Quantum Kernel Advantage over Classical Collapse in Medical Foundation Model Embeddings
Abstract
Quantum support vector machines demonstrate superior performance over classical linear and RBF kernels in binary insurance classification tasks using medical imaging data, with quantum kernels showing higher effective rank and better minority-class recall.
We provide evidence of quantum kernel advantage under noiseless simulation in binary insurance classification on MIMIC-CXR chest radiographs using quantum support vector machines (QSVM) with frozen embeddings from three medical foundation models (MedSigLIP-448, RAD-DINO, ViT-patch32). We propose a two-tier fair comparison framework in which both classifiers receive identical PCA-q features. At Tier 1 (untuned QSVM vs. untuned linear SVM, C = 1 both sides), QSVM wins minority-class F1 in all 18 tested configurations (17 at p < 0.001, 1 at p < 0.01). The classical linear kernel collapses to majority-class prediction on 90-100% of seeds at every qubit count, while QSVM maintains non-trivial recall. At q = 11 (MedSigLIP-448 plateau center), QSVM achieves mean F1 = 0.343 vs. classical F1 = 0.050 (F1 gain = +0.293, p < 0.001) without hyperparameter tuning. Under Tier 2 (untuned QSVM vs. C-tuned RBF SVM), QSVM wins all seven tested configurations (mean gain +0.068, max +0.112). Eigenspectrum analysis reveals quantum kernel effective rank reaches 69.80 at q = 11, far exceeding linear kernel rank, while classical collapse remains C-invariant. A full qubit sweep reveals architecture-dependent concentration onset across models. Code: https://github.com/sebasmos/qml-medimage
Community
Quantum kernels beat classical SVMs on chest X-rays where linear methods collapse to F1=0. Tested across 3 medical foundation models (MedSigLIP, RAD-DINO, ViT) on 2,371 MIMIC-CXR samples, 10 seeds, paired bootstrap. The quantum advantage is not coincidence: classical kernels structurally collapse to rank=q under PCA-q reduction, quantum kernels reach effective rank up to 6.3x higher. Identifies a concrete regime where quantum methods provably help.
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