THS4631 Datasheet, PDF(14/27 Page) Texas Instruments – HIGH-VOLTAGE, HIGH SLEW RATE, WIDEBAND FET-INPUT OPERATIONAL AMPLIFIER

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THS4631 Datasheet, PDF (14/27 Pages) Texas Instruments – HIGH-VOLTAGE, HIGH SLEW RATE, WIDEBAND FET-INPUT OPERATIONAL AMPLIFIER

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THS4631

SLOS451A â DECEMBER 2004 â REVISED MARCH 2005

values dominate the noise of the system. Although

the THS4631 JFET input stage is ideal for

high-source impedance because of the low-bias cur-

rents, the system noise and bandwidth is limited by a

high-source (RS) impedance.

SLEW RATE PERFORMANCE WITH VARYING

INPUT STEP AMPLITUDE AND RISE/FALL

TIME

Some FET input amplifiers exhibit the peculiar

behavior of having a larger slew rate when presented

with smaller input voltage steps and slower edge

rates due to a change in bias conditions in the input

stage of the amplifier under these circumstances.

This phenomena is most commonly seen when FET

input amplifiers are used as voltage followers. As this

behavior is typically undesirable, the THS4631 has

been designed to avoid these issues. Larger ampli-

tudes lead to higher slew rates, as would be antici-

pated, and fast edges do not degrade the slew rate of

the device. The high slew rate of the THS4631 allows

improved SFDR and THD performance, especially

noticeable above 5 MHz.

PRINTED-CIRCUIT BOARD LAYOUT

TECHNIQUES FOR OPTIMAL

PERFORMANCE

Achieving optimum performance with high frequency

amplifier-like devices in the THS4631 requires careful

attention to board layout parasitic and external

component types.

Recommendations that optimize performance include:

â¢ Minimize parasitic capacitance to any ac ground

for all of the signal I/O pins. Parasitic capacitance

on the output and input pins can cause instability.

To reduce unwanted capacitance, a window

around the signal I/O pins should be opened in all

of the ground and power planes around those

pins. Otherwise, ground and power planes should

be unbroken elsewhere on the board.

â¢ Minimize the distance (< 0.25â) from the power

supply pins to high frequency 0.1-ÂµF and 100-pF

de-coupling capacitors. At the device pins, the

ground and power plane layout should not be in

close proximity to the signal I/O pins. Avoid

narrow power and ground traces to minimize

inductance between the pins and the de-coupling

capacitors. The power supply connections should

always be de-coupled with these capacitors.

Larger (6.8 ÂµF or more) tantalum de-coupling

capacitors, effective at lower frequency, should

also be used on the main supply pins. These may

be placed somewhat farther from the device and

may be shared among several devices in the

same area of the PC board.

â¢ Careful selection and placement of external

components preserve the high frequency per-

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formance of the THS4631. Resistors should be a

very low reactance type. Surface-mount resistors

work best and allow a tighter overall layout.

Again, keep their leads and PC board trace

length as short as possible. Never use wirebound

type resistors in a high frequency application.

Since the output pin and inverting input pins are

the most sensitive to parasitic capacitance,

always position the feedback and series output

resistors, if any, as close as possible to the

inverting input pins and output pins. Other net-

work components, such as input termination re-

sistors, should be placed close to the gain-setting

resistors. Even with a low parasitic capacitance

shunting the external resistors, excessively high

resistor values can create significant time con-

stants that can degrade performance. Good axial

metal-film or surface-mount resistors have ap-

proximately 0.2 pF in shunt with the resistor. For

resistor values > 2.0 kâ¦, this parasitic capaci-

tance can add a pole and/or a zero that can

effect circuit operation. Keep resistor values as

low as possible, consistent with load driving

considerations.

â¢ Connections to other wideband devices on the

board may be made with short direct traces or

through onboard transmission lines. For short

connections, consider the trace and the input to

the next device as a lumped capacitive load.

Relatively wide traces (50 mils to 100 mils)

should be used, preferably with ground and

power planes opened up around them. Estimate

the total capacitive load and determine if isolation

resistors on the outputs are necessary. Low

parasitic capacitive loads (< 4 pF) may not need

an RS since the THS4631 is nominally compen-

sated to operate with a 2-pF parasitic load.

Higher parasitic capacitive loads without an RS

are allowed as the signal gain increases

(increasing the unloaded phase margin). If a long

trace is required, and the 6-dB signal loss intrin-

sic to a doubly-terminated transmission line is

acceptable, implement a matched impedance

transmission line using microstrip or stripline

techniques (consult an ECL design handbook for

microstrip and stripline layout techniques). A

50-â¦ environment is not necessary onboard, and

in fact, a higher impedance environment im-

proves distortion as shown in the distortion ver-

sus load plots. With a characteristic board trace

impedance based on board material and trace

dimensions, a matching series resistor into the

trace from the output of the THS4631 is used as

well as a terminating shunt resistor at the input of

the destination device. Remember also that the

terminating impedance is the parallel combination

of the shunt resistor and the input impedance of

the destination device: this total effective im-

pedance should be set to match the trace im-

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