rev-rev proof -- Answer to Question 2
Major Section: INTRODUCTION-TO-THE-THEOREM-PROVER
The correct answer to Question 2 in logic-knowledge-taken-for-granted is Subgoal (i) plus any one of the other other three. For your reference, the four choices were:
Subgoal (i):
(implies (and (not (endp z))
(true-listp z))
(true-listp (cdr z)))
Subgoal (ii):
(implies (and (not (endp z))
(true-listp z)
(equal (rev (rev (cdr z))) (cdr z)))
(equal (rev (rev z)) z))
Subgoal (iii):
(implies (and (not (endp z))
(equal (rev (rev (cdr z))) (cdr z)))
(equal (rev (rev z)) z))
Subgoal (iv):
(implies (and (not (endp z))
(true-listp (cdr z))
(equal (rev (rev (cdr z))) (cdr z)))
(equal (rev (rev z)) z))
In particular, it is wrong to think the Induction Step of the proof of
(implies (true-listp z)
(equal (rev (rev z)) z))
can be established by proving just Subgoal (ii),
Subgoal (iii), Subgoal (iv), or combinations of
those three. You must also prove Subgoal (i) or something
like it!The Inductive Step for the conjecture above is
Induction Step:
(implies (and (not (endp z))
; Induction Hypothesis:
(implies (true-listp (cdr z))
(equal (rev (rev (cdr z))) (cdr z))))
; Induction Conclusion:
(implies (true-listp z)
(equal (rev (rev z)) z)))
Note that the Inductive Hypothesis is an implication:
(implies (true-listp (cdr z))
(equal (rev (rev (cdr z))) (cdr z)))
This hypothesis can be true two different ways. The ``normal'' way -- the
way everybody remembers -- is that (true-listp (cdr z)) is true and thus
(equal (rev (rev (cdr z))) (cdr z)) is true. But the way many people
forget is that (true-listp (cdr z)) is false. You must prove the
Induction Step even in this ``forgetable'' case.In this case, the Induction Step simplifies to
Induction Step:
(implies (and (not (endp z))
(not (true-listp (cdr z))))
(implies (true-listp z)
(equal (rev (rev z)) z)))
By Promotion (see the list of tautologies in our discussion of
propositional calculus)
this is
Induction Step':
(implies (and (not (endp z))
(not (true-listp (cdr z)))
(true-listp z))
(equal (rev (rev z)) z))
Using the Contrapositive and rearranging the order of the hypotheses (see
propositional calculus
again), this is
Induction Step'':
(implies (and (not (endp z))
(true-listp z)
(not (equal (rev (rev z)) z)))
(true-listp (cdr z)))
Notice that Subgoal (i) implies Induction Step'':
Subgoal (i):
(implies (and (not (endp z))
(truelistp z))
(truelistp (cdr z)))
Every inductive proof of an implication raises a case like this.
If we denote the conjecture (implies p q) as p ---> q, then
the Induction Step will look like this:
( c & (p' ---> q')) ---> (p ---> q)where
c is the test that determines the inductive step, (e.g., (not (endp z)))
and p' and q' are inductive instances of p and q. Promotion produces
( c & p & (p' ---> q')) ---> qIt is then very common to prove that
p implies p',
(i): (c & p) ---> p'and then prove that
q' implies q,
(ii): (c & p & q') ---> qThese correspond exactly to our choices Subgoal (i) and Subgoal (ii).
It is sometimes helpful to remember this diagram:
(c & (p' ---> q')
^ |
| |
| v
--> (p ---> q )
When you understand why Subgoals (i) and (ii) are sufficient,
use your browser's Back Button to return to
logic-knowledge-taken-for-granted and go to question Q3.