Reprint

Innovative Methods and Materials in Structural Health Monitoring of Civil Infrastructures

Edited by
June 2021
288 pages
  • ISBN978-3-0365-0754-5 (Hardback)
  • ISBN978-3-0365-0755-2 (PDF)

This is a Reprint of the Special Issue Innovative Methods and Materials in Structural Health Monitoring of Civil Infrastructures that was published in

Biology & Life Sciences
Chemistry & Materials Science
Computer Science & Mathematics
Engineering
Environmental & Earth Sciences
Physical Sciences
Summary

In the past, when elements in sructures were composed of perishable materials, such as wood, the maintenance of houses, bridges, etc., was considered of vital importance for their safe use and to preserve their efficiency. With the advent of materials such as reinforced concrete and steel, given their relatively long useful life, periodic and constant maintenance has often been considered a secondary concern. When it was realized that even for structures fabricated with these materials that the useful life has an end and that it was being approached, planning maintenance became an important and non-negligible aspect. Thus, the concept of structural health monitoring (SHM) was introduced, designed, and implemented as a multidisciplinary method. Computational mechanics, static and dynamic analysis of structures, electronics, sensors, and, recently, the Internet of Things (IoT) and artificial intelligence (AI) are required, but it is also important to consider new materials, especially those with intrinsic self-diagnosis characteristics, and to use measurement and survey methods typical of modern geomatics, such as satellite surveys and highly sophisticated laser tools.

Format
  • Hardback
License and Copyright
© 2022 by the authors; CC BY-NC-ND license
Keywords
structural health monitoring; jointless bridge; high-speed railway; bearing; expansion device; displacement analysis; structural reliability estimation; structural health monitoring; modal identification; finite element model updating; cyber-physical systems; crowdsourcing; structural health monitoring; temperature effects; time-lag effect; Fourier series expansion; box-girder bridges; structural engineering; overall deformation monitoring; perspective transformation; edge detection; close-range photogrammetry; railway embankment; condition assessment; ground penetrating radar; multi-attribute utility theory; laser scanner; line scanner; structure monitoring; deformation; dynamic measurements; scan-to-BIM; point cloud; HBIM; FEM; Rhinoceros; terrestrial laser scanner (TLS); ground-based real aperture radar (GB-RAR); line scanner; vibration frequency; spectral analysis; displacement; structural health monitoring (SHM); structural health monitoring (SHM); vibration-based damage detection; system identification; subspace system identification (SSI); tie rod; structural health monitoring (SHM); natural frequencies; mode shapes; root-mean-square error (RMSE); deformation; environmental monitoring; long-range mapping; MMS; close-range photogrammetry; sub-millimetric EDM geodetic techniques; structural health monitoring; damage detection; damage localization; hybrid approach; neural network; timber bridges; stress-laminated timber decks; monitoring; humidity-temperature sensors; wood moisture content; multi-phase models; finite element method; moving load identification; strain influence line; load transverse distribution; strain integral coefficient; identification error; n/a