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Main Authors: Balakrishna, Keshav, Chityala, Aaryan, Kanna, Vivan, Pathak, Ishan, Ravula, Harshit, Lee, Aaron, Hammond, Alessandro, Al-Wishah, Moemal, Celi, Leo Anthony
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.17771
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author Balakrishna, Keshav
Chityala, Aaryan
Kanna, Vivan
Pathak, Ishan
Ravula, Harshit
Lee, Aaron
Hammond, Alessandro
Al-Wishah, Moemal
Celi, Leo Anthony
author_facet Balakrishna, Keshav
Chityala, Aaryan
Kanna, Vivan
Pathak, Ishan
Ravula, Harshit
Lee, Aaron
Hammond, Alessandro
Al-Wishah, Moemal
Celi, Leo Anthony
contents Accurate diagnosis of neurological disorders is contingent upon advanced imaging modalities such as Magnetic Resonance Imaging (MRI), which commonly utilize sparse imaging techniques to reconstruct images from limited data, thus reducing storage and acquisition time. However, challenges remain in managing noise and preserving critical diagnostic features for effective analysis. In this study, an ensemble classifier is enriched with PARAFAC CP tensor decompositions, drawing mathematical inspiration from quantum neural network architectures but implemented entirely classically. The model was evaluated on a large, balanced clinical dataset comprising 55,160 images across 8 diagnostic categories, employing both higher and lower PARAFAC rank configurations. Evaluated through 5-fold nested stratified cross-validation, both configurations achieved strong validation performance, demonstrating robustness to tensor network expressivity. Additionally, the proposed model achieved competitive performance relative to recent classical approaches, further underscoring the potential of quantum-inspired classical frameworks to enhance medical image analysis and support reliable clinical diagnosis. Future work will explore the integration of advanced encoding schemes, deployment on real quantum hardware, and the use of more diverse neurological datasets.
format Preprint
id arxiv_https___arxiv_org_abs_2605_17771
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Multi-Class Neurological Disorder Prediction with Tensor Network Feature Engineering
Balakrishna, Keshav
Chityala, Aaryan
Kanna, Vivan
Pathak, Ishan
Ravula, Harshit
Lee, Aaron
Hammond, Alessandro
Al-Wishah, Moemal
Celi, Leo Anthony
Applications
Accurate diagnosis of neurological disorders is contingent upon advanced imaging modalities such as Magnetic Resonance Imaging (MRI), which commonly utilize sparse imaging techniques to reconstruct images from limited data, thus reducing storage and acquisition time. However, challenges remain in managing noise and preserving critical diagnostic features for effective analysis. In this study, an ensemble classifier is enriched with PARAFAC CP tensor decompositions, drawing mathematical inspiration from quantum neural network architectures but implemented entirely classically. The model was evaluated on a large, balanced clinical dataset comprising 55,160 images across 8 diagnostic categories, employing both higher and lower PARAFAC rank configurations. Evaluated through 5-fold nested stratified cross-validation, both configurations achieved strong validation performance, demonstrating robustness to tensor network expressivity. Additionally, the proposed model achieved competitive performance relative to recent classical approaches, further underscoring the potential of quantum-inspired classical frameworks to enhance medical image analysis and support reliable clinical diagnosis. Future work will explore the integration of advanced encoding schemes, deployment on real quantum hardware, and the use of more diverse neurological datasets.
title Multi-Class Neurological Disorder Prediction with Tensor Network Feature Engineering
topic Applications
url https://arxiv.org/abs/2605.17771