Katana VentraIP

Digital-to-analog converter

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

This article is about conversion of digital signals to analog signals. For digital television converter boxes, see digital television adapter.

There are several DAC architectures; the suitability of a DAC for a particular application is determined by figures of merit including: 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.


DACs are commonly used in music players to convert digital data streams into analog audio signals. They are also used in televisions and mobile phones to convert digital video data into 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.


Due to the complexity and the need for precisely matched 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 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 oscilloscopes, may also use discrete DACs.

The where a stable 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 electric motor speed control and dimming LED lamps.

pulse-width modulator

Oversampling DACs or interpolating DACs such as those employing , use a pulse density conversion technique with oversampling. Audio delta-sigma DACs are sold with 384 kHz sampling rate and quoted 24-bit resolution, though quality is lower due to inherent noise (see § Figures of merit). Some consumer electronics use a type of oversampling DAC referred to as a 1-bit DAC.

delta-sigma modulation

[3]

The successive approximation or cyclic DAC, 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.

[4]

The 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 IC processes.[5]

thermometer-coded

Most DACs shown in this list rely on a constant reference voltage or current to create their output value. Alternatively, a multiplying DAC takes a variable input voltage or current as a conversion reference. This puts additional design constraints on the bandwidth of the conversion circuit.

[6]

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. The combination of the signals can be performed either in the time domain or in the frequency domain.

[7]

The most common types of electronic DACs are:[2]

Differential nonlinearity

Spurious-free dynamic range

[8]

 – Serial interface for digital audio

I²S

Kester, Walt (2005), , ISBN 0-7506-7841-0

The Data Conversion Handbook

S. Norsworthy, Richard Schreier, Gabor C. Temes, Delta-Sigma Data Converters.  0-7803-1045-4.

ISBN

Mingliang Liu, Demystifying Switched-Capacitor Circuits.  0-7506-7907-7.

ISBN

Principles of Data Conversion System Design. ISBN 0-7803-1093-4.

Behzad Razavi

Phillip E. Allen, Douglas R. Holberg, CMOS Analog Circuit Design.  0-19-511644-5.

ISBN

Robert F. Coughlin, Frederick F. Driscoll, Operational Amplifiers and Linear Integrated Circuits.  0-13-014991-8.

ISBN

A Anand Kumar, Fundamentals of Digital Circuits.  81-203-1745-9, ISBN 978-81-203-1745-1.

ISBN

Ndjountche Tertulien, "CMOS Analog Integrated Circuits: High-Speed and Power-Efficient Design".  978-1-4398-5491-4.

ISBN

. Archived from the original on 2009-12-13.

"ADC and DAC Glossary"

High-Resolution Multiplying DACs Handle AC Signals

with circuit diagrams.

R-2R Ladder DAC explained

Outlines HD, IMD and NPR measurements, also includes a derivation of quantization noise

Dynamic Evaluation of High-Speed, High Resolution D/A Converters