Mathematical Sciences Elliott, Thomas J. Yang, Chengran Binder, Felix C. Garner, Andrew J. P. Thompson, Jayne Gu, Mile |
| format |
Article |
| author |
Elliott, Thomas J. Yang, Chengran Binder, Felix C. Garner, Andrew J. P. Thompson, Jayne Gu, Mile |
| author_sort |
Elliott, Thomas J. |
| title |
Extreme dimensionality reduction with quantum modeling |
| title_short |
Extreme dimensionality reduction with quantum modeling |
| title_full |
Extreme dimensionality reduction with quantum modeling |
| title_fullStr |
Extreme dimensionality reduction with quantum modeling |
| title_full_unstemmed |
Extreme dimensionality reduction with quantum modeling |
| title_sort |
extreme dimensionality reduction with quantum modeling |
| publishDate |
2021 |
| url |
https://hdl.handle.net/10356/148840 |
| _version_ |
1701270581070004224 |