I have the following three premises:
P or Q P => R Q => R
The symbol => represents the 'implies' operation. I understand that these premises constitute a dilemma, but how can they be combined into one logical expression?
Since each proposition in the list is true at the same time, there's an implied
but we know that
and that leaves us with just:
An implication like
and that can be converted to:
using that, we have:
if we factorize we get:
but we know that
and that leads to the final answer:
The initial problem presentation is just Or-Elimination in Natural Deduction. This is a principle of intuitionistic logic, it does not require a classical argument about Boolean Algebra here.
Intuitively, P v Q is like the type of a disjoint sum of either P or Q (like a union type in some programming languages). If you have a way to go from P => R and another to go from Q => R --- in other words functions of that type, respectively --- you can put them together to eliminate the disjunction and get result R in both cases.
This is sometimes presented as a higher-order functional combinator like this:
You can actually define P v Q is the logical operator that allows this reasoning for arbitrary R.
Further note that this is one of the key aspects of the Curry-Howard correspondence of logic and programming.
implication A=>B should be read as "if A is TRUE B CANNOT be FALSE" for boolean algebra it has an equivalent formula: implication A=>B is (!A || B) .
in your case P=>R ~ !P || R , Q=>R ~ !Q||R so we have !(P || Q) && R
update: complex expression is usually made by &-ing simple expression. Most likely you should prove some some expression X (let say P == "it is raining", Q == "it is snowing" , R == "I'll take an umbrella". And you should prove something like X == "I'll take an umbrella if it is raining and snowing")
So you do ((P || Q) && (P=>R) && (Q => R) ) => X. and you should check if it is true for all cases when simple expressions are true. Left part of this is exactly equals P||Q && R