Burr-Brown Corporation Instrumentation Amplifiers 6

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Part	Manufacturer	Amplifier Type	Temperature Grade	Terminal Form	No. of Terminals	Package Code	Package Shape	Package Body Material	Maximum Negative Supply Voltage Limit	Maximum Input Offset Voltage	Maximum Average Bias Current (IIB)	Surface Mount	No. of Functions	Minimum Common Mode Reject Ratio	Technology	Maximum Supply Current	Nominal Negative Supply Voltage (Vsup)	Nominal Supply Voltage / Vsup (V)	Power Supplies (V)	Package Style (Meter)	Package Equivalence Code	Maximum Input Offset Current (IIO)	Sub-Category	Nominal Slow Rate	Maximum Non Linearity	Maximum Supply Voltage Limit	Terminal Pitch	Maximum Operating Temperature	Minimum Voltage Gain	Minimum Operating Temperature	Terminal Finish	Nominal Voltage Gain	Terminal Position	JESD-30 Code	Maximum Voltage Gain	Width	Qualification	Nominal Bandwidth (3dB)	JESD-609 Code
INA126EA-250	Burr-Brown Corporation	Instrumentation Amplifier	Industrial	Gull Wing	8	SOP	Square	Plastic/Epoxy	-18 V	500 µV	50 nA	Yes	1	74 dB			-15 V	15 V		Small Outline		5 nA	Instrumentation Amplifiers	0.4 V/us	0.012 %	18 V		85 °C (185 °F)	5	-40 °C (-40 °F)			Dual	S-PDSO-G8	10000		No	200 kHz
INA2126EA-250	Burr-Brown Corporation	Instrumentation Amplifier	Industrial	Gull Wing	16		Rectangular	Plastic/Epoxy	-18 V	500 µV	50 nA	Yes	2	74 dB			-15 V	15 V		Small Outline		5 nA	Instrumentation Amplifiers	0.4 V/us	0.012 %	18 V		85 °C (185 °F)	5	-40 °C (-40 °F)			Dual	R-PDSO-G16	10000	0.154 in (3.9 mm)	No	200 kHz
INA126E-250	Burr-Brown Corporation	Instrumentation Amplifier	Industrial	Gull Wing	8	SOP	Square	Plastic/Epoxy	-18 V	250 µV	25 nA	Yes	1	83 dB			-15 V	15 V		Small Outline		2 nA	Instrumentation Amplifiers	0.4 V/us	0.012 %	18 V		85 °C (185 °F)	5	-40 °C (-40 °F)			Dual	S-PDSO-G8	10000		No	200 kHz
INA2126E-250	Burr-Brown Corporation	Instrumentation Amplifier	Industrial	Gull Wing	16		Rectangular	Plastic/Epoxy	-18 V	250 µV	25 nA	Yes	2	83 dB			-15 V	15 V		Small Outline		2 nA	Instrumentation Amplifiers	0.4 V/us	0.012 %	18 V		85 °C (185 °F)	5	-40 °C (-40 °F)			Dual	R-PDSO-G16	10000	0.154 in (3.9 mm)	No	200 kHz
INA103AG	Burr-Brown Corporation	Instrumentation Amplifier	Other	Through-Hole	16	DIP	Rectangular	Ceramic, Metal-Sealed Cofired	-25 V	5.1 mV	12 uA	No	1	72 dB	Bipolar	12.5 mA	-15 V	15 V	±15 V	In-Line	DIP16,.3	1 uA	Instrumentation Amplifiers	15 V/us	0.01 %	25 V	0.1 in (2.54 mm)	85 °C (185 °F)	1	-25 °C (-13 °F)	Tin Lead	1000	Dual	R-CDIP-T16			No	6 MHz	e0
INA103BG	Burr-Brown Corporation	Instrumentation Amplifier	Other	Through-Hole	16	DIP	Rectangular	Ceramic, Metal-Sealed Cofired	-25 V	2.05 mV	8 uA	No	1	80 dB	Bipolar	12.5 mA	-15 V	15 V	±15 V	In-Line	DIP16,.3	500 nA	Instrumentation Amplifiers	15 V/us	0.004 %	25 V	0.1 in (2.54 mm)	85 °C (185 °F)	1	-25 °C (-13 °F)	Tin Lead	1000	Dual	R-CDIP-T16			No	6 MHz	e0

Instrumentation Amplifiers

An instrumentation amplifier is an electronic circuit that amplifies small differential voltages to produce a larger output voltage signal. The main purpose of an instrumentation amplifier is to provide a high-precision and stable amplification of small signals while rejecting any common-mode noise or interference.

An instrumentation amplifier consists of three operational amplifiers (op-amps) and precision resistors. The first two op-amps are used as buffer amplifiers, and the third op-amp is used as a differential amplifier. The input signals are applied to the buffer amplifiers, which provide high input impedance and low output impedance to minimize loading effects. The differential amplifier then amplifies the difference between the two input signals, and the resulting output signal is proportional to the difference in voltage between the two input signals.

Instrumentation amplifiers are used in applications where small voltage signals need to be accurately measured or amplified. They are commonly used in industrial control systems, biomedical instrumentation, data acquisition systems, and audio equipment.

One advantage of an instrumentation amplifier is that it can be used to measure small differential voltages even in the presence of significant common-mode noise, which can be difficult to achieve with other types of amplifiers. Additionally, many instrumentation amplifiers offer a high level of accuracy, stability, and linearity, which makes them a popular choice for precision measurement applications.