Papers
Topics
Authors
Recent
Search
2000 character limit reached

The generative quantum eigensolver (GQE) and its application for ground state search

Published 17 Jan 2024 in quant-ph | (2401.09253v1)

Abstract: We introduce the generative quantum eigensolver (GQE), a novel method for applying classical generative models for quantum simulation. The GQE algorithm optimizes a classical generative model to produce quantum circuits with desired properties. Here, we develop a transformer-based implementation, which we name the generative pre-trained transformer-based (GPT) quantum eigensolver (GPT-QE), leveraging both pre-training on existing datasets and training without any prior knowledge. We demonstrate the effectiveness of training and pre-training GPT-QE in the search for ground states of electronic structure Hamiltonians. GQE strategies can extend beyond the problem of Hamiltonian simulation into other application areas of quantum computing.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (37)
  1. D. Bluvstein, S. J. Evered, A. A. Geim, S. H. Li, H. Zhou, T. Manovitz, S. Ebadi, M. Cain, M. Kalinowski, D. Hangleiter, et al., “Logical quantum processor based on reconfigurable atom arrays,” Nature, pp. 1–3, 2023.
  2. A. Peruzzo, J. McClean, P. Shadbolt, M.-H. Yung, X.-Q. Zhou, P. J. Love, A. Aspuru-Guzik, and J. L. O’Brien, “A variational eigenvalue solver on a photonic quantum processor,” Nature Communications, vol. 5, p. 4213, July 2014.
  3. M. Cerezo, A. Arrasmith, R. Babbush, S. C. Benjamin, S. Endo, K. Fujii, J. R. McClean, K. Mitarai, X. Yuan, L. Cincio, and P. J. Coles, “Variational quantum algorithms,” Nature Reviews Physics, vol. 3, pp. 625–644, Sept. 2021. Number: 9 Publisher: Nature Publishing Group.
  4. K. Bharti, A. Cervera-Lierta, T. H. Kyaw, T. Haug, S. Alperin-Lea, A. Anand, M. Degroote, H. Heimonen, J. S. Kottmann, T. Menke, et al., “Noisy intermediate-scale quantum algorithms,” Reviews of Modern Physics, vol. 94, no. 1, p. 015004, 2022.
  5. A. B. Magann, S. E. Economou, and C. Arenz, “Randomized adaptive quantum state preparation,” Jan. 2023. arXiv:2301.04201 [quant-ph].
  6. S. Wang, E. Fontana, M. Cerezo, K. Sharma, A. Sone, L. Cincio, and P. J. Coles, “Noise-induced barren plateaus in variational quantum algorithms,” Nature communications, vol. 12, no. 1, p. 6961, 2021.
  7. A. Radford, J. Wu, R. Child, D. Luan, D. Amodei, and I. Sutskever, “Language Models are Unsupervised Multitask Learners,” 2019.
  8. A. Vaswani, N. Shazeer, N. Parmar, J. Uszkoreit, L. Jones, A. N. Gomez, L. Kaiser, and I. Polosukhin, “Attention is All you Need,” in Advances in Neural Information Processing Systems (I. Guyon, U. V. Luxburg, S. Bengio, H. Wallach, R. Fergus, S. Vishwanathan, and R. Garnett, eds.), vol. 30, Curran Associates, Inc., 2017.
  9. H. Zhao, L. Jiang, J. Jia, P. H. S. Torr, and V. Koltun, “Point Transformer,”
  10. A. Dosovitskiy, L. Beyer, A. Kolesnikov, D. Weissenborn, X. Zhai, T. Unterthiner, M. Dehghani, M. Minderer, G. Heigold, S. Gelly, J. Uszkoreit, and N. Houlsby, “An Image is Worth 16x16 Words: Transformers for Image Recognition at Scale,” Oct. 2020.
  11. J. Hoffmann, S. Borgeaud, A. Mensch, E. Buchatskaya, T. Cai, E. Rutherford, D. d. L. Casas, L. A. Hendricks, J. Welbl, A. Clark, T. Hennigan, E. Noland, K. Millican, G. v. d. Driessche, B. Damoc, A. Guy, S. Osindero, K. Simonyan, E. Elsen, J. W. Rae, O. Vinyals, and L. Sifre, “Training Compute-Optimal Large Language Models,” Mar. 2022. arXiv:2203.15556 [cs].
  12. G. Verdon, M. Broughton, J. R. McClean, K. J. Sung, R. Babbush, Z. Jiang, H. Neven, and M. Mohseni, “Learning to learn with quantum neural networks via classical neural networks,” arXiv preprint arXiv:1907.05415, 2019.
  13. D. Kim and E.-G. Moon, “Preparation of entangled many-body states with machine learning,” arXiv preprint arXiv:2307.14627, 2023.
  14. Y. Yang, Z. Zhang, A. Wang, X. Xu, X. Wang, and Y. Li, “Maximising quantum-computing expressive power through randomised circuits,” arXiv preprint arXiv:2312.01947, 2023.
  15. T. Garipov, P. Izmailov, D. Podoprikhin, D. P. Vetrov, and A. G. Wilson, “Loss surfaces, mode connectivity, and fast ensembling of dnns,” Advances in neural information processing systems, vol. 31, 2018.
  16. Z. Allen-Zhu, Y. Li, and Z. Song, “A convergence theory for deep learning via over-parameterization,” in International conference on machine learning, pp. 242–252, PMLR, 2019.
  17. Y. Zhou, J. Yang, H. Zhang, Y. Liang, and V. Tarokh, “Sgd converges to global minimum in deep learning via star-convex path,” arXiv preprint arXiv:1901.00451, 2019.
  18. New York, NY: Springer US, 2020.
  19. Y.-h. Lam, Y. Abramov, R. S. Ananthula, J. M. Elward, L. R. Hilden, S. O. Nilsson Lill, P.-O. Norrby, A. Ramirez, E. C. Sherer, J. Mustakis, and G. J. Tanoury, “Applications of Quantum Chemistry in Pharmaceutical Process Development: Current State and Opportunities,” Organic Process Research & Development, vol. 24, pp. 1496–1507, Aug. 2020. Publisher: American Chemical Society.
  20. G. Agarwal, H. A. Doan, L. A. Robertson, L. Zhang, and R. S. Assary, “Discovery of Energy Storage Molecular Materials Using Quantum Chemistry-Guided Multiobjective Bayesian Optimization,” Chemistry of Materials, vol. 33, pp. 8133–8144, Oct. 2021. Publisher: American Chemical Society.
  21. V. Zaytsev, M. Groshev, I. Maltsev, A. Durova, and V. Shabaev, “Calculation of the moscovium ground-state energy by quantum algorithms,” arXiv preprint arXiv:2207.08255, 2022.
  22. B. T. Gard, L. Zhu, G. S. Barron, N. J. Mayhall, S. E. Economou, and E. Barnes, “Efficient symmetry-preserving state preparation circuits for the variational quantum eigensolver algorithm,” npj Quantum Information, vol. 6, no. 1, p. 10, 2020.
  23. K. M. Pelzer, L. Cheng, and L. A. Curtiss, “Effects of Functional Groups in Redox-Active Organic Molecules: A High-Throughput Screening Approach,” The Journal of Physical Chemistry C, vol. 121, pp. 237–245, Jan. 2017. Publisher: American Chemical Society.
  24. C. d. l. Cruz, A. Molina, N. Patil, E. Ventosa, R. Marcilla, and A. Mavrandonakis, “New insights into phenazine-based organic redox flow batteries by using high-throughput DFT modelling,” Sustainable Energy & Fuels, vol. 4, pp. 5513–5521, Oct. 2020. Publisher: The Royal Society of Chemistry.
  25. S. Lee, J. Lee, H. Zhai, Y. Tong, A. M. Dalzell, A. Kumar, P. Helms, J. Gray, Z.-H. Cui, W. Liu, M. Kastoryano, R. Babbush, J. Preskill, D. R. Reichman, E. T. Campbell, E. F. Valeev, L. Lin, and G. K.-L. Chan, “Evaluating the evidence for exponential quantum advantage in ground-state quantum chemistry,” Nature Communications, vol. 14, p. 1952, Apr. 2023.
  26. J. Ceroni, T. F. Stetina, M. Kieferova, C. O. Marrero, J. M. Arrazola, and N. Wiebe, “Generating Approximate Ground States of Molecules Using Quantum Machine Learning,” Jan. 2023. arXiv:2210.05489 [quant-ph].
  27. Z. Liang, J. Cheng, R. Yang, H. Ren, Z. Song, D. Wu, X. Qian, T. Li, and Y. Shi, “Unleashing the potential of llms for quantum computing: A study in quantum architecture design,” arXiv preprint arXiv:2307.08191, 2023.
  28. M. Krenn, J. Landgraf, T. Foesel, and F. Marquardt, “Artificial intelligence and machine learning for quantum technologies,” Physical Review A, vol. 107, no. 1, p. 010101, 2023.
  29. T. Jaouni, S. Arlt, C. Ruiz-Gonzalez, E. Karimi, X. Gu, and M. Krenn, “Deep quantum graph dreaming: Deciphering neural network insights into quantum experiments,” arXiv preprint arXiv:2309.07056, 2023.
  30. H. R. Grimsley, S. E. Economou, E. Barnes, and N. J. Mayhall, “An adaptive variational algorithm for exact molecular simulations on a quantum computer,” Nature communications, vol. 10, no. 1, p. 3007, 2019.
  31. C. N. Self, K. E. Khosla, A. W. R. Smith, F. Sauvage, P. D. Haynes, J. Knolle, F. Mintert, and M. S. Kim, “Variational quantum algorithm with information sharing,” npj Quantum Information, vol. 7, pp. 1–7, July 2021. Number: 1 Publisher: Nature Publishing Group.
  32. A. Cervera-Lierta, J. S. Kottmann, and A. Aspuru-Guzik, “Meta-variational quantum eigensolver: Learning energy profiles of parameterized hamiltonians for quantum simulation,” PRX Quantum, vol. 2, no. 2, p. 020329, 2021.
  33. Z. Qiao, A. S. Christensen, M. Welborn, F. R. Manby, A. Anandkumar, and T. F. Miller, “Informing geometric deep learning with electronic interactions to accelerate quantum chemistry,” Proceedings of the National Academy of Sciences, vol. 119, p. e2205221119, Aug. 2022. Publisher: Proceedings of the National Academy of Sciences.
  34. D. Khan, S. Heinen, and O. A. von Lilienfeld, “Kernel based quantum machine learning at record rate: Many-body distribution functionals as compact representations,” The Journal of Chemical Physics, vol. 159, p. 034106, July 2023.
  35. H. F. Trotter, “On the product of semi-groups of operators,” Proceedings of the American Mathematical Society, vol. 10, no. 4, pp. 545–551, 1959.
  36. The CUDA Quantum development team, “CUDA Quantum: An open-source programming model for heterogeneous quantum-classical workflows,” 2023. Version 0.5.0.
  37. Qiskit contributors, “Qiskit: An open-source framework for quantum computing,” 2023.
Citations (10)
View on Semantic Scholar

Summary

No one has generated a summary of this paper yet.

Sign Up to Summarize

Paper to Video (Beta)

No one has generated a video about this paper yet.

Sign Up to Generate All Videos Subscribe on YouTube

Whiteboard

No one has generated a whiteboard explanation for this paper yet.

Sign Up to Generate

Open Problems

We haven't generated a list of open problems mentioned in this paper yet.

Generate Now

Continue Learning

We haven't generated follow-up questions for this paper yet.

Generate Now

Collections

Sign up for free to add this paper to one or more collections.

Sign Up

Tweets

Sign up for free to view the 16 tweets with 6 likes about this paper.

Sign Up for Free