Product details

Number of channels (#) 1 Total supply voltage (Max) (+5V=5, +/-5V=10) 5.5 Total supply voltage (Min) (+5V=5, +/-5V=10) 1.7 Vos (offset voltage @ 25 C) (Max) (mV) 0.1 GBW (Typ) (MHz) 1 Features e-Trim™ Slew rate (Typ) (V/us) 1 Rail-to-rail In, Out Offset drift (Typ) (uV/C) 1 Iq per channel (Typ) (mA) 0.0235 Vn at 1 kHz (Typ) (nV/rtHz) 60 CMRR (Typ) (dB) 121 Rating Catalog Operating temperature range (C) -40 to 125 Input bias current (Max) (pA) 10 Output current (Typ) (mA) 60 Architecture CMOS THD + N @ 1 kHz (Typ) (%) 0.002
Number of channels (#) 1 Total supply voltage (Max) (+5V=5, +/-5V=10) 5.5 Total supply voltage (Min) (+5V=5, +/-5V=10) 1.7 Vos (offset voltage @ 25 C) (Max) (mV) 0.1 GBW (Typ) (MHz) 1 Features e-Trim™ Slew rate (Typ) (V/us) 1 Rail-to-rail In, Out Offset drift (Typ) (uV/C) 1 Iq per channel (Typ) (mA) 0.0235 Vn at 1 kHz (Typ) (nV/rtHz) 60 CMRR (Typ) (dB) 121 Rating Catalog Operating temperature range (C) -40 to 125 Input bias current (Max) (pA) 10 Output current (Typ) (mA) 60 Architecture CMOS THD + N @ 1 kHz (Typ) (%) 0.002
SOT-SC70 (DCK) 5 4 mm² 2 x 2.1
  • Low IQ: 23.5 µA
  • Gain bandwidth product: 1 MHz
  • Low input bias current: 10 fA (typical)
  • Low offset voltage: ±100 µV (maximum)
  • Low drift: ±1.2 µV/°C
  • Low supply voltage operation: 1.7 V to 5.5 V
  • Input common mode range ±100 mV beyond rail
  • Fast slew rate: 1 V/µs
  • High load capacitance drive
  • High output current drive: 60 mA
  • Rail-to-rail output
  • EMI/RFI filtered inputs
  • Small packages: SC70 and WCSP (Preview)
  • Low IQ: 23.5 µA
  • Gain bandwidth product: 1 MHz
  • Low input bias current: 10 fA (typical)
  • Low offset voltage: ±100 µV (maximum)
  • Low drift: ±1.2 µV/°C
  • Low supply voltage operation: 1.7 V to 5.5 V
  • Input common mode range ±100 mV beyond rail
  • Fast slew rate: 1 V/µs
  • High load capacitance drive
  • High output current drive: 60 mA
  • Rail-to-rail output
  • EMI/RFI filtered inputs
  • Small packages: SC70 and WCSP (Preview)

The OPA396 features a combination of high bandwidth (1 MHz) along with very low quiescent current (23.5 µA) in a high-precision amplifier. These features combined with rail-to-rail input and output make this device an exceptional choice in high-gain, low-power applications. Ultra-low input bias current of 10 fA, 100 µV of offset (maximum), and 1.2 µV/°C of drift over temperature help maintain high precision in ratiometric and amperometric sensor front ends that have demanding low-power requirements.

The OPA396 uses Texas Instrument’s proprietary e‑trim™ operational amplifier technology, enabling a unique combination of ultra-low offset and low input offset drift without the need for any input switching or auto-zero techniques. The CMOS-based technology platform also features a modern, robust output stage design that is tolerant of high output capacitance, alleviating stability problems that are common in typical low-power amplifiers.

The OPA396 features a combination of high bandwidth (1 MHz) along with very low quiescent current (23.5 µA) in a high-precision amplifier. These features combined with rail-to-rail input and output make this device an exceptional choice in high-gain, low-power applications. Ultra-low input bias current of 10 fA, 100 µV of offset (maximum), and 1.2 µV/°C of drift over temperature help maintain high precision in ratiometric and amperometric sensor front ends that have demanding low-power requirements.

The OPA396 uses Texas Instrument’s proprietary e‑trim™ operational amplifier technology, enabling a unique combination of ultra-low offset and low input offset drift without the need for any input switching or auto-zero techniques. The CMOS-based technology platform also features a modern, robust output stage design that is tolerant of high output capacitance, alleviating stability problems that are common in typical low-power amplifiers.

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Technical documentation

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Type Title Date
* Data sheet OPA396 Precision, Low IQ, Low Input Bias Current Op Amp datasheet 22 Jul 2021
Application note Offset Correction Methods: Laser Trim, e-Trim, and Chopper (Rev. C) 13 Apr 2021

Design & development

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