ltc2440cgn-trpbf Linear Technology Corporation, ltc2440cgn-trpbf Datasheet - Page 23

ltc2440cgn-trpbf

Manufacturer Part Number

ltc2440cgn-trpbf

Description

24-bit High Speed Differential Delta Sigma Adc With Selectable Speed/resolution

Manufacturer

Linear Technology Corporation

Datasheet

1.LTC2440CGN-TRPBF.pdf (28 pages)

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APPLICATIONS INFORMATION

Direct Connection to Low Impedance Sources

If the ADC can be located physically close to the sensor,

it can be directly connected to sensors or other sources

with impedances up to 350Ω with no other components

required (see Figure 17).

Figure 17. Direct Connection to Low Impedance (<350Ω) Source

is Possible if the Sensor is Located Close to the ADC.

Longer Connections to Low Impedance Sources

If longer lead lengths are unavoidable, adding an input

capacitor close to the ADC input pins will average the

charging pulses and prevent reﬂ ections or ringing (see

Figure 18). Averaging the current pulses results in a DC

input current that should be taken into account. The re-

sulting 110kΩ input impedance will result in a gain error

of 0.44% for a 350Ω bridge (within the full scale specs

of many bridges) and a very low 12.6ppm error for a 2Ω

thermocouple connection.

REMOTE

THERMOCOUPLE

Figure 18. Input Capacitors Allow Longer Connection

Between the Low Impedance Source and the ADC.

1μF

4.5V to 5.5V

–

4.5V to 5.5V

LTC2440

REF

GND

REF

–

2440 F17

2440 F18

1μF

Buffering the LTC2440

Many applications will require buffering, particularly

where high impedance sources are involved or where the

device being measured is located some distance from the

LTC2440. When buffering the LTC2440 a few simple steps

should be followed.

Figure 19 shows a network suitable for coupling the inputs

of a LTC2440 to a LTC2051 chopper-stabilized op amp. The

3μV offset and low noise of the LTC2051 make it a good

choice for buffering the LTC2440. Many other op amps

will work, with varying performance characteristics.

The LTC2051 is conﬁ gured to be able to drive the 1μF ca-

pacitors at the inputs of the LTC2440. The 1μF capacitors

should be located close to the ADC input pins.

The measured total unadjusted error of Figure 19 is well

within the speciﬁ cations of the LTC2440 by itself. Most

autozero ampliﬁ ers will degrade the overall resolution to

some degree because of the extremely low input noise

of the LTC2440, however the LTC2051 is a good general

purpose buffer. The measured input referred noise of two

LTC2051s buffering both LTC2440 inputs is approximately

double that of the LTC2440 by itself, which reduces the ef-

fective resolution by 1-bit for all oversample ratios. Adding

gain to the LTC2051 will increase gain and offset errors

and will not appreciably increase the overall resolution,

so it has limited beneﬁ t.

Procedure For Coupling Any Ampliﬁ er to the LTC2440

The LTC2051 is suitable for a wide range of DC and low

frequency measurement applications. If another ampli-

ﬁ er is to be selected, a general procedure for evaluating

the suitability of an ampliﬁ er for use with the LTC2440 is

suggested here:

1. Perform a thorough error and noise analysis on the

ampliﬁ er and gain setting components to verify that the

ampliﬁ er will perform as intended.

2. Measure the large signal response of the overall circuit.

The capacitive load may affect the maximum slew rate of

the ampliﬁ er. Verify that the slew rate is adequate for the

LTC2440

2440fc

ltc2440cgn-trpbf Linear Technology Corporation, ltc2440cgn-trpbf Datasheet - Page 23

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