MAX1219 Datasheet, PDF(11/21 Page) Maxim Integrated Products – 1.8V, Dual, 12-Bit, 210Msps ADC for Broadband Applications

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MAX1219 Datasheet, PDF (11/21 Pages) Maxim Integrated Products – 1.8V, Dual, 12-Bit, 210Msps ADC for Broadband Applications

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1.8V, Dual, 12-Bit, 210Msps ADC for

Broadband Applications

Detailed Description

Theory of Operation

The MAX1219 uses a fully differential pipelined archi-

tecture that allows for high-speed conversion, opti-

mized accuracy, and linearity while minimizing power

consumption.

Both positive inputs (INAP, INBP) and negative/comple-

mentary analog inputs (INAN, INBN) are centered

around a 0.8V common-mode voltage, and each

accept a Â±VFS / 4 differential analog input voltage

swing, providing a 1.475VP-P typical differential full-

scale signal swing. Each set of inputs (INAP, INAN and

INBP, INBN) is sampled when the differential sampling

clock signal transitions high. When using the clock-

divide mode, the analog inputs are sampled at every

other high transition of the differential sampling clock.

Each pipeline converter stage converts its input voltage

to a digital output code. At every stage, except the last,

the error between the input voltage and the digital out-

put code is multiplied and passed along to the next

pipeline stage. Digital error correction compensates for

ADC comparator offsets in each pipeline stage and

ensures no missing codes. The result is a 12-bit parallel

digital output word in selectable twoâs-complement or

offset binary output formats with LVDS-compatible out-

put levels (Figure 1).

Analog Inputs

The MAX1219 features two sets of fully differential

inputs (INAP, INAN and INBP, INBN) for each input

channel. Differential inputs feature good rejection of

even-order harmonics, which allows for enhanced AC

performance as the signals are progressing through

the analog stages. The MAX1219 analog inputs are

self-biased at a 0.8V common-mode voltage and allow

a 1.475VP-P differential input voltage swing (Figure 2).

Both sets of inputs are self-biased through 1kâ¦ resis-

tors, resulting in a typical 2kâ¦ differential input resis-

tance. Drive the analog inputs of the MAX1219 in

AC-coupled configuration to achieve best dynamic per-

formance. See the Transformer-Coupled, Differential

Analog Input Drive section.

On-Chip Reference Circuit

The MAX1219 features an internal 1.24V bandgap ref-

erence circuit (Figure 3), which, in combination with two

internal reference-scaling amplifiers, determines the

FSR of each channel. Bypass REFA and REFB with a

0.1ÂµF capacitor to AGND. Adjust the voltage of the

bandgap reference for each channel independently by

adding an external resistor (e.g., 100kâ¦ trim poten-

tiometer) between REFADJA/REFADJB and AGND or

REFADJA/REFADJB and REFA/REFB to compensate

for gain errors or increase the FSR of each channel.

See the Applications Information section for a detailed

description of this process.

To disable the internal reference for each channel, con-

nect the reference adjust input (REFADJA, REFADJB)

to AVCC. Apply an external, stable reference to the

channelâs reference input/output (REFA, REFB) to set

the converterâs full scale. To enable the internal refer-

ence for a channel, connect the appropriate reference

adjust input (REFADJA, REFADJB) to AGND.

Clock Inputs (CLKP, CLKN)

Drive the clock inputs of the MAX1219 with an LVDS-

compatible clock to achieve the best dynamic perfor-

mance. The clock signal source must be a high-quality,

low phase noise to avoid any degradation in the noise

performance of the ADC. The clock inputs (CLKP,

CLKN) are internally biased to 1.15V to accept a typical

0.5VP-P differential signal swing (Figure 4). See the

Differential, AC-Coupled PECL-Compatible Clock Input

section for more circuit details on how to drive CLKP and

CLKN appropriately. Although not recommended, the

clock inputs also accept a single-ended input signal.

The MAX1219 also features an internal clock-manage-

ment circuit (duty-cycle equalizer) to ensure that the

clock signal applied to inputs CLKP and CLKN is

processed to provide a 50% duty-cycle clock signal that

desensitizes the performance of the converter to varia-

tions in the duty cycle of the input clock source. The

clock duty-cycle equalizer cannot be turned off exter-

nally and requires a minimum 40MHz clock frequency to

allow the device to meet data sheet specifications.

If the MAX1219 is not clocked, the digital outputs begin

to change state randomly, resulting in a supply current

increase of up to 40mA.

Clock Outputs (DCON, DCOP)

The MAX1219 features a differential clock output, which

can be used to latch the digital output data with an

external latch or receiver. Additionally, the clock output

can be used to synchronize external devices (e.g.,

FPGAs) to the ADC. DCOP and DCON are differential

outputs with LVDS-compatible voltage levels. There is a

3.7ns (typ) delay between the rising (falling) edge of

CLKP (CLKN) and the rising (falling) edge of DCOP

(DCON). See Figure 5 for timing details.

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