I am trying to graph the following function:
f(x) = 0 if x is rational else 1 # so 1 if x is irrational
My plan is to use python and matplotlib. How do you generate random irrational numbers in Python?
This is called Dirichlet function, and it's example of function that nowhere continuous. It's a simple mathematical fact, between any pair of numbers, there is infinite number of rational and infinite irrational number.
Plotting this function in practice is equivalent to plotting f(x) = 0 and f(x) = 1, as you're plotting using discrete pixels.
There are two gotchas:
Either way, this kind of "problem" is not meant to be approached as strictly programming problem.
|show 6 more comments|
The answer is you can't.
What you can do is figure out some epsilon after which this number is considered irrational.
It will look the same.
consider this: square root of 2 is an irrational number.
wolframlpah gives you an approximation : 1.4142135623730950488016887242096980785696718753769480...
python only sees 1.4142135623730950488016887242096980785696718753769480 which means: 1+ 4142135623730950488016887242096980785696718753769480/ 10000000000000000000000000000000000000000000000000000
A random number is irrational almost always (i.e. withprobability 1)
works almost always as you want!
|show 9 more comments|
It is not true that you cannot represent an irrational number in a computer program. It doesn't fit into memory, you cannot print the whole irrational number, but you can still do some calculations with them and do operations like "give me the first 100 digits". You can represent them as a kind of lazy enumerator. The problem is, that this does not really fit your needs because checking if this kind of number is rational is equivalent to the halting problem and hence undecidable.
But choosing an irrational number in an interval, e.g. between 0 and 1 is not always impossible, it just depends on what you want to do. I recently did that, but the application of those numbers just that they had to be compared and some decisions of the algorithm depended on the these comparisions. Here, representing them as lazy enumerators works fine: If you compare, you start on the left side and compare each digit until one number has a larger digit. So we just generate random digits on the fly and store the generated digits in an array until they are different from the corresponding digit of the number we are comparing to.
Just to make the difference clear between a finite number and an infinite number for which we only need a finite part: In the first case, the length of the number is fixed and bounded, in the second case, we only have to store a finite number of digits, but this number may grow beyond any bound, so every finite number is different from such an infinite number, if we compare enough digits.