TedTest

From the Ted Talk by Colm Kelleher: What is color?

Unscramble the Blue Letters

One of the most snriktig properties about life is that it has color. To understand the phenomenon of color, it helps to think about light as a wave. But, before we get to that, let's talk a little bit about wveas in general. Imagine you're sitting on a boat on the ocean watching a cork bob up and down in the water. The first thing you notice about the motion is that it repeats itself. The cork traces the same path over and over again... up and down, up and down. This repetitive or periodic motion is characteristic of waves. Then you notice something else... using a sottcwaph, you meuasre the time it takes for the piece of cork to go over its highest position down to its lowest and then back up again. susoppe this takes two seconds. To use the physics jargon, you've meersuad the period of the waves that cork is bobbing on. That is, how long it teaks a wave to go through its full range of mtioon once. The same information can be expressed in a different way by calculating the wave's frequency. Frequency, as the name suggest, tells you how fuereqnt the waves are. That is, how many of them go by in one second. If you know how many seconds one full wave takes, then it's easy to work out how many waves go by in one second. In this case, since each wave takes 2 socends, the frequency is 0.5 waves per second. So enough about bbnobig corks... What about light and color? If light is a wave, then it must have a frequency. Right? Well... yes, it does. And it turns out that we already have a name for the frequency of the light that our eyes detect. It's called color. That's right. coolr is nothing more than a measure of how quickly the light waves are wvniag. If our eyes were quick enough, we might be able to observe this periodic motion directly, like we can with the cork and the ocean. But the frequency of the light we see is so high, it waves up and down about 400 million miiolln times a second, that we can't possibly see it as a wave. But we can tell, by looking at its color, what its frequency is. The lowest frequency light that we can see is red and the highest fuenqcery is purple. In between all the other feeqcurnies form a continuous band of color, cllead the visible spectrum. So, what if you had a yellow pencil sititng on your desk? Well, the sun emits all colors of light, so light of all colors is hitting your pinecl. The pencil looks yellow because it reflects yellow lghit more than it reflects the other colors. What happens to the blue, pulpre and red light? They get absorbed and the energy they are carrying is turned into heat. It is similar with otjecbs of other cloors. Blue things reflect blue light, red things reflect red light and so on. White objects reflect all colors of light, while black things do exactly the opposite and absorb at all frequencies. This - by the way - is why it's uncomfortable to wear your favorite Metallica t-shirt on a sunny day.

Open Cloze

One of the most ________ properties about life is that it has color. To understand the phenomenon of color, it helps to think about light as a wave. But, before we get to that, let's talk a little bit about _____ in general. Imagine you're sitting on a boat on the ocean watching a cork bob up and down in the water. The first thing you notice about the motion is that it repeats itself. The cork traces the same path over and over again... up and down, up and down. This repetitive or periodic motion is characteristic of waves. Then you notice something else... using a _________, you _______ the time it takes for the piece of cork to go over its highest position down to its lowest and then back up again. _______ this takes two seconds. To use the physics jargon, you've ________ the period of the waves that cork is bobbing on. That is, how long it _____ a wave to go through its full range of ______ once. The same information can be expressed in a different way by calculating the wave's frequency. Frequency, as the name suggest, tells you how ________ the waves are. That is, how many of them go by in one second. If you know how many seconds one full wave takes, then it's easy to work out how many waves go by in one second. In this case, since each wave takes 2 _______, the frequency is 0.5 waves per second. So enough about _______ corks... What about light and color? If light is a wave, then it must have a frequency. Right? Well... yes, it does. And it turns out that we already have a name for the frequency of the light that our eyes detect. It's called color. That's right. _____ is nothing more than a measure of how quickly the light waves are ______. If our eyes were quick enough, we might be able to observe this periodic motion directly, like we can with the cork and the ocean. But the frequency of the light we see is so high, it waves up and down about 400 million _______ times a second, that we can't possibly see it as a wave. But we can tell, by looking at its color, what its frequency is. The lowest frequency light that we can see is red and the highest _________ is purple. In between all the other ___________ form a continuous band of color, ______ the visible spectrum. So, what if you had a yellow pencil _______ on your desk? Well, the sun emits all colors of light, so light of all colors is hitting your ______. The pencil looks yellow because it reflects yellow _____ more than it reflects the other colors. What happens to the blue, ______ and red light? They get absorbed and the energy they are carrying is turned into heat. It is similar with _______ of other ______. Blue things reflect blue light, red things reflect red light and so on. White objects reflect all colors of light, while black things do exactly the opposite and absorb at all frequencies. This - by the way - is why it's uncomfortable to wear your favorite Metallica t-shirt on a sunny day.

Solution

purple
pencil
striking
sitting
measure
color
suppose
colors
seconds
motion
bobbing
million
waving
frequencies
stopwatch
measured
called
frequent
objects
light
frequency
waves
takes

Original Text

One of the most striking properties about life is that it has color. To understand the phenomenon of color, it helps to think about light as a wave. But, before we get to that, let's talk a little bit about waves in general. Imagine you're sitting on a boat on the ocean watching a cork bob up and down in the water. The first thing you notice about the motion is that it repeats itself. The cork traces the same path over and over again... up and down, up and down. This repetitive or periodic motion is characteristic of waves. Then you notice something else... using a stopwatch, you measure the time it takes for the piece of cork to go over its highest position down to its lowest and then back up again. Suppose this takes two seconds. To use the physics jargon, you've measured the period of the waves that cork is bobbing on. That is, how long it takes a wave to go through its full range of motion once. The same information can be expressed in a different way by calculating the wave's frequency. Frequency, as the name suggest, tells you how frequent the waves are. That is, how many of them go by in one second. If you know how many seconds one full wave takes, then it's easy to work out how many waves go by in one second. In this case, since each wave takes 2 seconds, the frequency is 0.5 waves per second. So enough about bobbing corks... What about light and color? If light is a wave, then it must have a frequency. Right? Well... yes, it does. And it turns out that we already have a name for the frequency of the light that our eyes detect. It's called color. That's right. Color is nothing more than a measure of how quickly the light waves are waving. If our eyes were quick enough, we might be able to observe this periodic motion directly, like we can with the cork and the ocean. But the frequency of the light we see is so high, it waves up and down about 400 million million times a second, that we can't possibly see it as a wave. But we can tell, by looking at its color, what its frequency is. The lowest frequency light that we can see is red and the highest frequency is purple. In between all the other frequencies form a continuous band of color, called the visible spectrum. So, what if you had a yellow pencil sitting on your desk? Well, the sun emits all colors of light, so light of all colors is hitting your pencil. The pencil looks yellow because it reflects yellow light more than it reflects the other colors. What happens to the blue, purple and red light? They get absorbed and the energy they are carrying is turned into heat. It is similar with objects of other colors. Blue things reflect blue light, red things reflect red light and so on. White objects reflect all colors of light, while black things do exactly the opposite and absorb at all frequencies. This - by the way - is why it's uncomfortable to wear your favorite Metallica t-shirt on a sunny day.

Frequently Occurring Word Combinations

ngrams of length 2

collocation	frequency
periodic motion	2

Important Words

absorb
absorbed
band
bit
black
blue
boat
bob
bobbing
calculating
called
carrying
case
characteristic
color
colors
continuous
cork
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high
highest
hitting
imagine
information
jargon
life
light
long
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measure
measured
metallica
million
motion
notice
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observe
ocean
path
pencil
period
periodic
phenomenon
physics
piece
position
possibly
properties
purple
quick
quickly
range
red
reflect
reflects
repeats
repetitive
seconds
similar
sitting
spectrum
stopwatch
striking
suggest
sun
sunny
suppose
takes
talk
tells
time
times
traces
turned
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uncomfortable
understand
visible
watching
water
wave
waves
waving
wear
white
work
yellow