Editing Digital-to-analog converter

{{Short description|Device that converts a digital signal into an analog signal}}
{{about|conversion of digital signals to analog signals|digital television converter boxes|digital television adapter}}
{{Redirect|D2A|the D2A dive bomber|Aichi D1A}}
{{redirect|d-a-c|other uses|DAC (disambiguation)}}
{{Multiple issues|
{{refimprove|date=August 2016}}
{{prose|date=November 2019}}
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{{Use American English|date=January 2020}}

[[File:CirrusLogicCS4282-AB.jpg|thumb|right|200px|8-channel [[Cirrus Logic]] CS4382 digital-to-analog converter as used in a [[sound card]].]]

In [[electronics]], a '''digital-to-analog converter''' ('''DAC''', '''D/A''', '''D2A''', or '''D-to-A''') is a system that converts a [[Digital signal (signal processing)|digital signal]] into an [[analog signal]]. An [[analog-to-digital converter]] (ADC) performs the reverse function.

DACs are commonly used in [[digital audio player|music players]] to convert digital data streams into analog [[audio signal]]s. They are also used in [[television]]s and [[mobile phone]]s to convert digital video data into [[Analog television|analog video signals]]. These two applications use DACs at opposite ends of the frequency/resolution trade-off. The audio DAC is a low-frequency, high-resolution type while the video DAC is a high-frequency low- to medium-resolution type. 

There are several DAC [[hardware architecture|architectures]]; the suitability of a DAC for a particular application is determined by [[figures of merit]] including: [[resolution (audio)|resolution]], maximum [[sampling frequency]] and others.  Digital-to-analog conversion can degrade a signal, so a DAC should be specified that has insignificant errors in terms of the application. 

Due to the complexity and the need for precisely matched [[electronic components|components]], all but the most specialized DACs are implemented as [[integrated circuits]] (ICs). These typically take the form of [[metal–oxide–semiconductor]] (MOS) [[mixed-signal integrated circuit]] chips that integrate both [[Analogue electronics|analog]] and [[digital circuits]].

Discrete DACs (circuits constructed from multiple discrete electronic components instead of a packaged IC) would typically be extremely high-speed low-resolution power-hungry types, as used in military [[radar]] systems. Very high-speed test equipment, especially sampling [[oscilloscope]]s, may also use discrete DACs.

==Overview==
[[File:Sampled.signal.svg|thumb|Sampled signal.]]
A DAC converts an [[abstract object|abstract]] finite-precision number (usually a [[fixed-point arithmetic|fixed-point]] [[binary number]]) into a  physical quantity (e.g., a [[voltage]] or a [[pressure]]). In particular, DACs are often used to convert finite-precision [[time series]] data to a continually varying physical [[signal]].

Provided that a signal's bandwidth meets the requirements of the [[Nyquist&ndash;Shannon sampling theorem]] (i.e., a [[baseband]] signal with [[Bandwidth (signal processing)|bandwidth]] less than the [[Nyquist frequency]]) and was sampled with infinite resolution, the original signal can theoretically be reconstructed from the sampled data. However, an ADC's filtering can't ''entirely'' eliminate all frequencies above the Nyquist frequency, which will [[Aliasing|alias]] into the baseband frequency range. And the ADC's digital sampling process introduces some [[quantization error]] (rounding error), which manifests as low-level noise. These errors can be kept within the requirements of the targeted application (e.g. under the limited [[Dynamic range#Human perception|dynamic range of human hearing]] for audio applications).

==Applications==
[[File:8 bit DAC.svg|thumb|A simplified functional diagram of an 8-bit DAC]]
DACs and ADCs are part of an [[enabling technology]] that has contributed greatly to the [[digital revolution]]. To illustrate, consider a typical long-distance telephone call. The caller's voice is converted into an analog electrical signal by a [[microphone]], then the analog signal is converted to a digital stream by an ADC. The digital stream is then divided into [[network packet]]s where it may be sent along with other [[digital data]], not necessarily audio. The packets are then received at the destination, but each packet may take a completely different route and may not even arrive at the destination in the correct time order. The digital voice data is then extracted from the packets and assembled into a digital data stream. A DAC converts this back into an analog electrical signal, which drives an [[audio amplifier]], which in turn drives a [[Speaker (audio equipment)|speaker]], which finally produces sound.

===Audio===
[[File:Cd-player-top-loading-and-DAC.jpg|thumb|right|Top-loading [[CD player]] (top) and external digital-to-analog converter (bottom) from the same company.]]
[[File:DAC in the box.jpg|thumb|A 1990s external DAC from [[Audio Alchemy]] as an add-on for CD players, having only about 12&nbsp;cm width, intended to improve the sound of older or less expensive players.]]

Most modern audio signals are stored in digital form (for example [[MP3]]s and [[CD]]s), and in order to be heard through speakers, they must be converted into an analog signal. DACs are therefore found in [[CD player]]s, [[digital music player]]s, and PC [[sound card]]s.

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 (recording)|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 card]]s.

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 [[RAMDAC]]s 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 display]]s with [[DVI]] and/or [[HDMI]] connections became more widespread.{{Citation needed|date=October 2011}} A video DAC is, however, incorporated in any digital video player with analog outputs.  The DAC is usually integrated with some [[computer storage|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===
[[File:IBM Selectric II typewriter.ogv|thumb|IBM Selectric typewriter uses a mechanical digital-to-analog converter to control its typeball.]]

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.<ref>{{cite web |author=Brian Brumfield |url=https://www.youtube.com/watch?v=uTjxwVfx8GA | archive-url=https://web.archive.org/web/20151229033401/https://www.youtube.com/watch?v=uTjxwVfx8GA| archive-date=2015-12-29 | url-status=dead|title=Selectric Repair 10-3A Input: Keyboard |date=Sep 2, 2014 |via=YouTube |df=ymd-all}}</ref>

=== 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==
The most common types of electronic DACs are:<ref name="ADDCH">{{cite web |url=http://www.analog.com/media/en/training-seminars/design-handbooks/Data-Conversion-Handbook/Chapter3.pdf |title=Data Converter Architectures |work=Analog-Digital Conversion |publisher=[[Analog Devices]] |access-date=2017-08-30 |df=ymd-all |ref={{sfnref|"Data Converter Architectures"}}|url-status=live |archive-url=https://web.archive.org/web/20170830032212/http://www.analog.com/media/en/training-seminars/design-handbooks/Data-Conversion-Handbook/Chapter3.pdf |archive-date=2017-08-30}}</ref>
* The [[pulse-width modulator]] where a stable [[current (electricity)|current]] or [[voltage]] is switched into a low-pass [[analog filter]] with a duration determined by the digital input code. This technique is often used for [[Motor controller|electric motor speed control]] and dimming [[LED lamp]]s.
* Oversampling DACs or interpolating DACs such as those employing [[delta-sigma modulation]], use a pulse density conversion technique with [[oversampling]]. Audio delta-sigma DACs are sold with 384&nbsp;kHz sampling rate and quoted 24-bit resolution, though quality is lower due to inherent noise (see {{Slink|2=Figures of merit|nopage=y}}). Some consumer electronics use a type of oversampling DAC referred to as a [[1-bit DAC]].
* The binary-weighted DAC, which contains individual electrical components for each bit of the DAC connected to a summing point, typically an [[operational amplifier]]. Each input in the summing has powers-of-two weighting with the most current or voltage at the [[most-significant bit]]. This is one of the fastest conversion methods but suffers from poor accuracy because of the high precision required for each individual voltage or current.<ref>{{Cite web |url=https://www.electronics-tutorial.net/analog-integrated-circuits/data-converters/binary-weighted-resistor-dac/index.html |title=Binary Weighted Resistor DAC |website=Electronics Tutorial |language=en-US |access-date=2018-09-25 |df=ymd-all}}</ref>
** Switched [[resistor]] DAC contains a parallel resistor network.  Individual resistors are enabled or bypassed in the network based on the digital input.
** Switched [[current source]] DAC, from which different current sources are selected based on the digital input. [[File:DAC-1138KX - pcb top view.jpg|thumb|Current steering DAC - DAC1138KX]]
** Switched [[capacitor]] DAC contains a parallel capacitor network.  Individual capacitors are connected or disconnected with switches based on the input.
** The [[resistor ladder|R-2R ladder]] DAC which is a binary-weighted DAC that uses a repeating cascaded structure of resistor values R and 2R. This improves the precision due to the relative ease of producing equal valued-matched resistors.
* The successive approximation or cyclic DAC,{{sfn|"Data Converter Architectures"|p=3.29}} which successively constructs the output during each cycle.  Individual bits of the digital input are processed each cycle until the entire input is accounted for.
* The [[Thermometer code|thermometer-coded]] DAC, which contains an equal resistor or current-source segment for each possible value of DAC output. An 8-bit thermometer DAC would have 255 segments, and a 16-bit thermometer DAC would have 65,535 segments. This is a fast and highest precision DAC architecture but at the expense of requiring many components which, for practical implementations, fabrication requires high-density [[Semiconductor device fabrication|IC processes]].<ref>{{Citation |url=https://www.analog.com/media/en/training-seminars/tutorials/MT-014.pdf |archive-url=https://web.archive.org/web/20150503154823/http://www.analog.com/media/en/training-seminars/tutorials/MT-014.pdf |archive-date=2015-05-03 |url-status=live |author=Walt Kester |title=Basic DAC Architectures I: String DACs and Thermometer (Fully Decoded) DACs |publisher=[[Analog Devices]]}}</ref>
* Hybrid DACs, which use a combination of the above techniques in a single converter. Most DAC integrated circuits are of this type due to the difficulty of getting low cost, high speed and high precision in one device.
** The segmented DAC, which combines the thermometer-coded principle for the most significant bits and the binary-weighted principle for the least significant bits. In this way, a compromise is obtained between precision (by the use of the thermometer-coded principle) and number of resistors or current sources (by the use of the binary-weighted principle). The full binary-weighted design means 0% segmentation, the full thermometer-coded design means 100% segmentation.
* Most DACs shown in this list rely on a constant reference voltage or current to create their output value. Alternatively, a ''multiplying DAC''<ref>{{cite web |url=https://www.analog.com/media/en/news-marketing-collateral/solutions-bulletins-brochures/AnalogMultiplyingDACs.pdf |archive-url=https://web.archive.org/web/20110516075112/http://www.analog.com/static/imported-files/overviews/AnalogMultiplyingDACs.pdf |archive-date=2011-05-16 |url-status=live |title=Multiplying DACs: Flexible Building Blocks |year=2010 |publisher=[[Analog Devices]] |access-date=29 March 2012 |df=ymd-all}}</ref> takes a variable input voltage or current as a conversion reference. This puts additional design constraints on the bandwidth of the conversion circuit.
* Modern high-speed DACs have an interleaved architecture, in which multiple DAC cores are used in parallel. Their output signals are combined in the analog domain to enhance the performance of the combined DAC.<ref>{{Cite book|title=Interleaving Concepts for Digital-to-Analog Converters: Algorithms, Models, Simulations and Experiments|last=Schmidt|first=Christian|date=2020|publisher=Springer Fachmedien Wiesbaden|isbn=9783658272630|location=Wiesbaden|language=en|doi=10.1007/978-3-658-27264-7|s2cid=199586286}}</ref> The combination of the signals can be performed either in the time domain or in the frequency domain.

==Performance==
The most important characteristics of a DAC are:{{cn|date=August 2016}}
;Resolution: The number of possible output levels the DAC is designed to reproduce. This is usually stated as the number of [[bit]]s it uses, which is the [[binary logarithm]] of the number of levels. For instance, a 1-bit DAC is designed to reproduce 2 (2<sup>1</sup>) levels while an 8-bit DAC is designed for 256 (2<sup>8</sup>) levels. Resolution is related to the [[effective number of bits]] which is a measurement of the actual resolution attained by the DAC. Resolution determines [[color depth]] in video applications and [[audio bit depth]] in audio applications.
;Maximum [[sampling rate]]: The maximum speed at which the DACs circuitry can operate and still produce correct output. The [[Nyquist–Shannon sampling theorem]] defines a relationship between this and the [[Bandwidth (signal processing)|bandwidth]] of the sampled signal.
;[[Monotonicity]]: The ability of a DAC's analog output to move only in the direction that the digital input moves (i.e., if the input increases, the output doesn't dip before asserting the correct output.) This characteristic is very important for DACs used as a low-frequency signal source or as a digitally programmable trim element.{{cn|reason=Not a common specification IME. Bad behavior in this respect will be amply demonstrated as distortion.|date=August 2019}}
;[[Total harmonic distortion]] and noise (THD+N): A measurement of the distortion and noise introduced to the signal by the DAC. It is expressed as a percentage of the total power of unwanted [[harmonic distortion]] and noise that accompanies the desired signal.
;[[Dynamic range]]: A measurement of the difference between the largest and smallest signals the DAC can reproduce expressed in [[decibel]]s. This is usually related to resolution and [[noise floor]].

Other measurements, such as [[phase distortion]] and [[jitter]], can also be very important for some applications, some of which (e.g. wireless data transmission, composite video) may even ''rely'' on accurate production of phase-adjusted signals.

Non-linear PCM encodings (A-law / μ-law, ADPCM, NICAM) attempt to improve their effective dynamic ranges by using logarithmic step sizes between the output signal strengths represented by each data bit. This trades greater quantization distortion of loud signals for better performance of quiet signals.

==Figures of merit==
* Static performance:
** [[Differential nonlinearity]] (DNL) shows how much two adjacent code analog values deviate from the ideal 1&nbsp;LSB step.<ref name="maxim">{{cite web |url=http://www.maxim-ic.com/appnotes.cfm/appnote_number/641/ |title=ADC and DAC Glossary |publisher=Maxim |df=ymd-all |url-status=live |archive-url=https://web.archive.org/web/20070308223113/http://www.maxim-ic.com/appnotes.cfm/appnote_number/641 |archive-date=2007-03-08}}</ref>
** [[Integral nonlinearity]] (INL) shows how much the DAC transfer characteristic deviates from an ideal one.  That is, the ideal characteristic is usually a straight line; INL shows how much the actual voltage at a given code value differs from that line, in LSBs (1&nbsp;LSB steps).<ref name="maxim"/>
** Gain error<ref name="maxim"/>
** Offset error<ref name="maxim"/>
** Noise is ultimately limited by the [[thermal noise]] generated by passive components such as resistors. For audio applications and in room temperatures, such noise is usually a little less than 1{{nbsp}}[[μV]] (microvolt) of [[white noise]]. This practically limits resolution to less than 20~21 bits, even in 24-bit DACs.
* Frequency domain performance
** [[Spurious-free dynamic range]] (SFDR) indicates in dB the ratio between the powers of the converted main signal and the greatest undesired spur.<ref name="maxim"/>
** Signal-to-noise and distortion ([[SINAD]]) indicates in dB the ratio between the powers of the converted main signal and the sum of the noise and the generated harmonic spurs<ref name="maxim"/>
** i-th harmonic distortion (HDi) indicates the power of the i-th harmonic of the converted main signal
** [[Total harmonic distortion]] (THD) is the sum of the powers of all the harmonics of the input signal<ref name="maxim"/>
** If the maximum DNL is less than 1 LSB, then the {{nowrap|D/A}} converter is guaranteed to be monotonic. However, many monotonic converters may have a maximum DNL greater than 1 LSB.<ref name="maxim"/>
* Time domain performance:
** Glitch impulse area (glitch energy)<ref name="maxim"/><!--[[User:Kvng/RTH]]-->

==See also==
*{{anl|I²S}}

==References==
{{Reflist}}

== Further reading ==
* {{Citation
 | title = The Data Conversion Handbook
 | last = Kester
 | first = Walt
 | isbn = 0-7506-7841-0
 | url = https://www.analog.com/en/resources/technical-books/data-conversion-handbook.html
| year = 2005
 | publisher = Newnes
 }}
* S. Norsworthy, Richard Schreier, Gabor C. Temes, ''Delta-Sigma Data Converters''. {{ISBN|0-7803-1045-4}}.
* Mingliang Liu, ''Demystifying Switched-Capacitor Circuits''. {{ISBN|0-7506-7907-7}}.
*[[Behzad Razavi]], ''Principles of Data Conversion System Design''. {{ISBN|0-7803-1093-4}}.
* Phillip E. Allen, Douglas R. Holberg, ''CMOS Analog Circuit Design''. {{ISBN|0-19-511644-5}}.
* Robert F. Coughlin, Frederick F. Driscoll, ''Operational Amplifiers and Linear Integrated Circuits''. {{ISBN|0-13-014991-8}}.
* A Anand Kumar, ''Fundamentals of Digital Circuits''.  {{ISBN|81-203-1745-9}}, {{ISBN|978-81-203-1745-1}}.
* Ndjountche Tertulien, "CMOS Analog Integrated Circuits: High-Speed and Power-Efficient Design". {{ISBN|978-1-4398-5491-4}}.

== External links ==
* {{cite web |url=http://www.maxim-ic.com/appnotes.cfm/an_pk/641/CMP/WP-36 |title=ADC and DAC Glossary |archive-url=https://web.archive.org/web/20091213023149/http://www.maxim-ic.com/appnotes.cfm/an_pk/641/CMP/WP-36 |archive-date=2009-12-13 |url-status=dead}}
*[http://www.analog.com/library/analogDialogue/archives/44-09/mdac.html High-Resolution Multiplying DACs Handle AC Signals]
*[http://hyperphysics.phy-astr.gsu.edu/hbase/electronic/dac.html R-2R Ladder DAC explained] with circuit diagrams.
*[http://www.ieee.li/pdf/essay/dynamic_evaluation_dac.pdf Dynamic Evaluation of High-Speed, High Resolution D/A Converters] Outlines HD, IMD and NPR measurements, also includes a derivation of quantization noise

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[[Category:Digital signal processing]]
[[Category:Electronic circuits]]
[[Category:Analog computers]]