A Video Graphics Array (VGA) connector is a three-row 15-pin DE-15 connector. The 15-pin VGA connector was provided on many video cards, computer monitors, laptop computers, projectors, and high definition television sets. On laptop computers or other small devices, a mini-VGA port was sometimes used in place of the full-sized VGA connector.
Many devices still include VGA connectors, although VGA generally coexisted with DVI as well as the newer and more compact HDMI and DisplayPort interface connectors.
VGA connectors and cables carry analog component RGBHV (red, green, blue, horizontal sync, vertical sync) video signals, and VESA Display Data Channel (VESA DDC) data. In the original version of DE-15 pinout, one pin was keyed by plugging the female connector hole; this prevented non-VGA 15 pin cables from being plugged into a VGA socket. Four pins carried Monitor ID bits, which were rarely used; VESA DDC redefined some of these pins and replaced the key pin with +5 V DC power supply. Devices that comply with the DDC host system standard provide 5V ±5% and supply a minimum of 300 mA to a maximum of 1 A.
The VGA interface is not engineered to be hotpluggable (so that the user cannot connect or disconnect the output device while the host is running), although in practice this can be done and usually does not cause damage to the hardware or other problems. However, nothing in the design ensures that the ground pins form the first make or the last break in the connection, so hotplugging may introduce surges in signal lines that may or may not be adequately protected against damage. Also, depending on the hardware and software, monitor detection is sometimes unreliable when hotplugging a VGA connection.
DE-15 has been conventionally referred to ambiguously as D-sub 15, incorrectly as DB-15 and often as HD-15 (High Density, to distinguish it from the DE-9 connector used on the older CGA and EGA cards, as well as some early VGA cards, which have the same E shell size but only two rows of pins). The video connector is an “E” size D-sub connector, with 15 pins in three rows, which is the high-density connector version (DE15HD).
The same VGA cable can be used with a variety of supported VGA resolutions, ranging from 320×400px @70 Hz / 320x480px @60 Hz (12.6 MHz of signal bandwidth) to 1280×1024px (SXGA) @85 Hz (160 MHz) and up to 2048×1536px (QXGA) @85 Hz (388 MHz). There are no standards defining the quality required for each resolution but higher-quality cables typically contain coaxial wiring and insulation that make them thicker. Shorter VGA cables are less likely to introduce significant signal degradation. A good-quality cable should not suffer from signal crosstalk, whereby signals in one wire induce unwanted currents in adjacent wires, or ghosting. Ghosting occurs when impedance mismatches, 75Ohm by the specification, cause signals to be reflected. However, ghosting with long cables may be caused by equipment with incorrect signal termination or by passive cable splitters rather than the cables themselves.
There are DVI to VGA adapters and cables. As neither DVI nor VGA carry audio channels, a separate path for audio should be used, if needed. Simple adapters from other modern outputs such as HDMI to VGA are also commonplace, again requiring a separate audio path.
To connect VGA outputs to interfaces with different signaling, more complex converters may be used. Most of them need an external power source to operate and are inherently lossy. However, many modern displays are still made with multiple inputs including VGA, in which case adapters are not necessary.
VGA to SCART converters can pass color information, because VGA — SCART RGB signals are electrically compatible, except for synchronization. Many modern graphics adapters can modify their signal in software, including refresh rate, sync length, polarity and number of blank lines. Particular issues include interlace support and the use of the resolution 720×576 in PAL countries. Under these restrictive conditions, a simple circuit to combine the VGA separate synchronization signals into SCART composite sync may suffice.