So what I have done is nonsense?

What if I defined it as having period 2π?

It has a period of 2*i*pi not 2*pi.

So the period is 2iπ since you're thinking about it in the complex plane? (2iπ being one revolution)

Those are the equations I used for the co-efficients...

Hi;

No the period of my equations is either -2π to 2π or -π to π. I would never use anything for serious computation that contained i.

I would say that is a fairly useless fit. The good point about Fourier fits is that they are orthogonal and least squares at the same time.

Hi;

One question at a time because you have asked a big one. The orthogonality is in the basis.

To understand it as mathematicians do you have to understand basis vectors.
I understand it in a way more general, a geometric way.

We can discuss it all you want but we will have delve into some pretty bizarre concepts.

You already know about something about basis vectors but I will draw some pictures that will make it clear to you.

First some background. When I frst met you in here you wanted to end up at Cern. You might find when you get there that they are doing a completely different type of mathematics than you were taught.

You are and were taught bookmath. It is important to understand that it is not real math. Meaning, it is not the real mathematics you might be called upon to do on a day to day basis. Most students do not even know this and even if you do not believe listen to it anyway.

1) In bookmath the number line is continuous, in practical math the number line has holes in it! These holes are numbers that are left out!

2) No one should ever use the quadratic formula to solve a quadratic equation.

3) We can not really subtract as accurately as we can add!

4) (a^2 - b^2) ≠ (a -b)(a+b)

5) a1 + a2 + a3 +...+an ≠ an +...+ a3 + a2 + a1

6) A matrix has three states, invertible, singular and nearly singular.

7) Newton's iteration is rarely the best way to go and should be rarely used.

.
.
.

It is okay for now, you do not need to for us to get back on track.

Take a look at this drawing.

Uploaded Images

Forget orthogonality for a second. It is easy for you to eyeball the intersection of AB and CD. It is well defined.It is a tiny point. GH is on top of EF and therefore it is impossible to pinpoint an intersection. There are zillions of them. The third one is the interesting case, it is what we call nearly singular. It is close to being on top but it is not. The circle shows how wide the possible point of intersection is. It is hard to pick it out by eye. Do you follow?

Going to get some food in me, see you in a bit.