Papers
Topics
Authors
Recent
Gemini 2.5 Flash
Gemini 2.5 Flash
119 tokens/sec
GPT-4o
56 tokens/sec
Gemini 2.5 Pro Pro
43 tokens/sec
o3 Pro
6 tokens/sec
GPT-4.1 Pro
47 tokens/sec
DeepSeek R1 via Azure Pro
28 tokens/sec
2000 character limit reached

Evaluation of machine learning architectures on the quantification of epistemic and aleatoric uncertainties in complex dynamical systems (2306.15159v1)

Published 27 Jun 2023 in stat.ML, cs.LG, and math.DS

Abstract: Machine learning methods for the construction of data-driven reduced order model models are used in an increasing variety of engineering domains, especially as a supplement to expensive computational fluid dynamics for design problems. An important check on the reliability of surrogate models is Uncertainty Quantification (UQ), a self assessed estimate of the model error. Accurate UQ allows for cost savings by reducing both the required size of training data sets and the required safety factors, while poor UQ prevents users from confidently relying on model predictions. We examine several machine learning techniques, including both Gaussian processes and a family UQ-augmented neural networks: Ensemble neural networks (ENN), Bayesian neural networks (BNN), Dropout neural networks (D-NN), and Gaussian neural networks (G-NN). We evaluate UQ accuracy (distinct from model accuracy) using two metrics: the distribution of normalized residuals on validation data, and the distribution of estimated uncertainties. We apply these metrics to two model data sets, representative of complex dynamical systems: an ocean engineering problem in which a ship traverses irregular wave episodes, and a dispersive wave turbulence system with extreme events, the Majda-McLaughlin-Tabak model. We present conclusions concerning model architecture and hyperparameter tuning.

Definition Search Book Streamline Icon: https://streamlinehq.com
References (59)
  1. A review of uncertainty quantification in deep learning: Techniques, applications and challenges. Information Fusion, 76:243–297.
  2. Personalizing activity recognition models through quantifying different types of uncertainty using wearable sensors. IEEE Transactions on Biomedical Engineering, 67(9):2530–2541.
  3. A multi-fidelity framework and uncertainty quantification for sea surface temperature in the Massachusetts and Cape Cod Bays. Earth and Space Science, 7.
  4. On the statistical formalism of uncertainty quantification. Annual Review of Statistics and Its Application, 6(1):433–460.
  5. Model Reduction And Neural Networks For Parametric PDEs. The SMAI journal of computational mathematics, 7:121–157.
  6. Bayesian optimization with output-weighted optimal sampling. Journal of Computational Physics, 425:109901.
  7. Output-weighted optimal sampling for Bayesian experimental design and uncertainty quantification. SIAM/ASA Journal on Uncertainty Quantification, 9(2):564–592.
  8. Variational inference: A review for statisticians. Journal of the American Statistical Association, 112(518):859–877.
  9. Weight uncertainty in neural network. In International conference on machine learning, pages 1613–1622. PMLR.
  10. Adversarial examples, uncertainty, and transfer testing robustness in gaussian process hybrid deep networks.
  11. Convergence of sparse variational inference in gaussian processes regression. Journal of Machine Learning Research, 21(131):1–63.
  12. Dispersive wave turbulence in one dimension. Physica D: Nonlinear Phenomena, 152-153:551–572.
  13. Manifold Gaussian Processes for regression. In 2016 International Joint Conference on Neural Networks (IJCNN), pages 3338–3345.
  14. Real-time reconstruction of 3d ocean temperature fields from reanalysis data and satellite and buoy surface measurements. Submitted.
  15. Uncertainty quantification of turbulent systems via physically consistent and data-informed reduced-order models. Physics of Fluids, 34(7):075120.
  16. Deep Gaussian processes. In Carvalho, C. M. and Ravikumar, P., editors, Proceedings of the Sixteenth International Conference on Artificial Intelligence and Statistics, volume 31 of Proceedings of Machine Learning Research, pages 207–215, Scottsdale, Arizona, USA. PMLR.
  17. E. Pickering, T. S. (2022). Information fomo: The unhealthy fear of missing out on information. a method for removing misleading data for healthier models. Submitted.
  18. Dropout as a Bayesian approximation: Representing model uncertainty in deep learning. In international conference on machine learning, pages 1050–1059. PMLR.
  19. Genton, M. G. (2002). Classes of kernels for machine learning: A statistics perspective. J. Mach. Learn. Res., 2:299–312.
  20. Bayesian Neural Networks: An Introduction and Survey, pages 45–87. Springer International Publishing, Cham.
  21. Sequential bayesian experimental design for estimation of extreme-event probability in stochastic input-to-response systems. Computer Methods in Applied Mechanics and Engineering, 395:114979.
  22. Statistical modeling of fully nonlinear hydrodynamic loads on offshore wind turbine foundations using wave episodes and targeted cfd simulations through active sampling.
  23. Machine learning predictors of extreme events occurring in complex dynamical systems. Entropy, 21(925).
  24. Wave episode based gaussian process regression for extreme event statistics in ship dynamics: Between the scylla of karhunen–loève convergence and the charybdis of transient features. Ocean Engineering, 266:112633.
  25. Measurements of wind-wave growth and swell decay during the Joint North Sea Wave Project (JONSWAP). Deut. Hydrogr. Z., 8:1–95.
  26. Scalable Variational Gaussian Process Classification. In Lebanon, G. and Vishwanathan, S. V. N., editors, Proceedings of the Eighteenth International Conference on Artificial Intelligence and Statistics, volume 38 of Proceedings of Machine Learning Research, pages 351–360, San Diego, California, USA. PMLR.
  27. Aleatoric and epistemic uncertainty in machine learning: an introduction to concepts and methods. Machine Learning, 110.
  28. Hands-on bayesian neural networks—a tutorial for deep learning users. IEEE Computational Intelligence Magazine, 17(2):29–48.
  29. Empirical study of mc-dropout in various astronomical observing conditions. In Proceedings of the IEEE/CVF Conference on Computer Vision and Pattern Recognition (CVPR) Workshops.
  30. On universal approximation and error bounds for fourier neural operators. Journal of Machine Learning Research, 22:Art–No.
  31. Recent hydrodynamic tool development and validation for motions and slam loads on ocean-going high-speed vessels.
  32. Numerical simulation and validation study of wetdeck slamming on high speed catamaran. International Conference on Numerical Ship Hydrodynamics [9th].
  33. Numerical simulations of surface effect ship in waves. In Proceedings of the 2010 Conference on Grand Challenges in Modeling & Simulation, GCMS ’10, page 414–421, Vista, CA. Society for Modeling & Simulation International.
  34. A comprehensive and fair comparison of two neural operators (with practical extensions) based on fair data. Computer Methods in Applied Mechanics and Engineering, 393:114778.
  35. A one-dimensional model for dispersive wave turbulence. Journal of Nonlinear Science, 7:9–44.
  36. Sequential sampling strategy for extreme event statistics in nonlinear dynamical systems. Proceedings of the National Academy of Sciences, 115(44):11138–11143.
  37. Murphy, K. P. (2022). Probabilistic Machine Learning: An introduction. MIT Press.
  38. Global inducing point variational posteriors for bayesian neural networks and deep gaussian processes. In ICML.
  39. The promises and pitfalls of deep kernel learning. In de Campos, C. and Maathuis, M. H., editors, Proceedings of the Thirty-Seventh Conference on Uncertainty in Artificial Intelligence, volume 161 of Proceedings of Machine Learning Research, pages 1206–1216. PMLR.
  40. Multi-fidelity modelling via recursive co-kriging and Gaussian–Markov random fields. Proceedings. Mathematical, physical, and engineering sciences.
  41. Discovering and forecasting extreme events via active learning in neural operators. Nature Computational Science, 2:823–833.
  42. Uncertainty quantification in scientific machine learning: Methods, metrics, and comparisons. Journal of Computational Physics, 477:111902.
  43. Gaussian Processes for Machine Learning. Adaptive Computation and Machine Learning. MIT Press, Cambridge, MA, USA.
  44. Weak turbulence and collapses in the Majda–Mclaughlin–Tabak equation: Fluxes in wavenumber and in amplitude space. Physica D, (204):188–203.
  45. Last layer marginal likelihood for invariance learning. In Camps-Valls, G., Ruiz, F. J. R., and Valera, I., editors, Proceedings of The 25th International Conference on Artificial Intelligence and Statistics, volume 151 of Proceedings of Machine Learning Research, pages 3542–3555. PMLR.
  46. Sclavounos, P. D. (2012). Karhunen–Loève representation of stochastic ocean waves. Proceedings of the Royal Society A, 468(2145):2574–2594.
  47. Understanding Machine Learning - From Theory to Algorithms. Cambridge University Press.
  48. Nonlinear time domain simulation technology for seakeeping and wave-load analysis for modern ship design. Transactions - Society of Naval Architects and Marine Engineers, 111:557–583.
  49. Dropout: A simple way to prevent neural networks from overfitting. Journal of Machine Learning Research, 15(56):1929–1958.
  50. Marginal likelihood gradient for Bayesian neural networks. In Third Symposium on Advances in Approximate Bayesian Inference.
  51. Improving deterministic uncertainty estimation in deep learning for classification and regression. CoRR, abs/2102.11409.
  52. Uncertainty estimation using a single deep deterministic neural network. In III, H. D. and Singh, A., editors, Proceedings of the 37th International Conference on Machine Learning, volume 119 of Proceedings of Machine Learning Research, pages 9690–9700. PMLR.
  53. Aleatoric uncertainty estimation with test-time augmentation for medical image segmentation with convolutional neural networks. Neurocomputing, 338:34–45.
  54. Will Cousins, T. P. S. (2014). Quantification and prediction of extreme events in a one-dimensional nonlinear dispersive wave model. Physica D, (280-281):48–58.
  55. Kernel interpolation for scalable structured Gaussian Processes (KISS-GP). In Bach, F. and Blei, D., editors, Proceedings of the 32nd International Conference on Machine Learning, volume 37 of Proceedings of Machine Learning Research, pages 1775–1784, Lille, France. PMLR.
  56. Output-weighted sampling for multi-armed bandits with extreme payoffs. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences, 478(2260):20210781.
  57. One-dimensional wave turbulence. Physics Reports, 398(1):1–65.
  58. Wave turbulence in one-dimensional models. Physica D: Nonlinear Phenomena, 152-153:573–619. Advances in Nonlinear Mathematics and Science: A Special Issue to Honor Vladimir Zakharov.
  59. NeuralUQ: A comprehensive library for uncertainty quantification in neural differential equations and operators. arXiv preprint arXiv:2208.11866.
User Edit Pencil Streamline Icon: https://streamlinehq.com
Authors (3)
  1. Stephen Guth (3 papers)
  2. Alireza Mojahed (5 papers)
  3. Themistoklis P. Sapsis (40 papers)
Citations (1)
View on Semantic Scholar

Summary

We haven't generated a summary for this paper yet.

Ai Sparkles Streamline Icon: https://streamlinehq.com Summarize Now