Datasets:
The dataset viewer is not available because its heuristics could not detect any supported data files. You can try uploading some data files, or configuring the data files location manually.
TokaMark Sensor Robustness Benchmark Data
Associated paper: Benchmarking Sensor Robustness in Plasma Diagnostic Models: A Systematic Evaluation on TokaMark
Author: Neerav Gupta
Code: github.com/Neerav-Gupta/tokamark-robustness
Dataset Description
This dataset contains pre-processed numpy arrays, trained model checkpoints, and experiment results from the first systematic robustness benchmark of plasma diagnostic ML models under realistic sensor failure, using the TokaMark benchmark on MAST tokamak data.
We evaluate four architectures (XGBoost, LSTM, Transformer, and the TokaMark CNN baseline) across six physically-motivated failure scenarios and three imputation strategies, and compute shot-level alarm metrics using ground-truth disruption timestamps from FAIR-MAST.
The raw data originates from the FAIR-MAST dataset provided by UKAEA, IBM Research, and STFC. This dataset contains derived arrays prepared for robustness benchmarking and is not a redistribution of the raw FAIR-MAST data.
Key Results
| Model | Clean NRMSE | Robustness Score (RS) | Clean TPR | TPR (proximate 25%, zero-fill) |
|---|---|---|---|---|
| XGBoost | 0.494 | 0.841 | 0.40 | β |
| LSTM | 0.496 | 0.808 | 0.52 | 0.00 |
| Transformer | 0.470 | 0.765 | 0.48 | 0.08 |
| CNN (TokaMark baseline) | 0.528 | 0.764 | 0.60 | 0.46 |
Key finding: Under disruption-proximate sensor failure, LSTM alarm detection collapses to TPR = 0.00 with zero-fill imputation, but recovers to TPR = 1.00 with mean-fill β the opposite of its effect on NRMSE.
Dataset Structure
tokamark-robustness-data/
βββ data/
β βββ train_X_feat.npy # XGBoost feature vectors, train
β βββ train_X_ts.npy # Time series tensors, train
β βββ train_y.npy # Target labels, train
β βββ val_X_feat.npy # XGBoost feature vectors, val
β βββ val_X_ts.npy # Time series tensors, val
β βββ val_y.npy # Target labels, val
β βββ test_X_feat.npy # XGBoost feature vectors, test
β βββ test_X_ts.npy # Time series tensors, test
β βββ test_y.npy # Target labels, test
β βββ test_raw_samples.pkl # Raw test samples with t_cut timestamps
β βββ feature_names.json # Feature names for X_feat columns
βββ checkpoints/
β βββ xgboost_clean.pkl # Trained XGBoost model
β βββ lstm_clean.pt # Trained LSTM model
β βββ transformer_clean.pt # Trained Transformer model
β βββ cnn_clean.pt # Trained CNN baseline model
βββ results/
βββ xgboost_results.json
βββ lstm_results.json
βββ transformer_results.json
βββ cnn_results.json
βββ shot_level_metrics.json
βββ alarm_under_corruption.json
βββ alarm_mitigation_proximate.json
File Descriptions
Data Arrays
| File | Description | Shape |
|---|---|---|
train_X_feat.npy |
Training feature vectors for XGBoost | (9950, 142) |
train_X_ts.npy |
Training time series for LSTM/Transformer/CNN | (9950, 600, 18) |
train_y.npy |
Training targets (normalized plasma current) | (9950,) |
val_X_feat.npy |
Validation feature vectors | (2500, 142) |
val_X_ts.npy |
Validation time series | (2500, 600, 18) |
val_y.npy |
Validation targets | (2500,) |
test_X_feat.npy |
Test feature vectors | (2420, 142) |
test_X_ts.npy |
Test time series | (2420, 600, 18) |
test_y.npy |
Test targets | (2420,) |
test_raw_samples.pkl |
Raw test samples including t_cut disruption timestamps and signal time arrays |
2420 samples |
feature_names.json |
Feature names for the 142 X_feat columns | 142 names |
Checkpoints
| File | Description |
|---|---|
checkpoints/xgboost_clean.pkl |
Trained XGBoost model (clean data) |
checkpoints/lstm_clean.pt |
Trained LSTM model (clean data) |
checkpoints/transformer_clean.pt |
Trained Transformer model (clean data) |
checkpoints/cnn_clean.pt |
Trained TokaMark CNN baseline (clean data) |
Results
| File | Description |
|---|---|
results/xgboost_results.json |
Full robustness results for XGBoost |
results/lstm_results.json |
Full robustness results for LSTM |
results/transformer_results.json |
Full robustness results for Transformer |
results/cnn_results.json |
Full robustness results for CNN baseline |
results/shot_level_metrics.json |
Clean-data shot-level TPR and MWT |
results/alarm_under_corruption.json |
Shot-level alarm metrics under sensor failure |
results/alarm_mitigation_proximate.json |
Alarm metrics under proximate failure with each imputation strategy |
Data Details
| Split | Shots | Windows |
|---|---|---|
| Train | 200 | 9,950 |
| Val | 50 | 2,500 |
| Test | 50 | 2,420 |
Task: Task 4-4 from TokaMark β plasma current quench prediction. Given 150ms of diagnostic history across 14 input signals and 4 actuator signals (18 total channels), predict plasma current 100ms into the future.
All 50 test shots disrupted (finite t_cut in test_raw_samples.pkl), enabling real shot-level alarm metric computation.
Signal Order in X_ts (18 channels)
| Index | Signal | Category |
|---|---|---|
| 0 | interferometer-n_e_line | Kinetics |
| 1 | magnetics-b_field_pol_probe_ccbv_field | Magnetics |
| 2 | magnetics-b_field_pol_probe_obr_field | Magnetics |
| 3 | magnetics-b_field_pol_probe_obv_field | Magnetics |
| 4 | magnetics-b_field_pol_probe_omv_voltage | Magnetics |
| 5 | magnetics-b_field_tor_probe_cc_field | Magnetics |
| 6 | magnetics-b_field_tor_probe_saddle_voltage | Magnetics |
| 7 | magnetics-flux_loop_flux | Magnetics |
| 8 | pf_active-coil_current | Active coils |
| 9 | pf_active-solenoid_current | Active coils |
| 10 | soft_x_rays-horizontal_cam_lower | Radiatives |
| 11 | soft_x_rays-horizontal_cam_upper | Radiatives |
| 12 | spectrometer_visible-filter_spectrometer_dalpha_voltage | Kinetics |
| 13 | summary-ip | Plasma current |
| 14 | gas_injection-total_injected | Actuator |
| 15 | pulse_schedule-i_plasma | Actuator |
| 16 | pulse_schedule-n_e_line | Actuator |
| 17 | summary-power_nbi | Actuator |
Loading the Data
import numpy as np
import pickle
from huggingface_hub import snapshot_download
# Download everything
snapshot_download(
repo_id="Neerav-Gupta/tokamark-robustness-data",
repo_type="dataset",
local_dir="./tokamark_robustness_data"
)
# Load arrays
X_train_ts = np.load("./tokamark_robustness_data/data/train_X_ts.npy")
y_train = np.load("./tokamark_robustness_data/data/train_y.npy")
X_test_ts = np.load("./tokamark_robustness_data/data/test_X_ts.npy")
y_test = np.load("./tokamark_robustness_data/data/test_y.npy")
print(f"Train: {X_train_ts.shape}") # (9950, 600, 18)
print(f"Test: {X_test_ts.shape}") # (2420, 600, 18)
# Load raw test samples (includes t_cut disruption timestamps)
with open("./tokamark_robustness_data/data/test_raw_samples.pkl", "rb") as f:
test_samples = pickle.load(f)
# Each sample has: shot_id, window_index, input, actuator, output, t_cut
print(f"Sample keys: {list(test_samples[0].keys())}")
print(f"t_cut (disruption time): {test_samples[0]['t_cut']:.4f}s")
# Load trained LSTM checkpoint
import torch
ckpt = torch.load(
"./tokamark_robustness_data/checkpoints/lstm_clean.pt",
map_location="cpu"
)
print(f"LSTM n_features: {ckpt['n_features']}")
# Load trained CNN checkpoint
ckpt_cnn = torch.load(
"./tokamark_robustness_data/checkpoints/cnn_clean.pt",
map_location="cpu"
)
print(f"CNN n_channels: {ckpt_cnn['n_channels']}, "
f"input_len: {ckpt_cnn['input_len']}, "
f"backbone_hidden: {ckpt_cnn['backbone_hidden']}")
Reproducing Results
# Clone the code repository
git clone https://github.com/Neerav-Gupta/tokamark-robustness.git
cd tokamark-robustness
# Download this dataset
python -c "
from huggingface_hub import snapshot_download
snapshot_download(
repo_id='Neerav-Gupta/tokamark-robustness-data',
repo_type='dataset',
local_dir='fusion_research/data'
)
"
# Train all four models and run robustness evaluation
python scripts/train_xgboost.py
python scripts/train_lstm.py
python scripts/train_transformer.py
python scripts/train_cnn_baseline.py
# Compute shot-level alarm metrics
python scripts/compute_alarm_metrics.py
# Generate all 9 figures
python scripts/analyze_results.py
Citation
If you use this dataset please cite:
@misc{gupta2026tokamark_robustness,
title = {Benchmarking Sensor Robustness in Plasma Diagnostic Models:
A Systematic Evaluation on TokaMark},
author = {Gupta, Neerav},
year = {2026},
note = {Preprint, available at
https://github.com/Neerav-Gupta/tokamark-robustness}
}
Please also cite the original TokaMark benchmark:
@article{rousseau2026tokamark,
title = {TokaMark: A Comprehensive Benchmark for MAST Tokamak
Plasma Models},
author = {Rousseau, C{\'e}cile and Jackson, Samuel and
Ordonez-Hurtado, Rodrigo H. and Amorisco, Nicola C. and
Boschi, Tobia and Holt, George K. and Loreti, Andrea and
Sz{\'e}kely, Eszter and Whittle, Alexander and
Agnello, Adriano and Pamela, Stanislas and
Pascale, Alessandra and Akers, Robert and
Bernabe Moreno, Juan and Thorne, Sue and
Zayats, Mykhaylo},
journal = {arXiv preprint arXiv:2602.10132},
year = {2026}
}
License
Acknowledgements
Raw plasma data sourced from the FAIR-MAST dataset provided by UKAEA, IBM Research, and STFC. This benchmark dataset was prepared independently using the TokaMark data loading infrastructure.
- Downloads last month
- 75