EVAL_ADDIFFAMP_15 Datasheet, PDF(2/4 Page) Analog Devices – Differential Driver Evaluation Board

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EVAL_ADDIFFAMP_15 Datasheet, PDF (2/4 Pages) Analog Devices – Differential Driver Evaluation Board

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EVAL-ADDIFFAMP

HARDWARE

POWER SUPPLIES

Power is applied to the board through P1, a MolexÂ®

22-11-2032 3-pin header. Pin 1 (square footprint) is for the

positive supply, Pin 3 is for the negative supply, and Pin 2 is

connected to the ground plane of the board. Alternatively,

looped test points can be used; Test Point TP2 connects to the

positive supply, TP3 connects to the negative supply, and TP7

and TP8 connect to the ground plane. The TP5, TP6, TP9, and

TP10 test points also connect to the ground plane.

The board accommodates single or dual supplies. For single-

supply operation, simply connect the negative supply to the

ground plane.

It is very important that the power supply pins of the device

under test (DUT) have broadband decoupling circuitry. The

board layout facilitates this with footprints for two 1206 ceramic

capacitors on each supply. At frequencies beyond the resonant

frequency of the first capacitor and its associated internal and

external inductance, the second capacitor provides the required

low impedance return current path. For optimum performance,

place the smaller of the two capacitances closest to the DUT, in

positions C8 and C11. C13 provides the user with the option of

adding differential decoupling between the supplies. Bulk

decoupling is provided by C1 and C2; 10 Î¼F tantalum capacitors

are recommended.

FEEDBACK NETWORKS AND INPUT/OUTPUT

TERMINATIONS

R19 and R17 compose the upper resistive feedback loop (see

Figure 1), and R20 and R18 compose the lower feedback loop.

C3 and C4 are included across the feedback resistors to provide

frequency-dependent feedback, typically used to introduce a

real-axis pole in the closed-loop frequency response.

To minimize summing node capacitances, void the ground

plane under and around Pin 1 and Pin 8 of the DUT and the

copper that connects to them.

R6 and R7 are included as input termination resistors for

applications that have single-ended inputs. Having a place for a

shunt resistor on each input makes it simple to match the two

feedback factors. A common example of how this is used is

when the input signal originates from an unbalanced 50 Î©

source. In this case, the single-ended termination resistance is

50 Î© and the Thevenin equivalent resistance seen looking back

to the source is 25 Î©. For the traditional 4-resistor configuration,

where R19 = R20 and R17 = R18, the feedback networks are

matched by making the shunt resistor on the input leg opposite

the termination resistor equal to 25 Î©. R5 is provided for differ-

ential termination.

R15 and R16 series termination resistors are provided on each

of the outputs for impedance matching, analog-to-digital

converter (ADC) driving, and other system requirements.

VOCM INPUT

The VOCM input can be set to a dc level by adjusting Poten-

tiometer R1 that spans the power supplies. For the dc case, C9 is

provided at the wiper for decoupling.

An external voltage can be applied to VOCM via TP4 (referenced

to the ground plane of the board). In ADC driving applications,

it is convenient to apply the ADC dc reference voltage output

directly to TP4.

It is also possible to drive the VOCM input from an external ac

source. In this case, omit C9 or reduce it to a value that allows

the desired signal to be passed. For high frequency signals on

VOCM, connect the center conductor of a coaxial cable to TP4

and ground its shield at TP10.

R21 is provided for the high common-mode output impedance

application illustrated in Figure 77 of the AD8132 data sheet.

MEASURING OUTPUT COMMON-MODE VOLTAGE

The internal common-mode feedback loop used in the

differential drivers forces the output common-mode voltage to

be equal to the voltage applied to the VOCM input, thereby

providing excellent output balance. R11 and R12 form a voltage

divider across the differential output, and the voltage at the

divider tap is equal to the output common-mode voltage,

provided R11 and R12 are exactly matched in value. If R11 and

R12 are used to evaluate the output common-mode voltage,

they should be measured and matched to better than 300 ppm

to obtain results commensurate with the DUT output balance

error performance of â70 dB. The Test Point PR1 accepts

coaxial-type oscilloscope test points, such as the Berg

Electronics 33JR135-1.

INPUT/OUTPUT TRANSFORMERS

The board has the added flexibility of allowing the user to

incorporate transformers on its input and output. This

capability can be especially useful when connecting to single-

ended test equipment. Because both input and output

transformers have dual, nested footprints, the user can select

from a wide array of transformers available from companies

such as Mini-CircuitsÂ® and CoilcraftÂ®. The layout provides

footprints for connecting resistors to ground on the primary

and secondary transformer center taps, offering the user a

number of options with regard to the common-mode properties

of the evaluation circuit.

JP1, JP2, JP3, and JP4 are jumpers on the backside of the board

that provide direct shunts across their associated transformers.

Rev. A | Page 2 of 4

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