MAX1198 Datasheet, PDF(17/22 Page) Maxim Integrated Products – Dual, 8-Bit, 100Msps, 3.3V, Low-Power ADC with Internal Reference and Parallel Outputs

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MAX1198 Datasheet, PDF (17/22 Pages) Maxim Integrated Products – Dual, 8-Bit, 100Msps, 3.3V, Low-Power ADC with Internal Reference and Parallel Outputs

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Dual, 8-Bit, 100Msps, 3.3V, Low-Power ADC

with Internal Reference and Parallel Outputs

3.3V

MAX6062

0.1ÂµF

3.3V

0.1ÂµF

2 16.2kâ¦

1ÂµF

10Hz LOWPASS

FILTER

MAX4250

162â¦

100ÂµF

10Hz LOWPASS

FILTER

N.C.

2.048V

0.1ÂµF

29 REFOUT

31 REFIN

32 REFP

1 REFN

N=1

2 COM MAX1198

0.1ÂµF 0.1ÂµF 0.1ÂµF

NOTE: ONE FRONT-END REFERENCE CIRCUIT DESIGN MAY BE USED WITH UP TO 1000 ADCs.

0.1ÂµF

2.2ÂµF

10V

0.1ÂµF

N.C.

29 REFOUT

REFIN

REFP

N = 1000

1 REFN

2 COM

MAX1198

0.1ÂµF 0.1ÂµF 0.1ÂµF

Figure 8. External Buffered (MAX4250) Reference Drive Using a MAX6062 Bandgap Reference

Unbuffered External Reference Drives

Multiple ADCs

Connecting each REFIN to analog ground disables the

internal reference of each device, allowing the internal

reference ladders to be driven directly by a set of

external reference sources. Followed by a 10Hz low-

pass filter and precision voltage-divider, the MAX6066

generates a DC level of 2.500V. The buffered outputs

of this divider are set to 2.0V, 1.5V, and 1.0V, with an

accuracy that depends on the tolerance of the divider

resistors.

These three voltages are buffered by the MAX4252,

which provides low noise and low DC offset. The indi-

vidual voltage followers are connected to 10Hz low-

pass filters, which filter both the reference voltage and

amplifier noise to a level of 3nV/âHz. The 2.0V and 1.0V

reference voltages set the differential full-scale range

of the associated ADCs at 2VP-P. The 2.0V and 1.0V

buffers drive the ADCâs internal ladder resistances

between them.

Note that the common power supply for all active com-

ponents removes any concern regarding power-supply

sequencing when powering up or down. With the out-

puts of the MAX4252 matching better than 0.1%, the

buffers and subsequent lowpass filters can be replicat-

ed to support as many as 32 ADCs. For applications

that require more than 32 matched ADCs, a voltage

reference and divider string common to all converters

is highly recommended.

Typical QAM Demodulation Application

A frequently used modulation technique in digital com-

munications applications is quadrature amplitude

modulation (QAM). Typically found in spread-spec-

trum-based systems, a QAM signal represents a carrier

frequency modulated in both amplitude and phase. At

the transmitter, modulating the baseband signal with

quadrature outputs, a local oscillator followed by sub-

sequent upconversion can generate the QAM signal.

The result is an in-phase (I) and a quadrature (Q) carri-

er component, where the Q component is 90Â° phase

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