Related papers: Hybrid deep learning architecture for general disruption prediction across tokamaks

Hybrid deep learning architecture for general disruption prediction across tokamaks

URL: http://arxiv.org/abs/2007.01401v4
Date: Thu, 26 Nov 2020 07:54:35 GMT
Title: Hybrid deep learning architecture for general disruption prediction across tokamaks
Authors: J.X. Zhu, C. Rea, K. Montes, R.S. Granetz, R. Sweeney, R.A. Tinguely
Abstract summary: We present a new deep learning disruption prediction algorithm based on important findings from explorative data analysis. The new algorithm achieves high predictive accuracy on the C-Mod, DIII-D and EAST tokamaks.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: In this paper, we present a new deep learning disruption prediction algorithm based on important findings from explorative data analysis which effectively allows knowledge transfer from existing devices to new ones, thereby predicting disruptions using very limited disruptive data from the new devices. The explorative data analysis conducted via unsupervised clustering techniques confirms that time-sequence data are much better separators of disruptive and non-disruptive behavior than the instantaneous plasma state data with further advantageous implications for a sequence-based predictor. Based on such important findings, we have designed a new algorithm for multi-machine disruption prediction that achieves high predictive accuracy on the C-Mod (AUC=0.801), DIII-D (AUC=0.947) and EAST (AUC=0.973) tokamaks with limited hyperparameter tuning. Through numerical experiments, we show that boosted accuracy (AUC=0.959) is achieved on EAST predictions by including in the training only 20 disruptive discharges, thousands of non-disruptive discharges from EAST, and combining this with more than a thousand discharges from DIII-D and C-Mod. The improvement of predictive ability obtained by combining disruptive data from other devices is found to be true for all permutations of the three devices. Furthermore, by comparing the predictive performance of each individual numerical experiment, we find that non-disruptive data are machine-specific while disruptive data from multiple devices contain device-independent knowledge that can be used to inform predictions for disruptions occurring on a new device.

Related papers

Revisiting Multivariate Time Series Forecasting with Missing Values [65.30332997607141]
Missing values are common in real-world time series.<n>Current approaches have developed an imputation-then-prediction framework that uses imputation modules to fill in missing values, followed by forecasting on the imputed data.<n>This framework overlooks a critical issue: there is no ground truth for the missing values, making the imputation process susceptible to errors that can degrade prediction accuracy.<n>We introduce Consistency-Regularized Information Bottleneck (CRIB), a novel framework built on the Information Bottleneck principle.
arXiv Detail & Related papers (2025-09-27T20:57:48Z)
An Investigation on Machine Learning Predictive Accuracy Improvement and Uncertainty Reduction using VAE-based Data Augmentation [2.517043342442487]
Deep generative learning uses certain ML models to learn the underlying distribution of existing data and generate synthetic samples that resemble the real data. In this study, our objective is to evaluate the effectiveness of data augmentation using variational autoencoder (VAE)-based deep generative models. We investigated whether the data augmentation leads to improved accuracy in the predictions of a deep neural network (DNN) model trained using the augmented data.
arXiv Detail & Related papers (2024-10-24T18:15:48Z)
Prediction-Powered Inference [68.97619568620709]
Prediction-powered inference is a framework for performing valid statistical inference when an experimental dataset is supplemented with predictions from a machine-learning system. The framework yields simple algorithms for computing provably valid confidence intervals for quantities such as means, quantiles, and linear and logistic regression coefficients. Prediction-powered inference could enable researchers to draw valid and more data-efficient conclusions using machine learning.
arXiv Detail & Related papers (2023-01-23T18:59:28Z)
A Robust and Explainable Data-Driven Anomaly Detection Approach For Power Electronics [56.86150790999639]
We present two anomaly detection and classification approaches, namely the Matrix Profile algorithm and anomaly transformer. The Matrix Profile algorithm is shown to be well suited as a generalizable approach for detecting real-time anomalies in streaming time-series data. A series of custom filters is created and added to the detector to tune its sensitivity, recall, and detection accuracy.
arXiv Detail & Related papers (2022-09-23T06:09:35Z)
Uncertainty aware anomaly detection to predict errant beam pulses in the SNS accelerator [47.187609203210705]
We describe the application of an uncertainty aware Machine Learning method, the Siamese neural network model, to predictupcoming errant beam pulses. By predicting theupcoming failure, we can stop the accelerator before damage occurs.
arXiv Detail & Related papers (2021-10-22T18:37:22Z)
Scenario adaptive disruption prediction study for next generation burning-plasma tokamaks [0.0]
Next generation high performance (HP) tokamaks risk damage from unmitigated disruptions at high current and power. We demonstrate how the operational regimes of tokamaks can affect the power of a trained disruption predictor.
arXiv Detail & Related papers (2021-09-18T15:48:02Z)
Semantic Perturbations with Normalizing Flows for Improved Generalization [62.998818375912506]
We show that perturbations in the latent space can be used to define fully unsupervised data augmentations. We find that our latent adversarial perturbations adaptive to the classifier throughout its training are most effective.
arXiv Detail & Related papers (2021-08-18T03:20:00Z)
Multiple Organ Failure Prediction with Classifier-Guided Generative Adversarial Imputation Networks [4.040013871160853]
Multiple organ failure (MOF) is a severe syndrome with a high mortality rate among Intensive Care Unit (ICU) patients. Applying machine learning models to electronic health records is a challenge due to the pervasiveness of missing values.
arXiv Detail & Related papers (2021-06-22T15:49:01Z)
Enhancing Robustness of On-line Learning Models on Highly Noisy Data [7.812139470551903]
We extend a two-layer on-line data selection framework: Robust Anomaly Detector (RAD) with a newly designed ensemble prediction. RAD can robustly improve the accuracy of anomaly detection, to reach up to 98.95% for IoT device attacks, up to 85.03% for cloud task failures, and up to 77.51% for face recognition.
arXiv Detail & Related papers (2021-03-19T14:13:16Z)
Adversarial Refinement Network for Human Motion Prediction [61.50462663314644]
Two popular methods, recurrent neural networks and feed-forward deep networks, are able to predict rough motion trend. We propose an Adversarial Refinement Network (ARNet) following a simple yet effective coarse-to-fine mechanism with novel adversarial error augmentation.
arXiv Detail & Related papers (2020-11-23T05:42:20Z)
Adaptive Invariance for Molecule Property Prediction [38.637412590671865]
We introduce a novel approach to learn predictors that can generalize or extrapolate beyond the heterogeneous data. Our method builds on and extends recently proposed invariant risk minimization. Our predictor outperforms state-of-the-art transfer learning methods by significant margin.
arXiv Detail & Related papers (2020-05-05T19:47:20Z)
A Systematic Approach to Featurization for Cancer Drug Sensitivity Predictions with Deep Learning [49.86828302591469]
We train >35,000 neural network models, sweeping over common featurization techniques. We found the RNA-seq to be highly redundant and informative even with subsets larger than 128 features.
arXiv Detail & Related papers (2020-04-30T20:42:17Z)

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