Converting acceleration data to displacement data using FFT results in Zero-drift

35 views (last 30 days)
Johann Vormadal
Johann Vormadal on 23 May 2024
Commented: Johann Vormadal on 29 May 2024
I have a (n x 1) vector containing acceleration data from a sensor and I am trying to obtain the displacement by:
  1. performing an FFT
  2. Convert acceleration to displacement in the frequency domain by dividing by -omega^2
  3. performing an IFFT to get back to the time domain.
The idea is to make a conversion which doesn't result in any Zero-drift, but all my attempts so far result in the oscillation being superimposed on a very low frequency wave (See figure attached), and I can't tell where this low frequency oscillation is coming from. The result should be a near sinusoidal wave centred around zero.
Below is a (slightly modified) snippet from my code. The sensor data (Ch5) is attached as a .mat file.
Tinterval = 0.000625;
Length = length(Ch5);
SamplingFrequency = 1/Tinterval;
Frequency = SamplingFrequency*(0:Length-1)/Length;
Omega = 2*pi*Frequency;
ConversionFactor = -(Omega.^2).';
ConversionFactor(1,:) = 1; %To avoid dividing by zero
% Base Data
RawData = Ch5;
Data = RawData - mean(RawData);
FourierTransform = fft(Data);
Y_accel_base = ifft(FourierTransform).';
dY_base = abs(ifft(FourierTransform./ConversionFactor)).';
  2 Comments
Mathieu NOE
Mathieu NOE on 27 May 2024
hello
doing it by fft/ifft is a requirement or just an idea ?
also notice that the raw data is not zero mean, so you're going to have drift on first integration then a parabolic trend on the 2nd integration
Johann Vormadal
Johann Vormadal on 28 May 2024
Hi,
In my code I remove my DC offset before applying the fft.
The requirement is to have zero drift. the fft/ifft seems to be the best way to acheive this (in theory).

Sign in to comment.

Sign in to answer this question.

Answers (1)

Mathieu NOE
Mathieu NOE on 27 May 2024
Ran in:
FYI, a very simple time domain approach - assuming we don't care about the DC values , only the dynamic portion of the data is of interest
results may be even refined by adding some high pass filtering if you really need it
load('Ch5 data.mat')
dt = 0.000625;
fs = 1/dt; % sampling rate
acc = Ch5;
samples = numel(acc);
t = (0:samples-1)*dt;
% remove DC value
acc = acc - mean(acc);
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
velocity = cumtrapz(dt,acc);
velocity = detrend(velocity); % baseline correction
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
disp = cumtrapz(dt,velocity);
disp = detrend(disp); % baseline correction
%
figure(1)
subplot(311),plot(t,acc);
title('accel'); ylabel('m/s²');xlabel('time (s)');
subplot(312),plot(t,velocity);
title('velocity'); ylabel('m/s');xlabel('time (s)');
subplot(313),plot(t,disp);
title('disp'); ylabel('m');xlabel('time (s)');
  5 Comments
Show 3 older comments
Johann Vormadal
Johann Vormadal on 29 May 2024
Thank you for those links!
Those also use the fft method, but their code is slightly different and much more elegant. I will try and emulate them, and see if it solves my problem.

Sign in to comment.

Categories

Find more on Antennas, Microphones, and Sonar Transducers in Help Center and File Exchange

Tags

Products


Release

R2022a

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!