Difference between revisions of "PWM Motor Controller Interface"
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| − | Now imagine that this 1Hz signal is changed to | + | Now imagine that this 1Hz signal is changed to 1000 Hz. You will no longer hear the motor turn on just for 1/10th of a second. The motor will instead produce a high frequency noise as it is being switched on and off at a very fast rate. This will yield very smooth operation of the motor and hence you can control digitally. |
== PWM for LPC17xx == | == PWM for LPC17xx == | ||
Revision as of 22:28, 20 November 2012
What is PWM
PWM stands for Pulse Width Modulation. A signal duty cycle is controlled to produce the pulse width.
Application
The application of a PWM is usually in motor controls. If a motor is attached to your PWM signal, you could control the motor's speed using the PWM. Imagine that the PWM you produce lasts for one second (1 Hz). Now, imagine that the PWM is high 10% of the time and LOW 90% of the time. What you will end up doing is turning on the motor only 1/10th of a second, hence controlling the motor speed.
Example PWM that is ~ 25% HIGH, 75% LOW
__ __ __
| | | | | |
___| |________| |________| |_________
Example PWM that is ~ 90% HIGH, 10% LOW
_________ _________ _________
| | | | |
___| |_| |_|
Now imagine that this 1Hz signal is changed to 1000 Hz. You will no longer hear the motor turn on just for 1/10th of a second. The motor will instead produce a high frequency noise as it is being switched on and off at a very fast rate. This will yield very smooth operation of the motor and hence you can control digitally.
PWM for LPC17xx
TO DO
Motor Wiring Example
TO DO
