There's lot of literature on doing this by hand; see Karnaugh maps.
You can automate one of those techniques.
But in essence what you want to do is to construct a naive boolean equation representing your truth table, and then applied a symbolic boolean simplifier (or minimizer) to that equation (Hardware language synthesizers do this as part of their code generation process).
Constructing the naive equation is easy: build a conjunction for each row of
your truth table which produces true, and take the disjunction of all the conjunctions. Your first table would produce the naive equation:
(~a & ~b) | (a & ~b)
If you applied boolean simplification to this:
((~a | a) & ~b) // combine terms
(TRUE & ~b ) // consequence of ~a | a
~b // the answer
Your second table would produce the naive equation:
(~a & b) | (a & ~b )
Which doesn't simplify further.
You can use a program transformation system to accomplish this. Such a system typically allows you to define a parser for your input language (in this case, the truth tables), and to define transformations from your input langauge to the output language, and more transformations on the output language. Your input-to-output transformation would map the truth table notation to the boolean equation notation. Transformations on the boolean equations would then carry out the simplifications.
Once you have a simplified formula, then you want to apply yet another set of transformations to map from pure boolean algebra into your final computer language, in your case, PHP.
We've done this kind of thing quite often with our DMS Software Reengineering Toolkit. DMS brings some nice help to problem: it understands associate and commutative algebraic rewrites, which makes producting the simplification equations easier and more robust in the face of complicated formulas.
We've applied DMS to algebraic boolean formulas with literally hundreds of thousand of literals (terms of the form of A or ~A) in a number of cases. One example was a code generator that accepted a description of how to control a factory (literally) in terms of sensors (reading the factory state) and actuators (things that change the factory state), genrrated the equations, simplified them, and then translated them to multiple different target computer languages for industrial controllers called PLCs.
You can see an example, not of boolean simplification, but of real algebraic simplification using DMS. Boolean simplification is easier to write :-}