A good solution is to use my inpaint_nans. Simply supply NaN elements where no information exists, then use inpaint_nans. It will interpolate for the NaN elements, filling them in to be smoothly consistent with the data points.
B = nan(20);
B(3,2) = 5;
B(17,4) = 3;
B(16, 19) = 2.3;
B(5, 18) = 4.5;
Bhat = inpaint_nans(B);
For those interested in whether inpaint_nans can handle more complex surfaces, I once took a digitized Monet painting (seen on the left hand side, then corrupted it by deleting a random 50% of the pixels. Finally, I applied inpaint_nans to see if I could recover the image reasonably well. The right hand image is the inpainted one. While the resolution is low, the recovered image is a decent recovery.
As another example, try this:
[x,y] = meshgrid(0:.01:2);
z = sin(3*(x+y.^2)).*cos(2*x - 5*y);
Now, delete about 7/8 of the elements of this array, replacing them with NaNs.
k = randperm(numel(z));
zcorrupted = z;
zcorrupted(k(1:35000)) = NaN;
Recover using inpainting. The z-axis has a different scaling because there are minor variations above and below +/-1 around the edges, but otherwise, the latter surface is a good approximation.
zhat = inpaint_nans(zcorrupted);