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Distinguishing Calabi-Yau Topology using Machine Learning (2408.05076v1)

Published 9 Aug 2024 in math.AG

Abstract: While the earliest applications of AI methodologies to pure mathematics and theoretical physics began with the study of Hodge numbers of Calabi-Yau manifolds, the topology type of such manifold also crucially depend on their intersection theory. Continuing the paradigm of machine learning algebraic geometry, we here investigate the triple intersection numbers, focusing on certain divisibility invariants constructed therefrom, using the Inception convolutional neural network. We find $\sim90\%$ accuracies in prediction in a standard fivefold cross-validation, signifying that more sophisticated tasks of identification of manifold topologies can also be performed by machine learning.

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References (52)
  1. Machine Learning meets Number Theory: The Data Science of Birch-Swinnerton-Dyer. 11 2019, 1911.02008.
  2. Fibrations in cicy threefolds. Journal of High Energy Physics, 2017(10):1–63, 2017.
  3. Moduli-dependent Calabi-Yau and SU(3)-structure metrics from Machine Learning. JHEP, 05:013, 2021, 2012.04656.
  4. Lectures on Numerical and Machine Learning Methods for Approximating Ricci-flat Calabi-Yau Metrics. 12 2023, 2312.17125.
  5. Heterotic Compactification, An Algorithmic Approach. JHEP, 07:049, 2007, hep-th/0702210.
  6. Numerical spectra of the Laplacian for line bundles on Calabi-Yau hypersurfaces. JHEP, 07:164, 2023, 2305.08901.
  7. Machine Learning Calabi–Yau Metrics. Fortsch. Phys., 68(9):2000068, 2020, 1910.08605.
  8. Machine Learning Algebraic Geometry for Physics. 4 2022, 2204.10334.
  9. Machine learning Calabi-Yau hypersurfaces. Phys. Rev. D, 105(6):066002, 2022, 2112.06350.
  10. Machine learning cicy threefolds. Physics Letters B, 785:65–72, 2018.
  11. Getting CICY High. Phys. Lett. B, 795:700–706, 2019, 1903.03113.
  12. Eugenio Calabi. On kähler manifolds with vanishing canonical class. In Algebraic geometry and topology. A symposium in honor of S. Lefschetz, volume 12, pages 78–89, 1957.
  13. Complete intersection calabi-yau manifolds. Nuclear Physics B, 298(3):493–525, 1988.
  14. Vacuum configurations for superstrings. Nuclear Physics B, 258:46–74, 1985.
  15. Machine Learning in the String Landscape. JHEP, 09:157, 2017, 1707.00655.
  16. Formulae for Line Bundle Cohomology on Calabi-Yau Threefolds. Fortsch. Phys., 67(12):1900084, 2019, 1808.09992.
  17. Disentangling a deep learned volume formula. JHEP, 06:040, 2021, 2012.03955.
  18. Machine learning on generalized complete intersection Calabi-Yau manifolds. Phys. Rev. D, 107(8):086004, 2023, 2209.10157.
  19. Advancing mathematics by guiding human intuition with AI. Nature, 600(7887):70–74, 2021.
  20. Numerical Calabi-Yau metrics from holomorphic networks. 12 2020, 2012.04797.
  21. Matthew England. Machine Learning for Mathematical Software, page 165–174. Springer International Publishing, 2018.
  22. Inception neural network for complete intersection calabi–yau 3-folds. Machine Learning: Science and Technology, 2(2):02LT03, 2021.
  23. Machine learning for complete intersection Calabi-Yau manifolds: a methodological study. Phys. Rev. D, 103(12):126014, 2021, 2007.15706.
  24. Deep learning complete intersection Calabi-Yau manifolds. 11 2023, 2311.11847.
  25. Deep multi-task mining Calabi–Yau four-folds. Mach. Learn. Sci. Tech., 3(1):015006, 2022, 2108.02221.
  26. M Gagnon and Q Ho-Kim. An exhaustive list of complete intersection calabi-yau manifolds. Modern Physics Letters A, 9(24):2235–2243, 1994.
  27. All the hodge numbers for all calabi-yau complete intersections. Classical and Quantum Gravity, 6(2):105, 1989.
  28. Rigor with machine learning from field theory to the poincaré conjecture. Nature Reviews Physics, pages 1–10, 2024.
  29. Learning to Unknot. Mach. Learn. Sci. Tech., 2(2):025035, 2021, 2010.16263.
  30. Yang-Hui He. Deep-Learning the Landscape. Phys. Lett. B, 774:564–568, 6 2017, 1706.02714.
  31. Yang-Hui He. The Calabi–Yau Landscape: From Geometry, to Physics, to Machine Learning. Lecture Notes in Mathematics. Springer-Nature, 5 2018, 1812.02893.
  32. Yang-Hui He. Machine-Learning Mathematical Structures. 2021, 2101.06317.
  33. Yang-Hui He. A Triumvirate of AI Driven Theoretical Discovery. 5 2024, 2405.19973.
  34. Can AI make genuine theoretical discoveries? Nature, 625(7994):241–241, 2024.
  35. Learning Algebraic Structures: Preliminary Investigations. 5 2019, 1905.02263.
  36. Murmurations of elliptic curves . 4 2022, 2204.10140.
  37. Distinguishing elliptic fibrations with AI. Phys. Lett. B, 798:134889, 2019, 1904.08530.
  38. Machine learning calabi-yau four-folds. Physics Letters B, 815:136139, 2021.
  39. Graph Laplacians, Riemannian Manifolds and their Machine-Learning. 6 2020, 2006.16619.
  40. Calabi-Yau four-, five-, sixfolds as Pwn hypersurfaces: Machine learning, approximation, and generation. Phys. Rev. D, 109(10):106006, 2024, 2311.17146.
  41. Tristan Hubsch. Calabi-Yau manifolds: A Bestiary for physicists. World scientific, 1992.
  42. Identifying equivalent Calabi–Yau topologies: A discrete challenge from math and physics for machine learning. In Nankai Symposium on Mathematical Dialogues: In celebration of S.S.Chern’s 110th anniversary, 2 2022, 2202.07590.
  43. Kaniba Mady Keita. On Machine Learning Complete Intersection Calabi-Yau 3-folds. 4 2024, 2404.11710.
  44. Machine Learning of Calabi-Yau Volumes. Phys. Rev. D, 96(6):066014, 2017, 1706.03346.
  45. Deep learning for symbolic mathematics. CoRR, abs/1912.01412, 2019, 1912.01412.
  46. The dna of calabi-yau hypersurfaces, 2024, 2405.08871.
  47. Learning selection strategies in buchberger’s algorithm. In International Conference on Machine Learning, pages 7575–7585. PMLR, 2020.
  48. Fabian Ruehle. Evolving neural networks with genetic algorithms to study the String Landscape. JHEP, 08:038, 2017, 1706.07024.
  49. Fabian Ruehle. Data science applications to string theory. Phys. Rept., 839:1–117, 2020.
  50. Rethinking the inception architecture for computer vision. In Proceedings of the IEEE conference on computer vision and pattern recognition, pages 2818–2826, 2016.
  51. Charles Terence Clegg Wall. Classification problems in differential topology. v: On certain 6-manifolds. Inventiones mathematicae, 1(4):355–374, 1966.
  52. Shing-Tung Yau. Calabi’s conjecture and some new results in algebraic geometry. Proceedings of the National Academy of Sciences, 74(5):1798–1799, 1977.

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  1. Finiteness of Calabi–Yau topological types in any complex dimension
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