MAX1200 Datasheet, PDF(9/16 Page) Maxim Integrated Products – +5v sINGLE-sUPPLY, 1mSPS, 16-bIT sELF-cALIBRATING adc

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MAX1200 Datasheet, PDF (9/16 Pages) Maxim Integrated Products – +5v sINGLE-sUPPLY, 1mSPS, 16-bIT sELF-cALIBRATING adc

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+5V Single-Supply, 1Msps, 16-Bit

Self-Calibrating ADC

RFPS

RFPF

INP

RFNF

INN

RFNF

RFPF

RFNS

Figure 2. Simplified MDAC Architecture

Choice of Reference

It is important to choose a low-noise reference such as

the MAX6341, which can provide both excellent load

regulation and low temperature drift. The equivalent

input circuit for the reference pins is shown in Figure 3.

Note that the reference pins drive approximately 1kâ¦ of

resistance on-chip. They also drive a switched capaci-

tor of 21pF. To meet the dynamic performance, the ref-

erence voltage is required to settle to 0.0015% within

one clock cycle. Carefully choose an appropriate driv-

ing circuit (Figure 4). The capacitors at the reference

pins (RFPF, RFNF) provide the dynamic charge

required during each clock cycle, while the op amps

ensure accuracy of the reference signals. These

capacitors must have low dielectric-absorption charac-

teristics, such as polystyrene or teflon capacitors.

The reference pins can be connected to either single-

ended or differential voltages within the specified maxi-

mum levels. Typically the positive reference pin (RFPF)

would be driven to +4.096V, and the negative refer-

ence pin (RFNF) connected to analog ground for best

SNR performance. If THD performance is more impor-

tant to the application than signal-to-noise ratio, choose

a lower level, differential voltage such as VRFPS =

+3.5V and VRFNS = +1.5V.

There are sense pins, RFPS and RFNS, which can be

used with external amplifiers to compensate for any

resistive drop on these lines, internal or external to the

chip. Ensure a correct reference voltage by using prop-

er Kelvin connections at the sense pins.

Common-Mode Voltage

The switched-capacitor input circuit at the analog input

allows signals between AGND and the analog power

supply. Since the common-mode voltage has a strong

Figure 3. Equivalent Input at the Reference Pins. The sense

pins should not draw any DC current.

VRFP = +4.096V

MAX410

VRFN = 0

MAX410

CHIP BOUNDARY

RFPF

RFPS

RFNF

RFNS

MAX410

Figure 4. Drive Circuit for Reference Pins and Common-Mode

influence on the performance of the ADC, the best

results are obtained by choosing VCM = (VRFPS +

VRFNS) / 2. This can be achieved by using a resistive

divider between the two reference potentials. Figure 4

shows a typical driving circuit for good dynamic perfor-

mance.

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