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Storing small (1.0E-12) numbers as doubles in scientific notation

Here's the setup:

For my Bachelor's thesis, I want to test jet algorithms used at the LHC. Basically the first step is the folowing: Given some 4-momentum

``````p[0] = nullvector(45.0000000000106,33.03951484238976,14.97124733712793,26.6317895033428)
``````

I want to simulate experimental data by adding some (like, 50) randomly generated 4-vectors to the last three components in the order of 10^(-12), so that they are small (that's where the interesting physics happens), but significantly above the double float precision of 15 decimals. So the quick-and-dirty solution to that is the following:

``````seed=time(NULL);
srand(seed);
random=(rand()%9001)*1.0E-15;
random=random+1E-12;
printf("%.15E\n",random);
``````

This gives me random numbers between 1E-12 and 10E-12 (=1E-11) with three decimals max, so that in "real" doubles, that gives me 15 decimals.

Now to the point: Can I store numbers in that order with more than three decimals without overstepping double float precision?

PS: Is there a better way to generate small random numbers? (This sounds like another topic ;))

-

The traditional method for creating floating point random numbers is to make it a range [0-1) by taking `double x = (double)rand()/RAND_MAX;` - then multiply by `9001E-1` to scale your range to the `1E-12` to `1E-15` values [zero inclusive].
There are at least three problems with using remainder with `rand`: It discards some bits (mentioned above by Mats Petersson), there is poor entropy with poor generators (mentioned above by Frederick Cheung), and the distribution is non-uniform (the residues up to `RAND_MAX%YourQuotient` occur 1/RAND_MAX more often than others). – Eric Postpischil Mar 7 '13 at 22:06