Bridges play a crucial role in modern societies, regardless of their culture, geographical
location, or economic development. The safest, economical, and most resilient bridges are …

The number of bridges worldwide is extensive, making it financially and technically
challenging for the authorities to install a structural health monitoring (SHM) system and …

Bridges experience complex heat propagation phenomena that are governed by external
thermal loads, such as solar radiation and air convection, as well as internal factors, such as …

In structural health monitoring, temperature time-lag effect inevitably affects the state
assessment and damage warning of structures. Most of the existing studies focused on …

Drive‐by structural health monitoring (SHM) is a cost‐efficient alternative to the direct SHM
of short‐to medium‐size bridges requiring no sensors to be installed on the structure …

Featured Application According to field research results, a time-lag between structural
response and temperature load is commonly encountered in practice. Due to the fact that it …

This paper presents the results of 28-month-long monitoring of a slab portion of the Chillon
viaducts in Switzerland using strain gauges and thermocouples. This post-tensioned …

The paper presents damage detection techniques for structural health monitoring of bridges
incorporating computer vision derived measurements. The feasibility of the techniques is …

One challenge to the wider adoption of structural health monitoring (SHM) in bridges is
demonstrating the value added by the SHM system in maintenance and operation of the …

In the field of bridge health monitoring, it is ubiquitous to model the relationship for
monitoring data. However, in many cases, especially for concrete bridge structures, field …