Well, they are more important if you change the camera position. But if you keep the camera position the same, they don't change. Do you agree?
Yes, but if the camera position remains unchanged, relative sizes do not change.
You should see the effect of compression. If you don't, it's probably because your conscious brain is overriding your instinctive interpretation of the two images.
Try to imagine that you are looking at two different scenes. Imagine that they are not photographic images, but small windows that you are looking through at two different scenes. In the first, the nearest screwdriver has an angular size of about 7 degrees in my viewing conditions, and the second is about 3.5 degrees (very roughly), and they appear to me to be (very roughly) 3 feet away and 6 feet away.
In the second image, the angular sizes are about doubled, so the screwdrivers appear about 1.5 feet away and 3 feet away (very very roughly). So the distances appear compressed.
Of course, it is extremely difficult to estimate actual distances, we are not very good at doing that and even less good at doing it from photographs. Yet the brain is still pretty good a detecting differences in perspective and recognising that a telephoto image doesn't look entirely realistic (if the image contains enough objects that are familiar to us). Your screwdrivers pictures are not particularly good for demonstrating compression because we don't know what size those screwdrivers are, and that affects our judgement of distance.
Being able to estimate distance is a useful skill for a photographer. Most of us from the zone focusing era are pretty good at it. It can be learned, and carrying and using a laser rangefinder can help with that learning.
Yes, some people in the military used to be very good at estimating distances. I'm not sure if that is still the case today with laser rangefinders being so readily available.
We can define and measure compression when we talk about relative sizes of objects in a photograph. The longer the shooting distance is, the closer are the ratios of apparent sizes to the ratios of physical sizes. At a distance, as we move the objects along the line of sight, their apparent sizes don't change as much as they do at a closer distance.
getThat's all measurable.
But when you talk about brain overriding instinctive interpretation, the effect of compression becomes much harder to define and measure because we're now talking about viewer's inner experiences.
Hmm... because of that, the screwdrivers are actually good for illustrating differences in individual perception.
Now another shot (which I also posted earlier)
The apparent sizes of the screwdrivers are now almost the same (and their physical sizes are the same) and we have some compression even without zooming in.
I find it very difficult to have a rational discussion with you because you seem to be determined to not seriously consider the effect of magnification on perspective and depth perception. Please, let's forget all about relative distances because it is not relevant to compression. You seem determined to keep dragging it back into the discussion. It is not relevant to compression.
What matters is our judgement of absolute distance and that depends primarily on the angular size of a familiar object as seen by the human eye. If we see a person whose angular height is 4 degrees and they walk away from us until their angular height is 2 degrees, our visual system knows that they are about twice as far away.
If we look at something through a telescope that magnifies 6x, then the angular size of everything becomes six times larger when viewed through the telescope. Our brains interpret this to mean that everything is six times closer to us.
So, when we look through the telescope at a familiar scene, we do not think that we are looking at a scene in which every object is six times bigger, but instead we think we are looking at a scene in which everything is six times closer.
That is compression.
There is nothing more to it! It is really not rocket science.
Perspective doesn't change on magnification/zooming in.
Perception does, but as above, it can be hard to measure and define the 'compression' through perception effects.
Yes, apparent distance between objects along the line of sight shrinks at longer distances. But in the last few messages I was talking mostly about relative angular sizes, not relative distances.
But what is 'compressed' under this definition?
If you call something a compression, you have to show what is actually compressed.
We can see the compression even without zooming in, as in the image from my previous message above. It's just perspective at a long enough distance from the camera. The scene gets 'compressed' along the line of sight. Apparent distances along the line of sight between the objects shrink, and relative apparent sizes of objects gets closer to their relative physical sizes. It's as if something was squashing the scene along the line of sight.
So it's just the perspective at a distance that gets 'compressed'. Zooming in amplifies this effect for our perception (as you described) but it doesn't create the compression. Again, we can see things 'compressed' in wide angle shots without any zooming in.
I don't take seriously people who preach one thing and then do not have the ability to do it themselves. For me, they just waste my time 🙂
In any case there are countless videos on the internet demonstrating the compression effect when you zoom in from a given position. If you are too lazy to search for them then you are not really interested and I am not going to spoon feed you.
"Lens compression" is simply the appearance of background objects being closer to the foreground objects when, from a given position, you zoom in.
Yes, from a given position, which determines by the relative distances of objects from a camera, which stays the same, whether you zoom in with the lens or you crop to match in post. The relative distances only change when the camera position is changed. Zooming or cropping enables changes to the overall magnification, but the only way to selectively change the magnification of the background while maintaining the same magnification of the subject is to step forward or backward.
Sorry, I thought it was obvious that it is the distances from the viewer that appear to be compressed.
Take a simple example. Look through a 10x telescope or binoculars at something that is 1000 yards away. It appears to be only 100 yards away. The distance from you (to whatever you are looking at) appears to be compressed by a factor of 10.
You could tell if the distances appeared compressed if the objects kept their absolute sizes. Instead, the whole view is magnified. The actual compression is due to the gradual change in perspective at a distance.
Zooming in alone doesn't necessarily show compression as in my example image above, and you can see the 'compressed' perspective in wide angle shots without zooming in - just focus on the distant objects, again as in my examples above.
I haven't seen anyone post that zooming will necessarily result in the compression effect in every situation. It may or may not depending on the distances of camera to foreground, camera to background and the amount zoomed in. There are countless videos on the web demonstrating the "lens compression" effect.
"Lens compression" is simply the appearance of background objects being closer to the foreground objects when, from a given position, you zoom in.