2017-04-27 21:14:11 +02:00
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Klipper has several compelling features:
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2016-12-21 04:22:54 +01:00
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* High precision stepper movement. Klipper utilizes an application
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processor (such as a low-cost Raspberry Pi) when calculating printer
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movements. The application processor determines when to step each
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stepper motor, it compresses those events, transmits them to the
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micro-controller, and then the micro-controller executes each event
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2017-05-01 17:36:07 +02:00
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at the requested time. Each stepper event is scheduled with a
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2016-12-26 19:15:37 +01:00
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precision of 25 micro-seconds or better. The software does not use
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kinematic estimations (such as the Bresenham algorithm) - instead it
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calculates precise step times based on the physics of acceleration
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and the physics of the machine kinematics. More precise stepper
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movement translates to quieter and more stable printer operation.
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2016-12-21 04:22:54 +01:00
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* Best in class performance. Klipper is able to achieve high stepping
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rates on both new and old micro-controllers. Even an old 8bit AVR
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2017-04-11 19:53:33 +02:00
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micro-controller can obtain rates over 175K steps per second. On
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2017-09-27 19:59:47 +02:00
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more recent micro-controllers, rates over 500K steps per second are
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possible. Higher stepper rates enable higher print velocities. The
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stepper event timing remains precise even at high speeds which
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improves overall stability.
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2016-12-21 04:22:54 +01:00
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* Klipper supports printers with multiple micro-controllers. For
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example, one micro-controller could be used to control an extruder,
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while another controls the printer's heaters, while a third controls
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the rest of the printer. The Klipper host software implements clock
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synchronization to account for clock drift between
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micro-controllers. No special code is needed to enable multiple
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micro-controllers - it just requires a few extra lines in the config
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file.
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2016-12-21 04:22:54 +01:00
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* Configuration via simple config file. There's no need to reflash the
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micro-controller to change a setting. All of Klipper's configuration
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is stored in a standard config file which can be easily edited. This
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makes it easier to setup and maintain the hardware.
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2018-07-08 17:01:54 +02:00
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* Portable code. Klipper works on ARM, AVR, and PRU based
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micro-controllers. Existing "reprap" style printers can run Klipper
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without hardware modification - just add a Raspberry Pi. Klipper's
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internal code layout makes it easier to support other
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micro-controller architectures as well.
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* Simpler code. Klipper uses a very high level language (Python) for
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2017-04-27 21:14:11 +02:00
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most code. The kinematics algorithms, the G-code parsing, the
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heating and thermistor algorithms, etc. are all written in Python.
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This makes it easier to develop new functionality.
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2018-09-04 02:33:00 +02:00
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* Klipper uses an "iterative solver" to calculate precise step times
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from simple kinematic equations. This makes porting Klipper to new
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types of robots easier and it keeps timing precise even with complex
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kinematics (no "line segmentation" is needed).
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2016-12-21 04:22:54 +01:00
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2018-09-04 02:33:00 +02:00
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Additional features
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===================
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Klipper supports many standard 3d printer features:
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2018-09-04 02:33:00 +02:00
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* Klipper implements the "pressure advance" algorithm for extruders.
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When properly tuned, pressure advance reduces extruder ooze.
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2016-12-21 04:22:54 +01:00
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* Works with Octoprint. This allows the printer to be controlled using
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a regular web-browser. The same Raspberry Pi that runs Klipper can
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also run Octoprint.
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* Standard G-Code support. Common g-code commands that are produced by
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typical "slicers" are supported. One may continue to use Slic3r,
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Cura, etc. with Klipper.
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2018-09-04 02:33:00 +02:00
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* Support for multiple extruders. Extruders with shared heaters and
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extruders on independent carriages (IDEX) are also supported.
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* Support for cartesian, delta, and corexy style printers.
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* Automatic bed leveling support. Klipper can be configured for basic
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bed tilt detection or full mesh bed leveling. If the bed uses
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multiple Z steppers then Klipper can also level by independently
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manipulating the Z steppers. Most Z height probes are supported,
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including servo activated probes.
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2018-08-29 04:57:29 +02:00
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* Automatic delta calibration support. The calibration tool can
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perform basic height calibration as well as an enhanced X and Y
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dimension calibration. The calibration can be done with a Z height
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probe or via manual probing.
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* Support for common temperature sensors (eg, common thermistors,
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AD595, PT100, MAX6675, MAX31855, MAX31856, MAX31865). Custom
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thermistors and custom analog temperature sensors can also be
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configured.
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* Basic thermal heater protection enabled by default.
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* Support for standard fans, nozzle fans, and temperature controlled
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fans. No need to keep fans running when the printer is idle.
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2018-10-02 20:06:35 +02:00
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* Support for run-time configuration of TMC2130, TMC2208, TMC2224, and
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TMC2660 stepper motor drivers. There is also support for current
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control of traditional stepper drivers via AD5206 and MCP4451
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digipots.
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* Support for common LCD displays attached directly to the printer. A
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default menu is also available.
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* Constant acceleration and "look-ahead" support. All printer moves
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will gradually accelerate from standstill to cruising speed and then
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decelerate back to a standstill. The incoming stream of G-Code
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movement commands are queued and analyzed - the acceleration between
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2017-04-27 21:14:11 +02:00
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movements in a similar direction will be optimized to reduce print
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stalls and improve overall print time.
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2016-12-21 04:22:54 +01:00
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2018-09-04 02:33:00 +02:00
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* Klipper implements a "stepper phase endstop" algorithm that can
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improve the accuracy of typical endstop switches. When properly
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tuned it can improve a print's first layer bed adhesion.
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* Support for limiting the top speed of short "zigzag" moves to reduce
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printer vibration and noise. See the [kinematics](Kinematics.md)
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document for more information.
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* Sample configuration files are available for many common printers.
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Check the [config directory](../config/) for a list.
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To get started with Klipper, read the [installation](Installation.md)
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guide.
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Step Benchmarks
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===============
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Below are the results of stepper performance tests. The numbers shown
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represent total number of steps per second on the micro-controller.
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2018-07-08 17:01:54 +02:00
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| Micro-controller | Fastest step rate | 3 steppers active |
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| --------------------------- | ----------------- | ----------------- |
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| 16Mhz AVR | 151K | 100K |
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| 20Mhz AVR | 189K | 125K |
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2018-07-31 22:12:19 +02:00
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| Arduino Zero (ARM SAMD21) | 234K | 217K |
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2018-11-17 00:59:55 +01:00
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| STM32F103 | 333K | 300K |
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2018-10-13 17:57:13 +02:00
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| Arduino Due (ARM SAM3X8E) | 410K | 397K |
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2018-12-30 20:42:04 +01:00
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| SAM4S8C ARM | 455K | 455K |
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2018-10-18 15:44:30 +02:00
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| Smoothieboard (ARM LPC1768) | 487K | 487K |
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| Smoothieboard (ARM LPC1769) | 584K | 584K |
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2019-01-19 02:05:55 +01:00
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| SAMD51 ARM | 630K | 630K |
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2018-10-22 17:18:55 +02:00
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| SAM4E8E ARM | 638K | 638K |
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2018-11-17 00:59:55 +01:00
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| Beaglebone PRU | 680K | 680K |
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2017-08-11 17:40:54 +02:00
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On AVR platforms, the highest achievable step rate is with just one
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stepper stepping. On the STM32F103, Arduino Zero, and Due, the highest
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2018-09-04 02:33:00 +02:00
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step rate is with two simultaneous steppers stepping. On the PRU,
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2019-01-19 02:05:55 +01:00
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SAMD51, SAM4S8C, SAM4E8E, and LPC176x the highest step rate is with
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three simultaneous steppers.
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