Throwing light on the brain's perception of transparency
Researchers have created a new optical illusion that helps reveal how our brains determine the material properties of objects – such as whether they are transparent, shiny, matte or translucent – just from looking at them.
UNSW scientist Dr Juno Kim created a computer image of an object with the refractive index of glass. People perceived it as transparent when they viewed it in one orientation. But when it was flipped upside down, it then looked opaque and glossy to them.
"It's a brand new optical illusion," says Dr Kim, of the UNSW School of Optometry and Vision Science.
"It demonstrates the visual system has learnt to rely on the orientation of the horizon, and whether bright highlights are at the top or the bottom of an object, to work out whether objects are transparent or opaque. It shows that our brain is asking: which way is up?"
The study by Dr Kim and Dr Phillip Marlow of the University of Sydney is published in the journal i-Perception.
Crystal balls and other transparent round objects refract light so the sky appears at the bottom and the ground or ocean at the top.
A popular sculpture that demonstrates this inversion effect is Lucy Humphrey's Horizon, a large transparent acrylic sphere filled with water that featured in the Sculpture by the Sea exhibition in Sydney in 2013, and which was on show again in August 2016 at Barangaroo.
To produce the new optical illusion, he created a computer image of an object with a refractive index equivalent to Crown glass as viewed in outdoor light.
The object was rated as having a similar transparency to ice or glass on average by eight observers.
But when the object was viewed upside down and the bright highlights were at the top where you would expect the sky to be, it was mistaken as opaque and reflective, with some saying it looked like liquid metal.
"Our brain is sophisticated, but when it is trying to infer the material composition of an object just from the distorted pattern of light reflected from the surface, it makes guesses based on previous experience," says Dr Kim.
"And the second bias is that most objects tend to be convex, or round overall."
Apart from revealing the hidden working of the brain, the research could have applications for computer animators wanting to produce realistic images of objects, or for people making visual judgements about the composition of objects on a processing line.