MAX195BEWE+ Datasheet MAX195BCWE+, MAX195BCPE+, MAX195BEWE+T | P10-P12

MAX195

Data is clocked out on SCLK’s falling edge. Clock

data in on SCLK’s rising edge or, for clock speeds

above 2.5MHz, on the following falling edge to meet

the maximum SCLK-to-DOUT timing specification

(Figure 7). The maximum SCLK speed is 5MHz. See

the

Operating Modes and SPI/QSPI Interfaces

section

for additional information. When the conversion clock

is near its maximum (1.7MHz), reading the data after

each conversion (during the acquisition time) results

in lower throughput (about 70ksps max) than reading

the data during conversions, because it takes longer

than the minimum input acquisition time (four cycles

at 1.7MHz) to clock 16 data bits at 5Mbps. After the

data has been clocked in, leave some time (about

1µs) for any coupled noise on AIN to settle before

beginning the next conversion.

Whichever method is chosen for reading the data, con-

versions can be individually initiated by bringing CONV

low, or they can occur continuously by connecting EOC

to CONV. Figure 8 shows the MAX195 in its simplest

operational configuration.

16-Bit, 85ksps ADC with 10µA Shutdown

10 ______________________________________________________________________________________

EOC

SCLK

(CASE 1)

SCLK

(CASE 2)

CASE 1: SCLK IDLES LOW, DATA LATCHED ON RISING EDGE (CPOL = 0, CPHA = 0)

CASE 2: SCLK IDLES LOW, DATA LATCHED ON FALLING EDGE (CPOL = 0, CPHA = 1)

CASE 3: SCLK IDLES HIGH, DATA LATCHED ON FALLING EDGE (CPOL = 1, CPHA = 0)

NOTE: ARROWS ON SCLK TRANSITIONS INDICATE LATCHING EDGE

DOUT

SCLK

(CASE 3)

CONV

MSB LSB

B15

B14 B13 B12 B3 B2 B1

B11

CSS

CSH

MAX195

10µF

BP/UP/

SHDN

CLK

SCLK

VDDD

DOUT

DGND

REFERENCE

(0V TO VDDA)

ANALOG

INPUT

-5V

EOC

VDDA

VSSA

AGND

AIN

CONVERSION

CLOCK

+5V

REF

VSSD

RESET

CONV

0.1µF

10µF

0.1µF

Figure 7. Output Data Format, Reading Data Between Conversions (Mode 2)

Figure 8. MAX195 in the Simplest Operating Configuration

MAX195

16-Bit, 85ksps ADC with 10µA Shutdown

______________________________________________________________________________________ 11

BRIDGE

INSTRUMENTATION

AMPLIFIER

+5V

AIN

MAX195

VDDA

AGND

47µF

LOW ESR

0.1µF

CERAMIC

REF

COMPANY CAPACITOR FACTORY FAX [COUNTRY CODE] USA TELEPHONE

Sprague

595D series,

592D series

1-603-224-1430 603-224-1961

AVX TPS series 1-207-283-1941 800-282-4975

Sanyo

OS-CON series,

MVGX series

81-7-2070-1174 619-661-6835

Nichicon PL series 1-708-843-2798 708-843-7500

Figure 9. Ratiometric Measurement Without an Accurate Reference

Table 1. Low-ESR Capacitor Suppliers

__________Applications Information

Reference

The MAX195 reference voltage range is 0V to VDDA.

When choosing the reference voltage, the MAX195’s

equivalent input noise (40µV

RMS

in unipolar mode,

80µV

RMS

in bipolar mode) should be considered. Also, if

REF

exceeds VDDA, errors will occur due to the internal

protection diodes that will begin to conduct, so use cau-

tion when using a reference near VDDA (unless V

REF

and VDDA are virtually identical). V

REF

must never

exceed its absolute maximum rating (VDDA + 0.3V).

The MAX195 needs a good reference to achieve its

rated performance. The most important requirement is

that the reference must present a low impedance to the

REF input. This is often achieved by buffering the refer-

ence through an op amp and bypassing the REF input

with a large (1µF to 47µF), low-ESR capacitor in parallel

with a 0.1µF ceramic capacitor. Low-ESR capacitors

are available from the manufacturers listed in Table 1.

The reference must drive the main conversion DAC

capacitors as well as the capacitors in the calibration

DACs, all of which may be switching between GND and

REF at the conversion clock frequency. The total

capacitive load presented can exceed 1000pF and,

unlike the analog input (AIN), REF is sampled continu-

ously throughout the conversion.

The first step in choosing a reference circuit is to

decide what kind of performance is required. This often

suggests compromises made in the interests of cost

and size. It is possible that a system may not require an

accurate reference at all. If a system makes a ratiomet-

ric measurement such as Figure 9’s bridge circuit, any

relatively noise-free voltage that presents a low imped-

ance at the REF input will serve as a reference. The

+5V analog supply suffices if you use a large, low-

impedance bypass capacitor to keep REF stable dur-

ing switching of the capacitor arrays. Do not place a

resistance between the +5V supply and the bypass

capacitor, because it will cause linearity errors due to

the dynamic REF input current, which typically ranges

from 300µA to 400µA.

Figure 10 shows a more typical scheme that provides

good AC accuracy. The MAX874’s initial accuracy can

MAX195

be improved by trimming, but the drift is too great to

provide good stability over temperature. The MAX427

buffer provides the necessary drive current to stabilize

the REF input quickly after capacitance changes.

The reference inaccuracies contribute additional full-

scale error. A reference with less than

⁄

total error

(15 parts per million) over the operating temperature

range is required to limit the additional error to less

than 1LSB. The MAX6241 achieves a drift specification

of 1ppm/°C (typ). This allows reasonable temperature

changes with less than 1LSB error. While the

MAX6241’s initial-accuracy specification (0.02%)

results in an offset error of about ±14LSB, the reference

voltage can be trimmed or the offset can be corrected

in software if absolute DC accuracy is essential. Figure

11’s circuit provides outstanding temperature stability

and also provides excellent DC accuracy if the initial

error is corrected.

16-Bit, 85ksps ADC with 10µA Shutdown

12 ______________________________________________________________________________________

MAX195

MAX427

AGNDVSSA

VDDA

MAX874

GND

COMP

OUT

4.096V

+15V

-15V

47µF

LOW ESR

0.1µF

1000pF

0.1µF

10Ω

REF

1N914

10Ω

-5V

+5V

4 14

2.2µF

≥ 8V

1µF

10k

2.2µF

0.1µF

MAX6241

OUT

REF

TRIM

GND

AGND

MAX195

Figure 10. Typical Reference Circuit for AC Accuracy

Figure 11. High-Accuracy Reference

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MAX195BEWE+

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Analog to Digital Converters - ADC 16-Bit 85ksps 5V Precision ADC

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MAX195BEWE+

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