I'm not overly certain of your grasp of mathematics, so please accept my apologies if this goes over your head, or if it is indeed too simply explained, but the solution that instantly stood out to me is to use Fourier analysis on a discrete sampling of the width of the polygon at fixed angles.
Your approach to rotate by a small amount and test could be considered a discrete sampling of a continuous function.
We know that there is a continuous function that defines the measure you are after for each possible rotation, you are just evaluating it at set points. i.e. an angle to polygon width function is known to exist, and we can evaluate the width of the polygon for a finite set of angles given enough time.
So, supposing we could find an expression in terms of elementary functions for this angle-to-width function, we could potentially determine exactly all of the angles which yield the minimum possible width by solving an equation.
We know that because you are rotating through 2PI radians, the width function will be 2PI periodic, and so you could perfectly reconstruct the function, given that enough angles were sampled, by applying Fourier analysis.
The question is, how many samples do you need to produce a perfect reconstruction of the function?
I think it's determined by the smallest distance between the boundary points.
In short, I am resampling the perimiter of the boundary by placing evenly spaced samples along the perimiter, using a spacing that is equal to or smaller than the smallest distance. Let's call this number n. (To be honest I am not overly certain if this is correct)
Sample easterly and westerly points at n points at evenly spaced angles through 2PI radians, and plot their difference as an n-point angle to width function.
Take the Fourier transform of this graph to give you the sets of real Fourier series coefficients needed to define the distance function
Use any of your favourite methods for identifying the the minimum value of a function.
So I suppose for you triangle example you determine that you need ceil(3 + root(3)) = 5 samples. Calculate the distance at 0 2pi/5 4pi/5 6pi/6 and 8pi/5, take the Fourier transform of this result and reconstruct the signal, creating a formula like
a0 + a1 sin (t) + a2 sin (2t)
And then you have to determine the minimum of this function (for which there are many options)