# Percentage Based Probability

I have this code snippet:

``````Random rand = new Random();
int chance = rand.Next(1, 101);

if (chance <= 25) // probability of 25%
{
Console.WriteLine("You win");
}
else
{
Console.WriteLine("You lose");
}
``````

My question is, does it really calculate a 25% probability for winning here? Is the chance of winning for the player here is really 25%?

Edit:

I just wrote this:

``````        double total = 0;
double prob = 0;
Random rnd = new Random();
for (int i = 0; i < 100; i++)
{
double chance = rnd.Next(1, 101);
if (chance <= 25) prob++;
total++;
}
Console.WriteLine(prob / total);
``````

And it's highly inaccurate. It goes from about 0.15 to 0.3.

But when I do more checks (change from (i < 100) to (i < 10000)) it's much more accurate.

Why is this? Why aren't 100 checks enough for it to be accurate?

-
Yes, providing rand is giving a normal distribution of random values. –  Vlad Dec 6 '13 at 17:55
@Vlad I think you mean uniform distribution. Normal distribution is Gaussian. –  clcto Dec 6 '13 at 17:58
You're right, I meant one thing and wrote another. Thanks. –  Vlad Dec 6 '13 at 18:01
if you rolled a die 6 times would you call it "highly inaccurate" if you got 2 or 3 of one number instead of 1 of each? –  AwokeKnowing Dec 6 '13 at 19:22
The variable total follows a binomial distribution with p=0.25. The standard deviation of total for 100 trials is thus sqrt(25) = 5. Using a normal approximation you'd thus only expect ~66% of tests to be in the interval 20 <= total <= 30, which means your calculated p is only between .2 and .3 66% of the time. If you increase to 1000 the same 66% interval is .235 <= total <= .265. For 10000 it's .245 <= total <= .255 –  Ben Allison Dec 10 '13 at 12:15

This is very easy to check for yourself:

``````Random rand = new Random();
int yes = 0;
const int iterations = 10000000;
for (int i = 0; i < iterations; i++)
{
if (rand.Next(1, 101) <= 25)
{
yes++;
}
}
Console.WriteLine((float)yes/iterations);
``````

the result:

``````0.2497914
``````

The conslusion: Yes, yes it is.

Edit: Just for fun, the LINQy version:

``````Random rand = new Random();
const int iterations = 10000000;
int sum = Enumerable.Range(1, iterations)
.Count(i => rand.Next(1, 101) <= 25);
Console.WriteLine(sum / (float)iterations);
``````
-
I know, right? Kids these days... –  AwokeKnowing Dec 6 '13 at 18:07
Thank you, but I've updated the post with a code that does a similar check. The problem is that if it checks 100 times, the result can be anywhere from 0.15 to 0.3, but when I check 10000 times, it much more accurate (in the code I wrote). Why is this so? Why aren't 100 checks enough? –  BlueRay010 Dec 6 '13 at 18:54
If you flip a coin twice and get the same result is the coin broken? –  Rotem Dec 7 '13 at 14:16

For most cases, I would say yes. However, you have to remember that most randomization algorithms use a pseudo-random generator, and so to some extent, you're at the mercy of the idiosyncrasies of that particular generator. I do agree with @AwokeKnowing that you can you also just do a random number between 1 and 4 and get the same result. I assume that the .Net randomization algorithm should suffice for most cases. For more info see:

http://en.wikipedia.org/wiki/Pseudorandom_number_generator

-

yes, that should work fine. just as >=75 would work too. if you just want 25%, you can go ahead and just do a random number between 1 and 4.

but please note, a 25% chance does NOT mean that out of 100 tries, he will win 25 times. It just means each time he has a 25% chance of winning. it's theoretically possible for him to win every single time. (but that will not happen, especially with a pseudo-random generator).

Internally the random number will be between 0 and 1 so it's just as random to use 4 as 1000, as far as that goes. add the parameter just projects it to the range you want.

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I know, but sometimes I can't just use fractions (for example in percentages like 65% or 55%), so I'm planning to use this for other percentages too. Thank you very much for your help. –  BlueRay010 Dec 6 '13 at 18:00