I'm not sure which expressions you need to prove the algorithm against. But if they look like typical RPN expressions, you'll need to establish something like the following:

1) algoritm works for 2 operands (and one operator)
and
algorithm works for 3 operands (and 2 operators)
==> that would be your base case
2) if algorithm works for n operands (and n-1 operators)
then it would have to work for n+1 operands.
==> that would be the inductive part of the proof

Good luck ;-)

Take heart concerning mathematical proofs, and also their sometimes confusing names. In the case of an *inductive* proof one is still expected to "figure out" something (some fact or some rule), sometimes by *deductive* logic, but then these facts and rules put together constitute an broader truth, buy induction; That is: because the base case is established as true and because one proved that if X was true for an "n" case then X would also be true for an "n+1" case, then we don't need to try every case, which could be a big number or even infinite)

Back on the stack-based expression evaluator... One final hint (in addtion to Captain Segfault's excellent explanation you're gonna feel over informed...).

The RPN expressions are such that:
- they have one fewer operator than operand
- they never provide an operator when the stack has fewer than 2 operands
in it (if they didn;t this would be the equivalent of an unbalanced
parenthesis situation in a plain expression, i.e. a invalid expression).

Assuming that the expression is valid (and hence doesn't provide too many operators too soon), the order in which the operand/operators are fed into the algorithm do not matter; they always leave the system in a stable situtation:
- either with one extra operand on the stack (but the knowledge that one extra operand will eventually come) or
- with one fewer operand on the stack (but the knowledge that the number of operands still to come is also one less).

So the order doesn't matter.