# Help understanding a definitive integral

I am trying to translate a function in a book into code, using MATLAB and C#.

I am first trying to get the function to work properly in MATLAB.

Here are the instructions:

The variables are:

``````xt and m can be ignored.
zMax = Maximum Sensor Range (100)
zkt = Sensor Measurement (49)
zkt* = What sensor measurement should have been (50)
oHit = Std Deviation of my measurement (5)
``````

I have written the first formula, N(zkt;zkt*,oHit) in MATLAB as this:

``````hitProbabilty = (1/sqrt( 2*pi * (oHit^2) ))...
* exp(-0.5 * (((zkt- zktStar) ^ 2) / (oHit^2))  );
``````

This gives me the Gaussian curve I expect.

I have an issue with the definite integral below, I do not understand how to turn this into a real number, because I get horrible values out my code, which is this:

``````func = @(x) hitProbabilty * zkt * x;
normaliser = quad(func, 0, max) ^ -1;
hitProbabilty = normaliser * hitProbabilty;
``````

Can someone help me with this integral? It is supposed to normalize my curve, but it just goes crazy.... (I am doing this for zkt 0:1:100, with everything else the same, and graphing the probability it should output.)

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You should use the error function ERF (available in basic MATLAB)

EDIT1:

As @Jim Brissom mentioned, the cumulative distribution function (CDF) is related to the error function by:

``````normcdf(X) = (1 + erf(X/sqrt(2)) / 2 ,   where X~N(0,1)
``````

Note that NORMCDF requires the Statistics Toolbox

EDIT2:

I think there's been a small confusion seeing the comments.. The above only compute the normalizing factor, so if you want to compute the final probability over a certain range of values, you should do this:

``````zMax = 100;                         %# Maximum Sensor Range
zktStar = 50;                       %# What sensor measurement should have been
oHit = 5;                           %# Std Deviation of my measurement

%# p(0<z<zMax) = p(z<zMax) - p(z<0)
ncdf = diff( normcdf([0 zMax], zktStar, oHit) );
normaliser = 1 ./ ncdf;

zkt = linspace(0,zMax,500);         %# Sensor Measurement, 500 values in [0,zMax]
hitProbabilty = normpdf(zkt, zktStar, oHit) * normaliser;

plot(zkt, hitProbabilty)
xlabel('z^k_t'), ylabel('P_{hit}(z^k_t)'), title('Measurement Probability')
``````

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Sorry, but which part of my code do I replace with the error function? Do you mean instead of computing normaliser? –  James Sep 4 '10 at 21:37
Should I wait until after I compute all hitProbabilities, then do the ERF on that array? Then do I multiple the original array by the output of ERF? –  James Sep 4 '10 at 21:43
n = 1 ./ (normcdf((zMax-zktStar)/oHit) - 0.5); Always gives me the value 2, for all values, 0-100? erf() always gives me back 2? –  James Sep 4 '10 at 22:19
not really, try: `plot( 1 ./ (normcdf(([0:zMax]-zktStar)/oHit) - 0.5) )` and you will see a curve (`Inf` in the middle because we're dividing by zero!) –  Amro Sep 4 '10 at 22:21
It gives me a very odd graph, like an upside L, but mirrored horizontally and vertically as well. –  James Sep 4 '10 at 22:26

The N in your code is just the well-known gaussian or normal distribution. I am mentioning this because since you re-implemented it in Matlab, it seems you missed that, seeing as how it is obviously already implemented in Matlab.

Integrating the normal distribution will yield a cumulative distribution function, available in Matlab for the normal distribution via `normcdf`. The ncdf can be written in terms of `erf`, which is probably what Amro was talking about.

Using normcdf avoids integrating manually.

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I see, so over my loop of 100 values, I should use on the array, this gives me another array.. The articles multiplies the normal with the value, should I do this, or does the function do this for me? -- Do you also mean I can re-write my Gaussian function too? How would I go about doing this? I'm not really maths orientated, only being forced into it out of necessity, forgive my ignorance. –  James Sep 4 '10 at 21:50
You do not need to implement the normal distribution, in Matlab at least. You will have to do this in C#, though (unless you use a library, but this is a different matter). As for normalization: a cumulative distribution function f(x) expresses the probability that a random variable lies in the interval (-inf, x], which is basically the same as saying that the random variable is smaller or equal to x. normalcdf already includes the integration part, but not the power-to-minus-one part. This part probably refers to the percent point function, which is just the inverse of a cdf. –  Jim Brissom Sep 4 '10 at 22:05
I think I understand, so I can replace my code with: measurements = 0:1:100; actualDistance = 50; oHit = 50; hitProbabilities = normpdf(measurements, actualDistance, oHit ); normalisedProbabilities = edf(hitProbabilities); plot(measurements, normalisedProbabilities, measurements, normalisedProbabilities); –  James Sep 4 '10 at 22:11
Thanks for pointing out that the Gaussian function in instructions is a standard Gaussian function, so I don't have to re-write it in MATLAB and C#! –  James Sep 5 '10 at 9:10

In case you still need the result for the integral.

From Mathematica. The Calc is

``````hitProbabilty[zkt_] := (1/Sqrt[2*Pi*oHit^2])*Exp[-0.5*(((zkt - zktStar)^2)/(oHit^2))];
Integrate[hitProbabilty[zkt], {zkt, 0, zMax}];
``````

The result is (just for copy/paste)

``````((1.2533141373155001*oHit*zktStar*Erf[(0.7071067811865476*Sqrt[zktStar^2])/oHit])/
Sqrt[zktStar^2] +
(1.2533141373155001*oHit*(zMax-zktStar)*Erf[(0.7071067811865476*Sqrt[(zMax-zktStar)^2])/oHit])/
Sqrt[(zMax-zktStar)^2])/(2*oHit*Sqrt[2*Pi])
``````

Where Erf[] is the error function

HTH!

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