A Thin-Film Transistor (TFT) display, also known as an active-matrix display, is a type of liquid crystal display (LCD) that uses thin-film transistor technology to control individual pixels on the screen. TFT displays are widely used in devices like computer monitors, televisions, smartphones, and tablets due to their high image quality, fast response times, and ability to produce vibrant colors. Here's a simplified explanation of how a TFT display works:
Basic LCD Structure:
A TFT display consists of two layers of glass with a liquid crystal solution sandwiched in between. The glass layers are coated with transparent electrodes. The inner surface of each glass layer also has a color filter to create red, green, and blue sub-pixels for color reproduction.
Liquid Crystals:
The liquid crystal material is made up of organic molecules that can change their orientation when exposed to an electric field. By manipulating the orientation of these molecules, the passage of light through the liquid crystal layer can be controlled.
Pixel Arrangement:
The display is divided into an array of individual pixels. Each pixel is made up of three sub-pixels: one red, one green, and one blue. By varying the intensity of these colored sub-pixels, a wide range of colors can be displayed.
Thin-Film Transistors (TFTs):
A TFT is a tiny switching transistor located at each pixel. They are typically made using thin-film deposition techniques on the glass substrate. TFTs act as switches, allowing or blocking the flow of electrical current to the liquid crystal at each pixel.
Backlighting (for LCDs with LED backlight):
In most TFT displays, a backlight is used to illuminate the liquid crystal layer from behind. This allows the display to be visible even in low-light conditions. Modern TFT displays typically use LEDs as the backlight source due to their efficiency and controllable brightness.
Addressing Individual Pixels:
To display an image, the TFTs are controlled by a circuit called the "thin-film transistor array." This circuit sends electrical signals to the individual transistors, which in turn control the orientation of the liquid crystal molecules at each pixel. By selectively allowing light to pass through or blocking it, the display creates the desired image.
Color Reproduction:
By adjusting the voltage applied to each sub-pixel, the intensity of red, green, and blue light emitted by each pixel can be controlled. This combination of colors at each pixel creates a wide range of colors that make up the displayed image.
Updating the Display:
To change the image on the display, the TFTs are rapidly switched on and off in a precise sequence, updating the orientation of the liquid crystal molecules at each pixel. This process happens at a high speed, typically several times per second (refresh rate), resulting in smooth motion and video playback.
Overall, the precise control of individual pixels provided by thin-film transistors allows TFT displays to offer high-resolution, bright, and vivid images suitable for various electronic devices.