MAX104 Datasheet, PDF(25/32 Page) Maxim Integrated Products – ±5V, 1Gsps, 8-Bit ADC with On-Chip 2.2GHz Track/Hold Amplifier

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MAX104 Datasheet, PDF (25/32 Pages) Maxim Integrated Products – ±5V, 1Gsps, 8-Bit ADC with On-Chip 2.2GHz Track/Hold Amplifier

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Â±5V, 1Gsps, 8-Bit ADC with

On-Chip 2.2GHz Track/Hold Amplifier

Table 7. Thermal Performance for

MAX104 With or Without Heatsink

AIRFLOW

(linear ft./min.)

200

400

800

MAX104 Î¸JA (Â°C/W)

WITHOUT

HEATSINK

WITH HEATSINK

16.5

12.5

14.3

9.4

8.3

12.5

7.4

Thermal Performance

The MAX104 has been modeled to determine the ther-

mal resistance from junction to ambient. Table 7 lists

the ADCâs thermal performance parameters:

Ambient Temperature:

TA = +70Â°C

Heatsink Dimensions:

25mm x 25mm x 10mm

PC Board Size and Layout: 4" x 4"

2 Signal Layers

2 Power Layers

Heatsink Manufacturers

Aavid Engineering and IERC provide open-tool, low-

profile heatsinks, fitting the 25mm x 25mm ESBGA

package.

Aavid Engineering, Inc.

Phone: 714-556-2665

Heatsink Catalog #: 335224B00032

Heatsink Dimensions: 25mm x 25mm x 10mm

International Electronic Research Corporation (IERC)

Phone: 818-842-7277

Heatsink Catalog #: BDN09-3CB/A01

Heatsink Dimensions: 23.1mm x 23.1mm x 9mm

Bypassing/Layout/Power Supply

Grounding and power-supply decoupling strongly influ-

ence the MAX104âs performance. At 1GHz clock fre-

quency and 8-bit resolution, unwanted digital crosstalk

may couple through the input, reference, power supply,

and ground connections and adversely influence the

dynamic performance of the ADC. Therefore, closely

follow the grounding and power-supply decoupling

guidelines (Figure 22).

THERMAL RESISTANCE vs. AIRFLOW

WITHOUT

HEATSINK

WITH HEATSINK

0 100 200 300 400 500 600 700 800

AIRFLOW (linear ft./min.)

Figure 21. MAX104 Thermal Performance

Maxim strongly recommends using a multilayer printed

circuit board (PCB) with separate ground and power-

supply planes. Since the MAX104 has separate analog

and digital ground connections (GNDA, GNDI, GNDR,

and GNDD, respectively), the PCB should feature sep-

arate analog and digital ground sections connected at

only one point (star ground at the power supply). Digital

signals should run above the digital ground plane, and

analog signals should run above the analog ground

plane. Keep digital signals far away from the sensitive

analog inputs, reference inputs, and clock inputs. High-

speed signals, including clocks, analog inputs, and

digital outputs, should be routed on 50â¦ microstrip

lines, such as those employed on the MAX104EVKIT.

The MAX104 has separate analog and digital power-

supply inputs: VEE (-5V analog and substrate supply)

and VCCI (+5V) to power the T/H amplifier, clock distri-

bution, bandgap reference, and reference amplifier;

VCCA (+5V) to supply the ADCâs comparator array;

VCCO (+3V to VCCD) to establish power for all PECL-

based circuit sections; and VCCD (+5V) to supply all

logic circuits of the data converter.

The MAX104 VEE supply contacts must not be left

open while the part is being powered up. To avoid this

condition, add a high-speed Schottky diode (such as a

Motorola 1N5817) between VEE and GNDI. This diode

prevents the device substrate from forward biasing,

which could cause latchup.

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