MAX1124 Datasheet, PDF(14/17 Page) Maxim Integrated Products – 1.8V, 10-Bit, 250Msps Analog-to-Digital Converter with LVDS Outputs for Wideband Applications

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MAX1124 Datasheet, PDF (14/17 Pages) Maxim Integrated Products – 1.8V, 10-Bit, 250Msps Analog-to-Digital Converter with LVDS Outputs for Wideband Applications

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1.8V, 10-Bit, 250Msps Analog-to-Digital Converter

with LVDS Outputs for Wideband Applications

SINGLE-ENDED

INPUT TERMINAL 0.1ÂµF

ADT1â1WT

25â¦

15â¦ INP

25â¦

15â¦ INN

0.1ÂµF

AVCC

OVCC

MAX1124

D0P/NâD9P/N

AGND OGND

Figure 8. Transformer-Coupled Analog Input Configuration with Secondary-Side Termination

predetermined resistor value between REFADJ and

REFIO increases the full-scale range of the data con-

verter. Figure 6 shows the two possible configurations

and their impact on the overall full-scale range adjust-

ment of the MAX1124. Do not use resistor values of less

than 13kâ¦ to avoid instability of the internal gain regula-

tion loop for the bandgap reference.

Differential, AC-Coupled, PECL-Compatible

Clock Input

The preferred method of clocking the MAX1124 is differ-

entially with LVDS- or PECL-compatible input levels. To

accomplish this, a 50â¦ reverse-terminated clock signal

source with low phase noise is AC-coupled into a fast

differential receiver such as the MC100LVEL16 (Figure

7). The receiver produces the necessary PECL output

levels to drive the clock inputs of the data converter.

Differential, AC-Coupled Analog Input

An RF transformer provides an excellent solution to

convert a single-ended source signal to a fully differen-

tial signal, required by the MAX1124 for optimum

dynamic performance. In general, the MAX1124 pro-

vides the best SFDR and THD with fully differential

input signals and it is not recommended to drive the

ADC inputs in single-ended configuration. In differential

input mode, even-order harmonics are usually lower

since INP and INN are balanced, and each of the ADC

inputs only requires half the signal swing compared to

a single-ended configuration.

Figure 8 depicts a secondary-side termination of the 1:1

transformer into two separate 25â¦ loads. Terminating

the transformer in this fashion reduces the potential

effects of transformer parasitics. The source impedance

combined with the shunt capacitance provided by a PC

board and the ADCâs parasitic capacitance reduce the

combined bandwidth to approximately 550MHz.

SINGLE-ENDED

INPUT TERMINAL

0.1ÂµF

INP

50â¦

0.1ÂµF

INN

25â¦

AVCC

OVCC

MAX1124

D0P/NâD9P/N

AGND OGND

Figure 9. Single-Ended AC-Coupled Analog Input

Configuration

Single-Ended, AC-Coupled Analog Input

Although not recommended, the MAX1124 can be

used in single-ended mode (Figure 9). Analog signals

can be AC-coupled to the positive input INP through a

0.1ÂµF capacitor and terminated with a 50â¦ resistor to

AGND. The negative input should be 25â¦ reverse-ter-

minated and AC grounded with a 0.1ÂµF capacitor.

Grounding, Bypassing, and Board

Layout Considerations

The MAX1124 requires board layout design techniques

suitable for high-speed data converters. This ADC pro-

vides separate analog and digital power supplies. The

analog and digital supply voltage pins accept input

voltage ranges of 1.7V to 1.9V. Although both supply

types can be combined and supplied from one source,

it is recommended to use separate sources to cut down

on performance degradation caused by digital switch-

ing currents, which can couple into the analog supply

network. Isolate analog and digital supplies (AVCC and

OVCC) where they enter the PC board with separate

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