MAX1403_02 Datasheet, PDF(30/36 Page) Maxim Integrated Products – +3V, 18-Bit, Low-Power, Multichannel, Oversampling (Sigma-Delta) ADC

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MAX1403_02 Datasheet, PDF (30/36 Pages) Maxim Integrated Products – +3V, 18-Bit, Low-Power, Multichannel, Oversampling (Sigma-Delta) ADC

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+3V, 18-Bit, Low-Power, Multichannel,

Oversampling (Sigma-Delta) ADC

Analog Filtering

The digital filter does not provide any rejection close to

the harmonics of the modulator sample frequency.

However, due to the high oversampling ratio of the

MAX1403, these bands occupy only a small fraction of

the spectrum and most broadband noise is filtered.

Therefore, the analog filtering requirements in front of

the MAX1403 are considerably reduced compared to a

conventional converter with no on-chip filtering. In addi-

tion, because the partâs common-mode rejection of

90dB extends out to several kHz, common-mode noise

susceptibility in this frequency range is substantially

reduced.

Depending on the application, it may be necessary to

provide filtering prior to the MAX1403 to eliminate

unwanted frequencies the digital filter does not reject. It

may also be necessary in some applications to provide

additional filtering to ensure that differential noise sig-

nals outside the frequency band of interest do not satu-

rate the analog modulator.

If passive components are placed in front of the

MAX1403, when the part is used in unbuffered mode,

ensure that the source impedance is low enough not to

introduce gain errors in the system (Tables 13aâ13d).

This can significantly limit the amount of passive anti-

aliasing filtering that can be applied in front of the

MAX1403 in unbuffered mode. However, when the part

is used in buffered mode, large source impedances will

simply result in a small DC offset error (a 1kâ¦ source

resistance will cause an offset error of less than 10ÂµV).

Therefore, where any significant source impedances

are required, Maxim recommends operating the part in

buffered mode.

Calibration Channels

Two fully differential calibration channels allow mea-

surement of the system gain and offset errors. Connect

the CALOFF channel to 0V and the CALGAIN channel

to the reference voltage. Average several measure-

ments on both CALOFF and CALGAIN. Subtract the

average offset code and scale to correct for the gain

error. This linear calibration technique can be used to

remove errors due to source impedances on the analog

input (e.g., when using a simple RC anti-aliasing filter

on the front end).

Applications Information

SPI Interface (68HC11, PIC16C73)

Microprocessors with a hardware SPI (serial peripheral

interface) can use a 3-wire interface to the MAX1403

(Figure 12). The SPI hardware generates groups of

eight pulses on SCLK, shifting data in on one pin and

out on the other pin.

For best results, use a hardware interrupt to monitor the

INT pin and acquire new data as soon as it is available.

If hardware interrupts are not available, or if interrupt

latency is longer than the selected conversion rate, use

the FSYNC bit to prevent automatic measurement while

reading the data output register.

The example code in Listing 1 shows how to interface

with the MAX1403 using a 68HC11. System-dependent

initialization code is not shown.

fCLKIN = 2.4576MHz

-20

MF1, 0 = 0

FS1, 0 = 0

-40

fN = 50Hz

-60

-80

-100

-120

-140

-160

0 20 40 60 80 100 120 140 160 180 200

FREQUENCY (Hz)

Figure 11. Frequency Response of the SINC3 Filter

(Notch at 50Hz)

VDD VDD

INTERRUPT

68HC11

SCK

MISO

MOSI

RESET

INT

SCLK MAX1403

DOUT

DIN

Figure 12. MAX1403 to 68HC11 Interface

30 ______________________________________________________________________________________

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