Improved Product-State Approximation Algorithms for Quantum Local Hamiltonians

Author Thiago Bergamaschi



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Thiago Bergamaschi
  • Department of Computer Science, University of California, Berkeley, CA, USA

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Thiago Bergamaschi. Improved Product-State Approximation Algorithms for Quantum Local Hamiltonians. In 50th International Colloquium on Automata, Languages, and Programming (ICALP 2023). Leibniz International Proceedings in Informatics (LIPIcs), Volume 261, pp. 20:1-20:18, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2023) https://doi.org/10.4230/LIPIcs.ICALP.2023.20

Abstract

The ground state energy and the free energy of Quantum Local Hamiltonians are fundamental quantities in quantum many-body physics, however, it is QMA-Hard to estimate them in general. In this paper, we develop new techniques to find classical, additive error product-state approximations for these quantities on certain families of Quantum k-Local Hamiltonians. Namely, those which are either dense, have low threshold rank, or are defined on a sparse graph that excludes a fixed minor, building on the methods and the systems studied by Brandão and Harrow, Gharibian and Kempe, and Bansal, Bravyi and Terhal.
We present two main technical contributions. First, we discuss a connection between product-state approximations of local Hamiltonians and combinatorial graph property testing. We develop a series of weak Szemerédi regularity lemmas for k-local Hamiltonians, built on those of Frieze and Kannan and others. We use them to develop constant time sampling algorithms, and to characterize the "vertex sample complexity" of the Local Hamiltonian problem, in an analog to a classical result by Alon, de la Vega, Kannan and Karpinski. Second, we build on the information-theoretic product-state approximation techniques by Brandão and Harrow, extending their results to the free energy and to an asymmetric graph setting. We leverage this structure to define families of algorithms for the free energy at low temperatures, and new algorithms for certain sparse graph families.

Subject Classification

ACM Subject Classification
  • Theory of computation → Quantum information theory
  • Theory of computation → Approximation algorithms analysis
Keywords
  • Approximation Algorithms
  • Quantum Information

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References

  1. Scott Aaronson. The quantum pcp manifesto, October 2006. URL: http://www.scottaaronson.com/blog/?p=139.
  2. Dorit Aharonov, Itai Arad, Zeph Landau, and Umesh V. Vazirani. The detectability lemma and quantum gap amplification. In STOC '09, 2009. Google Scholar
  3. Noga Alon, Wenceslas Fernandez de la Vega, Ravi Kannan, and Marek Karpinski. Random sampling and approximation of max-csp problems. Electron. Colloquium Comput. Complex., 2002. Google Scholar
  4. Gunnar Andersson and Lars Engebretsen. Property testers for dense constraint satisfaction programs on finite domains. Random Struct. Algorithms, 21:14-32, 2002. Google Scholar
  5. Anurag Anshu, David Gosset, and Karen J. Morenz. Beyond product state approximations for a quantum analogue of max cut. In TQC, 2020. Google Scholar
  6. Itai Arad. A note about a partial no-go theorem for quantum pcp. Quantum Inf. Comput., 11:1019-1027, 2011. Google Scholar
  7. Sanjeev Arora, David R. Karger, and Marek Karpinski. Polynomial time approximation schemes for dense instances of np-hard problems. Journal of Computer and System Sciences, 58:193-210, 1999. Google Scholar
  8. S. Baker. Approximation algorithms for np-complete problems on planar graphs. Journal of the ACM, 1994. Google Scholar
  9. Nikhil Bansal, Sergey Bravyi, and Barbara M. Terhal. Classical approximation schemes for the ground-state energy of quantum and classical ising spin hamiltonians on planar graphs. Quantum Inf. Comput., 9:701-720, 2009. Google Scholar
  10. Boaz Barak, Prasad Raghavendra, and David Steurer. Rounding semidefinite programming hierarchies via global correlation. 2011 IEEE 52nd Annual Symposium on Foundations of Computer Science, pages 472-481, 2011. Google Scholar
  11. Alexander I. Barvinok. Combinatorics and complexity of partition functions. In Algorithms and combinatorics, 2016. Google Scholar
  12. Anirban Basak and Sumit Mukherjee. Universality of the mean-field for the potts model. Probability Theory and Related Fields, 168:557-600, 2015. Google Scholar
  13. Thiago Bergamaschi. Simulated quantum annealing is efficient on the spike hamiltonian. arXiv:Quantum Physics, 2020. URL: https://arxiv.org/abs/2011.15094.
  14. Christian Borgs, Jennifer T. Chayes, László Miklós Lovász, Vera T. Sós, and Katalin Vesztergombi. Convergent sequences of dense graphs ii. multiway cuts and statistical physics. Annals of Mathematics, 176:151-219, 2012. Google Scholar
  15. Fernando G. S. L. Brandão and Aram Wettroth Harrow. Product-state approximations to quantum ground states. In STOC '13, 2013. Google Scholar
  16. Sergey Bravyi, Anirban Narayan Chowdhury, David Gosset, and Pawel Wocjan. On the complexity of quantum partition functions. arXiv, abs/2110.15466, 2021. URL: https://arxiv.org/abs/2110.15466.
  17. Sergey Bravyi and David Gosset. Polynomial-time classical simulation of quantum ferromagnets. Physical review letters, 119 10:100503, 2017. Google Scholar
  18. Sergey Bravyi, David Gosset, Robert Koenig, and Kristan Temme. Approximation algorithms for quantum many-body problems. Journal of Mathematical Physics, 2019. Google Scholar
  19. Brielin Brown, Steven T. Flammia, and Norbert Schuch. Computational difficulty of computing the density of states. Physical review letters, 107 4:040501, 2011. Google Scholar
  20. Elizabeth Crosson and Aram Wettroth Harrow. Rapid mixing of path integral monte carlo for 1d stoquastic hamiltonians. Quantum, 5:395, 2021. Google Scholar
  21. Erik D. Demaine, Mohammad Taghi Hajiaghayi, and Ken ichi Kawarabayashi. Algorithmic graph minor theory: Decomposition, approximation, and coloring. 46th Annual IEEE Symposium on Foundations of Computer Science (FOCS'05), pages 637-646, 2005. Google Scholar
  22. Alan M. Frieze and Ravi Kannan. Quick approximation to matrices and applications. Combinatorica, 19:175-220, 1999. Google Scholar
  23. Shayan Oveis Gharan and Luca Trevisan. A new regularity lemma and faster approximation algorithms for low threshold rank graphs. In APPROX-RANDOM, 2013. Google Scholar
  24. Sevag Gharibian and Julia Kempe. Approximation algorithms for qma-complete problems. 2011 IEEE 26th Annual Conference on Computational Complexity, pages 178-188, 2011. Google Scholar
  25. Sevag Gharibian and Ojas Parekh. Almost optimal classical approximation algorithms for a quantum generalization of max-cut. arXiv, abs/1909.08846, 2019. URL: https://arxiv.org/abs/1909.08846.
  26. Oded Goldreich, Shafi Goldwasser, and Dana Ron. Property testing and its connection to learning and approximation. Electron. Colloquium Comput. Complex., 3, 1998. Google Scholar
  27. Aram Wettroth Harrow, Saeed Adel Mehraban, and Mehdi Soleimanifar. Classical algorithms, correlation decay, and complex zeros of partition functions of quantum many-body systems. Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing, 2020. Google Scholar
  28. Aram Wettroth Harrow and Ashley Montanaro. Extremal eigenvalues of local hamiltonians. arXiv, abs/1507.00739, 2015. URL: https://arxiv.org/abs/1507.00739.
  29. Matthew B. Hastings. Trivial low energy states for commuting hamiltonians, and the quantum pcp conjecture. Quantum Inf. Comput., 13:393-429, 2013. Google Scholar
  30. Vishesh Jain, Frederic Koehler, and Elchanan Mossel. The mean-field approximation: Information inequalities, algorithms, and complexity. In COLT, 2018. Google Scholar
  31. Vishesh Jain, Frederic Koehler, and Elchanan Mossel. The vertex sample complexity of free energy is polynomial. In COLT, 2018. Google Scholar
  32. Vishesh Jain, Frederic Koehler, and Andrej Risteski. Mean-field approximation, convex hierarchies, and the optimality of correlation rounding: a unified perspective. Proceedings of the 51st Annual ACM SIGACT Symposium on Theory of Computing, 2019. Google Scholar
  33. Robbie King. An improved approximation algorithm for quantum max-cut. arXiv, abs/2209.02589, 2022. URL: https://arxiv.org/abs/2209.02589.
  34. Alexei Y. Kitaev, Alexander Shen, and Mikhail N. Vyalyi. Classical and quantum computation. In Graduate studies in mathematics, 2002. Google Scholar
  35. Eun Jee Lee. Optimizing quantum circuit parameters via sdp. In International Symposium on Algorithms and Computation, 2022. Google Scholar
  36. Ojas Parekh and Kevin Thompson. Application of the level-2 quantum lasserre hierarchy in quantum approximation algorithms. In ICALP, 2021. Google Scholar
  37. Ojas Parekh and Kevin Thompson. Beating random assignment for approximating quantum 2-local hamiltonian problems. arXiv, abs/2012.12347, 2021. URL: https://arxiv.org/abs/2012.12347.
  38. Ojas Parekh and Kevin Thompson. An optimal product-state approximation for 2-local quantum hamiltonians with positive terms. arXiv, abs/2206.08342, 2022. URL: https://arxiv.org/abs/2206.08342.
  39. Prasad Raghavendra and Ning Tan. Approximating csps with global cardinality constraints using sdp hierarchies. In SODA, 2012. Google Scholar
  40. Andrej Risteski. How to calculate partition functions using convex programming hierarchies: provable bounds for variational methods. arXiv, abs/1607.03183, 2016. URL: https://arxiv.org/abs/1607.03183.
  41. Neil Robertson and Paul D. Seymour. Graph minors. ii. algorithmic aspects of tree-width. J. Algorithms, 7:309-322, 1986. Google Scholar
  42. Endre Szemerédi. Regular partitions of graphs. Colloq. Internat. CNRS, 260, 1975. Google Scholar
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