# Random number in a certain interval with a exponential distribution [closed]

I'd like to generate a random number in a certain interval using an exponential distribution. My problem is that if I use exprnd I can't control the interval, I can only give a mean value, but that doesn't suit my needs. Is there another function or is there some trick that I have to use?

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## closed as off topic by rubenvb, brimborium, stealthyninja, j0k, GravitonNov 9 '12 at 2:28

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Thanks, but I've tried that and it doesn't work. Even if the uniform distribution is between 0 and 1 and I set lambda(in this article's case theta) to 1 I still get values above 1. I'd like to have an exponential distribution between 0 and 1 –  user1797895 Nov 4 '12 at 11:31
It is not very clear what you want exactly. The exponential distribution has support $[0, \infty]$. You want a distribution in $[a,b]$, in what sense should it be exponential? –  pedrosorio Nov 4 '12 at 11:31
What do you mean? exponential distribution is supported on the unlimited interval [0,+\infty). –  Acorbe Nov 4 '12 at 11:31
@MitchWheat user doesn't want an exponential distribution from a uniform. He already has a function to sample from the exponential. –  pedrosorio Nov 4 '12 at 11:33
Well, let's say that a is 0 and b is 1 and lambda is 1. In this case I'd like to have a very high probility of having a 0, but a very low probability of getting a 1. –  user1797895 Nov 4 '12 at 11:34

Does this help? (or have I misunderstood the problem?)

%#Set the parameters
T = 2000; %#Number of observations to simulate
Mu = 0.5; %#Exponential distribution parameter
LB = 0; %#Lower bound on exponential distribution
UB = 1; %#Upper bound on exponential distribution

%#Validate the parameters
if LB < 0 || UB < 0; error('Bounds must be non-negative'); end
if Mu <= 0; error('Mu must be positive'); end

%#Determine LB and UB in terms of cumulative probabilities
LBProb = expcdf(LB, Mu);
UBProb = expcdf(UB, Mu);

%#Simulate uniform draws from the interval LBProb to UBProb
Draw = LBProb + (UBProb - LBProb) .* rand(T, 1);

%#Convert the uniform draws to exponential draws using the inverse cdf
X = expinv(Draw, Mu);

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I guess user doesn't need to obtain exponential from uniform map, rather to remap exponential itself. –  Acorbe Nov 4 '12 at 11:46
@Acorbe Perhaps... I'm not sure user has a mathematical formulation in mind of what user wants :-) But nonetheless, this is one way to solve the problem as stated in the question. –  Colin T Bowers Nov 4 '12 at 11:49
Thanks a lot - this gets me the results that I want. –  user1797895 Nov 4 '12 at 11:50
@user1797895 Glad I could help. I think the comments are fairly self-explanatory, but let me know if you'd like a more detailed explanation and I can add one. Cheers. –  Colin T Bowers Nov 4 '12 at 11:52
@user1797895 You realize for this you still need to define lambda (in this case 0.5), right? It is essentially the same as my second suggestion. –  pedrosorio Nov 4 '12 at 11:52

Here's a suggestion:

Sample from the exponential distribution with lambda=1, and reject any number outside of your intended interval. If your interval is [0,1], you have a probability of ~0.63 to get a number in that interval. That means a 99% probability of getting a "good" number after 10 samples.

Another possibility is to choose a high enough number n, such that the probability of sampling something over n is sufficiently small. For lambda = 1, n=1000 would suffice. Then you just sample from the exponential and transform it to your random sample by a+(b-a)*(sample/n)

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The problem is that I can't generate random numbers given lambda in the PDF - that would solve all my problems. I have to give a mean, which really goes against everything I'm doing. –  user1797895 Nov 4 '12 at 11:43
What I'd like is to get output in the same format as for example unifrnd(0,1,1, 10) , but with an exponential distribution. –  user1797895 Nov 4 '12 at 11:45
You don't want to give a mean, but you want "an exponential distribution"? What does this mean? You need to decide what kind of distribution you want... –  pedrosorio Nov 4 '12 at 11:47

Exponential distribution is supported on [0,+\infty). You may want to remap it on [0,1) using some measurable invertible map f, so that Y = f(X) is a random variable supported on [0,1).

Problem: you have to build such an f.

My suggestion is

 f(x) = 2/pi * arctan(x).


The function arctan maps (-\infty,\infty) to (-pi/2,pi/2). Because you are considering just positive samples (because your X goes exponentially) you will obtain samples in [0,pi/2); thus, you have to rescale by 2/pi. Moreover, because the MacLaurin expansion of arctan is x+o(x), you have samples that go exactly exponentially close enough to the origin.

Now, if you sample from whatever exponential (i.e. using possibly any value of \lambda - preferably small) and you evaluate f on the sample, you get samples that concentrate as you like (i.e. close to 0 and nearly exponential).

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