I'm trying to understand a para in my AI textbook, and need help with this.
Essentially, my question is why are there 2^(2^n) functions on n attributes if it takes 2^n bits to define a function?
Here is the para from the text (source: AI: A Modern Approach, Stuart Russell and Peter Norvig):
Decision Trees are good for some kinds of functions and bad for others. Is there any kind of representation that is efficient for all kinds of functions? Unfortunately, no. We can show this in a very general way. Consider the set of all Boolean functions on n attributes. How many different functions are in this set? This is just the number of different truth tables that we can write down, because the function is defined by its truth table. The truth table has 2^n rows, because each input case is described by n attributes. We can consider the 'answer' column of the table as a 2^n-bit number that defines the function. No matter what representation we use for functions, some of the functions (almost all of them, in fact) are going to require at least that many bits to represent.
If it takes 2^n bits to define the function, then there are 2^(2^n) different functions on n attributes.
A second question is: Why do we need 2^n bit number (see bold above), I thought we'd need n bit number only, for example if we have 3 attributes, we can define 2^3=8 functions, thus needing only 3 bits to define all 8 functions (000, 001, 010, 011, etc).
i've been thinking about this for awhile, not sure what eludes me, thank you for your time in looking into this!