A cathode-ray tube (CRT) is a device that was commonly used in older television sets and monitors to display images. It works based on the principles of electron beams, phosphorescent materials, and electromagnetic fields. Here's how a CRT generates images:
Electron Gun: The CRT contains an electron gun at the back of the tube. This electron gun emits a stream of high-energy electrons. These electrons are negatively charged.
Cathode: The electron gun is aimed at a cathode, which is a heated filament. When the filament heats up, it releases electrons through a process called thermionic emission.
Electron Acceleration: The released electrons are then accelerated using high-voltage electrodes. These electrodes are positively charged, which causes the electrons to gain significant energy.
Electron Focusing: After acceleration, the electron beam passes through a series of magnetic coils called focusing coils. These coils create a magnetic field that focuses the electron beam into a tight, narrow path.
Deflection System: Once focused, the electron beam moves through a pair of deflection coils. These coils are positioned orthogonally and are responsible for steering the electron beam across the screen horizontally and vertically. By adjusting the current through these coils, the position of the electron beam can be precisely controlled, allowing it to move across the entire screen.
Phosphorescent Screen: The front of the CRT is covered with a phosphorescent screen, also known as a phosphor-coated screen. This screen is coated with tiny phosphorescent particles that emit light when struck by the high-speed electrons.
Pixel Formation: The phosphorescent screen is divided into millions of tiny dots called pixels. Each pixel is composed of three sub-pixels: one red, one green, and one blue. These three primary colors of light are used to create a full spectrum of colors.
Image Creation: To create an image, the electron beam is directed to scan across the screen horizontally, moving from left to right. As it scans, the beam is turned on and off rapidly for each pixel based on the desired image. When the beam hits a phosphorescent sub-pixel, it causes the phosphor to emit light. By varying the intensity of the electron beam and the duration it hits each sub-pixel, different colors and brightness levels are produced.
Persistence: The emitted light from the phosphorescent material persists for a short time after being struck by electrons. This persistence allows the viewer's eyes to perceive a continuous image even though the electron beam is rapidly scanning across the screen.
Refresh Rate: The entire screen is painted one line at a time, from the top to the bottom, and the process repeats many times per second. The rapid scanning of the electron beam gives the illusion of a complete image being displayed, and the persistence of the phosphorescent material helps maintain the image until the next scan.
By controlling the movement of the electron beam and the intensity of the emitted light, CRTs were able to display a wide range of images and videos on television screens and monitors.