Okay, here's an attempt at a solution.

The basic trick is this: we *rasterise* the two curves, and then we can do the curve comparison on a tile by tile basis. This seems like a fairly reasonable way of comparing the curve superposition, at least. To encourage the optimiser to approach the curve, we also introduce a loss that penalises curves too far away from the other.

No guarantees this works for more complicated curves and transformations, but it's an idea, at least.

```
curve2<-data.frame(x=c(4,5,5,6,6,7),
y=c(2,2,1,1,2,3))
fillin <- function(ax, ay, bx, by, scaling= 10, steps= 100) floor(cbind(seq(from = ax, to = bx, len = steps), seq(from = ay, to = by, len = steps)) * scaling)
Bmat <- matrix(0, 100, 100)
for (i in 2:nrow(curve2)){
Bmat[fillin (curve2[i-1,1], curve2[i-1,2], curve2[i,1], curve2[i,2])] =1
}
Bmat.orig = Bmat
Bmat = Bmat.orig
#construct utility function based on
#manhattan distances to closest point?
shift = function(mat, offset){
mat0 = array(0, dim = dim(mat)+2)
mat0[1:nrow(mat) +1+ offset[1] , 1:ncol(mat) + 1+offset[2]] = mat
return(mat0[1:nrow(mat) + 1, 1:ncol(mat) + 1])
}
for (i in 1:100){
Bm = (Bmat != 0)
Btmp1 = shift(Bm, c(1,0))
Btmp2 = shift(Bm, c(-1,0))
Btmp3 = shift(Bm, c(0,1))
Btmp4 = shift(Bm, c(0,-1))
Bmat = Bmat + pmax(Bm ,Btmp1, Btmp2, Btmp3, Btmp4)/i
}
Bmat2 = replace(Bmat, Bmat == max(Bmat), max(Bmat) + 10)
#construct and compare rasterised versions
getcurve = function(trans = c(0,1), curve=data.frame(x=c(1,1,2,2,3) ,
y=c(9,6,6,3,3) ), Bmat = Bmat2){
Amat = array(0, dim = dim(Bmat))
curve[,1] = curve[,1] + trans[1]
curve[,2] = curve[,2] * trans[2]
for (i in 2:nrow(curve)){
fillin (curve[i-1,1], curve[i-1,2], curve[i,1], curve[i,2]) -> ind
if (min(ind) < 1 || max(ind) > nrow(Bmat)) return( array(-1, dim= dim(Bmat)))
Amat[ind] =1
}
Amat = (Amat - mean(Amat))/sd(as.vector(Amat))
Amat
}
compcurve = function(trans = c(0,1), curve=data.frame(x=c(1,1,2,2,3) ,
y=c(9,6,6,3,3) ) , Bmat = Bmat2){
Amat = getcurve(trans, curve, Bmat)
-sum(Amat * Bmat)
}
#SANN seems to work for this, but is slow. Beware of finite differencing
# - criterion is non-smooth!
optim(c(0,1), compcurve, method = "SANN", Bmat = Bmat2) -> output
image(Bmat)
contour(getcurve(output$par), add = T)
```

Result:

Not too shabby, maybe?

You will possibly have to fudge the specifics of the rasterisation to work for other problems. And you might wanna tune how the optim is done.

A 'smarter' alternative is to note that for an optimal solution, it's probably the case that at least one pair of vertices will conincide. This can give you a better search strategy. The advantage of the rasterisation scheme in comparison to area-between curves is that it's possibly more flexible wrt to different transformations and non-graphs (in particular, the vertical line in your first curve is a problem.) You can potentially avoid rasterisation by an appropriate computation, but it gives me a headache just to think about it.

Since we are maximising a criterion, then this is a maximum likelihood method. Curiously, I think it is actually *impossible* to phrase this question as a maximum likelihood problem using normal errors, because normal errors imply L2 based criterions, which will famously *not* give you exact superpositions.