I think the confusion here is coming from the fact that usually fitness functions give you back some scalar, sometimes on a discrete scale, but never a binary yes/no (or true/false). In this sense, this looks more like a 'classification' problem to be solved with neural nets (or possibly bayesian logic). Said so, you could certainly devise a GA to evolve whatever kind of classifier, and the fitness function would basically be expressed in terms of correct classifications over total evaluations.

Another pure GA approach to this - probably more relevant to the question - is to encode **the whole classification rule set** as a given individual for the genetic algorithm. In this sense, the fitness function could be expressed as a scalar representing how many yes/no classifications the given candidate solution at hand gets right over the total, and so forth. A similar approach can be found in this paper Using Real-Valued Genetic: Algorithms to Evolve R,de Sets for
Classification.

Example (one of the possible ways to encode this):

```
A1, A2, A3, Outcome
red dark large yes
green dark small yes
orange bright large no
```

Encoding: red = 000, dark = 001, large = 010, green = 011, small = 100, orange = 101, bright = 111, etc.
Outcome: yes = 1, no = 0

Chromosome:

```
A1, A2, A3, Outcome
000 001 010 1
011 001 100 1
101 111 010 0
```

All of the above gets translated into a candidate solution as:

```
000001010-1/011001100-1/101111010-0
```

You will generate a random bunch of these and evolve them whichever way you like by testing fitness (correct classification/ total classifications in the ruleset) of the entire rule set (be careful picking your cross-over strategy here!).

I also suggest you listen to a binary solo, to get you in the mood.

**NOTE**: I highly doubt this would work with a rule-set composed by *only* 3 rules, not enough breadth for the GA.

`[A_1 - A_i]`

and returns either yes or no. – Ishtar Apr 17 '11 at 11:48