../../../../_images/servo.jpg

Source: SERV-03-MI (Micro Servo)

Servo RC PWM Control

Library to control RC servos with PWM signals.

Change History

This library was revised for Sming version 4.0. These are the main changes:

  • Interrupts remain enabled during updates

  • ServoChannel value now specifies actual pulse duration in microseconds, such that minValue <= value <= maxValue. Previously it was 0 <= value <= (maxValue - minValue).

  • Max channels increased to 5.

See Pull Request #1870 for further details.

Brief introduction

There are generally two types of servo actuator (digital and analogue) and this library supports only the analogue variety.

Servo actuators have a logic-level control signal to set the position using an active-high pulse of around 1 - 2 ms. This pulse must be repeated every 20ms or so to ensure the position is maintained

Servos are generally insensitive to the exact period provided it’s no more than about 25ms. It’s the duration of the pulse which is critical.

For most servos 1.5ms is the default/centre position, however the min/max values will vary between models depending on the exact type and range of motion. These values are therefore configurable for each channel.

Physical connection

Servos typically use a 5V logic-level input but are usually fine with the 3.3v output from the ESP8266.

Warning

Like relays a servo is an electro-mechanical device, but it also has integrated control circuitry so doesn’t require flyback diodes, etc. to protect from current spikes.

However, remember to always insert a protection resistor of at least 200 ohms between the GPIO and the servo. This limits the current to <10mA if 5V is present on the line. For 12V servos a 1K resistor will perform the same function.

Technical Explanation

Each servo actuator is connected to a GPIO pin, which is toggled by an ISR driven from the Hardware Timer. The ServoChannel class represents this connection, and defines the current value (in microseconds) plus the range (minimum and maximum values) to which the value is constrained.

The hardware timer interrupt is managed by a single instance of the Servo class. All channels are updated sequentially at the start of each frame period (20ms in duration):

The first channel is set ON, then after the required time it is set OFF and the next channel set ON. The final interrupt turns the active channel OFF. This requires (NumChannels + 1) interrupts per frame, and the process repeats continuously whilst there is at least one active channel.

Channel updates (via calls to ServoChannel::setValue()) are not handled immediately, but deferred using a 10ms software timer (half the frame period). This allows more efficient updating and ensures the positions of all affected servos are changed at the same time.

A double-buffering technique is used for updates to avoid disabling interrupts, which allows use of the non-maskable timer interrupts for best timing accuracy and eliminates glitches in the output.

Updates involve re-calculating the list of active pins and timer intervals, which is stored into a second frame buffer. This is made active by the ISR when the current frame has completed.

If the ISR hasn’t yet processed a previous update, it will be retried after a further 10ms.

References

Used by

SoC support

  • esp32

  • esp32c2

  • esp32c3

  • esp32s2

  • esp32s3

  • esp8266

  • host

  • rp2040

  • rp2350