Logarithmic resistor ladder

A logarithmic resistor ladder is an electronic circuit composed of a series of resistors and switches, designed to create an attenuation from an input to an output signal, where the logarithm of the attenuation ratio is proportional to a digital code word that represents the state of the switches.

The logarithmic behavior of the circuit is its main differentiator in comparison with digital-to-analog converters in general, and traditional R-2R Ladder networks specifically. Logarithmic attenuation is desired in situations where a large dynamic range needs to be handled. The circuit described in this article is applied in audio devices, since human perception of sound level is properly expressed on a logarithmic scale.

Logarithmic input/output behavior

As in digital-to-analog converters, a binary word is applied to the ladder network, whose N bits are treated as representing an integer value according to the relation:

\mathrm {CodeValue} =\sum _{i=1}^{N}s_{i}\cdot 2^{i-1}

where

s_{i}

represents a value 0 or 1 depending on the state of the i^th switch.

For a conventional DAC or R-2R network, the output signal value (its voltage) would be:

V_{out}=a\cdot (\mathrm {CodeValue} +b)\cdot V_{in}

where

a

and

b

are design constants and where

V_{in}

typically is a constant reference voltage.

(DA-converters that are designed to handle a variable input voltage are termed multiplying DAC.^[1])

In contrast, the logarithmic ladder network discussed in this article creates a behavior as:

\log(V_{out}/V_{in})=a\cdot (\mathrm {CodeValue} +b)

where

V_{in}

is a variable input signal.

Circuit implementation

Schematic diagram

This example circuit is composed of 4 stages, numbered 1 to 4, and an additional leading Rsource and trailing Rload. Each stage i, has a designed input-to-output voltage attenuation ratio_i as:

Ratio_{i}={\text{if}}\;sw_{i}\;{\text{then}}\;\alpha ^{2^{i-1}}\;{\text{else}}\;1

For logarithmic scaled attenuators, it is common practice to express their attenuation in decibels:

dB(Ratio_{i})=20\log _{10}\alpha ^{2^{i-1}}=2^{i-1}\cdot 20\cdot \log _{10}\alpha

for

i=1..N

and

sw_{i}=1

This reveals a basic property: $dB(Ratio_{i+1})=2\cdot dB(Ratio_{i})$

To show that this $Ratio_{i}$ satisfies the overall intention:

\log(V_{out}/V_{in})=\log(\prod _{i=1}^{N}Ratio_{i})=\sum _{i=1}^{N}\log(Ratio_{i})=a\cdot (CodeValue+b)

for

b=0

and

a=\log(\alpha )

The different stages 1 .. N should function independently of each other, as to obtain 2^N different states with a composable behavior. To achieve an attenuation of each stage that is independent of its surrounding stages, either one of two design choices is to be implemented: constant input resistance or constant output resistance.

Constant input resistance

The input resistance of any stage shall be independent of its on/off switch position, and must be equal to R_load.

This leads to:

{\begin{cases}R_{i,parr}=(R_{i,b}\cdot R_{load})/(R_{i,b}+R_{load})\\R_{i,a}+R_{i,parr}=R_{load}\\R_{i,parr}/(R_{i,a}+R_{i,parr})=Ratio_{i}\end{cases}}

With these equations, all resistor values of the circuit diagram follow easily after choosing values for N, $\alpha$ and R_load. (The value of R_source does not influence the logarithmic behavior)

Constant output resistance

The output resistance of any stage shall be independent of its on/off switch position, and must be equal to R_source.

This leads to:

{\begin{cases}R_{i,ser}=R_{i,a}+R_{source}\\R_{i,ser}\cdot R_{i,b}/(R_{i,ser}+R_{i,b})=R_{source}\\R_{i,b}/(R_{i,ser}+R_{i,b})=Ratio_{i}\end{cases}}

Again, all resistor values of the circuit diagram follow easily after choosing values for N, $\alpha$ and R_source. (The value of R_load does not influence the logarithmic behavior)

Circuit variations

The circuit as depicted above, can also be applied in reverse direction. That correspondingly reverses the role of constant-input and constant-output resistance equations.
Since the stages do not influence each other's attenuation, the stage order can be chosen arbitrarily. Such reordering can have a significant effect on the input resistance of the constant output resistance attenuator and vice versa.

Background

R-2R ladder networks used for Digital-to-Analog conversion are rather old. A historic description is in a patent^[2] filed in 1955.

Multiplying DA-converters with logarithmic behavior were not known for a long time after that. An initial approach was to map the logarithmic code to a much longer code word, which could be applied to the classical (linear) R-2R based DA-converter. Lengthening the codeword is needed in that approach to achieve sufficient dynamic range. This approach was implemented in a device from Analog Devices inc.,^[3] protected through a 1981 patent filing.^[4]

References

↑ "Multiplying DACs, flexible building blocks" (PDF). Analog Devices inc. 2010. Retrieved 29 March 2012.
↑ US patent 3108266, Gordon, B. M., "Signal Conversion Apparatus", issued 22 October 1963
↑ "LOGDAC CMOS Logarithmic D/A Converter AD7118" (PDF). Analog Devices Inc. Archived from the original (PDF) on 25 August 2015. Retrieved 25 August 2015.
↑ US patent 4521764, Burton, David P., "Signal-controllable attenuator employing a digital-to-analog converter", issued 4 June 1985

External links

Online calculator to configure logarithmic ladder networks

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Logarithmic resistor ladder

Logarithmic input/output behavior

Circuit implementation

Constant input resistance

Constant output resistance

Circuit variations

Background

See also

References

External links