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What is the relationship between recursion and proof by induction ?

Let's say fn(n),

recursion is fn(n) calls itself until meet base condition;

induction is when base condition is meet, try to prove (base case + 1) is also correct.

It seems recursion and induction are in different direction. One is start from n to base case, the other is start from base case to infinite.

Could someone explain the idea in details ?

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1 Answer 1

up vote 6 down vote accepted

Recursion and induction are very much the same thing! This becomes obvious if you use a programming language with dependent types, such as Agda, but it can be demonstrated to some extent without them too.

Remember, that due to the Curry-Howard correspondence, types are propositions and programs are proofs. When you are writing a function of type Nat -> Nat (I will use Haskell notation), you are trying to prove that, given a natural number, your program will terminate and produce another natural number. Now we may have a definition like this:

f 0 = 1
f (1 + n) = n * f n

which is both a recursive definition of f and an inductive proof of its termination at the same time!

You can read it as a proof in a following way:

Let's prove that f x terminates for any x.

  • Base case: we have f 0 constant by definition so it terminates.
  • Inductive case: if we assume f n termiates, f (1 + n) terminates too (because all the functions it calls terminate).

Note that as recursion is not limited to a function decrementing its counter, induction is not limited to natural numbers either. There is also structural induction, corresponding to structural recursion, both of which are very popular in mathematics/programming. These are to be used when trying to prove things/define functions on more complex data structures (lists/trees/etc.).

Now, to address your concern about the "direction" of the recursion/induction. It is helpful to consider "direction of demand" and "direction of supply" here, which are opposite.

When you define recursive function, the demand (method calls) flows from larger values to base case. On the other hand, the supply (the return values) flow from the base case to the larger values of parameter. "definedness" is another way way of thinking about supply. It starts at the base case and propagates to infinity via the recursive case.

Now, when you are doing inductive proofs, theorems are your supply while goals are your demand. You can make a theorem T 0 out of the base case and then improve to however large T n you like using inductive case: your supply flows from 0 to infinity. Now if you have a goal G n, you can make a smaller goals G (n-k) out of it using the inductive step until you reach zero. This way your demand goes from n to 0.

As you can see, the direction of supply is "to infinity" in both cases and the direction of demand is "to zero" in both cases.

You can also reverse the apparent order in the descriptions of induction and recursion without changing their meaning:

Induction is when to prove that P n holds you need to first reduce your goal to P 0 by repeatedly applying the inductive case and then prove the resulting goal using the base case.

Similarly, recursion is when you first define a base case and then define the further values in terms of the previous ones. See, the directions are easily swapped!

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I disagree with this strongly, particularly your notion that direction is not a valid thing to consider. You cannot simply turn it around if only for the reason that the natural numbers are bounded below but not bounded above. I am not familiar with structural induction and I think there is a distinction being made here between this and mathematical induction as a form of proof. That said, as your answer has been accepted by the OP it is clear that your description satisfies him and that ultimately is the purpose of this site so I shall delete my answer. –  mathematician1975 Jun 22 '12 at 20:12
@mathematician1975, I don't think the purpose of this site is the OP satisfaction. We should strive to find the truth by pointing out each other's mistakes. Now about the direction reversal. I have provided examples of sentences with directions reversed. Are the sentences wrong? I think they are still true. Both induction and recursion are about formation of finite chains of reasoning/method calls. I don't see anything wrong in reversal of finite chains, do you? –  Rotsor Jun 22 '12 at 23:27
I've tried to clarify my point by introducing the "direction of supply/demand" notion. Not sure if it makes much sense, but there you go. :D –  Rotsor Jun 22 '12 at 23:50
@Rostor I agree with what you say here "I don't think the purpose of this site is the OP satisfaction.". I simply do not see mathematical induction as a finite process, nor recursion for that matter (unless purely in the context of computer programming). I see induction as a means of establishing proof of some statement that holds for all natural numbers. This very notion implies that the process is not finite since the set of natural numbers is not finite. Consider the sum of natural numbers from 1 to N. Induction give a proff, while induction merely an alternative means to calculate the sum. –  mathematician1975 Jun 23 '12 at 8:21
I guess we will not convince one another anyway - but it is good to debate these things regardless :) –  mathematician1975 Jun 23 '12 at 8:22

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