LTC2424IG Linear Technology, LTC2424IG Datasheet - Page 33

LTC2424IG

Manufacturer Part Number

LTC2424IG

Description

IC ADC 20BIT 4CH MICROPWR 28SSOP

Manufacturer

Linear Technology

Datasheet

1.LTC2424CGPBF.pdf (36 pages)

Specifications of LTC2424IG

Number Of Bits

Sampling Rate (per Second)

7.5

Data Interface

MICROWIRE™, Serial, SPI™

Number Of Converters

Power Dissipation (max)

1mW

Voltage Supply Source

Single Supply

Operating Temperature

-40°C ~ 85°C

Mounting Type

Surface Mount

Package / Case

28-SSOP (0.200", 5.30mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

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Current page: 33 of 36
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APPLICATIONS

An 8-Channel DC-to-Daylight Digitizer

The circuit in Figure 36 shows an example of the LTC2428’s

flexibility in digitizing a number of real-world physical

phenomena—from DC voltages to ultraviolet light. All of

the examples implement single-ended signal condition-

ing. Although differential signal conditioning is a pre-

ferred approach in applications where the sensor is a

bridge-type, is located some distance from the ADC or

operates in a high ambient noise environment, the

LTC2428’s low power dissipation allows circuit operation

in close proximity to the sensor. As a result, conditioning

the sensor output can be greatly simplified through the

use of single-ended arrangements. In those applications

where differential signal conditioning is required, chopper

amplifier-based or self-contained instrumentation ampli-

fiers (also available from LTC) can be used with the

LTC2428.

With the resistor network connected to CH0, the LTC2428

is able to measure DC voltages from 1mV to 1kV in a single

range without the need for autoranging. The 990k resistor

should be a 1W resistor rated for high voltage operation.

Alternatively, the 990k resistor can be replaced with a

series connection of several lower cost, lower power metal

film resistors.

The circuit connected to CH1 shows an LT1793 FET input

operational amplifier used as an electrometer for high

impedance, low frequency applications such as measur-

ing pH. The circuit has been configured for a gain of 21;

thus, the input signal range is –15mV V

amplifier circuit is necessary in these applications be-

cause high output impedance sensors cannot drive

switched-capacitor ADCs directly. The LT1793 was cho-

sen for its low input bias current (10pA, max) and low

noise (8nV/ Hz) performance. As shown, the use of a

driven guard (and Teflon

high impedance sensor applications; otherwise, PC board

surface leakage current effects can degrade results.

The circuit connected to CH2 illustrates a precision half-

wave rectifier that uses the LTC2428’s internal

an integrator. This circuit can be used to measure 60Hz,

INFORMATION

standoffs) is recommended in

250mV. An

ADC as

120Hz or from 400Hz to 1kHz with good results. The

LTC2428’s internal sinc

frequency in this range. Above 1kHz, limited amplifier

gain-bandwidth product and transient overshoot behavior

can combine to degrade performance. The circuit’s dy-

namic range is limited by operational amplifier input offset

voltage and the system’s overall noise floor. Using an

LTC1050 chopper-stabilized operational amplifier with a

approximately 5 orders of magnitude. The circuit configu-

ration is best implemented with a precision, 3-terminal,

2-resistor 10k

network) for R6 and R7 to maintain gain and temperature

stability. Alternatively, discrete resistors with 0.1% initial

tolerance and 5ppm/ C temperature coefficient would

also be adequate for most applications.

Two channels (CH3 and CH4) of the LTC2428 are used to

accommodate a 3-wire 100 , Pt RTD in a unique circuit

that allows true RMS/RF signal power measurement from

audio to gigahertz (GHz) frequencies. The unique feature

of this circuit is that the signal power dissipated in the 50

termination in the form of heat is measured by the 100

RTD. Two readings are required to compensate for the

RTD’s lead-wire resistance. The reading on CH4 is multi-

plied by 2 and subtracted from the reading on CH3 to

determine the exact value of the RTD.

While the LTC2428 is capable of measuring signals over a

range of five decades, the implementation (mechanical,

electrical and thermal) of this technique ultimately deter-

mines the performance of the circuit. The thermal resis-

tance of the assembly (the 50 /RTD mass to its enclosure)

will determine the sensitivity of the circuit. The dynamic

range of the circuit will be determined by the maximum

temperature the assembly is rated to withstand, approxi-

mately 850 C. Details of the implementation are quite

involved and are beyond the scope of this document.

Please contact LTC directly for a more comprehensive

treatment of this implementation.

In the circuit connected to the LTC2428’s CH5 input, a

thermistor is configured in a half-bridge arrangement that

Teflon is a trademark of Dupont Company.

of 5 V, the dynamic range of this application covers

network (for example, an IRC PFC-D

LTC2424/LTC2428

filter effectively eliminates any

LTC2424IG Linear Technology, LTC2424IG Datasheet - Page 33

LTC2424IG

Specifications of LTC2424IG

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