Presentation is loading. Please wait.

Presentation is loading. Please wait.

Time-frequency-domain modal identification of ambient vibration structures using Wavelet Transform Numerical example.

Published byBraden Winkley Modified over 9 years ago

Similar presentations

Presentation on theme: "Time-frequency-domain modal identification of ambient vibration structures using Wavelet Transform Numerical example."— Presentation transcript:

1 Time-frequency-domain modal identification of ambient vibration structures using Wavelet Transform Numerical example

2 Natural frequency & damping Frequency Time Cutting slide Frequency domain Time domain Damping Ratios Identification Natural Frequencies Identification

3 Wavelet transform  Continuous wavelet transform (CWT) is defined as convolution operator of signal X(t) and wavelet function : Wavelet function : Complex conjugate of wavelet function : Wavelet transform coefficient : Wavelet scale and translation parameters  Info of time and frequency can be obtained. Relation of wavelet scale and Fourier frequency can be estimated s : Wavelet scale; f F : Fourier frequency f s : Sampling frequency; f  : Central wavelet frequency

4 Wavelet function  The complex Morlet wavelet is commonly used in the CWT: : Fourier transform of complex Morlet wavelet : Fourier frequency and central wavelet frequency

5 Damping & mode shapes  Output displacements of the MDOF system can be decomposed in the structural normalized coordinates  Wavelet transform coefficient of output response:  Mode shape can be estimated via the wavelet coefficients of output displacements at point k and reference point:  Decay envelope and logarithmic decrement can be extracted from this decay envelope and in tern of modulus: and

6 Damped natural frequencies Wavelet transform (Floor1) Frequency domain Wavelet transform (Floor5)  =80s Frequency domain 5.91Hz 9.12Hz 14.02Hz Difficulties in identifying high-order low-dominant frequencnies Difficulties in identifying high-order low-dominant frequencnies due to inflexible resolutions & used smoothing due to inflexible resolutions & used smoothing

7 Refined by bandwidth filtering Filtered at frequency bandwidths Filtered at frequency bandwidths 1) 0-3.125Hz 1) 0-3.125Hz 2) 3.125-6.25Hz 2) 3.125-6.25Hz 3) 6.25-12.5Hz 3) 6.25-12.5Hz 4) 12.5-25Hz 4) 12.5-25Hz 5) 25-50Hz 5) 25-50Hz

8 Refined wavelet transform Bandwidth 0-20Hz [Bandwidth 0-3.125Hz] [Bandwidth 3.125-6.25Hz] [Bandwidth 6.25-12.5Hz] Only 1 st mode dominated f1=1.72Hz f2=5.37Hz f3=8.99Hz Refined and localized by Refined and localized by multiresolution analysis multiresolution analysis Filtered at frequency Filtered at frequency bandwidths bandwidths (0-3.125Hz; 3.125-6.25Hz (0-3.125Hz; 3.125-6.25Hz 6.25-12.5Hz; 12.5-25Hz; 6.25-12.5Hz; 12.5-25Hz; 25-50Hz) 25-50Hz) Dominant for mode 1 Dominant for mode 3 Dominant for mode 2

9 Refined wavelet transform [Bandwidth 0-3.125Hz] [Bandwidth 3.125-6.25Hz] [Bandwidth 6.25-12.5Hz] f1=1.72Hz f2=5.37Hz f3=8.99Hz Mode 1 Mode 2 Mode 3 [Slide 1] [Slide 2] [Slide 1] [Slide 2] [Slide 1] [Slide 2] 1.76Hz 5.49Hz 8.95Hz Amplitude envelope slop Damped Natural Frequencies (Hz) FEMFDDFDD-RDTWT mode 11.691.73 1.76 mode 25.225.355.345.47 mode 39.268.848.828.95 mode 413.613.6913.6713.72 mode 517.818.0518.0218.14

Download ppt "Time-frequency-domain modal identification of ambient vibration structures using Wavelet Transform Numerical example."

Similar presentations

Extracting Dynamic Characteristics from Strong Motion Data Palle Andersen Structural Vibration Solutions A/S Denmark www.svibs.com.

Extracting Dynamic Characteristics from Strong Motion Data Palle Andersen Structural Vibration Solutions A/S Denmark
Signal Estimation Technology Inc. Maher S. Maklad Optimal Resolution of Noisy Seismic Data Resolve++

Signal Estimation Technology Inc. Maher S. Maklad Optimal Resolution of Noisy Seismic Data Resolve++
Lecture 7: Basis Functions & Fourier Series

Lecture 7: Basis Functions & Fourier Series
Modal parameter estimation of low-rise building using sine sweep vibration tests Le Thai Hoa Wind Engineering Research Center Tokyo Polytechnic University.

Modal parameter estimation of low-rise building using sine sweep vibration tests Le Thai Hoa Wind Engineering Research Center Tokyo Polytechnic University.
Applications in Signal and Image Processing

Applications in Signal and Image Processing
slide 1 Measuring Natural Frequency and Non-Linear Damping on Oscillating Micro Plates ICEM 13 Alexandroupolis, Greece July 1-5, 2007 Sandia is a multiprogram.

slide 1 Measuring Natural Frequency and Non-Linear Damping on Oscillating Micro Plates ICEM 13 Alexandroupolis, Greece July 1-5, 2007 Sandia is a multiprogram.
MODULE 10 EXPERIMENTAL MODAL ANALYSIS Most vibration problems are related to resonance phenomena where operational forces excite one or more mode of vibration.

MODULE 10 EXPERIMENTAL MODAL ANALYSIS Most vibration problems are related to resonance phenomena where operational forces excite one or more mode of vibration.
Oscillation Detection and Modal Analysis of Ambient Data

Oscillation Detection and Modal Analysis of Ambient Data
Time and Frequency Representations Accompanying presentation Kenan Gençol presented in the course Signal Transformations instructed by Prof.Dr. Ömer Nezih.

Time and Frequency Representations Accompanying presentation Kenan Gençol presented in the course Signal Transformations instructed by Prof.Dr. Ömer Nezih.
Time-Frequency and Time-Scale Analysis of Doppler Ultrasound Signals

Time-Frequency and Time-Scale Analysis of Doppler Ultrasound Signals
Biomedical signal processing: Wavelets Yevhen Hlushchuk, 11 November 2004.

Biomedical signal processing: Wavelets Yevhen Hlushchuk, 11 November 2004.
Fourier Transform Analytic geometry gives a coordinate system for describing geometric objects. Fourier transform gives a coordinate system for functions.

Fourier Transform Analytic geometry gives a coordinate system for describing geometric objects. Fourier transform gives a coordinate system for functions.
Undecimated wavelet transform (Stationary Wavelet Transform)

Undecimated wavelet transform (Stationary Wavelet Transform)
Wavelet Transform A very brief look.

Wavelet Transform A very brief look.
Wavelet Transform. What Are Wavelets? In general, a family of representations using: hierarchical (nested) basis functions finite (“compact”) support.

Wavelet Transform. What Are Wavelets? In general, a family of representations using: hierarchical (nested) basis functions finite (“compact”) support.
Stability Spectral Analysis Based on the Damping Spectral Analysis and the Data from Dryden flight tests, ATW_f5_m83h10-1.

Stability Spectral Analysis Based on the Damping Spectral Analysis and the Data from Dryden flight tests, ATW_f5_m83h10-1.
ECE 501 Introduction to BME ECE 501 Dr. Hang. Part V Biomedical Signal Processing Introduction to Wavelet Transform ECE 501 Dr. Hang.

ECE 501 Introduction to BME ECE 501 Dr. Hang. Part V Biomedical Signal Processing Introduction to Wavelet Transform ECE 501 Dr. Hang.
Transforms: Basis to Basis Normal Basis Hadamard Basis Basis functions Method to find coefficients (“Transform”) Inverse Transform.

Transforms: Basis to Basis Normal Basis Hadamard Basis Basis functions Method to find coefficients (“Transform”) Inverse Transform.
On the Accuracy of Modal Parameters Identified from Exponentially Windowed, Noise Contaminated Impulse Responses for a System with a Large Range of Decay.

On the Accuracy of Modal Parameters Identified from Exponentially Windowed, Noise Contaminated Impulse Responses for a System with a Large Range of Decay.
ENG4BF3 Medical Image Processing

ENG4BF3 Medical Image Processing

Similar presentations

Ads by Google