The Application Research of Inverse Finite Element Method for Frame Deformation Estimation

Zhao, Yong; Bao, Hong; Fang, Hongmei

doi:10.1155/2017/1326309

Cited by 15 publications

(15 citation statements)

References 14 publications

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“…

is the length of the beam element;

and n are the axial coordinate of the locations where the section strains are evaluated and the number of locations, respectively. For the end-node loads,

and for the uniformly distributed loads,

[ 27 , 28 , 29 , 41 ].…”

Section: Inverse Finite Element Methods Algorithm For Beam Deformatmentioning

confidence: 99%

“…The two key steps in iFEM are: (1) the selection of suitable shape functions for the beam deformation sensing with iFEM; (2) the calculation of section strains from the measured surface strain data. For step (1), literatures [ 27 , 28 , 29 , 41 , 42 ] provide the detailed derivation process and results. For step (2), the section strains are computed through the following equation [ 27 , 28 ]:

where,

is the in-situ section strains vector at location

, along the x -axis.…”

Section: Inverse Finite Element Methods Algorithm For Beam Deformatmentioning

confidence: 99%

“…In the case of end-node loads, 12 strain measurements are required for the calculation of Section 2 strain vectors; in the case of uniformly distributed loads, 18 strain measurements are required for the calculation of Section 3 strain vectors. As aforementioned in the literatures [ 27 , 28 , 29 , 41 ], the number of strain measurements is reduced through the constitutive equations of Equation (14) (refer to Figure 3 ) and the equilibrium equations of Equation (15).

where, the section forces (

) and moments (

) are related to the section strains

.…”

Section: Construction Of Optimal Placement Of Sensorsmentioning

confidence: 99%

“…For the uniformly distributed transverse loads, the section strains

are constant,

are linear and

are parabolic.

[ 28 , 41 ]. Through the aforementioned results, the section strains are calculated as:…”

Section: Construction Of Optimal Placement Of Sensorsmentioning

confidence: 99%

See 3 more Smart Citations

Optimal Sensor Placement Based on Eigenvalues Analysis for Sensing Deformation of Wing Frame Using iFEM

Zhao

Bao

et al. 2018

Sensors

Self Cite

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For real time monitoring of the wing state, in this paper, the inverse Finite Element Method (iFEM) is applied, which describes the displacement field of beam according to the Timoshenko theory, to sense the wing frame deformation. In order to maintain the accuracy and stability of frame deformation sensing with iFEM, an optimal placement model of strain sensors based on eigenvalue analysis is constructed. Through the model solution with the Particle Swarm Optimization (PSO) algorithm, two different optimal placement schemes of sensors are obtained. Finally, a simulation is performed on a simple cantilever beam and a static load experiment is conducted on an aluminum alloy wing frame. The results demonstrate that the iFEM is able to accurately sense the deformation of the wing frame, when the two optimal placement schemes of sensors are used.

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“…

is the length of the beam element;

and n are the axial coordinate of the locations where the section strains are evaluated and the number of locations, respectively. For the end-node loads,

and for the uniformly distributed loads,

[ 27 , 28 , 29 , 41 ].…”

Section: Inverse Finite Element Methods Algorithm For Beam Deformatmentioning

confidence: 99%

where,

is the in-situ section strains vector at location

, along the x -axis.…”

Section: Inverse Finite Element Methods Algorithm For Beam Deformatmentioning

confidence: 99%

where, the section forces (

) and moments (

) are related to the section strains

.…”

Section: Construction Of Optimal Placement Of Sensorsmentioning

confidence: 99%

“…For the uniformly distributed transverse loads, the section strains

are constant,

are linear and

are parabolic.

[ 28 , 41 ]. Through the aforementioned results, the section strains are calculated as:…”

Section: Construction Of Optimal Placement Of Sensorsmentioning

confidence: 99%

See 2 more Smart Citations

Optimal Sensor Placement Based on Eigenvalues Analysis for Sensing Deformation of Wing Frame Using iFEM

Zhao

Bao

et al. 2018

Sensors

Self Cite

View full text Add to dashboard Cite

show abstract

“…When only Equation (8) is used, six strain sensors need to be placed in one section for the calculation of the section strains vector eε; thus, the total number of the strain sensors used to capture the surface strain measurements is 6 × n in one inverse finite beam element. Herein, n is the minimum number of the sections where the section strains are evaluated, which is different under different loading cases [21]. For the end-node load, n equals 2, whereas for the uniformly distributed load, n equals 3.…”

Section: Construction Of the Measurement Modelmentioning

confidence: 99%

Real-Time Monitoring of the Position and Orientation of a Radio Telescope Sub-Reflector with Fiber Bragg Grating Sensors

Zhao

et al. 2019

Sensors

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Environmental loads linked with pointing errors, such as gravity, thermal gradients, and wind disturbances, are a serious concern for large-aperture high-frequency radio telescopes. For the purpose of maintaining the pointing performance of a telescope, a contact measurement scheme is proposed on basis of fiber Bragg grating (FBG) strain sensors that can monitor the sub-reflector shift in real time as the input data of the adjustment system. In this scheme, the relationship between the in situ strain measurement and the deformation of the supporting structure, which is the main cause of sub-reflector shift, is deduced using the inverse Finite Element Method (iFEM). Finally, experimental studies are carried out on a simple physical structure model to validate the effectiveness and accuracy of the contact measurement scheme.

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A convolutional neural network‐based full‐field response reconstruction framework with multitype inputs and outputs

Sun

et al. 2022

Structural Contr & Hlth

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Summary Structural health monitoring (SHM) systems evaluate the state of the infrastructures by analyzing the monitored responses. As measuring all target responses is difficult to accomplish due to technical or economic limitations, converting other easy‐measuring responses to the target one is a popular way. Relative approaches are separated into data‐driven and model‐driven ones. This paper proposes a deep learning‐based framework to reconstruct multitypes of full‐field responses. The adopted architecture is a convolutional neural network (CNN) with an autoencoder structure and skip connections. Varied from other data‐driven approaches, the training set in this paper is the responses computed by a finite element model (FEM), with which the CNN can learn the full‐field mapping relationships among varied response types. Therefore, the proposed framework is data‐model‐co‐driven. In the numerical simulation section, a simply‐supported beam and a continuous beam bridge have been adopted to discuss the influence of hyperparameters (training epoch, kernel size, skip connection, and bottleneck size), sensor arrangement, modeling error, and measurement noise, which indicates that the framework applies to the in‐field structures. Furtherly, a laboratory experiment has been conducted to validate the framework using a two‐span continuous bridge with obvious FEM error. All results have shown that the deep‐learning‐based response reconstruction algorithms can obtain the training set from not only in‐field measurements, but also numerical models to improve the diversity of training data.

show abstract

The Application Research of Inverse Finite Element Method for Frame Deformation Estimation

Cited by 15 publications

References 14 publications

Optimal Sensor Placement Based on Eigenvalues Analysis for Sensing Deformation of Wing Frame Using iFEM

Optimal Sensor Placement Based on Eigenvalues Analysis for Sensing Deformation of Wing Frame Using iFEM

Real-Time Monitoring of the Position and Orientation of a Radio Telescope Sub-Reflector with Fiber Bragg Grating Sensors

A convolutional neural network‐based full‐field response reconstruction framework with multitype inputs and outputs

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