Let us more precisely define what we're trying to compute here. We have the infinite sum:

```
1 - ((x^2)/(2!)) + ((x^4)/(4!)) - ((x^6)/(6!)) + ...
```

Realize that the "..." here is informal notation for "process keeps going on forever". It is not a formal notation: it's asking the reader to think what the pattern is. Let us formally express what the terms of the sum should be.

Let T_n be the nth term:

```
T_n = (-1)^n * x^(2n)/(2n)!
```

Do you accept that this is a formal representation of the nth term of the partial sum?

If so, we can express this in terms of our programming language:

```
(define (t_n x n)
(/ (* (expt -1 n)
(expt x (* 2 n)))
(fact (* 2 n))))
(define (fact n)
(if (= n 0)
1
(* n (fact (sub1 n)))))
```

I do not know if what t_n computes is what your function computes. I do think that the t_n function here is an accurate representation of the math function.

If you accept that t_n computes the nth term of the partial sum, then:

```
(define (cos/approx x)
(for/sum ([k (in-range 100)])
(t_n x k)))
```

should be acceptable to you as an approximation of the cosine.

Once we start from a definition of cos/approx that is correct, we can start to work to make it efficient, via step-by-step rewriting to do things like preserve the accumulated factorials, etc., to eventually reach your definition. I believe there is a path to do so, though it may not fit in the margins of this textarea. :)

partial sumcomputed by the computer matches that of the mathematics. That is, given n, prove that the computation computes the correct partial sum. – dyoo Oct 5 '12 at 16:45