Here's a simple, effective, but perhaps somewhat naive approach.

First make sure you make a generic interpolator through both functions. That way you can evaluate both functions in between the given data points. I used a cubic-splines interpolator, since that seems general enough for the type of smooth functions you provided (and does not require additional toolboxes).

Then you evaluate the source function ("original") at a large number of points. Use this number also as a parameter in an inline function, that takes as input `X`

, where

```
X = [a b]
```

(as in `ax+b`

). For any input `X`

, this inline function will compute

the function values of the target function at the same x-locations, but then scaled and offset by `a`

and `b`

, respectively.

The sum of the squared-differences between the resulting function values, and the ones of the source function you computed earlier.

Use this inline function in `fminsearch`

with some initial estimate (one that you have obtained visually or by via automatic means). For the example you provided, I used a few random ones, which all converged to near-optimal fits.

All of the above in code:

```
function s = findScaleOffset
%% initialize
f2 = [0;0.450541598502498;0.0838213779969326;0.228976968716819;0.91333736150167;0.152378018969223;0.825816977489547;0.538342435260057;0.996134716626885;0.0781755287531837;0.442678269775446;0];
f1 = [-0.029171964726699;-0.0278570165494982;0.0331454732535324;0.187656956432487;0.358856370923984;0.449974662483267;0.391341738643094;0.244800719791534;0.111797007617227;0.0721767235173722;0.0854437239807415;0.143888234591602;0.251750993723227;0.478953530572365;0.748209818420035;0.908044924557262;0.811960826711455;0.512568916956487;0.22669198638799;0.168136111568694;0.365578085161896;0.644996661336714;0.823562159983554;0.792812945867018;0.656803251999341;0.545799498053254;0.587013303815021;0.777464637372241;0.962722388208354;0.980537136457874;0.734416947254272;0.375435649393553;0.106489547770962;0.0892376361668696;0.242467741982851;0.40610516900965;0.427497319032133;0.301874099075184;0.128396341665384;0.00246347624097456;-0.0322120242872125];
figure(1), clf, hold on
h(1) = subplot(2,1,1); hold on
plot(f1);
legend('Original')
h(2) = subplot(2,1,2); hold on
plot(f2);
linkaxes(h)
axis([0 max(length(f1),length(f2)), min(min(f1),min(f2)),max(max(f1),max(f2))])
%% make cubic interpolators and test points
pp1 = spline(1:numel(f1), f1);
pp2 = spline(1:numel(f2), f2);
maxX = max(numel(f1), numel(f2));
N = 100 * maxX;
x2 = linspace(1, maxX, N);
y1 = ppval(pp1, x2);
%% search for parameters
s = fminsearch(@(X) sum( (y1 - ppval(pp2,X(1)*x2+X(2))).^2 ), [0 0])
%% plot results
y2 = ppval( pp2, s(1)*x2+s(2));
figure(1), hold on
subplot(2,1,2), hold on
plot(x2,y2, 'r')
legend('before', 'after')
end
```

Results:

```
s =
2.886234493867320e-001 3.734482822175923e-001
```

Note that this computes the *opposite* transformation from the one you generated the data with. Reversing the numbers:

```
>> 1/s(1)
ans =
3.464721948700991e+000 % seems pretty decent
>> -s(2)
ans =
-3.734482822175923e-001 % hmmm...rather different from 7/11!
```

(I'm not sure about the 7/11 value you provided; using the exact values you gave to make a plot results in a *less accurate* approximation to the source function...Are you sure about the 7/11?)

Accuracy can be improved by either

- using a different optimizer (
`fmincon`

, `fminunc`

, etc.)
- demanding a higher accuracy from
`fminsearch`

through `optimset`

- having more sample points in both
`f1`

and `f2`

to improve the quality of the interpolations
- Using a better initial estimate

Anyway, this approach is pretty general and gives nice results. It also requires no toolboxes.

It has one major drawback though -- the solution found may not be the *global optimizer*, e.g., the quality of the outcomes of this method could be quite sensitive to the initial estimate you provide. So, always make a (difference) plot to make sure the final solution is accurate, or if you have a large number of such things to do, compute some sort of quality factor upon which you decide to re-start the optimization with a different initial estimate.

It is of course very possible to use the results of the Fourier+Mellin transforms (as suggested by chaohuang below) as an initial estimate to this method. That might be overkill for the simple example you provide, but I can easily imagine situations where this could indeed be very useful.

`f2`

and`f1`

? – Rasman Nov 26 '12 at 12:40`a*f(x)+b`

? And assuming you don't mean that: You don't know the value of x or what kind of function f is? – Dennis Jaheruddin Nov 26 '12 at 16:59