Plotting all numbers from a set
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Is it possible to plot all of the floating point numbers from a given set [1,2] to see the interval between consecutive numbers? How do I do this?
Accepted Answer
Walter Roberson
on 25 Oct 2013
If you need to "prove" without reference to the documentation of how floating point values are stored, consider empirical proof:
R = 1 + rand(1,10000000); %say 10 million attempts;
D = min(diff(unique(R))); %sort the tries. Find the adjacent differences. What is the smallest difference?
Any particular answer you get with this would be an upper-bound on the difference between adjacent values in the interval.
Now, how do you know that there are not locations in the interval where the difference might be smaller? You do not, with certainty -- but you can generate more random numbers. You can also use a minor variation of The Birthday Paradox in order to calculate the confidence value that you have found the minimum.
So then, how do you know that there are no locations where the difference between adjacent values is not more than the calculated value? Well, if you take
R = rand(1,1000000);
U = unique((R+D) - R);
then what information would U give you?
More Answers (2)
Jan
on 25 Oct 2013
1 vote
The question is not clear. "all floating point numbers from a given set [1,2]" are the two numbers 1.0 and 2.0, and it is easy to "plot" them. But what does "see the interval" mean then?
Do you mean all floating point numbers of a given interval?
Please explain, what you actually want to achieve.
3 Comments
Beaya
on 25 Oct 2013
Matt Kindig
on 25 Oct 2013
This question is still not clear. Given that the floating point values are defined as (by definition) on a discrete interval, of course they can be presented as 1 + k*epsilon, as floating point numbers are defined that way. The resulting will indeed be uniformly distributed, but only because you are defining them to be so (by defining them as double floating-point numbers, which have a finite set of 64-bit binary representations). In other words, you are not really proving anything.
Jan
on 25 Oct 2013
What do you mean by "prove"? What kind of "plot" do you want? A diagram with 2^52 values would not reveal anything. Reading the IEEE-754 definitions should clear all corresponding questions.
Azzi Abdelmalek
on 25 Oct 2013
0 votes
There is an infinity of floating numbers in your interval. You can't plot all the numbers
8 Comments
Walter Roberson
on 25 Oct 2013
There is not an infinity of floating point numbers in the interval: there are only 2^53 or so of them. Too large to manage is not the same as infinite ;-)
Azzi Abdelmalek
on 26 Oct 2013
Instead of checking the whole interval, which needs a huge amount of memory and time, we can check the beginning and the end of the interval.
a=1
n=1e+6 % number of samples
pas=1e-21; % step
t=a:pas:a+n*pas;
y=unique(t);
v=unique((diff(y)))
%Result
2.2204e-16
Check it again with
a=2-n*pas
% the result is the same
Walter Roberson
on 26 Oct 2013
1 + 1e+6 * 1e-21 does not reach 2, "the end of the interval" ?
Azzi Abdelmalek
on 26 Oct 2013
It's not what I meant, I said the first part of the interval [1,2] which is [1,1+1e+6*1e-21] and the last part of the interval [2-1e+6*1e-21,2]
Beaya
on 28 Oct 2013
Azzi Abdelmalek
on 28 Oct 2013
Edited: Azzi Abdelmalek
on 28 Oct 2013
From Walter's answer we can see the the smallest step is 2.2204e-16. I could choose pas=1e-22 but the number of samples must be greater, for example n=1e+7. I tried to choose pas as small as possible, at the same time I have to handle the problem of memory
You wrotte 1e-21 = -18.2817181715, It's not possible
Walter Roberson
on 28 Oct 2013
-18.2817181715 would be exp(1) - 21, and exp(1) is often given the letter "e" as its symbol.
1e-21 on the other hand means 1 * 10^(-21), and is a syntax known to MATLAB. It can also be written 1.0E-21
Beaya
on 1 Nov 2013
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