- Английский язык 3 класс (часть 1) Афанасьева. UNIT 3. Step 3. Номер №7
- Решение
- Apple Green Color Codes
- Apple Green Hex, RGB and CMYK Color Codes
- Shades and Variations of Apple Green
- Complementary Colors to Apple Green
- The Apple Green Color Code: The HEX Code
- The RGB Values and Percentages for Apple Green
- The CMYK Values and Percentages for Apple Green
- The Color Experts You Can Count On
- INFINITY NOW
- Thursday, September 3, 2009
- What Color is a Green Apple?
- What color is green apple
- System Colors
Английский язык 3 класс (часть 1) Афанасьева. UNIT 3. Step 3. Номер №7
Поработайте в парах. Задайте вопросы о цвете предметов и ответьте на них.
Образец 1 : What colour is the lake? − It is grey.
the sky, the night, the sun, the evening, the morning, the rainbow
Образец 2 : − What colour are grapes? − They are purple and green and yellow.
apples, oranges, lemons, plums, bananas
Решение
Поработайте в парах. Задайте вопросы о цвете предметов и ответьте на них.
Образец 1 : Какого цвета озеро? − Оно серое.
небо, ночь, солнце, вечер, утро, радуга
Образец 2 : − Какого цвета виноград? − Он фиолетовый, зеленый и желтый.
яблоки, апельсины, лимоны, сливы, бананы
ОТВЕТ
What colour is the sky? − It is blue.
What colour is the night? − It is dark blue and black.
What colour is the sun? − It is yellow.
What colour is the evening? − It is grey.
What colour is the morning? − It is yellow.
What colour is the rainbow? − It is red, orange, yellow, green, blue, dark blue and purple.
What colour are apples? − They are red and green and yellow.
What colour are oranges? − They are orange.
What colour are lemons? − They are yellow.
What colour are plums? − They are purple, green and yellow.
What colour are bananas? − They are yellow.
Перевод ответа
Какого цвета небо? − Оно голубое.
Какого цвета ночь? − Она темно−синяя и черная.
Какого цвета солнце? − Оно желтое.
Какого цвета вечер? − Он серый.
Какого цвета утро? − Оно желтое.
Какого цвета радуга? − Она красная, оранжевая, желтая, зеленая, голубая, синяя и фиолетовая.
Какого цвета яблоки? − Они красные, зеленые и желтые.
Какого цвета апельсины? − Они оранжевые.
Какого цвета лимоны? − Они желтые.
Какого цвета сливы? − Они фиолетовые, зеленые и желтые.
Какого цвета бананы? − Они желтые.
Источник
Apple Green Color Codes
Apple Green Hex, RGB and CMYK Color Codes
If you are looking for the specific color values of apple green, you will find them on this page. These values can help you match the specific shade you are looking for and even help you find complementary colors. Looking for a different shade of green? Follow this link: Green Color Codes
Shades and Variations of Apple Green
#5A7500
#293600
#95C200
#779C00
Complementary Colors to Apple Green
#506900
#C9FF19
#460069
#7A00B5
Apple Green Color Swatch Sample
Whether you’re a professional graphic designer or an amateur artist, finding the right color is essential for pulling off your graphic artwork. Though most of the time it can be easy to select the color that you desire, it’s not uncommon that you run into a situation where you need more complex and specific swatches for your task.
A perfect example of this is the color of apple green. This beautiful color is a popular choice for many clients and artists alike, but even with this being the case it is a complex color to create in any graphic system, and you could end up creating one of the many other types of green if you don’t know what you’re doing.
Luckily for you, you don’t have to go it alone. You can easily create the apple green color using the apple green color code specific to the type of program you’re running, and this article talks about the specific code that you need as well as the colors that make up this brilliant color. Keep reading this article to find out more!
The Apple Green Color Code: The HEX Code
The HEX color system is popular in many graphic design centers, so if you work in the industry there’s a good chance you’re completing your projects based on this spectrum. Thankfully, the HEX value for apple green is simple; the code you need to input is #8db600.
The RGB Values and Percentages for Apple Green
Each system has a different value, or percentage of colors, that make up every color in the graphic design spectrum, and the same can be said for apple green.
In the RGB (red, green, blue) system, the apple green color percentage is comprised of apple green in the RGB system is (141,182,0).
The CMYK Values and Percentages for Apple Green
Whereas the RGB values focus on a 3-color combination, the CMYK values focus on 4-color combinations. Furthermore, the CMYK values for apple green are (23,0,100,29) almost parallel to the actual percentages.
The Color Experts You Can Count On
Now that you know what values make up the apple green color code, you can be sure that you’ll get the right swatch every time. However, if you ever need help with any other color palette, you can be sure we can help you to get what you need.
At colorcodes.io, we are the experts in finding precise code numbers for any color that you’re looking for – and we do mean any color. This includes both the primary color (blue, red, and yellow swatches) and the secondary color (orange, purple, and green swatches) spectrums for HEX, RGB, CMYK, and PMS color codes.
Ready to get started? Simply check out our site to begin learning more. We’re sure we have every color code for all of your needs!
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INFINITY NOW
Eternity in the present
Thursday, September 3, 2009
What Color is a Green Apple?
Things aren’t always as they seem.
Take your favorite coffee cup and put it on the table in front of you. Now look at it. Let’s say for the sake of the argument that you have “normal,” non-corrected, 20/20, human eyesight. Your eyes are giving you information about the cup. Your image of it is sharp and clear. You assume that what you are seeing is the cup. But is it?
An enormous number of living creatures on earth have eyes. Elephants, eagles, dogs, hammerhead sharks, and houseflies all have eyes. But are their eyes identical? When other creatures look at your cup, do they see exactly what you see? Do they see shapes and colors the same way your eyes do? If not, then which image of your cup—the elephant’s, eagle’s, dog’s, shark’s, housefly’s, or yours—is “correct”? Which one is really the cup?
When you examine the problem this way, you begin to see that all of these images belong to the cup, but none of the images are the cup. The cup is a reality that is more than merely what your eyes can see. Your eyes only see a narrow band of the full spectrum of light. For example, your eyes can see no light from the ultraviolet or the infrared spectrums. Your eyes “see” the cup, for sure, but only in the spectrum of light that your eyes are designed with which to see.
What you see, your visual image of the cup, is limited by your eyes’ design. In fact, your eyes are sieves that filter out the chaotic light frequencies that interfere with your survival—so you can hunt a deer, spot a crouching lion, and avoid walking off a cliff. Therefore your image of the cup is incomplete. The cup’s cup-ness is more than what your eyes in their limitations can perceive.
When an apple appears green to you, it is not because the apple is actually green. The surface of the apple happens to absorb blue and red wavelengths of light while it reflects green. The apple then appears to your eyes to be green. But if you were significantly colorblind, you probably would not be able to tell a red from a green apple!
One in every 100 males has some “red-weakness” (Protanomaly), meaning shades of red are difficult to distinguish. Five in every 100 males has a “green-weakness” (Deuteranomaly). (Colorblindness in women is very rare. Tritanope is even rarer.) A colorblind person who looks at a colorful map of the world will see “the world” differently than you. The following four maps of the world demonstrate this.
When your eye sees the green apple, the really weird thing is that a green apple is actually absorbing every other color but green. Green is the only light wave that it rejects! Your eye sees the apple as green because green is the only light color it can’t keep (absorb).
We are “seeing things” because of light. Eyes are organs that process light. Light enters the eye, shining on what are called cones and rods, and the light triggers a chemical reaction in the rods and cones, and the chemicals turn into electrical impulses that are sent to a certain part of the brain where these impulses are received, organized, and transmitted to other parts of the brain for analysis and communication.
So when you look at your cup, are you seeing your cup? Yes and no. “Yes” because the image your eyes provide is an actual image of your cup. “No” because the image is not your actual physical cup. Like a camera, your eye catches light and provides a “photograph” of that light bouncing off of stuff like your cup. Light bounces off of the cup and goes into your eyes, and you “see the light” bouncing off the cup. You do not see the cup itself. For everyday purposes everyone seems to assume that the cup they “see” is the actual cup. In a very real sense it’s not.
Because light is the only thing eyes can see. Eyes receive and process light, not cups. Your eyes are light processors, not cup processors. The “photograph” of the cup is not the cup.
The moon, however, doesn’t give off its own light. It merely reflects the light of the sun. So how long does it take sunlight to travel from the sun all the way to the Earth and its moon? Eight minutes. We’re talking about 93 million miles at 186,282 miles per second in about 500 seconds (or a little over eight minutes). So when you look at the sun—hopefully you don’t stare at it!—you aren’t seeing the sun as it is, but as it was eight minutes ago. You’re looking eight minutes back in time.
When you look at the planet Saturn with your naked eye—easily done if you know where and what to look for—you aren’t seeing Saturn as it is, but as it was . . . one whole hour ago.
The nearest star to our sun (our sun is a star)—Proxima Centauri (Alpha Centauri C)—is 4.3 “light years” away. A light year is the distance light travels in one year. It takes light from Proxima Centauri four years to reach us. So when you look up and see Proxima Centauri, you are not seeing Proxima Centauri as it is, but as it was four years ago.
On a clear, cold, moonless night, drive out away from the lights of “civilization” and look up using only your naked eye. The sky is a virtual canopy of stars—thousands of them. Some of the dim stars you are looking at are 2000 light years from Earth. But you are not seeing those distant stars as they are today. You are seeing them as they were 2000 years ago when Jesus of Nazareth walked the Earth. Moreover, when Jesus gazed at these distant stars, he saw them as they were 2000 years before his time, or near the time when Abraham walked the Earth.
Again, things aren’t always as they seem. We can’t see anything in the heavens as it “is” right now. To stand in your backyard and look up at the stars is to leave “the now.” To stargaze is to travel backward in time. But this raises yet another oddity.
Look at your favorite coffee cup again. Not only is the cup in its cup-ness more than what your eyes can perceive, but the light traveling from your cup to your eye takes time to get there. It’s a very, very short amount of time, granted. But it takes time. Therefore, you can’t even look at your own coffee cup and see its image in “the now.” It’s nearly instantaneous, yes. And you can’t perceive it as anything other than instantaneous. But it’s not instantaneous.
When you look at your cup, you are seeing an image of it as it was a fraction of a second ago. In fact, because the speed of light is finite, there is no image that you can ever perceive visually in the actual present. Everything you perceive with your eyes is in the past due to a finite speed of light. How far in the past the object is seen depends on its distance from your eye.
Because light has a speed, you see the cup in front of you as it was fractions of a second ago. You see the moon as it was one second ago. You see the sun as it was eight minutes ago. You see Saturn as it was an hour ago. You see Proxima Centauri as it was four years ago. You see distant stars in the night sky as they were 2000 years ago.
My point? This blog is a parable of perception . When it comes to seeing, perception is not reality. But what about God? Is perception reality when it comes to God?
After much study and thought, I’m convinced that at the core of Jesus’ mission was his intent to provide for us corrective lenses . He came to reveal his heavenly Father as he really is. He came to correct our perception of God.
Faith is the willingness to trust his eyes instead of your own. Faith rests in what Jesus sees rather than what you think you see.
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What color is green apple
Color is a great way to impart vitality, provide visual continuity, communicate status information, give feedback in response to user actions, and help people visualize data. Look to the system’s color scheme for guidance when picking app accent colors that look great individually and in combination, and adapt well to accessibility and appearance modes.
Don’t rely solely on color to differentiate between objects or communicate important information. If your app uses color to convey information, be sure to provide text labels or glyph shapes so users with colorblindness or other visual disabilities can understand it.
Use color judiciously for communication. The power of color to call attention to important information is heightened when used sparingly. For example, a red triangle that warns of a critical problem becomes less effective when red is used elsewhere in an app for noncritical reasons.
Consider choosing a limited color palette that coordinates with your app logo. Subtle use of color is a great way to communicate your brand.
Consider choosing a color to indicate interactivity throughout your app. In Notes, interactive elements are yellow; in Calendar, interactive elements are red. If you define an accent color that denotes interactivity, make sure other colors in your app don’t compete with it.
Provide two versions of your accent color to make sure it looks good in both light and dark modes. When you use a system color for your accent color, you get automatic support for both appearance modes.
Avoid using the same color for interactive and noninteractive elements. If interactive and noninteractive elements have the same color, it’s hard for people to know where to tap.
Consider how artwork and translucency affect nearby colors. Variations in artwork sometimes warrant changes to nearby colors to maintain visual continuity and prevent interface elements from becoming overpowering or underwhelming. Maps, for example, displays a light color scheme when in map mode but switches to a dark color scheme when in satellite mode. Colors can also appear different when placed behind or applied to a translucent element like a toolbar.
Test your app’s color scheme under a variety of lighting conditions. Lighting varies significantly both indoors and outdoors, based on room ambiance, time of day, the weather, and more. Colors you see on your computer won’t always look the same when your app is used in the real world. Always preview your app under multiple lighting conditions, including outdoors on a sunny day, to see how colors appear. If necessary, adjust colors to provide the best possible viewing experience in the majority of use cases.
Consider how the True Tone display affects color. The True Tone display uses ambient light sensors to automatically adjust the white point of the display to adapt to the lighting conditions of the current environment. Apps that focus primarily on reading, photos, video, and gaming can strengthen or weaken this effect by specifying a white point adaptivity style. For developer guidance, see UIWhitePointAdaptivityStyle.
Consider how your use of color might be perceived in other countries and cultures. In some cultures, for example, red communicates danger; in others, red has positive connotations. Make sure the colors in your app send the appropriate message.
Avoid using colors that can make it hard for people to perceive content in your app. For example, a colorblind user might not be able to distinguish some color combinations, and insufficient contrast can cause icons and text to blend with the background and make content hard to read for users with visual disabilities. For guidance, see Color and Contrast.
System Colors
iOS offers a range of system colors that automatically adapt to vibrancy and changes in accessibility settings like Increase Contrast and Reduce Transparency. The system colors look great individually and in combination, on both light and dark backgrounds, and in both light and dark appearances.
Don’t hard-code system color values in your app. The color values provided below are intended for reference during your app design process. The actual color values may fluctuate from release to release, based on a variety of environmental variables. Always use the API to apply system colors; for developer guidance, see UIColor (UIKit) and Color (SwiftUI).
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