I will prove this by
~S=>~P is logically equivalent to P=>S.
P=>S is logically equivalent to ~PvS.
Let v mean "or" and & mean "and".
Suppose ~PvS is false.
Therefore, ~(~PvS) is true. (This just means that the negation of it will be true.)
~(~PvS) = P&~S (De Morgan's Law) -----------(1)
So, if our assumption is correct, then all three statements that we have: P&~S, R=>S,
and (PvQ)=>(RvS) should be all true.
(PvQ)=>(RvS) is logically equivalent to ~(PvQ)v(RvS).
Which is equivalent to (~P&~Q)v(RvS).-------------------(2)
The other premise R=>S is equivalent to ~RvS. ----------(3)
If (1) is true from out assumption, then both P and ~S have to be true. This is because of the nature of the & logical connective.
~S is true, so S must be false. Now we substitute P=True and S=False into (2).
On the Left hand side: If P is true, then ~P must be false. Because of the nature of the & connective, (~P&~Q) must be false regardless of what ~Q is.
So now the Right hand side: (RvS) must be true if we need (2) to be true. Since S is false, then R must be true.
We have now deduced that: S is false, R is true, P is true.
Now we can substitute these truth values into (3). Since S is false. Then ~R must be true.
Hence, ~(~R) is false. Thus, R is false.
However, contradiction with the fact that R is true. So, our original assumption that ~S=>~P is false was wrong. Therefore, ~S=>~P is true.
At the end of the day, the logical equivalences that were mentioned previously can be verified by using a truth table. But it is good to memorize them. Cheers.