arxiv_ai 92% Match Research Paper Industrial Engineers,Maintenance Professionals,ML Researchers in Industrial Applications,Data Scientists 2 weeks ago

Hypergraph Contrastive Sensor Fusion for Multimodal Fault Diagnosis in Induction Motors

graph-neural-networks › graph-learning

📄 Abstract

Abstract: Reliable induction motor (IM) fault diagnosis is vital for industrial safety and operational continuity, mitigating costly unplanned downtime. Conventional approaches often struggle to capture complex multimodal signal relationships, are constrained to unimodal data or single fault types, and exhibit performance degradation under noisy or cross-domain conditions. This paper proposes the Multimodal Hypergraph Contrastive Attention Network (MM-HCAN), a unified framework for robust fault diagnosis. To the best of our knowledge, MM-HCAN is the first to integrate contrastive learning within a hypergraph topology specifically designed for multimodal sensor fusion, enabling the joint modelling of intra- and inter-modal dependencies and enhancing generalisation beyond Euclidean embedding spaces. The model facilitates simultaneous diagnosis of bearing, stator, and rotor faults, addressing the engineering need for consolidated di- agnostic capabilities. Evaluated on three real-world benchmarks, MM-HCAN achieves up to 99.82% accuracy with strong cross-domain generalisation and resilience to noise, demonstrating its suitability for real-world deployment. An ablation study validates the contribution of each component. MM-HCAN provides a scalable and robust solution for comprehensive multi-fault diagnosis, supporting predictive maintenance and extended asset longevity in industrial environments.

Authors (7)

Usman Ali

Ali Zia

Waqas Ali

Umer Ramzan

Abdul Rehman

Muhammad Tayyab Chaudhry

+1 more

Submitted

October 17, 2025

arXiv Category

cs.AI

arXiv PDF

Key Contributions

This paper proposes the Multimodal Hypergraph Contrastive Attention Network (MM-HCAN), the first framework to integrate contrastive learning within a hypergraph topology for multimodal sensor fusion in induction motor fault diagnosis. It enables joint modeling of intra- and inter-modal dependencies, enhancing generalization beyond Euclidean spaces and facilitating simultaneous diagnosis of multiple fault types (bearing, stator, rotor) under noisy conditions.

Business Value

Enhances industrial safety and operational continuity by enabling more reliable and comprehensive fault diagnosis for induction motors, reducing costly unplanned downtime.

Paper Metadata

Innovation Type

Algorithmic

Deployment Feasibility

Moderate to High. Requires sensor infrastructure and computational resources for training and inference, but the framework itself is designed for practical application.

Limitations Addressed

Struggles of conventional approaches to capture complex multimodal signal relationships, constraints to unimodal data or single fault types, and performance degradation under noisy or cross-domain conditions.

Performance Gains

Improved performance compared to unimodal and conventional multimodal approaches, especially under noisy and cross-domain conditions.

Technical Tags

hypergraphcontrastive learningsensor fusionmultimodalfault diagnosisinduction motorsattention mechanismdeep learninggeneralizationnoise robustness

Research Topics

Industrial IoTPredictive MaintenanceMachine Learning for EngineeringMultimodal Data FusionGraph Neural Networks

Methods & Architectures

Multimodal Hypergraph Contrastive Attention Network (MM-HCAN)Contrastive LearningHypergraph RepresentationAttention MechanismSensor Fusion Hypergraph Neural NetworkAttention Network

Applications & Tasks

Industrial Machinery Manufacturing Energy Sector Condition Monitoring Fault DiagnosisMultimodal Data FusionComplex Signal RelationshipsNoisy DataCross-domain Generalization Induction Motor Fault DiagnosisBearing Fault DetectionStator Fault DetectionRotor Fault DetectionConsolidated Diagnostic Capabilities

Related Fields

Machine LearningSignal ProcessingIndustrial EngineeringGraph TheorySensor Networks

Keywords

induction motorfault diagnosishypergraphcontrastive learningsensor fusionmultimodalattentiondeep learningpredictive maintenanceindustrial IoTmachine learninggeneralizationnoise

Academic Context

#Industrial IoT#Predictive Maintenance#Machine Learning for Engineering#Multimodal Data Fusion#Graph Neural Networks

Commercial Potential

Potential Products

Predictive maintenance softwareIndustrial monitoring systemsSmart sensor platforms

Target Industries

ManufacturingEnergyAutomotiveAerospace

Use Case Examples

Early detection of bearing failures in electric motorsMonitoring the health of industrial pumps and compressorsPreventing catastrophic failures in power generation equipment

Competitive Edge

Offers a unified framework for multimodal fault diagnosis that surpasses traditional methods by leveraging hypergraphs and contrastive learning for richer feature representation and better generalization.

Market Opportunity

Significant, driven by the global industrial automation and predictive maintenance markets.

Revenue Models

Software licensinghardware-software bundlesdata analytics services.

Resource Requirements

Compute Needs

Moderate to High, especially for training on large multimodal datasets.

Data Requirements

Requires synchronized multimodal sensor data from induction motors, including data from healthy and faulty states.

Deployment Constraints

Requires reliable sensor deployment and data acquisition infrastructure in industrial settings.

Scalability

Scalability depends on the efficiency of hypergraph operations and the contrastive learning implementation. May require distributed computing for very large datasets.

Production Readiness

Maturity Level

Research

Time to Market

2-4 years

Patent Potential

Moderate, for the novel MM-HCAN architecture and its application.

View Full Paper Back to Papers