AD8203YRZ Analog Devices Inc, AD8203YRZ Datasheet - Page 15

AD8203YRZ

Manufacturer Part Number

AD8203YRZ

Description

IC,Differential Amplifier,SINGLE,BIPOLAR,SOP,8PIN,PLASTIC

Manufacturer

Analog Devices Inc

Type

Single Supplyr

Datasheets

1.AD8203YRMZ.pdf (20 pages)

2.AD8203YRZ.pdf (5 pages)

Specifications of AD8203YRZ

Amplifier Type

Differential

Number Of Circuits

Slew Rate

0.330 V/µs

Gain Bandwidth Product

60kHz

Current - Input Bias

40nA

Voltage - Input Offset

1000µV

Current - Supply

250µA

Voltage - Supply, Single/dual (±)

3.5 V ~ 12 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Bandwidth

60 kHz

Common Mode Rejection Ratio

Current, Input Bias

40 nA

Current, Supply

0.25 mA

Package Type

SOIC-8

Resistance, Input

320 Kilohms (Differential), 160 Kilohms (Common-Mode)

Temperature, Operating, Range

-40 to +125 °C

Voltage, Gain

14 V/V

Voltage, Input

-6 to +30 V

Voltage, Input Offset

-1 to +1 mV

Voltage, Noise

300 nV/sqrt Hz

Voltage, Output Swing

0.02 to 4.8 V

Voltage, Supply

3.5 to 12 V

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Output Type

Current - Output / Channel

-3db Bandwidth

Lead Free Status / Rohs Status

RoHS Compliant part Electrostatic Device

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Current page: 15 of 20
Download datasheet (307Kb)

GAIN TRIM

Figure 45 shows a method for incremental gain trimming by

using a trim potentiometer and external resistor R

The following approximation is useful for small gain ranges:

Thus, the adjustment range is ±2% for R

Internal Signal Overload Considerations

When configuring gain for values other than 14, the maximum

input voltage with respect to the supply voltage and ground

must be considered, since either the preamplifier or the output

buffer reaches its full-scale output (approximately V

with large differential input voltages. The input of the AD8203

is limited to (V

amplifier, with its fixed gain of ×7, reaches its full-scale output

before the output buffer. For gains greater than 7, the swing at

the buffer output reaches its full scale first and limits the

AD8203 input to (V

LOW-PASS FILTERING

In many transducer applications, it is necessary to filter the

signal to remove spurious high frequency components, includ-

ing noise, or to extract the mean value of a fluctuating signal

with a peak-to-average ratio (PAR) greater than unity. For

example, a full-wave rectified sinusoid has a PAR of 1.57, a

raised cosine has a PAR of 2, and a half-wave sinusoid has a

PAR of 3.14. Signals having large spikes can have PARs of

10 or more.

When implementing a filter, the PAR should be considered so

that the output of the AD8203 preamplifier (A1) does not clip

before A2, since this nonlinearity would be averaged and appear

as an error at the output. To avoid this error, both amplifiers

should be made to clip at the same time. This condition is

achieved when the PAR is no greater than the gain of the sec-

ond amplifier (2 for the default configuration). For example, if a

PAR of 5 is expected, the gain of A2 should be increased to 5.

EXT

= 1 MΩ, and so on.

ΔG ≈ (10 MΩ/R

DIFF

NC = NO CONNECT

− 0.2)/7 for overall gains ≤ 7, since the pre-

Figure 45. Incremental Gain Trim

EXT

− 0.2)/G, where G is the overall gain.

+IN

–IN

AD8203

GND

OUT

EXT

= 5 MΩ; ±10% for

GAIN TRIM

20kΩ MIN

EXT

OUT

− 0.2 V)

Rev. B | Page 15 of 20

Low-pass filters can be implemented in several ways by using

the features provided by the AD8203. In the simplest case, a

single-pole filter (20 dB/decade) is formed when the output of

A1 is connected to the input of A2 via the internal 100 kΩ

resistor by strapping Pin 3, Pin 4, and a capacitor added from

this node to ground, as shown in

across the capacitor to lower the gain, the corner frequency

increases; it should be calculated using the parallel sum of the

resistor and 100 kΩ.

If the gain is raised using a resistor, as shown in Figure 44, the

corner frequency is lowered by the same factor as the gain is

raised. Thus, using a resistor of 200 kΩ (for which the gain

would be doubled), the corner frequency is now 0.796 Hz μF

(0.039 μF for a 20 Hz corner frequency).

A 2-pole filter (with a roll-off of 40 dB/decade) can be implemented

using the connections shown in Figure 47. This is a Sallen-Key

form based on a ×2 amplifier. It is useful to remember that a 2-pole

filter with a corner frequency f

have the same attenuation at the frequency (f

at that frequency is 40 log (f

Using the standard resistor value shown and equal capacitors (see

Figure 47), the corner frequency is conveniently scaled at 1 Hz μF

(0.05 μF for a 20 Hz corner). A maximally flat response occurs

when the resistor is lowered to 196 kΩ and the scaling is then

1.145 Hz μF. The output offset is raised by approximately 5 mV

(equivalent to 250 μV at the input pins).

Figure 46. Single-Pole, Low-Pass Filter Using the Internal 100 kΩ Resistor

DIFF

NC = NO CONNECT

Figure 47. 2-Pole, Low-Pass Filter

+IN

–IN

+IN

–IN

), which is illustrated in Figure 48.

and a 1-pole filter with a corner at f

AD8203

GND

AD8203

GND

Figure 46. If a resistor is added

OUT

255kΩ

). The attenuation

(Hz) = 1/C(μF)

C IN FARADS

OUTPUT

2πC10

AD8203

OUT

AD8203YRZ Analog Devices Inc, AD8203YRZ Datasheet - Page 15

AD8203YRZ

Specifications of AD8203YRZ

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