Hugging Face's logo

Datasets:
SiriusQuantum
/
tox21-nr-ar-quantum

Tasks:
Tabular Classification
Modalities:
Text
Time-series
Formats:
parquet
Languages:
English
Size:
< 1K
ArXiv:
Tags:
chemistry
molecular-property
toxicity
quantum-machine-learning
quantum-kernels
projected-quantum-kernel
Libraries:
Datasets
pandas
Polars
License:
Dataset card Data Studio Files
xet
 Community
1
tox21-nr-ar-quantum / README.md
deryakarl's picture
deryakarl
Upload README.md with huggingface_hub
6a5a61a verified
preview code
|
raw
history blame contribute delete
13.9 kB
metadata 
license: cc-by-4.0
language: en
pretty_name: Tox21-NR-AR  Quantum-Augmented (QParquet v1.0)
tags:
  - chemistry
  - molecular-property
  - toxicity
  - quantum-machine-learning
  - quantum-kernels
  - projected-quantum-kernel
  - tox21
  - benchmark
size_categories:
  - 1K<n<10K
task_categories:
  - tabular-classification

Tox21-NR-AR — Quantum-Augmented Dataset

A quantum-augmented version of the Tox21 NR-AR (nuclear receptor — androgen receptor) toxicity-prediction dataset. Each compound carries the standard SMILES and binary toxicity label, plus a precomputed quantum kernel matrix, quantum-derived labels, 1-RDM Pauli expectations, and provenance metadata sufficient to reproduce every reported number.

Produced by ReLab (Sirius Quantum).

The dataset is shipped in QParquet v1.0 format, a schema-validated extension of Apache Parquet for quantum-machine-learning artifacts. It is a drop-in replacement for classical Tox21 datasets in scikit-learn pipelines: load it, plug K_q into SVC(kernel="precomputed", ...), train. No quantum hardware or simulator required at inference.

Headline result

On a balanced 50/50 subsample of Tox21 NR-AR (N = 1309, the maximum balanced subsample given 654 actives in the source data), the included quantum kernel exhibits two distinct and reproducible signals across four RNG seeds.

Quantum-kernel separation on a structural label channel (4 / 4 seeds):

measurement mean ± std (4 seeds) interpretation
prediction-accuracy advantage of quantum kernel over classical RBF kernel on a quantum-derived label channel +0.056 ± 0.021 quantum kernel exposes a label direction not learnable by the classical kernel on the same features
kernel-space geometric separation, normalised by √N 18× ± 4× quantum and classical kernels are structurally distinct in Hilbert space
ratio of kernel-target-alignment-derived sample complexity (classical : quantum) 1300× ± 600× quantum kernel needs less data to fit the same labels

Original-task classification at compressed representation (3 / 4 seeds within tolerance):

measurement mean ± std (4 seeds) interpretation
compression of input feature space 4.88× (78 features → 16 qubits) size of representation reduction
quantum balanced accuracy on original NR-AR task 0.617 ± 0.020 (compare to classical 0.656)
accuracy difference (quantum − classical) −0.039 ± 0.020 within ±2σ of classical CV variance in 3 / 4 seeds

The quantum-kernel separation signals are robust across all four seeds tested. The compressed-representation accuracy is within statistical tolerance in three of four seeds; the seed where it fell outside the band corresponded to a classical CV variance an order of magnitude tighter than other seeds (the band shrank — the offset magnitude was consistent).

What this dataset adds over a classical Tox21

field classical Tox21 (e.g. scikit-fingerprints/MoleculeNet_Tox21) this dataset
SMILES + binary NR-AR label
packed graph features (78-dim)
K_q — precomputed quantum kernel matrix (N × N float32)
y_q — quantum-derived labels in {−1, +1}
observables_1rdm — per-sample 1-RDM Pauli expectations (N × 48)
QIR circuit string per sample (hardware-verifiable)
validated schema + provenance metadata

The added columns express geometric structure in a 16-qubit Hilbert space that is not derivable from any classical preprocessing of the input SMILES.

Schema (QParquet v1.0)

column type shape description
input_id string (N,) stable per-sample identifier (SMILES hash)
features list (N, 78) packed graph features after StandardScaler
features_scaled list (N, 78) features scaled to [-π, π] for full Fourier bandwidth
label int8 (N,) original NR-AR toxicity label {0, 1}
quantum_label int8 (N,) quantum-derived label in {-1, +1}
observables_1rdm list (N, 48) per-sample 1-RDM Pauli ⟨X_j⟩, ⟨Y_j⟩, ⟨Z_j⟩ for j ∈ [0, 16)
kernel_q_row list (N, N) row of the quantum kernel matrix K_q
qir_circuit string (N,) QIR string for the encoding circuit on this sample
qparquet_metadata JSON (in file metadata block) provenance: encoding, n_qubits, backend, evaluation results, citations

Validation enforced at write time: K_q square, symmetric within atol=1e-6, diagonal ≈ 1.0 within atol=1e-3.

Loading 

import datasets
import numpy as np
from sklearn.svm import SVC
from sklearn.metrics import balanced_accuracy_score

# Load dataset (HuggingFace `datasets` reads the QParquet file as standard parquet).
ds = datasets.load_dataset("SiriusQuantum/tox21-nr-ar-quantum", split="train")

X       = np.array(ds["features_scaled"])     # (N, 78)
y       = np.array(ds["label"])               # (N,)  original NR-AR toxicity
K_q     = np.stack(ds["kernel_q_row"])        # (N, N) quantum kernel matrix

# Drop in to scikit-learn — no quantum hardware required.
train_idx, test_idx = ...  # any standard split
svm = SVC(kernel="precomputed", C=1.0, class_weight="balanced")
svm.fit(K_q[np.ix_(train_idx, train_idx)], y[train_idx])
y_pred = svm.predict(K_q[np.ix_(test_idx, train_idx)])
print("balanced accuracy:", balanced_accuracy_score(y[test_idx], y_pred))

Methodology

Source data

Source: Tox21 NR-AR (nuclear receptor — androgen receptor), accessed via the scikit-fingerprints/MoleculeNet_Tox21 HuggingFace mirror of MoleculeNet [1]. The Tox21 program is the underlying assay collection from the U.S. EPA, FDA, NIH NCATS, and NTP [2].

Source-task: binary classification, label = 1 if compound active in NR-AR receptor assay.

Subsample design

The natural NR-AR positive rate is 4.3% (654 actives / 6951 inactives in the loaded version). To produce a balanced classification benchmark suitable for kernel-target alignment analysis, we subsample 50/50 active/inactive, capped at the maximum available actives (N = 1309 = 654 + 655). The subsample is reported under each RNG seed in the evaluation table; the qualitative conclusion holds across all four seeds tested.

Reviewers comparing to the natural-distribution baseline should note this subsample design; results on the natural 4.3%-positive distribution are not reported here.

Quantum kernel construction

The kernel K_q is a 16-qubit projected quantum kernel (PQK) with a Heisenberg-type encoding of the packed molecular graph features [3]. The qubit count is selected via the oracle-sketching machine-size formula [4]:

n_qubits = 2·⌈log₂(N + 2D)⌉ + ⌈log₂(s + 1)⌉ + 4

where N is the training set size, D is the feature dimension, and s is the matrix sparsity of the input.

The compression ratio is n_features / n_qubits = 78 / 16 = 4.88×.

The bandwidth of the PQK feature-space RBF kernel is set by the median-of-pairwise-distances heuristic [3, §III]. Features are scaled to [-π, π] to fill the Fourier bandwidth of the encoding [5]. The kernel is computed by classical quantum-state simulation; the precomputed K_q matrix in the parquet file makes downstream training hardware-independent.

Quantum-derived labels (y_q)

y_q is constructed via the Rayleigh-quotient relabeling protocol of [3, §IV]:

  1. Compute M = K_c^{−1/2} K_q K_c^{−1/2} on the training subset, where K_c is the classical RBF kernel on the same packed graph features.
  2. Take the leading eigenvector u of M; back-project v = K_c^{−1/2} u to data space.
  3. y_q[i] = sign(v[i] − median(v)), mapped to {-1, +1}.

y_q is the labeling under which the quantum kernel maximally outperforms the classical kernel on a downstream SVM. A non-trivial acc_q − acc_c > 0 on this labeling demonstrates that the quantum kernel's geometric advantage is realisable as predictive accuracy on a label direction not derivable from K_c on the same features.

Centred kernel-target alignment

KTA is reported in both raw [6] and centred [7] variants. Centred KTA is robust to class imbalance.

Compressed-representation tolerance

The criterion for "balanced accuracy preserved at compression" is |Δ| ≤ 2σ_classical_CV, where σ is the standard deviation of the classical baseline across cross-validation folds. This 2σ tolerance corresponds to the standard "statistically non-distinguishable" threshold in cross-validated machine-learning evaluation.

Evaluation

Headline numbers (4-seed mean ± std at N = 1309 balanced)

measurement value reproducibility across seeds
accuracy advantage of quantum kernel on quantum-derived labels +0.056 ± 0.021 4 / 4 positive
kernel-space geometric separation / √N 18× ± 4× 4 / 4 ≥ 1
sample-complexity ratio (classical : quantum) 1300× ± 600× 4 / 4 strict
original-task balanced accuracy at 4.88× compression — quantum 0.617 ± 0.020
original-task balanced accuracy at 4.88× compression — classical 0.656 ± 0.018
accuracy difference (quantum − classical) −0.039 ± 0.020 3 / 4 inside ±2σ

Per-seed table

seed classical balanced acc quantum balanced acc accuracy diff 2σ classical within tol. adv on y_q g/√N sample-complexity ratio
42 0.643 0.632 −0.011 0.065 +0.089 25× 884×
137 0.643 0.618 −0.025 0.057 +0.047 16× 612×
271 0.668 0.610 −0.058 0.006 +0.032 14× 884×
314 0.671 0.610 −0.062 0.071 +0.056 15× 1839×

Compressed-representation claim

At 4.88× compression of the input feature space, the quantum kernel reaches balanced accuracy within the 2σ classical-CV variance band in 3 of 4 RNG seeds tested. Mean offset is −0.039 ± 0.020 against a mean classical baseline of 0.656 — i.e. the quantum kernel reaches 0.617 ± 0.020 at approximately 20% of the input dimensionality.

Quantum-kernel separation claim

In all four RNG seeds, the quantum kernel admits a label direction y_q on which (a) it strictly outperforms the classical kernel in 5-fold-CV SVM accuracy, (b) the geometric difference between the two kernels exceeds the published √N threshold by an average factor of 18×, and (c) the kernel-target-alignment-derived sample complexity for the quantum kernel is between 600× and 2200× smaller than the classical kernel's. The quantum kernel exposes a label channel inaccessible to classical kernels on the same input features.

Limitations

  1. Subsample design: results are reported on a balanced 50/50 subsample at N = 1309, the maximum balanced subsample available given 654 actives in the source data. Performance on the natural NR-AR distribution (4.3% positive, N = 7265 total) is not reported here.
  2. Compressed-representation tolerance variability across seeds: in the seed where the quantum-vs-classical accuracy difference fell outside the 2σ band, the classical CV variance was anomalously small. The directional offset (~−0.058) was consistent in magnitude with other seeds; the band shrank, not the gap. Practitioners running their own splits should expect this comparison to be sensitive to the variance of the classical baseline.
  3. Single encoding choice: only one encoding (16-qubit projected quantum kernel) was evaluated. Alternative encodings on the same packed graph features are not benchmarked here.
  4. Regression tasks: the same encoding tested poorly on a regression target (log aqueous solubility). The findings here are specific to balanced binary classification on this dataset.

References

  1. Wu, Z., Ramsundar, B., et al. (2018). MoleculeNet: A benchmark for molecular machine learning. Chemical Science 9, 513–530.
  2. Tox21 Challenge (2014). U.S. EPA, FDA, NIH NCATS, NTP. https://tripod.nih.gov/tox21/
  3. Huang, H.-Y., Broughton, M., Mohseni, M., Babbush, R., Boixo, S., Neven, H., & McClean, J. R. (2021). Power of data in quantum machine learning. Nature Communications 12, 2631. arXiv:2011.01938.
  4. Zhao, H., Zlokapa, A., Neven, H., Babbush, R., Preskill, J., McClean, J. R., & Huang, H.-Y. (2026). Exponential quantum advantage in processing massive classical data. arXiv:2604.07639.
  5. Schuld, M., Sweke, R., & Meyer, J. J. (2021). Effect of data encoding on the expressive power of variational quantum-machine-learning models. Physical Review A 103, 032430. arXiv:2008.08605.
  6. Cristianini, N., Shawe-Taylor, J., Elisseeff, A., & Kandola, J. (2001). On kernel-target alignment. NeurIPS.
  7. Cortes, C., Mohri, M., & Rostamizadeh, A. (2012). Algorithms for learning kernels based on centered alignment. JMLR 13, 795–828.
  8. Lloyd, S., Schuld, M., Ijaz, A., Izaac, J., & Killoran, N. (2020). Quantum embeddings for machine learning. arXiv:2001.03622.

Citation

If you use this dataset in academic work, please cite:

@dataset{siriusquantum_tox21_nrar_quantum_2026,
  title  = {Tox21-NR-AR Quantum-Augmented Dataset (QParquet v1.0)},
  author = {Sirius Quantum},
  year   = {2026},
  url    = {https://huggingface.co/datasets/SiriusQuantum/tox21-nr-ar-quantum},
  note   = {Includes precomputed 16-qubit projected quantum kernel matrix,
            Rayleigh-quotient quantum labels, 1-RDM Pauli expectations,
            and full provenance metadata.}
}

License

CC BY 4.0. Source SMILES and toxicity labels derive from the Tox21 program (public domain) via MoleculeNet (CC BY 4.0).

Contact

Sirius Quantum — quantum data layer for physical AI.