MAX1300_10 Datasheet, PDF(26/32 Page) Maxim Integrated Products – 8- and 4-Channel, ±3 x VREF Multirange Inputs, Serial 16-Bit ADCs

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MAX1300_10 Datasheet, PDF (26/32 Pages) Maxim Integrated Products – 8- and 4-Channel, ±3 x VREF Multirange Inputs, Serial 16-Bit ADCs

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8- and 4-Channel, Â±3 x VREF Multirange Inputs,

Serial 16-Bit ADCs

SAR

ADC REF

4.096V

MAX1300

MAX1301

5kÎ©

4.096V

BANDGAP

REFERENCE

V+

REF

OUT

1.0Î¼F

MAX6341

AVDD1

REFCAP

GND

VRCTH

AGND1

1.0Î¼F

Figure 18. External Reference Operation

Bridge Application

The MAX1300/MAX1301 convert 1kHz signals more

accurately than a similar sigma-delta converter that

might be considered in bridge applications. The input

impedance of the MAX1300, in combination with the cur-

rent-limiting resistors, can affect the gain of the

MAX1300. In many applications this error is acceptable,

but for applications that cannot tolerate this error, the

MAX1300 inputs can be buffered (Figure 20). Connect

the bridge to a low-offset differential amplifier and then

the true-differential inputs of the MAX1300/MAX1301.

Larger excitation voltages take advantage of more of the

(Â±3 x VREF)/4 differential input voltage range. Select an

input voltage range that matches the amplifier output. Be

aware of the amplifier offset and offset-drift errors when

selecting an appropriate amplifier.

Dynamically Adjusting the Input Range

Software control of each channelâs analog input range

and the unipolar endpoint overlap specification make it

possible for the user to change the input range for a

channel dynamically and improve performance in some

applications. Changing the input range results in a

small LSB step-size over a wider output voltage range.

For example, by switching between a (-3 x VREF)/2 to

0V range and a 0 to (+3 x VREF)/2 range, an LSB is

( ) +3 Ã VREF 2 Ã VREF

65,536 Ã 4.096

but the input voltage range effectively spans from

(-3 x VREF)/2 to (+3 x VREF)/2 (FSR = 3 x VREF).

Layout, Grounding, and Bypassing

Careful PC board layout is essential for best system per-

formance. Boards should have separate analog and

digital ground planes and ensure that digital and analog

signals are separated from each other. Do not run ana-

log and digital (especially clock) lines parallel to one

another, or digital lines underneath the device package.

Figure 1 shows the recommended system ground con-

nections. Establish an analog ground point at AGND1

and a digital ground point at DGND. Connect all analog

grounds to the star analog ground. Connect the digital

grounds to the star digital ground. Connect the digital

ground plane to the analog ground plane at one point.

For lowest noise operation, make the ground return to

the star groundâs power-supply low impedance and as

short as possible.

High-frequency noise in the AVDD1 power supply

degrades the ADCâs high-speed comparator perfor-

mance. Bypass AVDD1 to AGND1 with a 0.1Î¼F ceramic

surface-mount capacitor. Make bypass capacitor con-

nections as short as possible.

Parameter Definitions

Integral Nonlinearity (INL)

INL is the deviation of the values on an actual transfer

function from a straight line. This straight line is either a

best straight-line fit or a line drawn between the end-

points of the transfer function once offset and gain

errors have been nullified. The MAX1300/MAX1301 INL

is measured using the endpoint method.

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