arxiv_ai 95% Match Research Paper Embedded Systems Engineers,AI Researchers in Healthcare,Dermatologists,Neuromorphic Computing Researchers 2 weeks ago

Quantization-Aware Neuromorphic Architecture for Efficient Skin Disease Classification on Resource-Constrained Devices

computer-vision › medical-imaging

📄 Abstract

Abstract: Accurate and efficient skin lesion classification on edge devices is critical for accessible dermatological care but remains challenging due to computational, energy, and privacy constraints. We introduce QANA, a novel quantization-aware neuromorphic architecture for incremental skin lesion classification on resource-limited hardware. QANA effectively integrates ghost modules, efficient channel attention, and squeeze-and-excitation blocks for robust feature representation with low-latency and energy-efficient inference. Its quantization-aware head and spike-compatible transformations enable seamless conversion to spiking neural networks (SNNs) and deployment on neuromorphic platforms. Evaluation on the large-scale HAM10000 benchmark and a real-world clinical dataset shows that QANA achieves 91.6% Top-1 accuracy and 82.4% macro F1 on HAM10000, and 90.8%/81.7% on the clinical dataset, significantly outperforming state-of-the-art CNN-to-SNN models under fair comparison. Deployed on BrainChip Akida hardware, QANA achieves 1.5 ms inference latency and 1.7,mJ energy per image, reducing inference latency and energy use by over 94.6%/98.6% compared to GPU-based CNNs surpassing state-of-the-art CNN-to-SNN conversion baselines. These results demonstrate the effectiveness of QANA for accurate, real-time, and privacy-sensitive medical analysis in edge environments.

Authors (7)

Haitian Wang

Xinyu Wang

Yiren Wang

Zichen Geng

Xian Zhang

Yu Zhang

+1 more

Submitted

July 21, 2025

arXiv Category

eess.IV

arXiv PDF

Key Contributions

Introduces QANA, a novel quantization-aware neuromorphic architecture for efficient skin lesion classification on resource-constrained devices. QANA integrates efficient modules for robust feature representation and low-latency inference, enabling seamless conversion to SNNs for neuromorphic platforms, achieving high accuracy with significantly reduced computational and energy costs.

Business Value

Enables accessible, real-time dermatological diagnosis on low-power devices, improving healthcare access in remote areas and reducing the cost of diagnostic tools.

Paper Metadata

Innovation Type

Architecture Design

Deployment Feasibility

High, specifically designed for resource-constrained devices and neuromorphic platforms.

Limitations Addressed

Addresses computational, energy, and privacy constraints for accurate skin lesion classification on edge devices, overcoming limitations of traditional CNNs on resource-limited hardware.

Performance Gains

Achieves high accuracy (e.g., 91.6% Top-1 on HAM10000) and F1 scores (e.g., 82.4% macro F1) while being significantly more efficient (low-latency, energy-efficient) than state-of-the-art CNN-to-SNN models.

Technical Tags

Quantization-AwareNeuromorphic ArchitectureSkin Disease ClassificationResource-Constrained DevicesEdge AISpiking Neural Networks (SNNs)Ghost ModulesChannel AttentionSqueeze-and-ExcitationLow-Latency Inference

Research Topics

Edge AINeuromorphic ComputingMedical Image AnalysisEfficient Deep LearningBiomedical Applications

Methods & Architectures

Quantization-Aware TrainingNeuromorphic Architecture Design (QANA)Integration of Ghost ModulesEfficient Channel AttentionSqueeze-and-Excitation BlocksConversion to Spiking Neural Networks (SNNs) Quantization-Aware Neuromorphic Architecture (QANA)Spiking Neural Networks (SNNs)

Applications & Tasks

Dermatology Medical Diagnostics Edge Computing Healthcare Technology Computational Constraints on Edge DevicesEnergy Efficiency for AIPrivacy Concerns in HealthcareAccurate Skin Lesion Classification Skin Lesion ClassificationDeployment on Resource-Constrained DevicesConversion to Neuromorphic Platforms

Datasets & Benchmarks

Datasets

HAM10000, Real-world clinical dataset

Benchmarks

91.6% Top-1 accuracy on HAM10000 • 82.4% macro F1 on HAM10000 • 90.8% accuracy on clinical dataset • 81.7% macro F1 on clinical dataset

Top-1 AccuracyMacro F1 ScoreLatencyEnergy Efficiency

Related Fields

Computer VisionMedical ImagingNeuromorphic EngineeringEdge ComputingBiomedical Signal Processing

Keywords

Skin Disease ClassificationNeuromorphicQuantization-AwareEdge AISNNResource-ConstrainedMedical ImagingLow PowerDermatologyEfficient Deep Learning

Academic Context

#Edge AI#Neuromorphic Computing#Medical Image Analysis#Efficient Deep Learning#Biomedical Applications

Technology Stack

ML Infrastructure

Neuromorphic Platforms

Commercial Potential

Potential Products

Handheld diagnostic devices for skin conditionsAI-powered dermatology apps for smartphonesLow-power medical imaging systems

Target Industries

HealthcareMedical DevicesWearable TechnologyConsumer Electronics

Use Case Examples

On-device skin cancer screeningRemote diagnosis of common skin ailmentsPersonalized skin health monitoring

Competitive Edge

Offers a specialized, highly efficient architecture for skin disease classification on edge devices, outperforming existing CNN-to-SNN conversion methods.

Market Opportunity

Significant (growing market for edge AI in healthcare and medical devices)

Revenue Models

Device saleslicensing of the QANA architecture

Resource Requirements

Compute Needs

Extremely low compute and energy requirements, suitable for microcontrollers and neuromorphic chips.

Data Requirements

Requires labeled skin lesion images (e.g., HAM10000, clinical data).

Deployment Constraints

Hardware limitations (memory, processing power), power budget, and need for specialized neuromorphic hardware for full potential.

Scalability

Designed for scalability on resource-constrained devices, focusing on efficiency rather than massive scale.

Regulatory Considerations

Medical device regulations (e.g., FDA)

Production Readiness

Maturity Level

Research

Time to Market

Long (requires hardware integration and regulatory approval)

Patent Potential

High (novel architecture and quantization techniques)

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