Related papers: Deep Learning-based FEA surrogate for sub-sea pressure vessel

Deep Learning-based FEA surrogate for sub-sea pressure vessel

URL: http://arxiv.org/abs/2206.03322v1
Date: Mon, 6 Jun 2022 00:47:10 GMT
Title: Deep Learning-based FEA surrogate for sub-sea pressure vessel
Authors: Harsh Vardhan, Janos Sztipanovits
Abstract summary: A pressure vessel contains electronics, power sources, and other sensors that can not be flooded. A traditional design approach for a pressure vessel design involves running multiple Finite Element Analysis (FEA) based simulations. Running these FEAs are computationally very costly for any optimization process. A better approach is the surrogate design with the goal of replacing FEA-based prediction with some learning-based regressor.
Score: 0.799536002595393
License: http://creativecommons.org/licenses/by/4.0/
Abstract: During the design process of an autonomous underwater vehicle (AUV), the pressure vessel has a critical role. The pressure vessel contains dry electronics, power sources, and other sensors that can not be flooded. A traditional design approach for a pressure vessel design involves running multiple Finite Element Analysis (FEA) based simulations and optimizing the design to find the best suitable design which meets the requirement. Running these FEAs are computationally very costly for any optimization process and it becomes difficult to run even hundreds of evaluation. In such a case, a better approach is the surrogate design with the goal of replacing FEA-based prediction with some learning-based regressor. Once the surrogate is trained for a class of problem, then the learned response surface can be used to analyze the stress effect without running the FEA for that class of problem. The challenge of creating a surrogate for a class of problems is data generation. Since the process is computationally costly, it is not possible to densely sample the design space and the learning response surface on sparse data set becomes difficult. During experimentation, we observed that a Deep Learning-based surrogate outperforms other regression models on such sparse data. In the present work, we are utilizing the Deep Learning-based model to replace the costly finite element analysis-based simulation process. By creating the surrogate we speed up the prediction on the other design much faster than direct Finite element Analysis. We also compared our DL-based surrogate with other classical Machine Learning (ML) based regression models( random forest and Gradient Boost regressor). We observed on the sparser data, the DL-based surrogate performs much better than other regression models.

Related papers

Machine learning surrogates for efficient hydrologic modeling: Insights from stochastic simulations of managed aquifer recharge [0.0]
We propose a hybrid modeling workflow for process-based hydrologic models and machine learning surrogate models. As a case study, we apply this workflow to simulations of variably saturated groundwater flow at a prospective managed aquifer recharge site. Our results demonstrate that ML surrogate models can achieve under 10% mean absolute percentage error and yield order-of-magnitude runtime savings.
arXiv Detail & Related papers (2024-07-30T15:24:27Z)
End-to-End Meta-Bayesian Optimisation with Transformer Neural Processes [52.818579746354665]
This paper proposes the first end-to-end differentiable meta-BO framework that generalises neural processes to learn acquisition functions via transformer architectures. We enable this end-to-end framework with reinforcement learning (RL) to tackle the lack of labelled acquisition data.
arXiv Detail & Related papers (2023-05-25T10:58:46Z)
Learning Controllable Adaptive Simulation for Multi-resolution Physics [86.8993558124143]
We introduce Learning controllable Adaptive simulation for Multi-resolution Physics (LAMP) as the first full deep learning-based surrogate model. LAMP consists of a Graph Neural Network (GNN) for learning the forward evolution, and a GNN-based actor-critic for learning the policy of spatial refinement and coarsening. We demonstrate that our LAMP outperforms state-of-the-art deep learning surrogate models, and can adaptively trade-off computation to improve long-term prediction error.
arXiv Detail & Related papers (2023-05-01T23:20:27Z)
Data efficient surrogate modeling for engineering design: Ensemble-free batch mode deep active learning for regression [0.6021787236982659]
We propose a simple and scalable approach for active learning that works in a student-teacher manner to train a surrogate model. By using this proposed approach, we are able to achieve the same level of surrogate accuracy as the other baselines like DBAL and Monte Carlo sampling.
arXiv Detail & Related papers (2022-11-16T02:31:57Z)
DeepAL for Regression Using $\epsilon$-weighted Hybrid Query Strategy [0.799536002595393]
We propose a novel sampling technique by combining the active learning (AL) method with Deep Learning (DL) We call this method $epsilon$-weighted hybrid query strategy ($epsilon$-HQS). During the empirical evaluation, better accuracy of the surrogate was observed in comparison to other methods of sample selection.
arXiv Detail & Related papers (2022-06-24T14:38:05Z)
Physics-informed machine learning with differentiable programming for heterogeneous underground reservoir pressure management [64.17887333976593]
Avoiding over-pressurization in subsurface reservoirs is critical for applications like CO2 sequestration and wastewater injection. Managing the pressures by controlling injection/extraction are challenging because of complex heterogeneity in the subsurface. We use differentiable programming with a full-physics model and machine learning to determine the fluid extraction rates that prevent over-pressurization.
arXiv Detail & Related papers (2022-06-21T20:38:13Z)
Conservative Objective Models for Effective Offline Model-Based Optimization [78.19085445065845]
Computational design problems arise in a number of settings, from synthetic biology to computer architectures. We propose a method that learns a model of the objective function that lower bounds the actual value of the ground-truth objective on out-of-distribution inputs. COMs are simple to implement and outperform a number of existing methods on a wide range of MBO problems.
arXiv Detail & Related papers (2021-07-14T17:55:28Z)
A Deep Neural Network Surrogate Modeling Benchmark for Temperature Field Prediction of Heat Source Layout [0.0]
Deep neural network (DNN) regression method is a feasible way for its good computation performance. This paper proposes a DNN based surrogate modeling task benchmark. Experiments are conducted with ten representative state-of-the-art DNN models.
arXiv Detail & Related papers (2021-03-20T13:26:21Z)
A Hypergradient Approach to Robust Regression without Correspondence [85.49775273716503]
We consider a variant of regression problem, where the correspondence between input and output data is not available. Most existing methods are only applicable when the sample size is small. We propose a new computational framework -- ROBOT -- for the shuffled regression problem.
arXiv Detail & Related papers (2020-11-30T21:47:38Z)
Surrogate Model For Field Optimization Using Beta-VAE Based Regression [0.0]
Oilfield development related decisions are made using reservoir simulation-based optimization study. Deep learning has been used in past to generate surrogates, but such models often fail to quantify prediction uncertainty. beta-VAE based regression is proposed to generate simulation surrogates for use in optimization workflow.
arXiv Detail & Related papers (2020-08-26T08:03:03Z)
AutoSimulate: (Quickly) Learning Synthetic Data Generation [70.82315853981838]
We propose an efficient alternative for optimal synthetic data generation based on a novel differentiable approximation of the objective. We demonstrate that the proposed method finds the optimal data distribution faster (up to $50times$), with significantly reduced training data generation (up to $30times$) and better accuracy ($+8.7%$) on real-world test datasets than previous methods.
arXiv Detail & Related papers (2020-08-16T11:36:11Z)

This list is automatically generated from the titles and abstracts of the papers in this site.