SLAAE76C March   2023  – May 2025 MSPM0G1105 , MSPM0G1106 , MSPM0G1107 , MSPM0G1505 , MSPM0G1506 , MSPM0G1507 , MSPM0G3105 , MSPM0G3106 , MSPM0G3107 , MSPM0G3505 , MSPM0G3506 , MSPM0G3507

 

  1.   1
  2.   Abstract
  3.   Trademarks
  4. MSPM0G Hardware Design Check List
  5. Power Supplies in MSPM0G Devices
    1. 2.1 Digital Power Supply
    2. 2.2 Analog Power Supply
    3. 2.3 Built-in Power Supply and Voltage Reference
    4. 2.4 Recommended Decoupling Circuit for Power Supply
  6. Reset and Power Supply Supervisor
    1. 3.1 Digital Power Supply
    2. 3.2 Power Supply Supervisor
  7. Clock System
    1. 4.1 Internal Oscillators
    2. 4.2 External Oscillators
    3. 4.3 External Clock Output (CLK_OUT)
    4. 4.4 Frequency Clock Counter (FCC)
  8. Debugger
    1. 5.1 Debug port pins and Pinout
    2. 5.2 Debug Port Connection With Standard JTAG Connector
  9. Key Analog Peripherals
    1. 6.1 ADC Design Considerations
    2. 6.2 OPA Design Considerations
    3. 6.3 DAC Design Considerations
    4. 6.4 COMP Design Considerations
    5. 6.5 GPAMP Design Considerations
  10. Key Digital Peripherals
    1. 7.1 Timer Resources and Design Considerations
    2. 7.2 UART and LIN Resources and Design Considerations
    3. 7.3 MCAN Design Considerations
    4. 7.4 I2C and SPI Design Considerations
  11. GPIOs
    1. 8.1 GPIO Output Switching Speed and Load Capacitance
    2. 8.2 GPIO Current Sink and Source
    3. 8.3 High-Speed GPIOs (HSIO)
    4. 8.4 High-Drive GPIOs (HDIO)
    5. 8.5 Open-Drain GPIOs Enable 5V Communication Without a Level Shifter
    6. 8.6 Communicate With a 1.8V Device Without a Level Shifter
    7. 8.7 Unused Pins Connection
  12. Layout Guides
    1. 9.1 Power Supply Layout
    2. 9.2 Considerations for Ground Layout
    3. 9.3 Traces, Vias, and Other PCB Components
    4. 9.4 How to Select Board Layers and Recommended Stack-up
  13. 10Bootloader
    1. 10.1 Bootloader Introduction
    2. 10.2 Bootloader Hardware Design Considerations
      1. 10.2.1 Physical Communication interfaces
      2. 10.2.2 Hardware Invocation
  14. 11Summary
  15. 12References
  16. 13Revision History

6.2 OPA Design Considerations

The MSPM0G OPA is a zero-drift chopper stabilized operational amplifier with a programmable gain stage. The OPA can used for signal amplification and buffering and can work in general-purpose mode, buffer mode and PGA mode.

When using the OPA in general-purpose mode, add an external resistor and capacitor to create the amplifier circuit. The OPA can be configured through software for buffer mode. For PGA mode, software can configure the OPA up to 32x PGA gain.

Note: The PGA gain is only in the negative terminal.

When two or more OPAs are available on a device, the two can be combined to form a differential amplifier. The output equation for the differential amplifier is given by the Vdiff equation in Figure 6-2.

Two OPA Differential Amplifier Block Diagram and Equation Figure 6-2 Two OPA Differential Amplifier Block Diagram and Equation

Alternately, two or more OPAs that are available on a device can be combined to form a multistage or cascaded amplifier. Using the programmable input muxes, all combinations of inverting and non-inverting multistage amplifiers can be implemented. The output equation for the noninverting to noninverting cascaded amplifier is given by the Vout equation in Figure 6-3.

Two OPA Noninverting to Noninverting Cascade Amplifier Block Diagram and Equation Figure 6-3 Two OPA Noninverting to Noninverting Cascade Amplifier Block Diagram and Equation