McCollough effect Totally Explained

Everything about The Mccollough Effect totally explained

The McCollough effect is a phenomenon of human visual perception in which colorless gratings appear colored depending on (contingent on) the orientation of the gratings. It is an aftereffect requiring a period of induction to produce it. For example, if someone alternately looks at a red horizontal grating and a green vertical grating for a few minutes, a black-and-white horizontal grating will then look greenish and a black-and-white vertical grating will then look pinkish. The effect was discovered by Celeste McCollough in 1965.

How to obtain the effect

To obtain the effect, first look at a test image similar to that at top right. It should contain oppositely oriented gratings of lines, such as horizontal and vertical as shown here. Next, stare alternately at two induction images similar to the ones directly beneath the top image. One image should show one orientation of grating (here horizontal) with a coloured background (red) and the other should show the other orientation of grating (here vertical) with a different, preferably oppositely coloured background (green). Each image should be gazed at for several seconds at a time, and the two images should be gazed at for a total of several minutes for the effect to become visible. Stare approximately at the centre of each image, allowing the eyes to move around a little. After several minutes, look back to the test image; the gratings should appear tinted by the opposite colour to that of the induction gratings (for example, horizontal should appear greenish and vertical pinkish).

Properties of the effect

The McCollough effect is remarkable because it's very long lasting (for example, Jones & Holding, 1975, found that 10 minutes of induction can lead to the effect lasting 24 hours), because it depends on retinal orientation (tilting the head by 45 degrees makes the colors in the above example disappear; tilting the head by 90 degrees makes the colors reappear such that the gravitationally vertical grating now looks green), and because inducing the effect with one eye leads to no effect being seen with the other eye (but see White, Petry, Riggs, & Miller, 1978, for some evidence of binocular interactions). The effect is different from colored afterimages, which appear superimposed on whatever is seen and which are quite brief.
   Any aftereffect requires a period of induction (or adaptation) with an induction stimulus (or, in the case of the McCollough effect, induction stimuli). It then requires a test stimulus on which the aftereffect can be seen. In the McCollough effect as described above, the induction stimuli are the red horizontal grating and the green vertical grating. A typical test stimulus might show adjacent patches of black-and-white vertical and horizontal gratings (as above). The McCollough-effect colours are less saturated than the induction colours.
   The induction stimuli can have any different colors. The effect is strongest, however, when the colors are complementary, such as red and green, and blue and orange. A related version of the McCollough effect also occurs with a single color and orientation. For example, induction with only a red horizontal grating makes a black-and-white horizontal test grating appear greenish whereas a black-and-white vertical test grating appears colourless (although there's some argument about that). Stromeyer (1978) called these non-redundant effects. According to him, the classic effect with induction from two different orientations and colours simply makes the illusory colors more noticeable via contrast.
   The effect is specific to the region of the retina that's exposed to the induction stimuli. This has been shown by inducing opposite effects in adjacent regions of the retina (for example, from one region of the retina verticals appear pink and horizontals appear greenish; from an adjacent region of the retina, verticals appear greenish and horizontals appear pink). Nevertheless, if a small region of the retina is exposed to the induction stimuli, and the test contors run through this region, the effect spreads along those test contours. Of course, if the induced area is in the fovea (central vision) and the eyes are allowed to move, then the effect will appear everywhere in the visual scene visited by the fovea.
   The effect is also optimal when the thickness of the bars in the induction stimulus matches that of those in the test stimulus (i.e, the effect is tuned, albeit broadly, to spatial frequency). This property led to non-redundant effects being reported by people who had used computer monitors with uniformly colored phosphors to do word processing. These monitors were popular in the 1980s, and commonly showed text as green on black. People noticed later when reading text of the same spatial frequency, in a book say, that it looked pink. Also a horizontal grating of the same spatial frequency as the horizontal lines of the induction text (such as the horizontal stripes on the letters "IBM" on the envelope for early floppy disks) looked pink.

Explanations of the effect

McCollough's paper sparked hundreds of scientific papers on the effect (for example, see reviews by Stromeyer, 1978, and by McCollough, 2000). The effect has been variously attributed to adaptation of cells in the lateral geniculate nucleus designed to correct for chromatic aberration of the eye, to adaptation of cells in the visual cortex jointly responsive to color and orientation (this was McCollough's explanation), to processing within higher centres of the brain (including the frontal lobes as held by Barnes et al., 1999), and to learning and memory. In 2006, the explanation of the effect was still the subject of debate, although there was a consensus in favour of McCollough's original explanation.

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