I wrote a Matlab implementation of Ridder's method on the Matlab file exchange: submission 54458. I've copied the code below for reference:

```
function xZero = rootSolve(func,xLow,xUpp)
% XZERO = ROOTSOLVE(FUNC, XLOW, XUPP)
%
% FUNCTION: This function uses Ridder's Method to return a root, xZero,
% of func on the interval [xLow,xUpp]
%
% INPUTS:
% func = a function for a SISO function: y = f(x)
% xLow = the lower search bound
% xUpp = the upper search bound
%
% OUTPUTS:
% xZero = the root of the function on the domain [xLow, xUpp]
%
% NOTES:
% 1) The function must be smooth
% 2) sign(f(xLow)) ~= sign(f(xUpp))
% 3) This function will return a root if one exists, and the function is
% not crazy. If there are multiple roots, it will return the first one
% that it finds.
maxIter = 50;
fLow = feval(func,xLow);
fUpp = feval(func,xUpp);
xZero = [];
tol = 10*eps;
if (fLow > 0.0 && fUpp < 0.0) || (fLow < 0.0 && fUpp > 0.0)
for i=1:maxIter
xMid = 0.5*(xLow+xUpp);
fMid = feval(func,xMid);
s = sqrt(fMid*fMid - fLow*fUpp);
if s==0.0, break; end
xTmp = (xMid-xLow)*fMid/s;
if fLow >= fUpp
xNew = xMid + xTmp;
else
xNew = xMid - xTmp;
end
xZero = xNew;
fNew = feval(func,xZero);
if abs(fNew)<tol, break; end
%Update
if sign(fMid) ~= sign(fNew)
xLow = xMid;
fLow = fMid;
xUpp = xZero;
fUpp = fNew;
elseif sign(fLow) ~= sign(fNew)
xUpp = xZero;
fUpp = fNew;
elseif sign(fUpp) ~= sign(fNew)
xLow = xZero;
fLow = fNew;
else
error('Something bad happened in riddersMethod!');
end
end
else
if fLow == 0.0
xZero = xLow;
elseif fUpp == 0.0
xZero = xUpp;
else
error('Root must be bracketed in Ridder''s Method!');
end
end
```