Extension of indirect displacement estimation method using acceleration and strain to various types of beam structures

Identification of structural crack location has become an intensely investigated subject due to its practical importance. In this paper, a hybrid method is presented to detect crack locations using wavelet transform and fractal dimension (FD) for beam structures. Wavelet transform is employed to decompose the mode shape of the cracked beam. In many cases, small crack location cannot be identified from approximation signal and detailed signals. And FD estimation method is applied to calculate FD parameters of detailed signals. The crack locations will be detected accurately by FD singularity of the detailed signals. The effectiveness of the proposed method is validated by numerical simulations and experimental investigations for a cantilever beam. The results indicate that the proposed method is feasible and can been extended to more complex structures.

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A coupled subsample displacement estimation method for ultrasound-based strain elastography

Physics in Medicine and Biology ◽

10.1088/0031-9155/60/21/8347 ◽

2015 ◽

Vol 60 (21) ◽

pp. 8347-8364 ◽

Cited By ~ 30

Author(s):

Jingfeng Jiang ◽

Timothy J Hall

Keyword(s):

Estimation Method ◽

Displacement Estimation ◽

Strain Elastography

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Research on the estimation method of the point-of-interest (POI) displacement for ultra-precision flexible motion system based on functional optical fiber sensor

Mechanics & Industry ◽

10.1051/meca/2021047 ◽

2021 ◽

Vol 22 ◽

pp. 48

Author(s):

Yujie Li ◽

Ming Zhang ◽

Yu Zhu

Keyword(s):

Optical Fiber ◽

Optical Fiber Sensor ◽

Estimation Method ◽

Fiber Optic Sensor ◽

Fiber Sensor ◽

Optic Fiber ◽

Estimation Model ◽

Fiber Sensors ◽

Optimal Position ◽

Displacement Estimation

This paper proposes a POI displacement estimation method based on the functional optical fiber sensor and the phase modulation principle to improve the POI displacement estimation accuracy. First, the relation between the object deformation and the optic fiber lightwave phase is explained; the measurement principle of functional optical fiber sensor based on the heterodyne interference principle and its layout optimization method is proposed, and a POI displacement estimation model is presented based on the data approach. Secondly, a beam is taken as the simulation object, the optimal position and length of the optical fiber sensor are determined based on its simulation data. Finally, the experimental device is designed to verify the effectiveness of the POI displacement estimation method based on the optic fiber sensors. The frequency-domain plot of the signals shows that the optical fiber sensors can express the flexible deformation of the analyzed object well. The POI displacement estimation model with the fiber optic sensor signals as one of the inputs is constructed. Through estimating the test data, the error using the optical fiber sensor-based POI displacement estimation method proposed in this paper reduces by more than 61% compared to the rigid body-based assumption estimation method.

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Dynamic Displacement Estimation for Long-Span Bridges Using Acceleration and Heuristically Enhanced Displacement Measurements of Real-Time Kinematic Global Navigation System

Sensors ◽

10.3390/s20185092 ◽

2020 ◽

Vol 20 (18) ◽

pp. 5092

Author(s):

Kiyoung Kim ◽

Hoon Sohn

Keyword(s):

Kalman Filter ◽

Large Scale ◽

Reduction Method ◽

Estimation Method ◽

Sampling Frequency ◽

Displacement Measurement ◽

Dynamic Displacement ◽

Displacement Estimation ◽

Gnss Receiver ◽

Civil Infrastructures

In this paper, we propose a dynamic displacement estimation method for large-scale civil infrastructures based on a two-stage Kalman filter and modified heuristic drift reduction method. When measuring displacement at large-scale infrastructures, a non-contact displacement sensor is placed on a limited number of spots such as foundations of the structures, and the sensor must have a very long measurement distance (typically longer than 100 m). RTK-GNSS, therefore, has been widely used in displacement measurement on civil infrastructures. However, RTK-GNSS has a low sampling frequency of 10–20 Hz and often suffers from its low stability due to the number of satellites and the surrounding environment. The proposed method combines data from an RTK-GNSS receiver and an accelerometer to estimate the dynamic displacement of the structure with higher precision and accuracy than those of RTK-GNSS and 100 Hz sampling frequency. In the proposed method, a heuristic drift reduction method estimates displacement with better accuracy employing a low-pass-filtered acceleration measurement by an accelerometer and a displacement measurement by an RTK-GNSS receiver. Then, the displacement estimated by the heuristic drift reduction method, the velocity measured by a single GNSS receiver, and the acceleration measured by the accelerometer are combined in a two-stage Kalman filter to estimate the dynamic displacement. The effectiveness of the proposed dynamic displacement estimation method was validated through three field application tests at Yeongjong Grand Bridge in Korea, San Francisco–Oakland Bay Bridge in California, and Qingfeng Bridge in China. In the field tests, the root-mean-square error of RTK-GNSS displacement measurement reduces by 55–78 percent after applying the proposed method.

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Experimental Validation of an Improved Dynamic Displacement Estimation Method using Accelerometer and Gyroscope

Structural Health Monitoring 2017 ◽

10.12783/shm2017/14171 ◽

2017 ◽

Author(s):

YIZHENG LIAO ◽

ANNE KIREMIDJIAN ◽

RAM RAJAGOPAL ◽

CHIN-HSIUNG LOH

Keyword(s):

Experimental Validation ◽

Estimation Method ◽

Dynamic Displacement ◽

Displacement Estimation

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Real-Time Structure Shape Estimation Using Distributed Fiber Bragg Grating Sensors

Volume 2: Multifunctional Materials; Enabling Technologies and Integrated System Design; Structural Health Monitoring/NDE; Bio-Inspired Smart Materials and Structures ◽

10.1115/smasis2009-1261 ◽

2009 ◽

Author(s):

Hong-Il Kim ◽

Lae-Hyong Kang ◽

Jae-Hung Han

Keyword(s):

Real Time ◽

High Speed ◽

Estimation Method ◽

Time Estimation ◽

Flexible Beam ◽

Beam Model ◽

Shape Estimation ◽

Rotating Beam ◽

Structural Shape ◽

Beam Structures

One of the emerging issues in lightweight aerospace structures is the real-time estimation of the structural shape changes. In order to reconstruct the structure shape based on the measured strain data at multiple points, the displacement-strain transformation (DST) method has been used. In this study, simulation for a 1-D beam model was performed to verify the DST method. Bending displacements for various excitation conditions were successfully estimated using the simulated strain signals. Strain sensor positions were optimized by the minimization of the condition number of the DST matrix for the 1-D beam. We further expanded the shape estimation method to rotating beams. A rotating flexible beam experimental model was constructed and a numerical simulation model was also prepared. Multiplexed four FBG sensors were fabricated and attached to the rotating beam structures to measure strains at four different locations. The experimental device has an optical rotary coupler, and the sensor signals are transmitted through the optical rotary coupler. Bending displacements were estimated based on the FBG signals and compared with directly measured displacement data using photographs taken by a high-speed camera. This shows the validity of the proposed shape estimation technique based on DST matrix for rotating beam structures.

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