Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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);
noise *= d;   % weighted noise

movements = velocity + noise;

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

share|improve this question

1 Answer 1

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


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.

share|improve this answer
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

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.