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jStepper

A high performance stepper motor library for embedded systems.

jStepper is an Arduino style C++ library targeted for the Atmel ATMega CPU family but can be adapted wholly or in part to many other embedded systems.

There are simpler ways to control stepper motors such as the Arduino 'stepper' library or the popular AccelStepper library. However, my application required high performance and unique features that weren't available in other open-source projects.

FEATURES

🔷 Supports up to 3 stepper motors per instance of the library.

🔷 Multiple instances limited only to the number of available 16 bit timers.

🔷 High speed stepping up to 20,000 PPS on three concurrent motors.

🔷 Very slow step rates down to one step every 72 minutes.

🔷 Accurate step pulse timing with minimal timebase jitter.

🔷 Constant speed mode (square profile).

🔷 Real-time linear acceleration/deceleration (trapeziod & triangle profiles).

🔷 Synchronize option plans motors to arrive at the destination at the same time.

🔷 Plan-ahead feature eliminates overhead between motor movements.

🔷 Primitive functions for single stepping, direction, driver enable, & endstop detection.

🔷 Built-in homing function, interrupt driven (non-blocking).

🔷 Interrupt driven stepping and planning operates in the background (non-blocking).

🔷 Library manages I/O and interrupt redirection dynamically for multiple instances.

🔷 Supports relative and absolute positioning.

🔷 User programmed timer interrupt callback.

🔷 Fast I/O and math functions available to your program. See the jio.h & jsmath.h files.

🔷 Command complete callback relieves user program of constant monitoring.

HARDWARE

The general hardware model is an Arduino (or similar) ATMega board with a shield (daughter board) containing stepper driver modules. This is very similar to the popular RAMPS architecture. This library will also work with hybrids such as the Rambo and others.

The code generates STEP and DIRECTION signals in real time. The user supplies control pin and geometry information via a template structure. The I/O assignments are 'soft' and may be changed on the fly.

The library has been tested on the ATMega 2560 platform. It should also work on the ATMega 328 and other derivatives of Atmel CPU's. Additionally this library or some of its concepts can be ported to other embedded platforms.

NOTE: If the timer compare outputs are available in your hardware, these can be connected to the stepper drivers. This eliminates any timebase jitter caused by overlapping interrupt service routines.

EXAMPLES

Please see the examples folder.

INSTALLATION

  1. Download the latest library version from: https://github.com/johnny49r/jStepper as a .ZIP file. It will be named jStepper-master.ZIP.
  2. Place the ZIP file in the Arduino/libraries folder.
  3. Launch the Arduino IDE and goto Sketch→Include Library→Add .ZIP Library…
  4. Select the ZIP file in your Arduino/libraries folder. The IDE should create a folder called ‘jStepper-master’ and unpack all files in that folder. Your sketch should also contain a new directive ‘#include <jStepper.h>’. If not you will need to add it manually.
  5. The library can also be added manually by creating a new folder in your Arduino/libraries folder and extract the contents of the ZIP file into the new folder. Close the IDE and restart. You should now find the library is available to add to your sketch and you can add ‘#include <jStepper.h>’ to your sketch.

USAGE

You will need to initialize a structure (jsMotorConfig) and pass it to the library in the begin() function. Each instance of the library will need a different copy of the jsMotorConfig with different settings. Each copy of the jsMotorConfig will specify the timer it will use; 1, 3, 4, or 5. Once the structure has been passed to the library it is ready to accept commands.

NOTE: The library pre-allocates interrupt service routines for all available 16 bit timers. This means that you can't use the ISR(TIMERn_CMPn_vect) or it will conflict with the library. However you can add your own interrupt handler through the 'addTimerCallBack' function (see examples).

TODO

  • Documentation
  • Examples
  • Installation

DISCLAIMER

This code is functional and all features work but it is a work-in-progress. I welcome your suggestions for improvement and additional functionality. Enjoy!