Human–Machine Collaboration Framework for Bridge Health Monitoring

Human–Machine Collaboration Framework for Bridge Health Monitoring

Abstract In bridge health monitoring (BHM), a prominent goal is to rapidly deliver assessment metrics for these essential and aging urban lifelines when subjected to natural hazard. A vibration-based machine learning (ML) BHM paradigm has been established over the past three decades to allow near-re...

Full description

Saved in:
Bibliographic Details
Published in:Journal of bridge engineering Vol. 29; no. 7
Main Authors: Muin, Sifat, Chern, Chrystal, Mosalam, Khalid M.
Format: Journal Article
Language:English
Published: New York American Society of Civil Engineers 01-07-2024
Subjects:
Aging (natural)
Bridges
Collaboration
Cooperation
Damage
Damage assessment
Damage detection
Decision making
Machine learning
Probability theory
Reinforced concrete
Statistical analysis
Structural health monitoring
Technical Papers
Vibration
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Abstract In bridge health monitoring (BHM), a prominent goal is to rapidly deliver assessment metrics for these essential and aging urban lifelines when subjected to natural hazard. A vibration-based machine learning (ML) BHM paradigm has been established over the past three decades to allow near-real-time automated health state classification, with a particular focus on the tasks of feature engineering and ML damage identification. This paper presents the human–machine collaboration (H-MC) framework to address challenges of this paradigm, especially in the context of reinforced concrete highway BHM. These challenges include specification of strong motion events, data multidimensionality, and ML model interpretability. The H-MC framework for BHM employs the techniques of multivariate novelty detection and probability of exceedance envelope models with ordinal filter-based feature selection to maximize the use of available data from both recorded and simulated events while maintaining the statistical and physical significance of the results. The framework is demonstrated using a numerical example and two case studies. The findings show the effectiveness of the proposed method for efficient damage assessment to facilitate rapid decision-making.
ISSN:1084-0702
1943-5592
DOI:10.1061/JBENF2.BEENG-6587