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Related Experiment Videos

Real-Time Edge Computing for Road Surface Classification Using Multi-IMU Data and a Hybrid CNN-LSTM Classification

Luis A Arce-Saenz1, Luis A Salazar-Calderón1, Renato Galluzzi1,2

  • 1School of Engineering and Sciences, Tecnologico de Monterrey, Mexico City 14380, Mexico.

Sensors (Basel, Switzerland)
|July 15, 2026
PubMed
Summary

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This study optimized deep learning models for real-time road quality monitoring using vibration data. The edge-optimized system significantly reduced processing time, enabling effective road condition classification and anomaly detection for enhanced vehicle safety.

Area of Science:

  • Engineering
  • Computer Science
  • Transportation Science

Background:

  • Road quality monitoring is crucial for vehicle safety, ride comfort, and advanced driver-assistance systems.
  • Deep learning models excel at road surface classification but require optimization for real-time embedded applications.
  • Effective road feature knowledge supports proactive measures for both vehicles and infrastructure.

Purpose of the Study:

  • To deploy an edge-optimized deep learning model for real-time road condition classification using vibration data.
  • To evaluate the system's performance in terms of inference latency and classification accuracy.
  • To demonstrate the feasibility of real-time temporal deep learning models in a cyber-physical system.

Main Methods:

  • A hybrid model combining convolutional neural networks (CNNs) and long short-term memory (LSTM) networks was utilized.
Keywords:
deep learningedge computinggeospatial mappingintelligent transportation systemsreal-time processingroad surface monitoring

Related Experiment Videos

  • Continuous vibration data from multiple inertial measurement units (IMUs) were processed.
  • The system was deployed on a MicroAutoBox III Embedded PC for edge processing at speeds of 5.0–25.0 km/h.
  • Main Results:

    • Inference latency was reduced by 88% (from 33.8 ms to 4.05 ms) compared to offline deployment.
    • A weighted-average F1-score of 0.8751 was achieved in real-world conditions, meeting the 86 Hz sensor polling rate requirement.
    • Geospatial mapping successfully localized structural anomalies, demonstrating robustness to varying lighting conditions.

    Conclusions:

    • The edge-optimized deep learning architecture enables real-time road condition classification within strict processing limits.
    • The cyber-physical system proves the feasibility of deploying temporal deep learning models for road monitoring.
    • Future research will focus on highway-speed validation and domain adaptation for broader applicability.