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Learning to control non-equilibrium dynamics using local imperfect gradients (2404.03798v1)

Published 4 Apr 2024 in cond-mat.stat-mech, cond-mat.dis-nn, and cond-mat.soft

Abstract: Standard approaches to controlling dynamical systems involve biologically implausible steps such as backpropagation of errors or intermediate model-based system representations. Recent advances in machine learning have shown that "imperfect" feedback of errors during training can yield test performance that is similar to using full backpropagated errors, provided that the two error signals are at least somewhat aligned. Inspired by such methods, we introduce an iterative, spatiotemporally local protocol to learn driving forces and control non-equilibrium dynamical systems using imperfect feedback signals. We present numerical experiments and theoretical justification for several examples. For systems in conservative force fields that are driven by external time-dependent protocols, our update rules resemble a dynamical version of contrastive divergence. We appeal to linear response theory to establish that our imperfect update rules are locally convergent for these conservative systems. For systems evolving under non-conservative dynamics, we derive a new theoretical result that makes possible the control of non-equilibrium steady-state probabilities through simple local update rules. Finally, we show that similar local update rules can also solve dynamical control problems for non-conservative systems, and we illustrate this in the non-trivial example of active nematics. Our updates allow learning spatiotemporal activity fields that pull topological defects along desired trajectories in the active nematic fluid. These imperfect feedback methods are information efficient and in principle biologically plausible, and they can help extend recent methods of decentralized training for physical materials into dynamical settings.

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References (72)
  1. Deep learning. nature, 521(7553):436–444, 2015.
  2. Backpropagation and the brain. Nature Reviews Neuroscience, 21(6):335–346, 2020.
  3. Learning without neurons in physical systems. Annual Review of Condensed Matter Physics, 14:417–441, 2023.
  4. Random synaptic feedback weights support error backpropagation for deep learning. Nature communications, 7(1):13276, 2016.
  5. Deep physical neural networks trained with backpropagation. Nature, 601(7894):549–555, 2022.
  6. Continual learning of multiple memories in mechanical networks. Physical Review X, 10(3):031044, 2020.
  7. Supervised learning in physical networks: From machine learning to learning machines. Physical Review X, 11(2):021045, 2021.
  8. Demonstration of decentralized physics-driven learning. Physical Review Applied, 18(1):014040, 2022.
  9. Equilibrium propagation: Bridging the gap between energy-based models and backpropagation. Frontiers in computational neuroscience, 11:24, 2017.
  10. Extending the framework of equilibrium propagation to general dynamics. 2018.
  11. Physical learning beyond the quasistatic limit. Physical Review Research, 4(2):L022037, 2022.
  12. John Bechhoefer. Control theory for physicists. Cambridge University Press, 2021.
  13. Optimal transport and control of active drops. Proceedings of the National Academy of Sciences, 119(35):e2121985119, 2022.
  14. Geometric approach to optimal nonequilibrium control: Minimizing dissipation in nanomagnetic spin systems. Physical Review E, 95(1):012148, 2017.
  15. Controlling the speed and trajectory of evolution with counterdiabatic driving. Nature Physics, 17(1):135–142, 2021.
  16. Unified, geometric framework for nonequilibrium protocol optimization. Physical Review Letters, 130(10):107101, 2023.
  17. Near-optimal protocols in complex nonequilibrium transformations. Proceedings of the National Academy of Sciences, 113(37):10263–10268, 2016.
  18. Variational control forces for enhanced sampling of nonequilibrium molecular dynamics simulations. The Journal of chemical physics, 151(24), 2019.
  19. Optimal finite-time processes in stochastic thermodynamics. Physical review letters, 98(10):108301, 2007.
  20. Phase transition in protocols minimizing work fluctuations. Physical review letters, 120(18):180605, 2018.
  21. Active matter under control: Insights from response theory. Physical Review X, 14(1):011012, 2024.
  22. Optimal control of nonequilibrium systems through automatic differentiation. Physical Review X, 13(4):041032, 2023.
  23. Probing the theoretical and computational limits of dissipative design. The Journal of Chemical Physics, 155(19), 2021.
  24. Learning to control active matter. Physical Review Research, 3(3):033291, 2021.
  25. Physics of smart active matter: integrating active matter and control to gain insights into living systems. Soft Matter, 2023.
  26. Directed aging, memory, and nature’s greed. Science advances, 5(12):eaax4215, 2019.
  27. Spatiotemporal control of active topological defects. arXiv preprint arXiv:2212.00666, 2022.
  28. How a well-adapting immune system remembers. Proceedings of the National Academy of Sciences, 116(18):8815–8823, 2019.
  29. Learning and organization of memory for evolving patterns. Physical Review X, 12(2):021063, 2022.
  30. Variational design principles for nonequilibrium colloidal assembly. The Journal of chemical physics, 154(1), 2021.
  31. Dissipation and lag in irreversible processes. Europhysics Letters, 87(6):60005, 2009.
  32. Numerical optimization. Springer, 1999.
  33. WT Góźdź and G Gompper. Shape transformations of two-component membranes under weak tension. Europhysics Letters, 55(4):587, 2001.
  34. Calculation of free energies in fluid membranes subject to heterogeneous curvature fields. Physical Review E, 80(1):011925, 2009.
  35. How proteins produce cellular membrane curvature. Nature reviews Molecular cell biology, 7(1):9–19, 2006.
  36. Harvey F Lodish. Molecular cell biology. Macmillan, 2008.
  37. Universal thermodynamic bounds on nonequilibrium response with biochemical applications. Physical Review X, 10(1):011066, 2020.
  38. Topologically constrained fluctuations and thermodynamics regulate nonequilibrium response. Phys. Rev. E, 108:044113, Oct 2023.
  39. Active nematics. Nature communications, 9(1):3246, 2018.
  40. Hydrodynamics of soft active matter. Reviews of modern physics, 85(3):1143, 2013.
  41. The actin cytoskeleton as an active adaptive material. Annual review of condensed matter physics, 11:421–439, 2020.
  42. Orientational order of motile defects in active nematics. Nature materials, 14(11):1110–1115, 2015.
  43. Topological defects promote layer formation in myxococcus xanthus colonies. Nature Physics, 17(2):211–215, 2021.
  44. Emergence of active nematics in chaining bacterial biofilms. Nature communications, 10(1):2285, 2019.
  45. Topological defects in the nematic order of actin fibres as organization centres of hydra morphogenesis. Nature Physics, 17(2):251–259, 2021.
  46. Integer topological defects organize stresses driving tissue morphogenesis. Nature materials, 21(5):588–597, 2022.
  47. Topological active matter. Nature Reviews Physics, 4(6):380–398, 2022.
  48. Dislocation reactions, grain boundaries, and irreversibility in two-dimensional lattices using topological tweezers. Proceedings of the National Academy of Sciences, 110(39):15544–15548, 2013.
  49. Disordered actomyosin networks are sufficient to produce cooperative and telescopic contractility. Nature communications, 7(1):12615, 2016.
  50. Spatiotemporal control of liquid crystal structure and dynamics through activity patterning. Nature materials, 20(6):875–882, 2021.
  51. Spatio-temporal patterning of extensile active stresses in microtubule-based active fluids. PNAS nexus, 2(5):pgad130, 2023.
  52. Shining a light on rhoa: Optical control of cell contractility. The International Journal of Biochemistry & Cell Biology, 161:106442, 2023.
  53. Simulating structured fluids with tensorial viscoelasticity. The Journal of Chemical Physics, 158(5), 2023.
  54. Signatures of odd dynamics in viscoelastic systems: From spatiotemporal pattern formation to odd rheology. arXiv preprint arXiv:2210.01159, 2022.
  55. Motor crosslinking augments elasticity in active nematics. Soft Matter, 2024.
  56. Optimal control of active nematics. Physical review letters, 125(17):178005, 2020.
  57. Exact coherent structures and phase space geometry of preturbulent 2d active nematic channel flow. Physical Review Letters, 128(2):028003, 2022.
  58. Reinforcement learning: An introduction. MIT press, 2018.
  59. Deterministic policy gradient algorithms. In International conference on machine learning, pages 387–395. Pmlr, 2014.
  60. On contrastive divergence learning. In International workshop on artificial intelligence and statistics, pages 33–40. PMLR, 2005.
  61. Projection onto a simplex. arXiv preprint arXiv:1101.6081, 2011.
  62. Fluctuations and irreversible processes. Physical Review, 91(6):1505, 1953.
  63. Juan MR Parrondo. Reversible ratchets as brownian particles in an adiabatically changing periodic potential. Physical Review E, 57(6):7297, 1998.
  64. Shortcuts to adiabatic pumping in classical stochastic systems. Physical Review Letters, 124(15):150603, 2020.
  65. Thermodynamic metrics and optimal paths. Physical review letters, 108(19):190602, 2012.
  66. Geometry of thermodynamic control. Physical Review E, 86(4):041148, 2012.
  67. John G Kirkwood. The statistical mechanical theory of transport processes I. General theory. The Journal of Chemical Physics, 14(3):180–201, 1946.
  68. Gavin E Crooks. Measuring thermodynamic length. Physical Review Letters, 99(10):100602, 2007.
  69. O Mazonka and C Jarzynski. Exactly solvable model illustrating far-from-equilibrium predictions. arXiv preprint cond-mat/9912121, 1999.
  70. R Van Zon and EGD Cohen. Stationary and transient work-fluctuation theorems for a dragged Brownian particle. Physical Review E, 67(4):046102, 2003.
  71. Nonequilibrium response for markov jump processes: Exact results and tight bounds. Physical Review Letters, 132(3):037101, 2024.
  72. Fine structure of the topological defect cores studied for disclinations in lyotropic chromonic liquid crystals. Nature Communications, 8(1):14974, 2017.
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