MAX1492CAI+T Maxim Integrated Products, MAX1492CAI+T Datasheet - Page 28

MAX1492CAI+T

Manufacturer Part Number

MAX1492CAI+T

Description

IC ADC W/LCD DRIVER 28-SSOP

Manufacturer

Maxim Integrated Products

Datasheet

1.MAX1494CCJ.pdf (34 pages)

Specifications of MAX1492CAI+T

Display Type

LCD

Configuration

7 Segment + 2 Annunciators

Interface

Serial

Digits Or Characters

A/D 3.5 Digits

Current - Supply

960µA

Voltage - Supply

2.7 V ~ 5.25 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

28-SSOP

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

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3.5- and 4.5-Digit, Single-Chip ADCs

with LCD Drivers

At power-up, the serial interface, LCD driver, digital fil-

ter, and modulator circuits reset. The registers return to

their default values. Allow time for the reference to set-

tle before starting calibration.

The MAX1492/MAX1494 offer on-chip offset calibration.

The device offset-calibrates during every conversion

when the OFFSET_CAL1 bit is 0. Enhanced offset calibra-

tion is only needed in the MAX1494 when RANGE = 1.

It is performed on demand by setting the OFFSET_CAL2

bit to 1.

The MAX1492/MAX1494 feature independent power-

down control of the analog and digital circuitry. Writing a

1 to the PD_DIG and PD_ANA bits in the control register

powers down the analog and digital circuitry, reducing

the supply current to 400µA. PD_DIG powers down the

digital filter and LCD drivers, while PD_ANA powers

down the analog modulator and ADC input buffers.

Adequate display contrast can be obtained in most

applications by connecting V

tions where a wide temperature range is expected, the

voltage levels for some triplexed LCDs may need to vary

with temperature to maintain good display contrast and

viewing angle. The amount of temperature compensation

depends upon the type of liquid crystal used. Display

manufacturers usually specify the temperature variation

of the LCD thresholds voltage (RMS

is approximately 1/3 of the peak display voltage. The

peak display voltage is equal to V

(MAX1494 only). Therefore, a typical -4mV/°C tempera-

ture coefficient of an LCD threshold corresponds to a

+12mV/°C temperature coefficient at V

The MAX1492/MAX1494 feature peak-detection circuit-

ry. When activated (PEAK bit = 1), the devices display

only the highest voltage measured to the LCD.

The MAX1492/MAX1494 feature data-hold circuitry.

When activated (HOLD bit = 1), the devices display the

current reading on the LCD.

The MAX1492/MAX1494 feature a low-battery detection

input. When the voltage at LOW BATT drops below

2.048V (typ), the LOW_BATT bit of the status register

goes high and the LOW BATT segment of the LCD turns

on.

DISP

______________________________________________________________________________________

LCD Compensation (MAX1494 Only)

DISP

Power-Down Modes

Offset Calibration

Power-On Reset

to GND. In applica-

DISP

- RMS

Low Battery

DVDD

OFF

- V

), which

Peak

Hold

DISP

Connect the differential inputs of the MAX1492/

MAX1494 to the bridge network of the strain gauge. In

Figure 20, the analog supply voltage powers the bridge

network and the MAX1492/MAX1494 along with the ref-

erence voltage. The MAX1492/MAX1494 handle an

analog input-voltage range of ±200mV and ±2V full

scale. The analog/reference inputs of the parts allow

the analog input range to have an absolute value of

anywhere between -2.2V and +2.2V.

Figure 21 shows a connection from a thermocouple to

the MAX1492/MAX1494. In this application, the

MAX1492/MAX1494 take advantage of the on-chip input

buffers that allow large source impedances on the front

end. The decoupling capacitors reduce noise pickup

from the thermocouple leads. To place the differential

voltage from the thermocouple at a suitable common-

mode voltage, the AIN- input of the MAX1492/MAX1494

is biased to GND. Use an external temperature sensor,

such as the DS75, and a µC to perform cold junction-

temperature compensation.

Low-power, single-supply operations make the

MAX1492/MAX1494 ideal for loop-powered 4–20mA

transmitters. Loop-powered transmitters draw their

power from the 4–20mA loop, limiting the transmitter

circuitry to a current budget of 4mA. Tolerances in the

loop further limit this current budget to 3.5mA. Since

the MAX1492/MAX1494 only consume 950µA, a total of

2.55mA remains to power the remaining transmitter cir-

cuitry. Figure 22 shows a block diagram for a loop-

powered 4–20mA transmitter.

To measure 4–20mA signals, connect a shunt resistor

across AIN+ and AIN- to create the ±2V or ±200mV

input voltage (Figure 23).

Figures 24–27 show the transfer functions of the

MAX1492/MAX1494. The output data is stored in the

ADC data register in two’s complement.

A -1 in the ADC result register displays -0 on the LCD as

shown in Figures 24–27. Negative values on the LCD

are offset by 1. For example, -100 in the ADC result reg-

ister appears as -99 on the LCD.

When using analog and digital supplies from the same

source, isolate the digital supply from the analog sup-

ply with a low-value resistor (10Ω) or ferrite bead. For

Supplies, Layout, and Bypassing

Thermocouple Measurement

Strain Gauge Measurement

4–20mA Measurement

4–20mA Transmitter

Transfer Functions

MAX1492CAI+T Maxim Integrated Products, MAX1492CAI+T Datasheet - Page 28

MAX1492CAI+T

Specifications of MAX1492CAI+T

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