Doing that will produce a lateral inversion. @jbriggs444 post above says it all.SecularSanity said:
sophiecentaur said:
Can you draw a ray diagram of what you mean?SecularSanity said:
Because it's still in a mirror. But when there's a white screen in the way, the observer looks from the other direction and does the lateral inversion for himself. This is just as well because cameras wouldn't work otherwise. My dad had a plate camera with a ground glass screen, put in place of the plate, to do framing and focussing. That image was laterally inverted because of the viewpoint of the observer as a ten year old, I found that cool. The photo's were fine though.SecularSanity said:
sophiecentaur said:
sophiecentaur said:
That's because a plane mirror doesn't "mirror" 2D objects that are parallel to the mirror plane. A plane mirror only inverts the out-of-plane axis. And if the object has no extend or is symmetrical along that axis, then the object and mirror image are identical.Drakkith said:
Oi! Young man . It’s my old boat that’s female. Not I. Read my profile before you get fruity.SecularSanity said:
I seem to remember a friend's 'Russian' SLR (Zenit?) that used a mirror instead of a pentaprism to display an image the right way up. A cheap option but the image was laterally inverted. Perhaps that didn't matter with Cyrilic script - I couldn't read it even the right way round anyway.Drakkith said:
I too have the same question but not getting an answer...SHASHWAT PRATAP SING said:
Have you read the entire thread?Vibhupriya said:
Where are you relative to the focal point and curvature center?Vibhupriya said:
Here's a possible reason for what you saw what you saw. It's to do with the way we 'see' images. There are many times when we see an out - of - focus image but don't ask "why?". If you are very short sighted for instance, you still identify features of the notice on the wall, even though it's not sharp. Similarly, if you are long sighted, you still recognise the layout of the book in front of you. So we don't actually need to have a focused imaged in order to 'see' it; we can identify which way up it is, though. Point is, the image can be anywhere and you will often be able to identify what you see.Vibhupriya said:
Thank u for the answer I understood..sophiecentaur said:
What are you trying to say..A.T. said:
I'm trying to clarify your question. Are you asking about the situation as shown below? Here the visual you see is not inverted (because the image in the retina is inverted). But if you move beyond point C the visual you see will flip.Vibhupriya said:
I always have a problem with that statement. Your brain has to deal with an inverted image on the retina under all conditions. Why would it be relevant here?A.T. said:
See:sophiecentaur said:
More confusion here. Afaics, (your red / green diagram) if the rays from the bottom (red) of the object come from above the axis then the image is inverted. If I have an entirely different imaging system from my eye (a system involving a fan of tubes, for instance), the image will still be inverted. Can you suggest a situation when an eye and a system of tubes would disagree? That is my problem.A.T. said:
If you are facing a plane mirror and someone is standing behind you, you can see that person in the mirror. How are you able see a real person if that person is behind you?SHASHWAT PRATAP SING said:
You have to be more specific on what you mean by "image is inverted".sophiecentaur said:
You have to be more specific on what you mean by "disagree". Eyes cannot disagree because they don't interpret the signals, the brains do.sophiecentaur said:
You are a bit hung up on the meaning and implications of a 'real image' and this could be your problem. The terms real and virtual are used to differentiate between images for which the 'rays' diverge a point in 'real' space or when they only appear to diverge from a point somewhere.SHASHWAT PRATAP SING said:
Whether or not a brain is involved, the directions of arrival will be consistent. The eye (plus brain) or camera with a single lens will interpret the direction of arrival as being the same as a system of tubes. (This is not hard and I thought my description would be adequate.)A.T. said:
I mean precisely what is meant in any other context; the visual impression. When introducing the flat lens equation, no one introduces the optics of the eye into the theory and it hardly seems necessary here. The results are always consistent because your eye works the same, whatever you look at.A.T. said:
If your point is that for the question "visual impression flipped or not?" we don't need to concern ourselves with the details of the eye/brain/camera, then I agree.sophiecentaur said:
The "ourselves" issue just makes it harder. If, as I suggested, you replace the model with an object that's off axis and you look at that then the same optics is involved with a special case, when the face is the image. Put the object within f distance and you can see a sharp image at some distance greater than f (usual formula) The image will be inverted. Move your head closer and the image will be blurred (you cannot focus when it image distance is nearer than your near spot) but still inverted. Wherever you put your eye, you will still get an inverted image. Exactly the same optics applies to your eye, wherever you place it. I guess what I have been objecting to is your sudden introduction of the 'upside down' image on the retina as if it has some special significance. It's always "flipped". All that needs to be said is that the image seen gets progressively more and more blurred; nothing special happens as your eye goes past the image plane. A suitable correcting lens could bring the image to the near spot and you could see it fine.A.T. said:
It just means eye and object are at the same distance from the mirror. Here the visual flip occurs when they both are at twice the focal length from the mirror.sophiecentaur said:
Exactly and it confuses the cause and effect of what is seen. The image is formed, wherever you happen to be looking from but 'so what?'.A.T. said:
Exactly and it confuses the cause and effect of what is seen. An image is formed, wherever you happen to be looking from.A.T. said:
sophiecentaur said:
That red / green diagram is confusing me. It seems to indicate that red and green rays all end up at points on the retina. Can that happen without another lens being introduced?
For an object between F and C there is no virtual image behind the mirror. Or the virtual image is at hyperinfinity.sophiecentaur said:
Your diagram shows a different situation, than my diagram. The object in your diagram is not between C and F.sophiecentaur said:
Ahh. I get that. But can you show where the image is for the observer at the face position? There must be a construction which will show the rays forming a real or virtual image somewhere.A.T. said:
We've both acknowledged that higher up but the red / green diagram shows it coincides with the retina. Which side is it really?A.T. said:
The real image formed by the mirror is behind the observer, as shown on the very left edge of my diagram.sophiecentaur said:
For a normal sighted person it would be in front of the retina, inside the eyeball. If the mirror has a long focal length, then a far sighted person between C and F might be able to get it on the retina and see a sharp image of the own face.sophiecentaur said:
So what you are saying is that the red cone has a vertex at the red o but the eye lens focuses it short of that point. Makes sense - parallel rays will focus on the retina (relaxed lens muscles). Diverging rays, further back (accommodation) and converging rays in front.A.T. said:
Before the red rays enter the eye, they are focused by the mirror on the big red O of the real image on the far left. Then the eye lens focuses them shorter on the small red o near the retina.sophiecentaur said: