# The Art of Computer Programming (2nd ed.): Mathematical Induction [closed]

In 1.2.1 Mathematical Induction section, Knuth presents mathematical induction as a two steps process to prove that P(n) is true for all positive integers n:

a) Give a proof that P(1) is true;

b) Give a proof that "if all P(1), P(2),..., P(n) are true, then P(n+1) is also true";

I have serious doubt about that. Indeed, I believe that point b) should be:

b) Give a proof that "if P(n) is true, then P(n+1) is also true". The major difference here is that you are only assuming that P(n) is true, not P(n-1), etc.

However, these books are old and have been read by many people (most of them being much more clever than I am^^).

So what is my confusion here?

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If `n` is arbitrary and P(1) ... P(n) are true, then can't you say `k = n + 1`, so by the previous statement, P(1) ... P(k) = P(1) ... P(n + 1) is also true? –  Blender Mar 15 at 8:12
Maybe a question for math.stackexchange.com? –  Markus Mar 15 at 8:13
possibly a question for math.stackexchange ? Although, the reference is from Computer Science. –  Srikanth Venugopalan Mar 15 at 8:14
There are two typical ways of doing induction. The version you're using is usually called "weak induction" or just "induction," while Knuth is using "complete induction" or "strong induction." The two are equivalent to one another. –  templatetypedef Mar 15 at 8:17
@blender: yes, this is my point. Knuth is doing it the other way around. Proving P(n) => P(n+1) proves that P(1)..P(n) is true. Stating that P(1)...P(n) is true, without actually proving it seems too strong to me;) –  Korchkidu Mar 15 at 8:34
The entire point here is that the choice of `n` is arbitrary. Since `P(n)` implies `P(n+1)` is the conerstone of induction, then all the intermediate values between 1 and `n` will also hold under the assumption of `P(n)`. You are supposed to show that if `P(0)` implies `P(1)` and `P(n)` implies `P(n+1)` then all conditions hold by the nature of `n` being arbitrary.