Observability Analysis for Structural System Identification Based on Static-State Estimation Articles uri icon

publication date

  • June 2025

start page

  • 1

end page

  • 19

issue

  • 8386282

volume

  • 2025

International Standard Serial Number (ISSN)

  • 1545-2255

Electronic International Standard Serial Number (EISSN)

  • 1545-2263

abstract

  • The concept of observability analysis has garnered substantial attention in the field of structural system identifcation. Its primary aim is to identify a specifc set of structural characteristics, such as Young's modulus, area, inertia, and possibly their combinations (e.g., fexural or axial stifness). These characteristics can be uniquely determined when provided with a suitable subset of deflections, forces, and/or moments at the nodes of the structure. This problem is particularly intricate within the realm of structural system identification, mainly due to the presence of nonlinear unknown variables, such as the product of vertical defection and fexural stifness, in accordance with modern methodologies. Consequently, the mechanical and geometrical properties of the structure are intricately linked with node defections and/or rotations. The paper at hand serves a dual purpose: firstly, it introduces the concept of static-state estimation, especially tailored for the identifcation of structural systems; and secondly, it presents a novel observability analysis method grounded in static-state estimation principles, designed to overcome the aforementioned challenges. Computational experiments shed light on the algorithm's potential for practical structural systemidentifcation applications, demonstrating signifcant advantages over the existing state-of-the-art methods found in the literature. It is noteworthy that these advantages could potentially be further amplifed by addressing the static-state estimation principles problem, which constitutes a subject for future research. Solving this problem would help address the additional challenge of developing efficient techniques that can accommodate redundancy and uncertainty when estimating the current state of the structure.

subjects

  • Statistics

keywords

  • observability analysis; state estimation; structural health monitoring; structural system identification