AD8555ACP-R2 Analog Devices Inc, AD8555ACP-R2 Datasheet - Page 25

AD8555ACP-R2

Manufacturer Part Number

AD8555ACP-R2

Description

IC AMP CHOPPER 2MHZ 10MA 16LFCSP

Manufacturer

Analog Devices Inc

Series

DigiTrim®r

Datasheet

1.AD8555ARZ.pdf (28 pages)

Specifications of AD8555ACP-R2

Rohs Status

RoHS non-compliant

Amplifier Type

Chopper (Zero-Drift)

Number Of Circuits

Slew Rate

1.2 V/µs

Gain Bandwidth Product

2MHz

Current - Input Bias

16nA

Voltage - Input Offset

2µV

Current - Supply

2mA

Current - Output / Channel

10mA

Voltage - Supply, Single/dual (±)

2.7 V ~ 5.5 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

16-LFCSP

Output Type

-3db Bandwidth

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FILTERING FUNCTION

The AD8555’s FILT/DIGOUT pin can be used to create a sim-

ple low-pass filter. The AD8555’s internal 18 kΩ resistor can be

used with an external capacitor for this purpose. Typical

responses of the AD8555, configured for a gain of 70 and gain

of 1280, are shown in Figure 54 and Figure 55, respectively. This

filtering feature can be used to pass the signals within the filter’s

pass band while limiting the out-of-band signals bandwidth

and, therefore, reducing the noise of the overall solution.

Figure 55. Typical Response of the AD8555 at FILT/DIGOUT Pin (Gain = 1280)

Figure 54. Typical Response of the AD8555 at FILT/DIGOUT Pin (Gain = 70)

OUT

FILTER

Figure 53. AD8555 Configured to Filter Noise

VDD

= 0.100 μ F

100

FILTER

VDD

DIGIN

VNEG

FILT/DIGOUT

= 0.010 μ F

AD8555

VCLAMP

VOUT

VPOS

VSS

FILTER

= 0.001 μ F

10k

= 0.001 μ F

10k

= 0.100 μ F

VSS

VDD

100k

50k

Rev. A | Page 25 of 28

DRIVING CAPACITIVE LOADS

The AD8555 can drive large capacitive loads. This feature is

useful when the amplifier, placed close to the sensor, has to

drive long cables. Most instrumentation amplifiers have diffi-

culty driving capacitance due to the degradation of the phase

margin caused by the additional phase lag from the capacitive

load. Higher capacitance at the output can increase the amount

of overshoot and ringing in the amplifier’s step response and

could even affect the stability of the device. Additionally, the

value of the capacitive load that an amplifier can drive before

oscillation varies with gain, supply voltage, input signal, and

temperature. Figure 57 and Figure 58 show the overshoot

response of AD8555 versus the capacitive load with a different

value isolation resistor (R

ers, the AD8555 responds with overshoot when driving large

creases. This is because the pole created by C

first; however, at some point, the pole is farther in than the pole

setting of the buffer amplifier and is ignored by AD8555.

, but after a point (approximately 22 nF), the overshoot de-

0.1

FILTER

VDD

OUTPUT

BUFFER

Figure 56. Test Circuit for Driving Capacitive Loads

= ±2.5V

Figure 57. Positive Overshoot Graph vs. C

VDD

DIGIN

VNEG

FILT/DIGOUT

AD8555

= 100

LOAD CAPACITANCE (nF)

) in Figure 56. Similar to all amplifi-

= 1nF

VCLAMP

VOUT

VPOS

VSS

= 50

VSS

VDD

= 20

dominates at

= 10

= 0

AD8555

OUT

100

AD8555ACP-R2 Analog Devices Inc, AD8555ACP-R2 Datasheet - Page 25

AD8555ACP-R2

Specifications of AD8555ACP-R2

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