OPA365 Datasheet, PDF(10/24 Page) Burr-Brown (TI) – 2.2V, 50MHz, Low-Noise, Single-Supply Rail-to-Rail OPERATIONAL AMPLIFIERS

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OPA365 Datasheet, PDF (10/24 Pages) Burr-Brown (TI) – 2.2V, 50MHz, Low-Noise, Single-Supply Rail-to-Rail OPERATIONAL AMPLIFIERS

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OPA365

OPA2365

SBOS365D â JUNE 2006 â REVISED JUNE 2009

A simplified schematic illustrating the rail-to-rail input

circuitry is shown in Figure 5.

CAPACITIVE LOADS

The OPA365 may be used in applications where driving

a capacitive load is required. As with all op amps, there

may be specific instances where the OPA365 can be-

come unstable, leading to oscillation. The particular op

amp circuit configuration, layout, gain and output load-

ing are some of the factors to consider when establish-

ing whether an amplifier will be stable in operation. An

op amp in the unity-gain (+1V/V) buffer configuration

and driving a capacitive load exhibits a greater tenden-

cy to be unstable than an amplifier operated at a higher

noise gain. The capacitive load, in conjunction with the

op amp output resistance, creates a pole within the

feedback loop that degrades the phase margin. The

degradation of the phase margin increases as the ca-

pacitive loading increases.

When operating in the unity-gain configuration, the

OPA365 remains stable with a pure capacitive load up

to approximately 1nF. The equivalent series resistance

(ESR) of some very large capacitors (CL > 1ÂµF) is suffi-

cient to alter the phase characteristics in the feedback

loop such that the amplifier remains stable. Increasing

the amplifier closed-loop gain allows the amplifier to

drive increasingly larger capacitance. This increased

capability is evident when observing the overshoot re-

sponse of the amplifier at higher voltage gains. See the

typical characteristic graph, Small-Signal Overshoot

vs. Capacitive Load.

One technique for increasing the capacitive load drive

capability of the amplifier operating in unity gain is to in-

sert a small resistor, typically 10â¦ to 20â¦, in series with

the output; see Figure 6. This resistor significantly re-

duces the overshoot and ringing associated with large

capacitive loads. A possible problem with this technique

is that a voltage divider is created with the added series

resistor and any resistor connected in parallel with the

capacitive load. The voltage divider introduces a gain

error at the output that reduces the output swing. The

error contributed by the voltage divider may be insignifi-

cant. For instance, with a load resistance, RL = 10kâ¦,

and RS = 20â¦, the gain error is only about 0.2%. Howev-

er, when RL is decreased to 600â¦, which the OPA365

is able to drive, the error increases to 7.5%.

VC C + 1.8V

www.ti.com

Regulated

Charge Pump

VOU T = VC C +1.8V

Patent Pending

Very Low Ripple

IB IAS

Topology

IB IA S

VINâ

VI N +

IBIA S

VOU T

IB IA S

Figure 5. Simplified Schematic

V+

OPA365

VOUT

VIN

10â¦ to

20â¦

Figure 6. Improving Capacitive Load Drive

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