Do you understand how splines are arrived at?

## Summary of doing splines

You break the range into pieces based on the control points (splitting at the control points or putting the breaks between them), and plop some parameterized function into each sub-range, then constrain the functions by the control points, artificially introduced end-point constraints, and inter-segment constrains.

If you've counted your degrees of freedom and constraints right, you get a solvable system of equations which tells you the right parameters in terms of the control points and away you go.

The result is a set of parameters for a piecewise function. Generally a piecewise continuous and differentiable function, because what would be the point otherwise.

## How you can use that in this case

So consider making each interior point the center of a segment which will be occupied by a peak-like function (Gaussian on a linear background, maybe) and use the end points as constraints.

For `n`

total points you'd have `D*(n-2)`

parameters if each segment has `D`

parameters. You have four end-point constraints `f(start)=y_0`

, `f(end)=y_n`

, `f'(start) = f'(end) = 0)`

, and some set of match constraints between the segments:

```
f_n(between n and n+1) = f_n+1(between n and n+1)
f'_n(between n and n+1) = f'_n+1(between n and n+1)
...
```

plus each segment is constrained by it's relationship to the control point (usually either `f(point n) = y_n`

or `f'(point n) = 0`

or both (but you get to decide).

How many matching constraints you can have depends on the number of degrees of freedom (total number of constraints must equal total number of DoF, right?). You have have to introduce some extra endpoint constraints in the form `f''(start) = 0`

... to get it right.

At that point you're just looking at a lot of tedious algebra to earn how to translate this into a big system of linear equation which you can solve with a matrix inversion.

Most numeric methods books will cover this stuff.