Forward-Backward Induction

Theorem
Let $P \left({n}\right)$ be a propositional function depending on $n \in \N$.

Suppose that:
 * $(1): \quad \forall n \in \N: P \left({2^n}\right)$ holds.
 * $(2): \quad P \left({n}\right) \implies P \left({n-1}\right)$.

Then $P \left({n}\right)$ holds for all $\forall n \in \N$.

The proof technique based on this result is called backwards induction.

Proof
Suppose $\exists k \in \N$ such that $P \left({k}\right)$ is false.

From Power of Real Number greater than One is Unbounded Above‎, $\left\{{2^n: n \in \N}\right\}$ is unbounded above

Therefore we can find:
 * $M = 2^N > k$

Now let us create the set:
 * $S = \left\{{n \in \N: n < M, P \left({n}\right) \mbox{ is false}}\right\}$

As $k < M$ and $P \left({k}\right)$ is false, $S \ne \varnothing$ and as $\forall x \in S: x < M$ it follows that $S$ is bounded above.

So from Integers Bounded Above has Greatest Element, $S$ has a greatest element.

However, $P \left({n}\right)$ holds for $m < n \le M$ and hence $P \left({m+1}\right)$ holds.

But $P \left({m+1}\right) \implies P \left({m}\right)$ and so $P \left({m}\right)$ holds after all.

So there can be no such $m$ and therefore $S = \varnothing$, hence there can be no such $k \in \N$ such that $P \left({k}\right)$ is false.

Hence the result.