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Predicting strain and stress fields in self-sensing nanocomposites using deep learned electrical tomography

Author(s):

ORCID

ORCID
Medium: journal article
Language(s): English
Published in: Smart Materials and Structures, , n. 4, v. 31
Page(s): 045024
DOI: 10.1088/1361-665x/ac585f
Abstract:

Conductive nanocomposites, enabled by their piezoresistivity, have emerged as a new instrument in structural health monitoring. To this end, studies have recently found that electrical resistance tomography (ERT), a non-destructive conductivity imaging technique, can be utilized with piezoresistive nanocomposites to detect and localize damage. Furthermore, by incorporating complementary optimization protocols, the mechanical state of the nanocomposites can also be determined. In many cases, however, such approaches may be associated with high computational cost. To address this, we develop deep learned frameworks using neural networks to directly predict strain and stress distributions—thereby bypassing the need to solve the ERT inverse problem or execute an optimization protocol to assess mechanical state. The feasibility of the learned frameworks is validated using simulated and experimental data considering a carbon nanofiber plate in tension. Results show that the learned frameworks are capable of directly and reliably predicting strain and stress distributions based on ERT voltage measurements.

Structurae cannot make the full text of this publication available at this time. The full text can be accessed through the publisher via the DOI: 10.1088/1361-665x/ac585f.
  • About this
    data sheet
  • Reference-ID
    10659945
  • Published on:
    28/03/2022
  • Last updated on:
    28/03/2022
 
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