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Main Authors: Abdullah, Abdullah, Sandjaja, Fannya Ratana, Majeed, Ayesha Abdul, Wickremasinghe, Gyan, Rafferty, Karen, Sharma, Vishal
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.10254
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author Abdullah, Abdullah
Sandjaja, Fannya Ratana
Majeed, Ayesha Abdul
Wickremasinghe, Gyan
Rafferty, Karen
Sharma, Vishal
author_facet Abdullah, Abdullah
Sandjaja, Fannya Ratana
Majeed, Ayesha Abdul
Wickremasinghe, Gyan
Rafferty, Karen
Sharma, Vishal
contents This study investigates uncertainty quantification (UQ) using quantum-classical hybrid machine learning (ML) models for applications in complex and dynamic fields, such as attaining resiliency in supply chain digital twins and financial risk assessment. Although quantum feature transformations have been integrated into ML models for complex data tasks, a gap exists in determining their impact on UQ within their hybrid architectures (quantum-classical approach). This work applies existing UQ techniques for different models within a hybrid framework, examining how quantum feature transformation affects uncertainty propagation. Increasing qubits from 4 to 16 shows varied model responsiveness to outlier detection (OD) samples, which is a critical factor for resilient decision-making in dynamic environments. This work shows how quantum computing techniques can transform data features for UQ, particularly when combined with classical methods.
format Preprint
id arxiv_https___arxiv_org_abs_2411_10254
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Uncertainty in Supply Chain Digital Twins: A Quantum-Classical Hybrid Approach
Abdullah, Abdullah
Sandjaja, Fannya Ratana
Majeed, Ayesha Abdul
Wickremasinghe, Gyan
Rafferty, Karen
Sharma, Vishal
Machine Learning
This study investigates uncertainty quantification (UQ) using quantum-classical hybrid machine learning (ML) models for applications in complex and dynamic fields, such as attaining resiliency in supply chain digital twins and financial risk assessment. Although quantum feature transformations have been integrated into ML models for complex data tasks, a gap exists in determining their impact on UQ within their hybrid architectures (quantum-classical approach). This work applies existing UQ techniques for different models within a hybrid framework, examining how quantum feature transformation affects uncertainty propagation. Increasing qubits from 4 to 16 shows varied model responsiveness to outlier detection (OD) samples, which is a critical factor for resilient decision-making in dynamic environments. This work shows how quantum computing techniques can transform data features for UQ, particularly when combined with classical methods.
title Uncertainty in Supply Chain Digital Twins: A Quantum-Classical Hybrid Approach
topic Machine Learning
url https://arxiv.org/abs/2411.10254