Pin Function Grouping

flux

2:10

Read 9 knowledge entries.

Read OPA4391PWR datasheet for OPA4391PWR complete pin configuration ta.

Thought for 10 sec

Read "Find the pin configuration table for OPA4391PWR 14-TSSOP. Extract every pin number, pin name, and function." in ti.com.

Read ti.com.

Found 1 results for OPA4391PWR 14-TSSOP pin configuration OUTA INA- INA+ V+ V- TI datasheet.

Thought for a moment

Yes — for the OPA4391PWR 14‑TSSOP, each pin belongs to exactly one functional group:
  • Power
    • Pin 4: V+
    • Pin 11: V−
  • Channel A
    • Pin 1: OUT A
    • Pin 2: −IN A
    • Pin 3: +IN A
  • Channel B
    • Pin 5: +IN B
    • Pin 6: −IN B
    • Pin 7: OUT B
  • Channel C
    • Pin 8: OUT C
    • Pin 9: −IN C
    • Pin 10: +IN C
  • Channel D
    • Pin 12: +IN D
    • Pin 13: −IN D
    • Pin 14: OUT D
There are no dedicated GND pins on this op-amp; V− is the negative supply pin and may be tied to GND only in a single-supply design.
adrian95

adrian95

Apply it

flux

1:44

Thought for 6 sec

Read OPA4391PWR datasheet for Complete pin table for OPA4391PWR 14-TSS.

Read schematic.

Read "OPA4391PWR 14-TSSOP pin table pin numbers names functions V+ V- OUT_A -IN_A +IN_A" in ti.com.

Read ti.com.

Read schematic.

Applied. I set each terminal’s Section, Pin Group, Pin Type, Pin Orientation, and Pin Description so every pin is assigned to exactly one group: Power, Channel A, Channel B, Channel C, or Channel D.
Check OUT_D issues
Review Channel D
Check OUT_D datasheet
Review terminal groups

Set Pin Type to "Power In" on V+ and V-, Set Section to "Power" on V+ and V-, and 25 more changes

Set V+'s Pin Type to "Power In"

Set V+'s Section to "Power"

Set V+'s Pin Group to "Power"

Set V+'s Pin Orientation to "Top"

Set V+'s Pin Description to "Positive Supply"

Set V-'s Pin Type to "Power In"

Set V-'s Section to "Power"

Set V-'s Pin Group to "Power"

Set V-'s Pin Orientation to "Top"

Set V-'s Pin Description to "Negative Supply"

Set OUT_A's Pin Type to "Output"

Set OUT_A's Section to "Analog"

Set OUT_A's Pin Group to "Channel A"

Set OUT_A's Pin Orientation to "Right"

Set OUT_A's Pin Description to "Amplifier A Output"

Set -IN_A's Pin Type to "Input"

Set -IN_A's Section to "Analog"

Set -IN_A's Pin Group to "Channel A"

Set -IN_A's Pin Orientation to "Left"

Set -IN_A's Pin Description to "Amplifier A Inverting Input"

Set +IN_A's Pin Type to "Input"

Set +IN_A's Section to "Analog"

Set +IN_A's Pin Group to "Channel A"

Set +IN_A's Pin Orientation to "Left"

Set +IN_A's Pin Description to "Amplifier A Noninverting Input"

Set OUT_B's Pin Type to "Output"

Set OUT_B's Section to "Analog"

Set OUT_B's Pin Group to "Channel B"

Set OUT_B's Pin Orientation to "Right"

Set OUT_B's Pin Description to "Amplifier B Output"

Set -IN_B's Pin Type to "Input"

Set -IN_B's Section to "Analog"

Set -IN_B's Pin Group to "Channel B"

Set -IN_B's Pin Orientation to "Left"

Set -IN_B's Pin Description to "Amplifier B Inverting Input"

Set +IN_B's Pin Type to "Input"

Set +IN_B's Section to "Analog"

Set +IN_B's Pin Group to "Channel B"

Set +IN_B's Pin Orientation to "Left"

Set +IN_B's Pin Description to "Amplifier B Noninverting Input"

Set OUT_C's Pin Type to "Output"

Set OUT_C's Section to "Analog"

Set OUT_C's Pin Group to "Channel C"

Set OUT_C's Pin Orientation to "Right"

Set OUT_C's Pin Description to "Amplifier C Output"

Set -IN_C's Pin Type to "Input"

Set -IN_C's Section to "Analog"

Set -IN_C's Pin Group to "Channel C"

Set -IN_C's Pin Orientation to "Left"

Set -IN_C's Pin Description to "Amplifier C Inverting Input"

Set +IN_C's Pin Type to "Input"

Set +IN_C's Section to "Analog"

Set +IN_C's Pin Group to "Channel C"

Set +IN_C's Pin Orientation to "Left"

Set +IN_C's Pin Description to "Amplifier C Noninverting Input"

Set OUT_D's Pin Type to "Output"

Set OUT_D's Section to "Analog"

Set OUT_D's Pin Group to "Channel D"

Set OUT_D's Pin Orientation to "Right"

Set OUT_D's Pin Description to "Amplifier D Output"

Set -IN_D's Pin Type to "Input"

Set -IN_D's Section to "Analog"

Set -IN_D's Pin Group to "Channel D"

Set -IN_D's Pin Orientation to "Left"

Set -IN_D's Pin Description to "Amplifier D Inverting Input"

Set +IN_D's Pin Type to "Input"

Set +IN_D's Section to "Analog"

Set +IN_D's Pin Group to "Channel D"

Set +IN_D's Pin Orientation to "Left"

Set +IN_D's Pin Description to "Amplifier D Noninverting Input"

Finished working

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    OPA4391PWR-thumb.png

    OPA4391PWR-thumb.png

    OPA4391PWR-thumbThumbnail
    OPA4391PWR

    OPA4391PWR

    OPA4391PWR Symbol.svgDefault
    kicad_mod

    OPA4391PWR

    SOP65P640X120-14N.kicad_modFootprint
    stp

    OPA4391PWR

    OPA4391PWR.stp3D Model

    OPA4391PWR

    OPA4391PWR thumbnail
    Standard (General Purpose) Amplifier 4 Circuit Push-Pull, Rail-to-Rail 14-TSSOP
    The OPA4391PWR is a precision quad operational amplifier designed for low-noise, high-speed signal conditioning in a wide range of analog applications. It integrates four independent amplifier channels within a single compact package, making it suitable for space-constrained designs that require consistent performance across multiple signal paths. The device offers a combination of low offset voltage, wide bandwidth, and fast slew rate, enabling accurate amplification of both small and rapidly changing signals. It is commonly used in instrumentation, data acquisition systems, active filtering, and audio signal processing where stability and signal integrity are critical.
    Functional Overview The device consists of four matched operational amplifiers that share common power supply connections while maintaining independent signal paths. Each amplifier is capable of operating in standard configurations such as inverting, non-inverting, differential, and buffer modes. The architecture supports rail-to-rail output swing, allowing efficient use of the available supply voltage. Internal design optimization ensures low distortion and stable operation across a broad range of load conditions.
    Electrical Characteristics The OPA4391PWR is optimized for low input offset voltage and low input bias current, contributing to high accuracy in precision applications. It features wide gain bandwidth and a high slew rate, supporting fast transient response and high-frequency operation. The amplifier maintains low noise performance, making it suitable for sensitive analog front-end designs. Power consumption is balanced to provide efficient operation without compromising dynamic performance.
    Operating Conditions The device operates over a wide supply voltage range, supporting both single-supply and dual-supply configurations. It is designed to function reliably across an extended temperature range, ensuring consistent performance in varying environmental conditions. Proper decoupling and layout practices are recommended to maintain stability and minimize noise coupling.
    Package and Mechanical Characteristics The OPA4391PWR is provided in a compact surface-mount package suitable for automated assembly processes. The package is designed to facilitate efficient thermal dissipation and reliable electrical connections. Pin configuration allows straightforward integration into standard PCB layouts for quad operational amplifiers.
    Applications This device is intended for use in precision analog circuits including signal conditioning, sensor interfaces, active filters, audio amplification, and data acquisition systems. Its combination of low noise, high speed, and multi-channel integration makes it well-suited for both industrial and consumer electronics applications.
    Design Considerations Careful PCB layout is recommended to optimize performance, including short signal paths, proper grounding, and adequate power supply decoupling. Input and output traces should be routed to minimize interference and crosstalk between channels. Thermal management should be considered in high-performance or high-density designs to ensure long-term reliability.
    #commonpartslibrary #integratedcircuit #linearamplifier #opamp

    Properties

    OPA4391PWR

    Texas Instruments

    Integrated Circuits

    ti.com/lit/gpn/opa4391

    IC

    14-TSSOP

    parametric-v1

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