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You can likely user an I/O pin as an output to "power" fairly high-impedance devices such as pullup resistors for buttons, or even potentiometers of moderate to high total resistance.

A reason you might wish to do so would to be able to stop the device from draining power while the entire system is in a low-power sleep mode, or to otherwise disable it beyond merely ignoring its input.

However, it's worth noting that powering an analog device such as a potentiometer from an I/O pin is likely to inject noise and full scale voltage uncertainty into the signal so derived, as the output voltage under load may be neither the same as the supply rail, not "quiet".

And, of course, you must not attempt to use an I/O pin to power lower-impedance (aka more "power hungry") loads via an output pin. Generally, active devices should not be powered in this way - especially ones such as radio transmitters, other microcontrollers or complex logic functions, ultrasonic transmitters, and definitely not motors, relays, or solenoids.

You can likely use an I/O pin as an output to "power" fairly high-impedance devices such as pullup resistors for buttons, or even potentiometers of moderate to high total resistance.

A reason you might wish to do so would to be able to stop the device from draining power while the entire system is in a low-power sleep mode, or to otherwise disable it beyond merely ignoring its input.

However, it's worth noting that powering an analog device such as a potentiometer from an I/O pin is likely to inject noise and full scale voltage uncertainty into the signal so derived, as the output voltage under load may be neither the same as the supply rail, not "quiet".

And, of course, you must not attempt to use an I/O pin to power lower-impedance (aka more "power hungry") loads via an output pin. Generally, active devices should not be powered in this way - especially ones such as radio transmitters, other microcontrollers or complex logic functions, ultrasonic transmitters, and definitely not motors, relays, or solenoids.

You can likely "power" fairly high-impedance devices via digital pins such as pullup resistors for buttons, or even potentiometers of moderate to high total resistance.

A reason you might wish to do so would to be able to stop the device from draining power while the entire system is in a low-power sleep mode, or to otherwise disable it beyond merely ignoring its input.

However, it's worth noting that powering an analog device such as a potentiometer from an I/O pin is likely to inject noise and voltage uncertainty noise into the signal so derived, as the output voltage under load may be neither the same as the supply rail, not "quiet".

And, of course, you must not attempt to power lower-impedance (aka more "power hungry") loads via an output pin. Generally, active devices should not be powered via digital pins - especially ones such as radio transmitters, other microcontrollers or complex logic functions, ultrasonic transmitters, and definitely not motors, relays, or solenoids.

You can likely user an I/O pin as an output to "power" fairly high-impedance devices such as pullup resistors for buttons, or even potentiometers of moderate to high total resistance.

A reason you might wish to do so would to be able to stop the device from draining power while the entire system is in a low-power sleep mode, or to otherwise disable it beyond merely ignoring its input.

However, it's worth noting that powering an analog device such as a potentiometer from an I/O pin is likely to inject noise and full scale voltage uncertainty into the signal so derived, as the output voltage under load may be neither the same as the supply rail, not "quiet".

And, of course, you must not attempt to use an I/O pin to power lower-impedance (aka more "power hungry") loads via an output pin. Generally, active devices should not be powered in this way - especially ones such as radio transmitters, other microcontrollers or complex logic functions, ultrasonic transmitters, and definitely not motors, relays, or solenoids.

You can likely "power" fairly high-impedance devices via digital pins such as pullup resistors for buttons, or even potentiometers of moderate to high total resistance.

A reason you might wish to do so would to be able to stop the device from draining power while the entire system is in a low-power sleep mode, or to otherwise disable it beyond merely ignoring its input.

However, it's worth noting that powering an analog device such as a potentiometer from an I/O pin is likely to inject noise and voltage uncertainty noise into the signal so derived, as the output voltage under load may be neither the same as the supply rail, not "quiet".

And of course you must not attempt to power lower-impedance (aka more "power hungry") loads via an output pin. Generally, active devices should not be powered via digital pins - especially ones such as radio transmitters, other microcontrollers or complex logic functions, ultrasonic transmitters, and definitely not motors, relays, or solenoids.

You can likely "power" fairly high-impedance devices via digital pins such as pullup resistors for buttons, or even potentiometers of moderate to high total resistance.

A reason you might wish to do so would to be able to stop the device from draining power while the entire system is in a low-power sleep mode, or to otherwise disable it beyond merely ignoring its input.

However, it's worth noting that powering an analog device such as a potentiometer from an I/O pin is likely to inject noise and voltage uncertainty noise into the signal so derived, as the output voltage under load may be neither the same as the supply rail, not "quiet".

And, of course, you must not attempt to power lower-impedance (aka more "power hungry") loads via an output pin. Generally, active devices should not be powered via digital pins - especially ones such as radio transmitters, other microcontrollers or complex logic functions, ultrasonic transmitters, and definitely not motors, relays, or solenoids.