Colour monitors have pixels that are red, green and blue.
Yes, they appear opposite one another on a standard colour wheel.
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Yes; less than one pixel is 0 pixels which is nothing = no image Vector images can be of any size but when rendered to screen (or any imaging device which uses pixels) of course the result must be at least 1 pixel for the object to appear. The vector object might very well be there but be invisible due to the (low) resolution of the imaging output.
The standard error is the standard deviation divided by the square root of the sample size.
The plural of standard is standards.
Monochrome monitors are a type of computer display which were very common in the early days of computing, from the 1960s through the 1980s, before the advent of color monitors. They are still used today in some computerized cash register systems, amongst other select applications. Unlike color monitors, which display text and graphics in multiple colors through the use of alternating-intensity red, green, and blue phosphors, monochrome monitors have only one color of phosphor (mono = one, chrome = color). All text and graphics are displayed in that color. Some monitors have the ability to vary the brightness of individual pixels, thereby creating the illusion of depth and color, exactly like a black-and-white television. Monochrome monitors are available in three colors: if the P1 phosphor is used, the screen is green monochrome. If the P3 phosphor is used, the screen is amber monochrome. If the P4 phosphor is used, the screen is white monochrome (known as "page white"); this is the same phosphor as used in early television sets. Monochrome monitors, pixel-for-pixel, produce sharper text and images than color CRT monitors. This is because on a monochrome monitor, each pixel is made up of one phosphor, located in the dead center of the pixel; whereas on a color monitor, each pixel is made up of three phosphors (one red, one blue, one green), none of which are in the center of the pixel. Color LCD monitors, however, do not suffer from this malady and therefore are just as sharp as monochrome CRT monitors. Because of their superior sharpness over color CRT monitors, monochrome monitors were used in almost all dumb terminals; and they still enjoy use in text-based applications such as computerized cash registers and order terminals (such as those seen at many fast-food restaurants). Monochrome monitors are particularly susceptible to screen burn (hence the advent, and name, of the screen saver), on account of the fact that the phosphors used are very high-intensity. Another effect of the high-intensity phosphors is an effect known as "ghosting", wherein a dim afterglow of the screen's contents is briefly visible after the screen has been blanked.
False. A dot on the screen that contains a color is called a "pixel."
A pixel (from PICture ELement)
I will explain how a monochrome (black-and-white) display works. A color display has the same basic mechanism, but with each pixel replaced by a triple of independent elements that produce varying amounts of red, green, and blue.
The standard for mounting hardware and communication for monitors is VESA, the Video Electronic Standards Association
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Computer monitors have higher resolution (more lines or pixels) than television monitors (screens or tubes). Computer monitors also have the ability to "address" (pinpoint and turn on/off or color) every pixel (single dot of color on the screen). Television monitors do not have that precision.
White uses the most energy to display. This is because most monitors use the RGB pixel (Red Green Blue). To display the color white, the monitor must turn on all three pixels, thus consuming the most energy.
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pixel
A pixel is one dot in the image. A 10 megapixel camera will have 10 million pixels that make up the image.