Double integration of raw acceleration data is a pretty poor estimate for displacement. The reason is that at each integration, you are compounding the noise in the data.

If you are dead set on working in the time-domain, the best results come from the following steps.

1. Remove the mean from your sample (now have zero-mean sample)

2. Integrate once to get velocity using some rule (trapezoidal, etc.)

3. Remove the mean from the velocity

4. Integrate again to get displacement.

5. Remove the mean. Note, if you plot this, you will see drift over time.

6. To eliminate (some to most) of the drift (trend), use a least squares fit (high degree depending on data) to determine polynomial coefficients.

7. Remove the least squares polynomial function from your data.

A much better way to get displacement from acceleration data is to work in the frequency domain. To do this, follow these steps...

1. Remove the mean from the accel. data

2. Take the Fourier transform (FFT) of the accel. data.

3. Convert the transformed accel. data to displacement data by dividing each element by -omega^2, where omega is the frequency band.

4. Now take the inverse FFT to get back to the time-domain and scale your result.

This will give you a much better estimate of displacement.

% 测试积分对正弦信号的作用

clc

clear

close all

% 原始正弦信号

ts = 0.001;

fs = 1/ts;

t = 0:ts:1000*ts;

f = 50;

dis = sin(2*pi*f*t);

% 位移

vel = 2*pi*f.*cos(2*pi*f*t);

% 速度

acc = -(2*pi*f).^2.*sin(2*pi*f*t);

% 加速度

% 多个正弦波的测试

% f1 = 400;

% dis1 = sin(2*pi*f1*t);

% 位移

% vel1 = 2*pi*f1.*cos(2*pi*f1*t);

% 速度

% acc1 = -(2*pi*f1).^2.*sin(2*pi*f1*t);

% 加速度

% dis = dis + dis1;

% vel = vel + vel1;

% acc = acc + acc1;

% 结：频域积分正常恢复信号，时域积分恢复加入的高频信息有误差

% 加噪声测试

acc = acc + (2*pi*f).^2*0.2*randn(size(acc));

% 结：噪声会使积分结果产生大的趋势项

figure

ax(1) = subplot(311);

plot(t, dis), title('位移')

ax(2) = subplot(312);

plot(t, vel), title('速度')

ax(3) = subplot(313);

plot(t, acc), title('加速度')

linkaxes(ax, 'x');

% 由加速度信号积分算位移

[disint, velint] = IntFcn(acc, t, ts, 2);

axes(ax(2));hold on

plot(t, velint, 'r'),

legend({'原始信号', '恢复信号'})

axes(ax(1));hold on

plot(t, disint, 'r'),

legend({'原始信号', '恢复信号'})

% 测试积分算子的频率特性

n = 30;

amp = zeros(n, 1);

f = [5:30 40:10:480];

figure

for i = 1:length(f)

    fi = f(i);

    acc = -(2*pi*fi).^2.*sin(2*pi*fi*t);

    % 加速度

    [disint, velint] = IntFcn(acc, t, ts, 2);

    % 积分算位移

    amp(i) = sqrt(sum(disint.^2))/sqrt(sum(dis.^2));

    plot(t, disint)

    drawnow

end

close

figure

plot(f, amp)

title('位移积分的频率特性曲线')

xlabel('f')

ylabel('单位正弦波的积分位移幅值')

% 积分操作由加速度求位移，可选时域积分和频域积分

function [disint, velint] = IntFcn(acc, t, ts, flag)

if flag == 1

    % 时域积分

    [disint, velint] = IntFcn_Time(t, acc);

    velenergy = sqrt(sum(velint.^2));

    velint = detrend(velint);

    velreenergy = sqrt(sum(velint.^2));

    velint = velint/velreenergy*velenergy; 

    disenergy = sqrt(sum(disint.^2));

    disint = detrend(disint);

    disreenergy = sqrt(sum(disint.^2));

    disint = disint/disreenergy*disenergy;

    % 此操作是为了弥补去趋势时能量的损失

    % 去除位移中的二次项

    p = polyfit(t, disint, 2);

    disint = disint - polyval(p, t);

else

    % 频域积分

    velint =  iomega(acc, ts, 3, 2);

    velint = detrend(velint);

    disint =  iomega(acc, ts, 3, 1);

    % 去除位移中的二次项

    p = polyfit(t, disint, 2);

    disint = disint - polyval(p, t);

end

end

% 时域内梯形积分

function [xn, vn] = IntFcn_Time(t, an)

vn = cumtrapz(t, an);

vn = vn - repmat(mean(vn), size(vn,1), 1);

xn = cumtrapz(t, vn);

xn = xn - repmat(mean(xn), size(xn,1), 1);

end

function dataout =  iomega(datain, dt, datain_type, dataout_type)

%%%%%%%%%%%%%%%%

%

%   IOMEGA is a MATLAB script for converting displacement, velocity, or

%   acceleration time-series to either displacement, velocity, or

%   acceleration times-series. The script takes an array of waveform data

%   (datain), transforms into the frequency-domain in order to more easily

%   convert into desired output form, and then converts back into the time

%   domain resulting in output (dataout) that is converted into the desired

%   form.

%

%   Variables:

%   ----------

%

%   datain       =   input waveform data of type datain_type

%

%   dataout      =   output waveform data of type dataout_type

%

%   dt           =   time increment (units of seconds per sample)

%

%                    1 - Displacement

%   datain_type  =   2 - Velocity

%                    3 - Acceleration

%

%                    1 - Displacement

%   dataout_type =   2 - Velocity

%                    3 - Acceleration

%

%

%%%%%%%%%%%%%%%%

%   Make sure that datain_type and dataout_type are either 1, 2 or 3

if (datain_type < 1="" ||="" datain_type=""> 3)

    error('Value for datain_type must be a 1, 2 or 3');

elseif (dataout_type < 1="" ||="" dataout_type=""> 3)

    error('Value for dataout_type must be a 1, 2 or 3');

end

%   Determine Number of points (next power of 2), frequency increment

%   and Nyquist frequency

N = 2^nextpow2(max(size(datain)));

df = 1/(N*dt);

Nyq = 1/(2*dt);

%   Save frequency array

iomega_array = 1i*2*pi*(-Nyq : df : Nyq-df);

iomega_exp = dataout_type - datain_type;

%   Pad datain array with zeros (if needed)

size1 = size(datain,1);

size2 = size(datain,2);

if (N-size1 ~= 0 && N-size2 ~= 0)

    if size1 > size2

        datain = vertcat(datain,zeros(N-size1,1));

    else

        datain = horzcat(datain,zeros(1,N-size2));

    end

end

%   Transform datain into frequency domain via FFT and shift output (A)

%   so that zero-frequency amplitude is in the middle of the array

%   (instead of the beginning)

A = fft(datain);

A = fftshift(A);

%   Convert datain of type datain_type to type dataout_type

for j = 1 : N

    if iomega_array(j) ~= 0

        A(j) = A(j) * (iomega_array(j) ^ iomega_exp);

    else

        A(j) = complex(0.0,0.0);

    end

end

%   Shift new frequency-amplitude array back to MATLAB format and

%   transform back into the time domain via the inverse FFT.

A = ifftshift(A);

datain = ifft(A);

%   Remove zeros that were added to datain in order to pad to next

%   biggerst power of 2 and return dataout.

if size1 > size2

    dataout = real(datain(1:size1,size2));

else

    dataout = real(datain(size1,1:size2));

end

return

本文转自新浪了凡春秋的博客，博主：了凡春秋，中国科技大学。