Modeling of environmental influence in structural health assessment for reinforced concrete buildings

Yuen, Ka‐Veng; Kuok, Sin‐Chi

doi:10.1007/s11803-010-0014-4

Cited by 44 publications

(26 citation statements)

References 27 publications

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“…Note that this periodic component is not suited to model nonharmonic effects, for example, such as those identified by Yuen and Kuok. [28]…”

Section: Periodic Componentsmentioning

confidence: 99%

Bayesian dynamic linear models for structural health monitoring

Goulet

2017

Struct Control Health Monit

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Type: Article de revue / Journal article Référence:Citation:Goulet, James-A. (2017 AbstractIn several countries, infrastructure is in poor condition and this situation is bound to remain prevalent for the years to come. A promising solution for mitigating the risks posed by ageing infrastructure is to have arrays of sensors for performing, in real-time, structural health monitoring (SHM) across populations of structures. This paper presents a Bayesian Dynamic Linear Model (BDLM) framework for modeling the time-dependent responses of structures and external effects by breaking it into components. The specific contributions of this paper are to provide (1) a formulation for simultaneously estimating the hidden states of structural responses as well as the external effects it depends on, e.g. temperature and loading, (2) a state estimation formulation that is robust toward the errors caused by numerical inaccuracies, (3) an efficient way for learning the model parameters, and (4) a formulation for handling non-uniform time steps.

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“…Note that this periodic component is not suited to model nonharmonic effects, for example, such as those identified by Yuen and Kuok. [28]…”

Section: Periodic Componentsmentioning

confidence: 99%

Bayesian dynamic linear models for structural health monitoring

Goulet

2017

Struct Control Health Monit

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“…Due to possible changes in the buildings' natural frequencies during its service life [29,30], uncertainty in the stiffness of the building of ±10% is considered. Table 2 gives the uncontrolled and controlled responses of the building in the x-direction.…”

Section: Response In the X-directionmentioning

confidence: 99%

Proposed Configurations for the Use of Smart Dampers with Bracings in Tall Buildings

Aly

Zasso

Resta

2012

Smart Materials Research

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This paper presents wind-induced response reduction in a very slender building using smart dampers with proposed bracingslever mechanism system. The building presents a case study of an engineered design that is instructive. The paper shows that shear response and flexural response of tall buildings present two very different cases for vibration suppression. Smart dampers are implemented optimally in the building to reduce its response in the lateral directions for both structural safety and occupant comfort concerns. New bracings-lever mechanism configurations are proposed for the dampers to improve their performance. The study shows how the proposed configurations can enable application to flexural response and scenarios where the interstory drift is not enough for dampers to work effectively. In addition, a decentralized bang-bang controller improved the performance of the smart dampers.

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“…Although there have been advancements in the finite element techniques and the frequency of the primary structure can be measured on‐site during the setup of the TMD, uncertainties may exist as a result of some localized damage or changing ambient conditions, such as wind speed (aeroelastic effects; Gu and Peng, ), temperature, relative humidity, building occupancy and other factors that might occur with the building during its service life. However, some long‐term monitoring studies reveal that the structural modal frequencies exhibited substantial seasonal variation without evidence of structural damage (Xia et al ., ; Sohn et al ., ; Lee and Yun, ; Yuen and Kuok, , ). Clinton et al .…”

Section: Introductionmentioning

confidence: 99%

Proposed robust tuned mass damper for response mitigation in buildings exposed to multidirectional wind

Aly

2012

Struct. Design Tall Spec. Build.

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SUMMARY The most common device for control of tall buildings under wind loads is the tuned mass damper (TMD). However, during their lifetimes, high‐rise and slender buildings may experience natural frequency changes under wind speed, ambient temperatures and relative humidity variations, among other factors, which make the TMD design challenging. In this paper, a proposed approach for the design of robust TMDs is presented and investigated. The approach accounts for structural uncertainties, optimization objectives and input excitation (wind or earthquake). For the use of TMDs in buildings, practical design parameters can be different from the optimum ones. Nevertheless, predetermined optimal parameters for a primary structure with uncertainties are useful to attain design robustness. To illustrate the applicability of the proposed approach, an example of a very slender building with uncertain natural frequencies is presented. The building represents a case study of an engineered design that is instructive. Basically, due to its geometry, the building behaves differently in one lateral direction (cantilever building) than the other (shear building). The proposed approach shows its robustness and effectiveness in reducing the response of tall buildings under multidirectional wind loads. In addition, linear‐quadratic Gaussian and fuzzy logic controllers enhanced the performance of the TMD. Copyright © 2012 John Wiley & Sons, Ltd.

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Modeling of environmental influence in structural health assessment for reinforced concrete buildings

Cited by 44 publications

References 27 publications

Bayesian dynamic linear models for structural health monitoring

Bayesian dynamic linear models for structural health monitoring

Proposed Configurations for the Use of Smart Dampers with Bracings in Tall Buildings

Proposed robust tuned mass damper for response mitigation in buildings exposed to multidirectional wind

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