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In order to develop my implementation of the particle filter algorithm, I need to generate hypotheses about the movements relating to the object to be tracked: if I set N samples and if I use a 2-by-1 state vector, then at each step I have to generate N pairs of random values (a 2-by-N matrix). Moreover, if I know the statistics of movements (mean and standard deviation), then I could use the mean and standard deviation to generate all N values. Finally, to model the uncertainty of the movement, I could generate a noise matrix (a 2-by-N matrix) and add it to the matrix of movements.

Based on these premises, I have implemented the algorithm running in matlab, and I used the following code in order to generate the hypotheses of movement.

ds_mean = [dx_mean dy_mean];
ds_stddev = [dx_stddev dy_stddev];
d = 5;

V = zeros(2,N);
V(1,:) = normrnd(ds_mean(1),ds_stddev(1),1,N);   % hypotheses of movement on x axis
V(2,:) = normrnd(ds_mean(2),ds_stddev(2),1,N);   % hypotheses of movement on y axis

E = d*randn(2,N);   % weighted noise

M = V + E;   % hypotheses of movement

A problem occurred when I had to implement the same algorithm using C++ and OpenCV: substantially, while the above matlab code generates good predictions (it works great), instead the same code written in C++ (see the code below) generates poor predictions (ie far away from the object). Why?

RNG m_rng;

x_mean = // ...
y_mean = // ...
x_stddev = // ...
y_stddev = // ...

Mat velocity(STATE_DIM, NUM_PARTICLES, DataType<double>::type);
m_rng.fill(velocity.row(0), RNG::NORMAL, x_mean, x_stddev);
m_rng.fill(velocity.row(1), RNG::NORMAL, y_mean, y_stddev);

Mat noise(STATE_DIM, NUM_PARTICLES, DataType<double>::type);
m_rng.fill(noise,RNG::NORMAL,0,1);
noise *= d;   % weighted noise

movements = velocity + noise;

How to make sure that the C++ algorithm works as well as the algorithm implemented in matlab?

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1 Answer 1

I think I just serendipitously answered your question here, or at least provided an alternative solution.

http://stackoverflow.com/a/13897938/1899861

I believe this will generate proper random numbers, and has been tested to death when compiled using Microsoft C on Intel processors (386, 486, Pentium).

FYI, 4.0 * atan(1.0) yields a much better value of PI than the constant in the above environment.

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How to get values ​​distributed according to the normal distribution using the random vectors returned by your code? –  enzom83 Dec 16 '12 at 2:39
    
I had a half-dozen Phds in stats testing the output, so am going to have to guess, but my guess would be to build a large table and run it through some statistics code that can test for a normal dist curve. IIRC, there's some C code online for that, and at least 1 Open Source Lib for stats available for the downloading. Give that a try. --- OR --- Write the vectors as records in a .csv file. IE ascii with comma separators, and then suck that into your existing matlab (MathLab?) system (or something like SAS). –  RocketRoy Dec 16 '12 at 6:27
    
It appears that Matlab supports .csv files, so that seems to be an option. –  RocketRoy Dec 16 '12 at 6:39
    
Wikipedia says OpenCV has a C interface as well, so you might be able to use my C code as it is, without porting it to C++; –  RocketRoy Dec 16 '12 at 6:42

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