DG406_11 Datasheet, PDF(10/16 Page) Vishay Siliconix – 16-Ch/Dual 8-Ch High-Performance CMOS Analog Multiplexers

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DG406_11 Datasheet, PDF (10/16 Pages) Vishay Siliconix – 16-Ch/Dual 8-Ch High-Performance CMOS Analog Multiplexers

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DG406, DG407

Vishay Siliconix

APPLICATIONS HINTS

Sampling speed is limited by two consecutive events: the

transition time of the multiplexer, and the settling time of the

sampled signal at the output.

tTRANS is given on the data sheet. Settling time at the load

depends on several parameters: RDS(on) of the multiplexer,

source impedance, multiplexer and load capacitances,

charge injection of the multiplexer and accuracy desired.

The settling time for the multiplexer alone can be derived

from the model shown in figure 5. Assuming a low

impedance signal source like that presented by an op amp or

a buffer amplifier, the settling time of the RC network for a

given accuracy is equal to nï´:

% ACCURACY

# BITS

0.25

0.012

0.0017

RDS(on)

RS = 0

VOUT

CD(on)

Figure 5. Simplified Model of One Multiplexer Channel

The maximum sampling frequency of the multiplexer is:

N(tSETTLING

tTRANS)

(1)

where N = number of channels to scan

tSETTLING = nï´ = n x RDS(on) x CD(on)

For the DG406 then, at room temp and for 12-bit accuracy,

using the maximum limits:

100

Î©

10-12F)

300

10-12s

(2)

fs = 694 kHz

(3)

From the sampling theorem, to properly recover the original

signal, the sampling frequency should be more than twice

the maximum component frequency of the original signal.

This assumes perfect bandlimiting. In a real application

sampling at three to four times the filter cutoff frequency is a

good practice.

Therefore from equation 2 above:

x fs = 173 kHz

(4)

From this we can see that the DG406 can be used to sample

16 different signals whose maximum component frequency

can be as high as 173 kHz. If for example, two channels are

used to double sample the same incoming signal then its

cutoff frequency can be doubled.

The block diagram shown in Figure 6 illustrates a typical data

acquisition front end suitable for low-level analog signals.

Differential multiplexing of small signals is preferred since

this method helps to reject any common mode noise. This is

especially important when the sensors are located at a

distance and it may eliminate the need for individual

amplifiers. A low RDS(on), low leakage multiplexer like the

DG407 helps to reduce measurement errors. The low power

dissipation of the DG407 minimizes on-chip thermal

gradients which can cause errors due to temperature

mismatch along the parasitic thermocouple paths. Please

refer to Application Note AN203 for additional information.

Sensor 1

Sensor 8

Analog

Multiplexer

DG407

Inst

Amp

S/H

12-Bit

A/D

Converter

Controller

Figure 6. Measuring low-level analog signals is more accurate when using a differential multiplexing technique

Vishay Siliconix maintains worldwide manufacturing capability. Products may be manufactured at one of several qualified locations. Reliability data for Silicon

Technology and Package Reliability represent a composite of all qualified locations. For related documents such as package/tape drawings, part marking, and

reliability data, see www.vishay.com/ppg?70061.

www.vishay.com

Document Number: 70061

S11-0179-Rev. J, 07-Feb-11

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