N
Nibbler
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- #31
Ah right, sarcasm, sorry, I did'nt read the whole thread :>
E
*Exor*
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- #32
You bastards are gonna be the death of me 
Don't even do it on purpose please
Or should I say Do'nt?
Don't even do it on purpose please
Or should I say Do'nt?
H
Hashmonster
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- #33
nibbler your one made the things i look at go a little screwy!
N
Nibbler
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- #34
That's the magic
T
Testin da Cable
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- #35
F
Furr
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- #36
argggg my eyes , IT hurts
wtf is that tdc the white spots go black and then my eye starts twitching and itching , its really painful
wtf is that tdc the white spots go black and then my eye starts twitching and itching , its really painful
T
Testin da Cable
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- Thread starter
- #37
hearken to me now boy, for thou art under my evil spell.....BWAHAHAHAHAHAHAHAHAHAHAHAHAHAHAHAHAHAHA
F
Furr
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- #38
my eyes still hurt ya bast , im starting to feel a bit tired know so my eyes really cane
*wanders around like a blind man*
where this evil spell cant see
*wanders around like a blind man*
where this evil spell cant see
T
Testin da Cable
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- #39
oh dear heh
well, the flickering black spots you see are actually focus points for the electro-magnetic energy emission of your monitor. these points permit a precise bombardment of your brain with this energy via your retina. in your case I guess the energy level went off the scale slightly and scalded your eyeballs [and the rest of your face, but your eyes would indeed hurt the most].
you can combat the effect by ripping out your eyes and dipping them in battery acid for a few seconds. [it might also help to go to bed and sleep for a couple of hours, but imo the acid thing would prolly work faster]
-TdC
well, the flickering black spots you see are actually focus points for the electro-magnetic energy emission of your monitor. these points permit a precise bombardment of your brain with this energy via your retina. in your case I guess the energy level went off the scale slightly and scalded your eyeballs [and the rest of your face, but your eyes would indeed hurt the most].
you can combat the effect by ripping out your eyes and dipping them in battery acid for a few seconds. [it might also help to go to bed and sleep for a couple of hours, but imo the acid thing would prolly work faster]
-TdC
F
Furr
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- #40
*bah sleep what a waste of 5 hours+, pas a blind man some battery acid someone?
O
old.Kez
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- #41
Assuming this isn't following the trend of the rest of the post in the sarcastic sentences, I fear you must be wrong (I'm also quite tired, so if it is sarcasm - fnar) on the basis that electro-magnetic charges from my monitor don't affect little magic eye books that contain the same pattern.
k.
T
Testin da Cable
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- #42
it was Kez
following that is
funny thing is, I used to be able to accurately be ably to explain such phenoms. strange. I can only conclude that doing actual work kills your brain off. stay in school kids!
following that is
funny thing is, I used to be able to accurately be ably to explain such phenoms. strange. I can only conclude that doing actual work kills your brain off. stay in school kids!
O
old.Kez
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- #43
I shall attempt to delete my post then.
O
old.Kez
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- #44
I have been thwarted by some spastic configured option that says I can not delete it.
Great.
Great.
C
Custy
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- #45
Actually did a question on this in alevel physics, how the retina works like a Charge couple device inside a digital camera. It's all to do with the sensetivity of each rod/cone which makes up the eye, as the light hits it is desensetises blah.. blah.. blah.. yada.. yada..
T
Testin da Cable
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- #46
lol too bad Kez. it will end up well I trust
and Custy, I am actually interested, so if you'd care to divulge feel free good man!
and Custy, I am actually interested, so if you'd care to divulge feel free good man!
H
Hashmonster
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- #47
kez, just edit the post - put something unrelated in there
C
Custy
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- #48
heres the blurb from my CDrom textbook...
Do you see the grey spots at the intersections? Stare at any one of them and it disappears. Why?
Consider two regions of your retina. One region views an intersection of a white horizontal and vertical band and the other region views a white band between two intersections (the region going away from the intersection). Although the two regions themselves receive the same amount of light, the situation in their neighbouring regions is different. At the intersection, there is light coming in from all four sides, but in the white band that lies between the two intersections it is surrounded by two dark sides.
This leads to a physiological mechanism called lateral inhibition, which has the effect of causing a bright surround make an area appear darker and, conversely, a dark surround will make an area appear lighter.
The physiological explanation: your retina is partially composed of many small rod and cone nerve cells, which function as receptors of light. These receptors are arranged in rows on the inside of your retina. A number of scientists have shown that it is possible to illuminate and record from a single receptor (A) without illuminating its neighbouring receptors. It was discovered that if you illuminate a single receptor (A) you will get a large response; however, when you add illumination to A's neighbours, the response in A decreases. In other words, illumination of receptors 'inhibits' the firing of neighbouring receptors. This effect is called lateral inhibition because it is transmitted laterally, across the retina, in a structure of the retina called the lateral plexus.
In the case of the Hermann grid, there is light coming from the four sides of the intersection, but from only two sides of a band going away from the intersection. The region viewing the intersection is more inhibited than the region of the band going away. Thus the intersection appears darker than the other section. You see dark spots at the intersections of the white bands, but not at the points away from the intersections. The effect is greater in your peripheral vision, where lateral inhibition acts over greater distances, if you concentrate on a particular junction the darker spot there may disappear!
Do you see the grey spots at the intersections? Stare at any one of them and it disappears. Why?
Consider two regions of your retina. One region views an intersection of a white horizontal and vertical band and the other region views a white band between two intersections (the region going away from the intersection). Although the two regions themselves receive the same amount of light, the situation in their neighbouring regions is different. At the intersection, there is light coming in from all four sides, but in the white band that lies between the two intersections it is surrounded by two dark sides.
This leads to a physiological mechanism called lateral inhibition, which has the effect of causing a bright surround make an area appear darker and, conversely, a dark surround will make an area appear lighter.
The physiological explanation: your retina is partially composed of many small rod and cone nerve cells, which function as receptors of light. These receptors are arranged in rows on the inside of your retina. A number of scientists have shown that it is possible to illuminate and record from a single receptor (A) without illuminating its neighbouring receptors. It was discovered that if you illuminate a single receptor (A) you will get a large response; however, when you add illumination to A's neighbours, the response in A decreases. In other words, illumination of receptors 'inhibits' the firing of neighbouring receptors. This effect is called lateral inhibition because it is transmitted laterally, across the retina, in a structure of the retina called the lateral plexus.
In the case of the Hermann grid, there is light coming from the four sides of the intersection, but from only two sides of a band going away from the intersection. The region viewing the intersection is more inhibited than the region of the band going away. Thus the intersection appears darker than the other section. You see dark spots at the intersections of the white bands, but not at the points away from the intersections. The effect is greater in your peripheral vision, where lateral inhibition acts over greater distances, if you concentrate on a particular junction the darker spot there may disappear!
T
Testin da Cable
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- #49
hmmm
thanks mate
thanks mate
C
Custy
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- #50
lmao :]
S
Summo
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- #51
TDC J00 BASTID MEH EIES AER TEH B0RKEN!!!¬!¬""1`111!!!!