In a typical telephone call, a
microphone converts speech into an analog electrical signal, which is digitized by an ADC. The resulting digital data can be multiplexed with other digital information for transmission over a shared communication system. At the receiving end, a DAC converts the digital signal back into analog form so it can be amplified and reproduced as sound.
Audio (top) and external digital-to-analog converter (bottom) from the same company. as an add-on for CD players, having only about 12 cm width, intended to improve the sound of older or less expensive players. Most modern audio signals are stored in digital form (for example,
MP3s and
CDs), and in order to be heard through speakers, they must be converted into an analog signal. DACs are therefore found in
CD players,
digital music players, and PC
sound cards. Specialist standalone DACs can also be found in high-end
hi-fi systems. These normally take the digital output of a compatible CD player or dedicated
transport (which is basically a CD player with no internal DAC) and convert the signal into an analog
line-level output that can then be fed into an
amplifier to drive speakers. Similar digital-to-analog converters can be found in
digital speakers, such as
USB speakers and in
sound cards. In
voice over IP applications, the source must first be digitized for transmission, so it undergoes conversion via an ADC and is then reconstructed into analog using a DAC on the receiving party's end.
Video Video sampling tends to work on a completely different scale altogether thanks to the highly nonlinear response both of cathode ray tubes (for which the vast majority of digital video foundation work was targeted) and the human eye, using a "gamma curve" to provide an appearance of evenly distributed brightness steps across the display's full dynamic range - hence the need to use
RAMDACs in computer video applications with deep enough color resolution to make engineering a hardcoded value into the DAC for each output level of each channel impractical (e.g. an Atari ST or Sega Genesis would require 24 such values; a 24-bit video card would need 768...). Given this inherent distortion, it is not unusual for a television or video projector to truthfully claim a linear contrast ratio (difference between darkest and brightest output levels) of 1000:1 or greater, equivalent to 10 bits of audio precision, even though it may only accept signals with 8-bit precision and use an LCD panel that only represents 6 or 7 bits per channel. Video signals from a digital source, such as a computer, must be converted to analog form if they are to be displayed on an analog monitor. As of 2007, analog inputs were more commonly used than digital, but this changed as
flat-panel displays with
DVI and/or
HDMI connections became more widespread. A video DAC is, however, incorporated in any digital video player with analog outputs. The DAC is usually integrated with some
memory (
RAM), which contains conversion tables for
gamma correction, contrast and brightness, to make a device called a
RAMDAC.
Digital potentiometer A device that is distantly related to the DAC is the
digitally controlled potentiometer, used to control an analog signal digitally.
Mechanical A one-bit mechanical actuator assumes two positions: one when on, another when off. The motion of several one-bit actuators can be combined and weighted with a
whiffletree mechanism to produce finer steps. The
IBM Selectric typewriter uses such a system.
Communications DACs are widely used in modern communication systems, enabling the generation of digitally defined transmission signals. High-speed DACs are used for
mobile communications and ultra-high-speed DACs are employed in
optical communications systems. ==Types==