... but Helen - I'm surprised at your statement. Why on earth would it be called a 'nodal' point if there's no 'crossover' happening..? And how on can a lens invert an image without having 'crossover'...?
...
Sparky,
I didn't say that there is no crossover. I said that it happens at the aperture stop (a single entity) rather than a nodal point (of which there are two in a complex lens).
When I spoke of 'nodal points' it was in the general term of discussing the establishment of focal length (please see the title of the thread to understand why this is). And so - yes - if you reverse an optical system - we can establish the existence of a SECOND nodal point for that system - in that orientation. I agree with you if that's the situation we're talking about.
That is the situation we are talking about, but it applies all the time, no matter which way round the lens is. Object-side distances are measured from the front (aka forward and first) nodal point and image-side distances are measured from the rear (aka second) nodal point. It is possible for the two nodal points to be coincident.
[As an aside, a lot of the tequinical* information on the web about stitched panoramas refers to 'the nodal point' of a lens as being 'where the rays cross the axis' or somesuch.]
Maybe it is worth starting from the basic definitions. You will already know a lot of this, but I am trying to clear up what appears to be some confusion.
For a simple single-element symmetrical lens a ray that is headed into the centre of the lens emerges from the other side undeviated. For a complex lens the equivalent ray that is headed towards the front nodal point will appear to emerge undeviated from the rear nodal point. That is the property that defines the two nodal points.
There are a couple of catches:
-The front nodal point may be behind the rear nodal point.
-The ray may not exist, because the image is projected from the exit pupil, not the rear nodal point. Furthermore, even if an object point is within the field of view of the lens the ray between it and the front nodal point may not be capable of entering the lens - it may be outside the bounds of the front element.
Neither of these two catches matter when you are doing calculations involving object distance, image distance and magnification, if you measure image distances from the rear nodal point and object distances from the front nodal point. If you use only one nodal point, such as the rear nodal point, for these calculations they will be incorrect. The error may not be significant: for example when the distance between the nodal points is very small in comparison to the object distance.
This is a lot more simple than it sounds. If I get the time and can find a scanner I will either scan a page from one of the textbooks, or draw it out myself. For now, here is a very simple sketch drawn for a completely different reason. I was a bit naughty when I drew all the lines as solid, instead of partly solid and partly dashed. It is of a Zeiss Distagon 35 mm f/3.5 for the Contax 645. It was drawn
"to show different entrance and exit angles for ray heading towards centre of entrance pupil and then out of centre of exit pupil. Also shows that lens aperture may be too small for parallel ray heading towards front nodal point to actually enter lens". The ray that is headed towards the centre of the entrance pupil and shown to exit from the centre of the exit pupil actually crosses the optical axis at the centre of the aperture stop (just to the left of the exit pupil).
Dead Link Removed
Best,
Helen
*A word for something that poses as being technical, but is not. It was named after Terence Tequinical, the anarchist.
