Chromatic Adaptation

Have you ever entered a movie theater on a sunny afternoon? The room probably appeared completely dark but as your visual system adjusted to the reduced level of light you were able to see better after a few moments.

This “adaptation mechanism” allows our eyes to recover from an oversensitivity to a particular stimuli. “Chromatic adaptation” occurs when our eyes adjust to certain color stimuli. Follow the instructions below and see how the visual system responds to a color overload.

Instructions: Fixate upon the black spot in between the uniform cyan and yellow areas for about 30 seconds. Then scroll down and shift your gaze to the black spot in the 2nd image. Note that the image of the seaplane appears approximately uniform after this adaptation.



Challenge yourself to try and count the dots in the diagram below. Despite a static image, your eyes will make it dynamic attempting to “fill-in” the white circle intersections with the black of the background. Quite an amazing effect!

Instructions: Simply stare at the white circles and notice the intermittent blinking effect.




Do you want to see if there’s anything you missed???

The Moon Illusion


The moon illusion is one of the most famous of all illusions. Stated simply, the full moon, when just above the horizon, appears much larger than when it is overhead. Yet the moon, a quarter of a million miles away from the earth, always subtends the same angle wherever it is in the sky, roughly 0.5 degrees.

The first problem is for photographers. A wonderful picture presents itself, with the full moon just rising above a spectacular horizon. Click, the picture is taken. Yet the result is disappointing. The moon seems much smaller in the photograph than it did when viewed with the naked eye. Even professional photographers fall for this one. Yet on a normal lens, 50mm on a 35mm camera, the field of view is around 50 degrees, and the width of the moon, subtending an angle of 0.5 degrees, will be 100th of the width of the photo! Many photographs that you see in magazines, containing both a moon and a landscape, will be composites. The landscape will be taken with a normal lens, the moon taken with a telephoto lens, to get a bigger image.

How does this illusion come about? Since the moon always subtends an angle of 0.5 degrees, the image on the retina must always be the same. Clearly the problem is one of interpretation. One simple experiment shows this to be so. A full moon just above the horizon will not appear so large to the human eye if a piece of paper is held up to that eye with a hole in it, so that only the moon can be seen through the hole and not the horizon. If the other eye is open at the same time, viewing both the moon and the horizon, the two eyes will each see different sized moons!

One explanation is believed to be as follows. We ‘know’ that a cloud that is overhead will be larger than when it moves towards the horizon. And an airplane that is a mere speck on the horizon becomes large when it is overhead. And we are all familiar with standing under a tree which seems enormous, yet at a couple of hundred paces seems insignificant. It would seem that so much of our world is interpreted this way that we are ill-equipped to cope with an object like the moon, that subtends the same angle at the eye, whatever position it occupies in the sky. And so our brain ‘interprets’ the image that it ‘sees’, and tells us that the moon is larger than it really is.

Thanks to Robert Becker, who adds the following observations to the Moon Illusion.

One extension to the moon illusion that I learned about in a psychology class in college, is to use after images to demonstrate this effect. Simply stare at a small (2 cm diam) circle of colored paper, held at arm’s length, for 20-30 seconds (the color doesn’t matter, but if you use bright purple, you get a nice yellow moon after-image. It also helps to have a small dot in the circle’s center to focus on — otherwise the eye tends to wander across the circle and make the after image not as crisp. After staring at the circle, stare straight up at the ceiling (some 2 m above your head) and observe the small moon-like after image. Then repeat the procedure, but this time look over at a distant wall (some 5-10 m away). The “horizon moon” is huge, even though it still has the same angle in our eye as the overhead moon. Since we mentally project that object to be a greater distance away, when it’s image does not get smaller, we “see” it as much bigger.

The Amazing Dots


Count the black dots…