Structural health monitoring technology can assess the status and integrity of structures in
real time by advanced sensors, evaluate the remaining life of structure, and make the …

Through the integration of advanced sensors, actuators, and micro-processors, aircraft smart
skin technology can improve the structural performance of aircraft and make them self …

Flexible smart sensing skin is a key enabling technology for the future “Fly-by-Feel” control
of morphing aircraft. It represents the next-generation skin of aircraft that can exhibit a more …

Aircraft smart skin technology requires the integration of large-scale, lightweight, and
integrative sensor networks with aircraft structural skin, but it is difficult to directly …

Composite structures may be subjected to internal damages caused by impact events, which
can seriously degrade the property of the structures. Hence, impact monitoring is of great …

Simultaneous presence of multiple fatigue cracks in the same structural element is a critical
problem affecting system safety. However, initiation and growth of these cracks is affected by …

Aircraft smart skin requires the integration of large-scale, ultrathin, and high-sensitive sensor
network on the surface for structural health monitoring (SHM). However, it is fairly difficult to …

To monitor possible failures of a composite, several Structural Health Monitoring (SHM)
systems have been developed. However, these methods typically involve embedding …

The particle filter (PF) has shown great potential for on-line fatigue crack growth prognosis
by combining crack measurements from structural health monitoring (SHM) techniques. In …

For the reliable damage monitoring of aircraft structures under Time-Varying Conditions
(TVCs), Gaussian Mixture Model (GMM)-based damage monitoring methods combined with …