G-code

This page tries to describe the flavour of G-codes that the RepRap firmwares use and how they work. The main target is additive fabrication using FFF processes. Codes for print head movements follow the NIST RS274NGC G-code standard, so RepRap firmwares are quite usable for CNC milling and similar applications as well. See also on Wikipedia's G-code article.

There are a few different ways to prepare GCode for a printer. One method would be to use a slicing program such as Slic3r, Skeinforge or Cura. These programs import a CAD model, slice it into layers, and output the GCode required to print each layer. Slicers are the easiest way to go from a 3D model to a printed part, however the user sacrifices some flexibility when using them. Another option for GCode generation is to use a lower level library like mecode. Libraries like mecode give you precise control over the tool path, and thus are useful if you have a complex print that is not suitable for naive slicing. The final option is to just write the GCode yourself. This may be the best choice if you just need to run a few test lines while calibrating your printer.

As many different firmwares exist and their developers tend to implement new features without discussing strategies or looking what others did before them, a lot of different sub-flavours for the 3D-Printer specific codes developed over the years. This particular page is the master page for RepRap. Nowhere in here should the same code be used for two different things; there are always more numbers to use... The rule is: add your new code here, then implement it.

Unfortunately human nature being what it is, the best procedures aren't always followed, so some multiple uses of the same code exist. The rule which should be followed is that later appearances of a code on this page (later than the original use of a code), are deprecated and should be changed, unless there is a good technical reason (like the general G-Code standard) why a later instance should be preferred. Note that the key date is appearance here, not date of implementation.

Introduction

A typical piece of Gcode as sent to a RepRap machine might look like this:

N3 T0*57
N4 G92 E0*67
N5 G28*22
N6 G1 F1500.0*82
N7 G1 X2.0 Y2.0 F3000.0*85
N8 G1 X3.0 Y3.0*33

Gcode can also be stored in files on SD cards. A file containing RepRap Gcode usually has the extension .g, .gco or .gcode. Files for BFB/RapMan have the extension .bfb. Gcode stored in file or produced by a slicer might look like this:

G92 E0
G28
G1 F1500
G1 X2.0 Y2.0 F3000
G1 X3.0 Y3.0

The meaning of all those symbols and numbers (and more) is explained below.

Slicers will (optionally?) add GCode scripts to the beginning and end of their output file to perform specified actions before and/or after a print such as z-probing the build-area, heating/cooling the bed and hotend, performing ooze free "nozzle wipe" startup routine, switching system power on/off, and even "ejecting" parts. More info on the Start GCode routines and End GCode routines pages.

To find out which specific Gcode(s) are implemented in any given firmware, there are little tables attached to the command descriptions, like this one:

Here means:

{{yes}}

The Gcode is fully supported by the firmware.

{{partial}} or {{experimental}}

There is some support for the Gcode. Often it is required to check out the source code branch for the firmware (usually stored in a different branch) or to flip configuration switches on the mainboard.

automatic

The firmware handles this Gcode automatically, so there's no need to send the command. An example is power supply on/off Gcode (M80/M81) in the Teacup firmware.

???

It is unknown if the firmware supports this Gcode. You may want to test this yourself before using it in production.

{{no}}

The firmware does not support this Gcode.

deprecated

The firmware deprecated this Gcode. The firmware author(s) should amend the deprecated Gcode on this page with workarounds (if needed) and the last supported firmware version that will accept this Gcode.

For the technically minded, Gcode line endings are Unix Line Endings (\n), but will accept Windows Line Endings (\r\n), so you should not need to worry about converting between the two, but it is best practice to use Unix Line Endings where possible.

Fields

A RepRap Gcode is a list of fields that are separated by white spaces or line breaks. A field can be interpreted as a command, parameter, or for any other special purpose. It consists of one letter directly followed by a number, or can be only a stand-alone letter (Flag). The letter gives information about the meaning of the field (see the list below in this section). Numbers can be integers (128) or fractional numbers (12.42), depending on context. For example, an X coordinate can take integers (X175) or fractionals (X17.62), but selecting extruder number 2.76 would make no sense. In this description, the numbers in the fields are represented by nnn as a placeholder.

In RepRapFirmware, some parameters can be followed by more than one number, with colon used to separate them. Typically this is used to specify extruder parameters, with one value provided per extruder. If only one value is provided where a value is needed for each extruder, then that value is applied to all extruders.

Letter	Meaning
Gnnn	Standard GCode command, such as move to a point
Mnnn	RepRap-defined command, such as turn on a cooling fan
Tnnn	Select tool nnn. In RepRap, a tool is typically associated with a nozzle, which may be fed by one or more extruders.
Snnn	Command parameter, such as time in seconds; temperatures; voltage to send to a motor
Pnnn	Command parameter, such as time in milliseconds; proportional (Kp) in PID Tuning
Xnnn	A X coordinate, usually to move to. This can be an Integer or Fractional number.
Ynnn	A Y coordinate, usually to move to. This can be an Integer or Fractional number.
Znnn	A Z coordinate, usually to move to. This can be an Integer or Fractional number.
U,V,W	Additional axis coordinates (RepRapFirmware)
Innn	Parameter - X-offset in arc move; integral (Ki) in PID Tuning
Jnnn	Parameter - Y-offset in arc move
Dnnn	Parameter - used for diameter; derivative (Kd) in PID Tuning
Hnnn	Parameter - used for heater number in PID Tuning
Fnnn	Feedrate in mm per minute. (Speed of print head movement)
Rnnn	Parameter - used for temperatures
Qnnn	Parameter - not currently used
Ennn	Length of extrudate. This is exactly like X, Y and Z, but for the length of filament to consume.
Nnnn	Line number. Used to request repeat transmission in the case of communications errors.
*nnn	Checksum. Used to check for communications errors.

Case sensitivity

The original NIST GCode standard requires gcode interpreters to be case-insensitive, except for characters in comments. However, not all 3D printer firmwares conform to this and some recognise uppercase command letters and parameters only.

Firmwares that are known to be case-insensitive

RepRapFirmware version 1.19 and later (except within quoted strings)

Firmwares that are known to be case-sensitive

RepRapFirmware version 1.18 and earlier

Quoted strings

In RepRapFirmware, some commands support quoted strings when providing file names and other string parameters. This allows file names, WiFi passwords etc. to contain spaces, semicolons and other characters that would otherwise not be permitted. Double-quote characters are used to delimit the string, and any double-quote character within the string must be repeated.

Unfortunately, many gcode sender programs convert all characters to uppercase and don't provide any means to disable this feature. Therefore, within a quoted-string, the single-quote character is used as a flag to force the following character to lowercase. If you want to include a single quote character in the string, use two single quote characters to represent one single quote character.

Example: to add SSID MYROUTER with password ABCxyz;" 123 to the WiFi network list, use command:

M587 S"MYROUTER" P"ABCxyz;"" 123"

or if you can't send lowercase characters:

M587 S"MYROUTER" P"ABC'X'Y'Z;"" 123"

Comments

Gcode comments begin at a semicolon, and end at the end of the line:

N3 T0*57 ; This is a comment
N4 G92 E0*67
; So is this
N5 G28*22

Some firmwares also obey the CNC GCode standard, which is to enclose comments in round brackets. Comments of this form must start and end on the same line:

(Home some axes)
G28 (here come the axes to be homed) X Y

Comments and white space will be ignored by your RepRap Printer. It's better to strip these out on the host computer before sending the Gcode to your printer, as this saves bandwidth.

Special fields

N: Line number

Example

N123

If present, the line number should be the first field in a line. For G-code stored in files on SD cards the line number is usually omitted.

If checking is supported, the RepRap firmware expects line numbers to increase by 1 each line, and if that doesn't happen it is flagged as an error. But you can reset the count using M110 (see below).

Although supported, usage of N in Machinekit is discouraged as it serves no purpose.

*: Checksum

Example: *71

If present, the checksum should be the last field in a line, but before a comment. For G-code stored in files on SD cards the checksum is usually omitted.

The firmware compares the checksum against a locally-computed value. If they differ, it requests a repeat transmission of the line.

Checking

Example

N123 [...G Code in here...] *71

The RepRap firmware checks the line number and the checksum. You can leave both of these out - RepRap will still work, but it won't do checking. You have to have both or neither though. If only one appears, it produces an error.

The checksum "cs" for a GCode string "cmd" (including its line number) is computed by exor-ing the bytes in the string up to and not including the * character as follows:

int cs = 0;
for(i = 0; cmd[i] != '*' && cmd[i] != NULL; i++)
   cs = cs ^ cmd[i];
cs &= 0xff;  // Defensive programming...

and the value is appended as a decimal integer to the command after the * character.

Buffering

If buffering is supported, the RepRap firmware stores some commands in a ring buffer internally for execution. This means that there is no (appreciable) delay while a command is acknowledged and the next transmitted. In turn, this means that sequences of line segments can be plotted without a dwell between one and the next. As soon as one of these buffered commands is received it is acknowledged and stored locally. If the local buffer is full, then the acknowledgment is delayed until space for storage in the buffer is available. This is how flow control is achieved.

Typically, the following moving commands are buffered: G0-G3 and G28-G32. The Teacup Firmware buffers also some setting commands: G20, G21, G90 and G91. All other G, M or T commands are not buffered.

RepRapFirmware also implements an internal queue to ensure that certain codes (like M106) are executed in the right order and not when the last move has been added to the look-ahead queue.

When an unbuffered command is received it is stored, but it is not acknowledged to the host until the buffer is exhausted and then the command has been executed. Thus the host will pause at one of these commands until it has been done. Short pauses between these commands and any that might follow them do not affect the performance of the machine.

G-commands

G0 & G1: Move

• G0 : Rapid linear Move
• G1 : Linear Move

Usage

G0 Xnnn Ynnn Znnn Ennn Fnnn Snnn

G1 Xnnn Ynnn Znnn Ennn Fnnn Snnn

Parameters

Not all parameters need to be used, but at least one has to be used

Xnnn The position to move to on the X axis

Ynnn The position to move to on the Y axis

Znnn The position to move to on the Z axis

Ennn The amount to extrude between the starting point and ending point

Fnnn The feedrate per minute of the move between the starting point and ending point (if supplied)

Snnn Flag to check if an endstop was hit (S1 to check, S0 to ignore, S2 see note, default is S0)¹

Examples

G0 X12               ; move to 12mm on the X axis
G0 F1500             ; Set the feedrate to 1500mm/minute
G1 X90.6 Y13.8 E22.4 ; Move to 90.6mm on the X axis and 13.8mm on the Y axis while extruding 22.4mm of material

The RepRap firmware spec treats G0 and G1 as the same command, since it's just as efficient as not doing so.²

Most RepRap firmwares do subtle things with feedrates.

G1 F1500           ; Set feedrate to 1500mm/m
G1 X50 Y25.3 E22.4 ; Move and extrude

In the above example, we first set the feedrate to 1500mm/m, then move to 50mm on X and 25.3mm on Y while extruding 22.4mm of filament between the two points.

G1 F1500                 ; Feedrate 1500mm/m
G1 X50 Y25.3 E22.4 F3000 ; Accelerate to 3000mm/m

However, in the above example, we set a feedrate of 1500 mm/m, then do the same move, but accelerating to 3000 mm/m. Everything stays synchronized, so extrusion accelerates right along with X and Y movement.

The RepRap spec treats the feedrate as simply another variable (like X, Y, Z, and E) to be linearly interpolated. This gives complete control over the acceleration and deceleration of the printer head in a way that ensures everything moves smoothly together and the right volume of material is extruded at all points.³

To reverse the extruder by a given amount (for example to reduce its internal pressure while it does an in-air movement so that it doesn't dribble) simply use G0 or G1 to send an E value that is less than the currently extruded length.

Notes

¹Some firmwares allow for the RepRap to enable or disable the "sensing" of endstops during a move. Please check with whatever firmware you are using to see if they support the S parameter in this way, as damage may occur if you assume incorrectly. In RepRapFirmware, using the S1 or S2 parameter on a delta printer causes the XYZ parameters to refer to the individual tower motor positions instead of the head position, and to enable endstop detection as well if the parameter is S1.

²In the RS274NGC Spec, G0 is Rapid Move, which was used to move between the current point in space and the new point as quickly and efficiently as possible, and G1 is Controlled Move, which was used to move between the current point in space and the new point as precise as possible.

³Some firmwares may not support setting the feedrate inline with a move.

⁴RepRapFirmware provides an additional 'R1' parameter to tell the machine to go back to the coordinates a print was previously paused at. If this parameter is used and the code contains axis letters, an offset will be added to the pause coordinates (e.g. G1 R1 Z5).

Some older machines, CNC or otherwise, used to move faster if they did not move in a straight line. This is also true for some non-Cartesian printers, like delta or polar printers, which move easier and faster in a curve.

G2 & G3: Controlled Arc Move

Usage

G2 Xnnn Ynnn Innn Jnnn Ennn Fnnn (Clockwise Arc)

G3 Xnnn Ynnn Innn Jnnn Ennn Fnnn (Counter-Clockwise Arc)

Parameters

Xnnn The position to move to on the X axis

Ynnn The position to move to on the Y axis

Innn The point in X space from the current X position to maintain a constant distance from

Jnnn The point in Y space from the current Y position to maintain a constant distance from

Ennn The amount to extrude between the starting point and ending point

Fnnn The feedrate per minute of the move between the starting point and ending point (if supplied)

Examples

G2 X90.6 Y13.8 I5 J10 E22.4

(Move in a Clockwise arc from the current point to point (X=90.6,Y=13.8), with a center point at (X=current_X+5, Y=current_Y+10), extruding 22.4mm of material between starting and stopping)

G3 X90.6 Y13.8 I5 J10 E22.4

(Move in a Counter-Clockwise arc from the current point to point (X=90.6,Y=13.8), with a center point at (X=current_X+5, Y=current_Y+10), extruding 22.4mm of material between starting and stopping)

Notes

¹In Marlin Firmware not implemented for DELTA and SCARA printers.

G4: Dwell

Pause the machine for a period of time.

Parameters

Pnnn Time to wait, in milliseconds (In Teacup, P0, wait until all previous moves are finished)

Snnn Time to wait, in seconds (Only on Repetier, Marlin, Smoothieware, and RepRapFirmware 1.16 and later)

Example

G4 P200

In this case sit still doing nothing for 200 milliseconds. During delays the state of the machine (for example the temperatures of its extruders) will still be preserved and controlled.

On Marlin, Smoothie and RepRapFirmware, the "S" parameter will wait for seconds, while the "P" parameter will wait for milliseconds. "G4 S2" and "G4 P2000" are equivalent.

G6: Direct Stepper Move

Perform a direct, uninterpolated, and non-kinematic synchronized move of one or more steppers directly. Units may be linear (e.g., mm or inches on DELTA) or specified in degrees (SCARA). This command is useful for initialization, diagnostics, and calibration, and should be disabled on production equipment. This type of move can be potentially dangerous, especially for deltabots, so implementations should do their best to limit movement to prevent twerking and damaging the carriage assembly.

Parameters

Annn Stepper A position or angle

Bnnn Stepper B position or angle

Cnnn Stepper C position or angle

R Relative move flag

SCARA Examples

G6 A45     ; Move SCARA A stepper to the 45° position
G6 B20 R   ; Move SCARA B stepper 20° counter-clockwise

DELTA Example

G6 C10 R   ; Move DELTA C carriage up by 10mm

G10: Tool Offset

Usage

G10 Pnnn Xnnn Ynnn Znnn Rnnn Snnn¹

Parameters

Pnnn Tool number

Xnnn X offset

Ynnn Y offset

U,V,Wnnn U, V and W axis offsets⁵

Znnn Z offset²

Rnnn Standby temperature(s)

Snnn Active temperature(s)

Examples

G10 P2 X17.8 Y-19.3 Z0.0

(sets the offset for tool (or in older implementations extrude head) 2 to the X, Y, and Z values specified)

G10 P1 R140 S205

(set standby and active temperatures³ for tool 1)

Remember that any parameter that you don't specify will automatically be set to the last value for that parameter. That usually means that you want explicitly to set Z0.0. RepRapFirmware will report the tool parameters if only the tool number is specified.

The precise meaning of the X, Y (and other offset) values is: with no offset this tool is at this position relative to where a tool with offset (0, 0, 0) would be. So if the tool is 10mm to the left of a zero-offset tool the X value would be -10, and so on.

The R value is the standby temperature in ^oC that will be used for the tool, and the S value is its operating temperature. If you don't want the tool to be at a different temperature when not in use, set both values the same. See the T code (select tool) below. In tools with multiple heaters the temperatures for them all are specified thus: R100.0:90.0:20.0 S185.0:200.0:150.0 .

See also M585.

Notes

¹Marlin uses G10/G11 for executing a retraction/unretraction move. The RepRapPro version of Marlin supports G10 for tool offset. Smoothie uses G10 for retract and G10 Ln for setting workspace coordinates.

²It's usually a bad idea to put a non-zero Z value in as well unless the tools are loaded and unloaded by some sort of tool changer or are on indepedent carriages. When all the tools are in the machine at once they should all be set to the same Z height.

³If the absolute zero temperature (-273.15) is passed as active and standby temperatures, RepRapFirmware will only switch off the tool heater(s) without changing their preset active or standby temperatures. RepRapFirmware-dc42 does not support this setting.

⁴The NIST G-code standard mentions an additional L parameter, which is ignored (except in smoothie). This command is subject to discussion.

⁵Tool offsets are applied after any X axis mapping has been performed. Therefore if for example you map X to U in your M563 command to create the tool, you should specify a U offset not an X offset. If you map X to both X and U, you can specify both offsets.

G10: Retract

Parameters

Snnn retract length (S1 = long retract, S0 = short retract = default) (Repetier only)

Example

G10

Retracts filament according to settings of M207 (Marlin, RepRapFirmware) or according to the S value (Repetier).

RepRapFirmware recognizes G10 as a command to set tool offsets and/or temperatures if the P parameter is present, and as a retraction command if it is absent.

G11: Unretract

Parameters

Snnn retract length (S1 = long retract, S0 = short retract = default) (Repetier only)

Example

G11

Unretracts/recovers filament according to settings of M208 (Marlin, RepRapFirmware) or according to the S value (Repetier).

G12: Clean Tool

Usage

[P<0|1>] [S<count>] [T<count>]

G12 Pnnn Snnn Tnnn

Parameters

Pnnn¹ Pattern style selection

Snnn Number of strokes (i.e. back-and-forth movements)

Tnnn Number of repetitions

Examples

G12 ; stroke pattern (default)

To generate a three triangle zig-zag pattern which will be stroked three times time use the following command. G12 P1 S3 T2 ; zig-zag pattern with 2 triangles

Notes

¹In Marlin firmware and Derivatives Mk4duo this is implemented by hard-coded firmware behaviours As defined for variables NOZZLE_CLEAN_STROKES, NOZZLE_CLEAN_START_POINT, NOZZLE_CLEAN_END_POINT and NOZZLE_CLEAN_PARK.

With NOZZLE_CLEAN_PARK enabled, the nozzle will automatically return to the XYZ position after G12 is run.

More on this behaviour is documented inside of the code base.

G17..19: Plane Selection (CNC specific)

These codes set the current plane as follows:

• G17 : XY (default)
• G18 : ZX
• G19 : YZ

This mode applies to G2/G3 arc moves. Normal arc moves are in the XY plane, and for most applications that's all you need. For CNC routing it can be useful to do small "digging" moves while making cuts, so to keep the G-code compact it uses G2/G3 arcs involving the Z plane.

These commands are supported in Marlin 1.1.4 and later with ARC_SUPPORT and CNC_WORKSPACE_PLANES enabled.

G20: Set Units to Inches

Example

G20

Units from now on are in inches.

G21: Set Units to Millimeters

Example

G21

Units from now on are in millimeters. (This is the RepRap default.)

G22 & G23: Firmware controlled Retract/Precharge

Usage

G22 ; Retract

G23 ; Unretract/Precharge

Relying on machine's firmware to execute extrusion retract/precharge move, instead of having slicer generating to E axis G1 movement. The retract/precharge length, velocity is handled by the machine firmware.

G26: Mesh Validation Pattern

Usage

G26 C P O2.25 ; Do a typical test sequence

The G26 Mesh Validation Pattern is designed to be used in conjunction with various Mesh Bed Leveling systems – those that adjust for an uneven —rather than just tilted— bed. The G26 command prints a single layer pattern over the entire print bed, giving a clear indication of how accurately every mesh point is defined. G26 can be used to determine which areas of the mesh are less-than-perfect and how much to adjust each mesh point.

G26 has large feature list, including a built-in test that extrudes material onto the bed. By default this is configured for PLA temperatures and a nozzle size of 0.4mm. (This will be adjustable in an upcoming version of Marlin.)

See the G26_Mesh_Validation_Tool.cpp file in the Marlin source code for full documentation of the G26 parameter list.

G28: Move to Origin (Home)

Parameters

This command can be used without any additional parameters.

X Flag to go back to the X axis origin

Y Flag to go back to the Y axis origin

Z Flag to go back to the Z axis origin

Examples

G28     ; Home all axes
G28 X Z ; Home the X and Z axes

When the firmware receives this command, it quickly moves the specified axes (or all axes if none are given) to the endstops, backs away from each endstop by a short distance, and slowly bumps the endstop again to increase positional accuracy. This process, known as "Homing", is required to determine the position of the print carriage(s). Some firmware may even forbid movement away from endstops and other operations until the axes have been homed.

The X, Y, and Z parameters act only as flags. Any coordinates given are ignored. For example, G28 Z10 results in the same behavior as G28 Z. Delta printers cannot home individual axes, but must always home all three towers, so the X Y Z parameters are simply ignored on these machines.

Marlin firmware (version 1.1.0 and later) provides an option called Z_SAFE_HOMING for printers that use a Z probe to home Z instead of an endstop. With this option, the XY axes are homed first, then the carriage moves to a position –usually the middle of the bed– where it can safely probe downward to home Z.

RepRapFirmware uses macro files to home either all axes or individual axes. If all axes are homed, the file homeall.g is processed. For individual axes the homex.g, homey.g, or homez.g file will be used. On Delta printers, G28 command will always home all three towers by processing the homedelta.g file, regardless of any X Y Z parameters.

Because the behavior of G28 is unspecified, it is recommended not to automatically include G28 in your ending GCode. On a Cartesian this will result in damaging the printed object. If you need to move the carriage at the completion of a print, use G0 or G1.

Notes

¹ MK4duo has a B parameter that tells the printer to return to the coordinates it was at before homing.

G29: Detailed Z-Probe

This command uses a probe to measure the bed height at 3 or more points to determine its tilt and overall flatness. It then enables compensation so that the nozzle will remain parallel to the bed. The printer must be homed with G28 before using this command.

Each firmware behaves differently and depends on the type of bed leveling that's been configured. For example, Marlin 1.0.2 provides 3 different types of automatic bed leveling (probe required) and a manual bed leveling option. See your firmware's documentation for the specific options available.

Usage

G29

G29 Snnn

Parameters

Snnn Firmware-dependent behavior

Pfile.csv Optional file name for bed height map file (RepRapFirmware only)

Examples

G29    ; Probe the bed and enable compensation
G29 S2 ; Special operation - see below
G29 P1 ; UBL automated probe - see below

G29 Auto Bed Leveling (Marlin)

Marlin 1.0.2 and earlier provides three options for automatic bed leveling:

• The 3-point method probes the bed at three points to produce a matrix, adjusting for a flat but tilted bed.
• The planar grid method (non-Delta) probes a grid pattern to produce a matrix by the "least-squares" method, adjusting for a flat but tilted bed.
• The bilinear grid method (Delta only) probes a grid pattern to produce a mesh, using bilinear interpolation to adjust for an uneven bed.

Marlin 1.1.0 and later allows the bilinear grid (i.e., "mesh") method to be used on all types of machines, not just deltas. This is the recommended leveling method going forward.

Also in Marlin 1.1.0 and later, the PROBE_MANUALLY option allows all forms of Auto Bed Leveling to be used without a probe. The procedure is similar to that of MESH_BED_LEVELING (see below). Begin the process with G29 to move the nozzle to the first point. Adjust the Z axis using G1 or your host software. Send G29 again to move to the next point and repeat until all points have been sampled.

Parameters

P Set the size of the grid that will be probed (P x P points). Not supported by non-linear delta printer bed leveling. Example: G29 P4

S Set the XY travel speed between probe points (in units/min)

D Dry-Run mode. Just evaluate the bed Topology - Don't apply or clean the rotation Matrix. Useful to check the topology after a first run of G29.

V Set the verbose level (0-4). Example: G29 V3

T Generate a Bed Topology Report. Example: G29 P5 T for a detailed report. This is useful for manual bed leveling and finding flaws in the bed (to assist with part placement). Not supported by non-linear delta printer bed leveling.

F Set the Front limit of the probing grid

B Set the Back limit of the probing grid

L Set the Left limit of the probing grid

R Set the Right limit of the probing grid

Global Parameters

E By default G29 will engage the Z probe, test the bed, then disengage. Include E or E1 to engage/disengage the Z probe for each sample. (This has no effect for fixed probes.)

G29 Unified Bed Leveling (Marlin)

Marlin firmware (version 1.1.0 and later) includes the AUTO_BED_LEVELING_UBL option for Unified Bed Leveling. UBL combines mesh leveling, tilted plane adjustment, 3-point leveling, and manual editing tools all together in a single package. To accomplish so much, UBL overloads `G29` with several new parameters and provides an additional G26 Mesh Tuning feature.

See the MarlinFW website for a dedicated Unified Bed Leveling page and complete documentation on `G29` for UBL and `G26` Mesh Validation.

G29 UBL Parameters (synopsis)

A     Activate   Activate the Unified Bed Leveling system. (i.e., M420 S1)
D     Disable    Disable the Unified Bed Leveling system. (i.e., M420 S0)

B#    Business   Do Manual Probing in 'Business Card' mode.
H#    Height     Height to raise the nozzle after each Manual Probe of the bed.

C     Continue   Continue, Constant, or Current Location, depending on Phase.
E     Every      Stow the probe after every sampled point.
F#    Fade       Fade leveling compensation gradually, until it ceases at the given height.
I#    Invalidate Invalidate a specified number of Mesh Points (X and Y).
J#    Grid       Do a grid (planar) leveling of the current Mesh using a grid with n points on a side.
K#    Kompare    Compare (diff) current Mesh with stored Mesh #, replacing current Mesh with the result.

L     Load       Load Mesh from the previously activated location in the EEPROM.
L#    Load       Load Mesh from the specified location in the EEPROM.
S     Store      Store the current Mesh in the Activated area of the EEPROM. Also save all settings.
S #   Store      Store the current Mesh at the specified area in EEPROM, set as the Activated area.
S -1  Store      Store the current Mesh as a print-out suitable to be fed back into the system.

O     Map        Display the Mesh Map Topology.

P0    Phase 0    Zero Mesh Data and turn off the Mesh Compensation System.
P1    Phase 1    Invalidate the Mesh and do Automatic Probing to generate new Mesh data.
P2    Phase 2    Probe unpopulated areas of the Mesh (those that couldn't be auto-probed).
P3    Phase 3    Fill unpopulated Mesh points with a fixed value. No 'C' for "smart fill" extrapolation.
P4    Phase 4    Fine tune the Mesh. ** Delta Mesh Compensation requires an LCD panel. **
P5    Phase 5    Find Mean Mesh Height and Standard Deviation.
P6    Phase 6    Shift Mesh height. All Mesh points are adjusted by the amount specified with 'C'.

Q     Test       Load specified Test Pattern to help check system operation.

R #   Repeat     Repeat the command the specified number of times. Default: grid points X * Y.

T     3-Point    Perform a 3-Point Bed Leveling on the current Mesh.

U     Unlevel    Perform a probe of the outer perimeter to assist in physically leveling the bed.

W     What?      Print a report of Unified Bed Leveling stored data.

X #              The X location for the command
Y #              The Y location for the command

Z     Zero       Do a single probe to set the Z Height of the nozzle.
Z #   Zero       Raise/lower the entire Mesh to conform with the specified difference (plus zprobe_zoffset).

G29 Manual Bed Leveling (Marlin)

Marlin firmware (version 1.0.2 and later) also provides a MESH_BED_LEVELING feature that can be used to perform bed leveling on machines lacking a probe. This form of bed leveling compensates for uneven Z height across the surface of the bed using a mesh and bilinear interpolation.

Manual Bed Leveling Usage

G29 S1 ; Move to the first point and wait for a measurement
G29 S2 ; Store the current Z, move to the next point
G29 S3 Xn Yn Zn.nn ; Modify the Z height of a single point

Options for the S parameter

S0 Produces a mesh report

S1 Start probing mesh points

S2 Probe the next mesh point

S3 Xn Yn Zn.nn Manually modify a single point

S4 Zn.nn Set z offset. Positive away from bed, negative closer to bed.

G29 Auto Bed Leveling (Repetier-Firmware)

Repetier firmware since v0.91 supports G29 with the optional Snnn parameter as described below. Useful to simply detect the Z bed angle so you can manually readjust your bed and get it as close to in plane as possible. If you wish to apply automatic software Z plane compensation on Repetier, use G32 instead with firmware 0.92.8 and above.

S0 Default value. Z bed heights are calculated at the measured points, relative to current Z position before issuing G29.

S1 Same as S0, except printer immediately moves to Z maximum position (Z max endstop required!), and calculates new Z maximum height. You must first issue G28 Z to home to Z maximum position before issuing G29 Snnn for this to work correctly, or the printer height will be invalid.

S2 Same as S1, except new calculated Z height is also stored to EEPROM.

G29 Auto Bed Leveling (RepRapFirmware)

RepRapFirmware:

S0 (default if no S parameter) Probe the bed, save the height map in a file on the SD card, and activate bed compensation. The default folder for the height map file is /sys and the default file name is heightmap.csv.

S1 Load the height map from file and activate bed compensation. The default folder and filename as for S0.

S2 Clear bed height map

To define the grid, see M557.

G29.1: Set Z probe head offset

Example

G29.1 X30 Y20 Z0.5

Set the offset of the Z probe head. The offset will be subtracted from all probe moves.

G29.2: Set Z probe head offset calculated from toolhead position

Example

G29.2 Z0.0

Set the offset of the Z probe head. The offset will be subtracted from all probe moves. The calculated value is derived from the distance of the toolhead from the current axis zero point.

The user would typically place the toolhead at the zero point of the axis and issue the G29.2 command.

G30: Single Z-Probe

Usage

G30 Pnnn Xnnn Ynnn Znnn Hnnn Snnn

Parameters

Pnnn Probe point number

Xnnn X coordinate

Ynnn Y coordinate

Znnn Z coordinate

Hnnn Height correction

Snnn Set parameter

Example

G30

Examples (RepRapFirmware)

G30                          ; Probe the bed at the current XY position. When the probe is triggered, set the Z coordinate to the probe trigger height.
G30 S-1                      ; Probe the bed at the current XY position. When the probe is triggered, do not adjust the Z coordinate.
G30 P0 X20 Y50 Z-99999       ; Probe the bed at X20 Y50 and save the XY coordinates and the height error as point 0
G30 P3 X180 Y180 Z-99999 S4  ; Probe the bed at X180 Y180, save the XY coordinates and the height error as point 3 and calculate 4-point compensation or calibration
G30 P3 X180 Y180 Z-99999 S-1 ; As previous example but just report the height errors

In its simplest form probes bed at current XY location.

RepRapFirmware supports additional behaviour: if a Pn field is specified the probed X, Y, and Z values are saved as point n on the bed for calculating the offset plane or for performing delta printer calibration. If X, Y, or Z values are specified (e.g. G30 P1 X20 Y50 Z0.3) then those values are used instead of the machine's current coordinates. A silly Z value (less than -9999.0) causes the machine to probe at the current point to get Z, rather than using the given value. If an S field is specified (e.g. G30 P1 Z0.3 S) the bed plane is computed for compensation and stored. The combination of these options allows for the machine to be moved to points using G1 commands, and then probe the bed, or for the user to position the nozzle interactively and use those coordinates. The user can also record those values and place them in a setup GCode file for automatic execution.

RepRapFirmware uses the value of the S parameter to specify what computation to perform. If the value is -1 then the Z offsets of all the points probed are printed, but no calibration is done. If the value is zero or not present, then this specifies that the number of factors to be calibrated is the same as the number of points probed. Otherwise, the value indicates the number of factors to be calibrated, which must be no greater than the number of points probed. In version 1.09, the number of factors may be 3, 4 or 5 when doing auto bed compensation on a Cartesian or CoreXY printer, and 3, 4, 6 or 7 when doing auto calibration of a Delta printer.

RepRapFirmware supports an optional H parameter, which is a height correction for that probe point. It allows for the Z probe having a trigger height that varies with XY position. The nominal trigger height of the Z probe (e.g. at bed centre) is declared in the Z parameter of the G31 command in the config.g file. When you probe using G30 and the probe triggers, the firmware will assume that the nozzle is at the nominal trigger height plus the value you have in the H parameter.

¹MK4duo Firmware support an optional parameter for Autocalibration Delta.

Usage

G30 Xnnn Ynnn Znnn Annn E R I D T S U

Parameters

Xnnn X coordinate

Ynnn Y coordinate

Znnn Z coordinate

Annn A Autocalibration width nnn precision

E Adjust Endstop

R Adjust Endstop & Delta Radius

I Adjust Tower

D Adjust Diagonal Rod

T Adjust Tower Radius

Sn Stows the probe if 1 (default=1)

Un <bool> with a non-zero value will apply the result to current zprobe_zoffset

G31: Set or Report Current Probe status

Usage

G31 Pnnn Xnnn Ynnn Znnn Cnnn Snnn

Parameters

Pnnn Trigger value

Xnnn Probe X offset¹

Ynnn Probe Y offset¹

Znnn Trigger Z height

Cnnn Temperature coefficient²

Snnn Calibration temperature²

Tnnn (RepRapFirmware 1.17 and later) Z probe type to which these parameters apply, defaults to the current Z probe type as defined by M558 P parameter

Examples

G31 P500 Z2.6
G31 X16.0 Y1.5

When used on its own this reports whether the Z probe is triggered, or gives the Z probe value in some units if the probe generates height values. If combined with a Z and P field (example: G31 P312 Z0.7) this will set the Z height to 0.7mm when the Z-probe value reaches 312 when a G28 Z0 (zero Z axis) command is sent. The machine will then move a further -0.7mm in Z to place itself at Z = 0. This allows non-contact measuring probes to approach but not touch the bed, and for the gap left to be allowed for. If the probe is a touch probe and generates a simple 0/1 off/on signal, then G31 Z0.7 will tell the RepRap machine that it is at a height of 0.7mm when the probe is triggered.

In RepRapFirmware, separate G31 parameters may be defined for different probe types (i.e. 0+4 for switches, 1+2 for IR probes and 3 for alternative sensors). To specify which probe you are setting parameters for, send a M558 command to select the probe type before sending the G31 command, or use the T parameter.

In Repetier, G31 supports no parameters and simply prints the high/low status of the Z probe.

Notes

¹X and Y offsets of the Z probe relative to the print head (i.e. the position when the empty tool is selected) can be specified in RepRapFirmware. This allows you to calculate your probe coordinates based on the geometry of the bed, without having to correct them for Z probe X and Y offset.

²In RepRapFirmware, additional parameters 'S' (bed temperature in ^oC at which the specified Z parameter is correct, default is current bed temperature) and 'C' (temperature coefficient of Z parameter in mm/^oC, default zero) can be set for the alternative (ultrasonic) sensor. This is useful for probes that are affected by temperature. This facility is deprecated and likely to be removed in a future version of RepRapFirmware.

G31: Dock Z Probe sled

G32: Probe Z and calculate Z plane

Usage

G32           ; Probe and calculate
G32 Snnn      ; Each firmware has its own parameters
G32 Snnn Pnnn ; Refer to their specific documentation

This command is implemented as a more sophisticated form of bed leveling (which uses a transformation matrix or motorized correction. Smoothieware uses this code instead of `G29`.

Each firmware behaves differently. For example, Repetier firmware allows for motorized rotation of the bed whilst ReprapFirmware probes the bed with a transformation matrix.

Probe and calculate in Reprapfirmware

This command probes the bed at 3 or more pre-defined points (see M557) and updates transformation matrix for bed leveling compensation.

Parameters

Snnn Store transformation matrix after probing¹

Examples

G32
G32 S2

RepRapFirmware executes macro file bed.g if present instead of using the M557 coordinates.

Notes

¹Currently only Repetier firmware v0.92.8 and higher have working support for an optional Snnn parameter. The numeric value sets the behavior that occurs immediately after point probe and transformation matrix calculation. These are the values for Reprapfirmware:

S0 Default value. Transformation matrix is updated in RAM but is not stored to EEPROM. Z bed height not calculated.

S1 Transformation matrix is updated in RAM but is not stored to EEPROM. Printer immediately moves to Z maximum position (Z max endstop required!), and calculates new Z maximum height. You must first issue G28 to home to Z maximum position before issuing G32 Snnn for this to work correctly, or the printer height will be invalid.

S2 Same as S1, except transformation matrix and Z max heights are also stored to EEPROM.

S3 Transformation matrix is stored to EEPROM. Z bed height not calculated.

Probe and calculate in Repetier firmware

This command probes the bed at 3 or more pre-defined points and implements bed leveling compensation by either moving the A axis during printing (as with regular bed leveling, G29) or by tilting the bed with motors.

Parameters

Snnn Bed leveling method

Pnnn Bed correction method

The values for Snnn and Pnnn are as follows:

S0 This method measures at the 3 probe points and creates a plane through these points. If you have a really planar bed this gives the optimum result. The 3 points must not be in one line and have a long distance to increase numerical stability.

S1 This measures a grid. Probe point 1 is the origin and points 2 and 3 span a grid. We measure BED_LEVELING_GRID_SIZE points in each direction and compute a regression plane through all points. This gives a good overall plane if you have small bumps measuring inaccuracies.

S2 Bending correcting 4 point measurement. This is for cantilevered beds that have the rotation axis not at the side but inside the bed. Here we can assume no bending on the axis and a symmetric bending to both sides of the axis. So probe points 2 and 3 build the symmetric axis and point 1 is mirrored to 1m across the axis. Using the symmetry we then remove the bending from 1 and use that as plane.

P0 Use a rotation matrix. This will make z axis go up/down while moving in x/y direction to compensate the tilt. For multiple extruders make sure the height match the tilt of the bed or one will scratch. This is the default.

P1 Motorized correction. This method needs a bed that is fixed on 3 points from which 2 have a motor to change the height. The positions are defined in firmware by BED_MOTOR_1_X, BED_MOTOR_1_Y, BED_MOTOR_2_X, BED_MOTOR_2_Y, BED_MOTOR_3_X, BED_MOTOR_3_Y Motor 2 and 3 are the one driven by motor driver 0 and 1. These can be extra motors like Felix Pro 1 uses them or a system with 3 z axis where motors can be controlled individually like the Sparkcube does. This method requires a Z max endstop.

G32: Undock Z Probe sled

G33: Firmware dependent

G33: Measure/List/Adjust Distortion Matrix (Repetier - Redeem)

Usage

G33

G33 Lnnn

G33 Rnnn

G33 Xnnn Ynnn Znnn

Parameters

L0 List distortion matrix in a report

R0 Reset distortion matrix

X[pos] Y[pos] Z[zCorrection] Set correction for nearest point

Examples

G33
G33 R0

When used with no parameters, G33 will measure a grid of points and store the distortion dips and valleys in the bed surface, and then enable software distortion correction for the first few or several layers. The values will be stored in EEPROM if enabled in firmware. You must previously have G28 homed, and your Z minimum/maximum height must be set correctly for this to work. Use the optional parameters to list, reset or modify the distortion settings. Distortion correction behavior can be later turned on or off by code M323.

G33: Delta Auto Calibration (Marlin 1.1.x)

End-stops and tower angle corrections are normalized, resets the height of the 1st printed layer according to Z-offset defined in M851(P0);

Performs a 1-4-7 point calibration of delta height (P1), end-stops, delta radius (P2) and tower angle corrections (P>=3) by a least squares iteration process based on the displacement method.

Usage

G33

G33 Pn T Cx.xx Fn Vn E A

Parameters

Pn Number of probe points: n*n (n=0-10), when P is omitted the default set in Configuration.h is used.

T Do not calibrate tower angle corrections (if used with P>=3); do not use the probe points near the towers, but the probe points opposite to the towers (if used with P=2)

Cx.xx Force the iterations to stop when a standard deviation from the zero plane less then x.xx mm is achieved; when C is omitted the iterations go on until the best possible standard deviation is reached.

Fn Force to run at least n iterations (n=1-30) and take the best result

Vn Verbose level: (n=0-2) 0 = dry run without calibration; 1(default) = settings ; 2 = settings and probe results

E Engage the probe for each point

A Auto tune calibration parameters. This probes 7 points and calculates the displacements when end-stops, delta radius and tower angle corrections are changed. The resulting scale factors can be used in Configuration.h to finetune G33 to the printer used. (Marlin 2.0.x upwards)

Examples

G33 : calibrates with the default settings.
G33 Auto Calibrate
Checking... AC
.Height:297.77    Ex:+0.00  Ey:+0.00  Ez:+0.00    Radius:100.00
.Tower angle :    Tx:+0.00  Ty:+0.00  Tz:+0.00
Iteration : 01                                    std dev:0.306
.Height:297.65    Ex:-0.15  Ey:-0.14  Ez:+0.00    Radius:100.77
.Tower angle :    Tx:-0.02  Ty:+0.11  Tz:+0.00
Iteration : 02                                    std dev:0.049
.Height:297.67    Ex:-0.12  Ey:-0.12  Ez:+0.00    Radius:100.87
.Tower angle :    Tx:-0.03  Ty:+0.20  Tz:+0.00
Iteration : 03                                    std dev:0.033
.Height:297.69    Ex:-0.10  Ey:-0.12  Ez:+0.00    Radius:100.91
.Tower angle :    Tx:-0.03  Ty:+0.25  Tz:+0.00
Iteration : 04                                    std dev:0.031
.Height:297.69    Ex:-0.07  Ey:-0.11  Ez:+0.00    Radius:100.92
.Tower angle :    Tx:-0.03  Ty:+0.30  Tz:+0.00
Calibration OK                                    rolling back.
.Height:297.69    Ex:-0.10  Ey:-0.12  Ez:+0.00    Radius:100.91
.Tower angle :    Tx:-0.03  Ty:+0.25  Tz:+0.00
Save with M500 and/or copy to Configuration.h

G33 P6 V0 : probes 36 points in dry run mode.
G33 Auto Calibrate
Checking... AC (DRY-RUN)
.Height:297.77    Ex:+0.00  Ey:+0.00  Ez:+0.00    Radius:100.00
.Tower angle :    Tx:+0.00  Ty:+0.00  Tz:+0.00
.      c:+0.03     x:+0.32   y:+0.34   z:+0.41
.                 yz:+0.37  zx:+0.32  xy:+0.17
End DRY-RUN                                       std dev:0.306

G33 P4 C0.05 T : probes 16 points and
                 stops when a standard deviation of 0.05mm is reached;
                 calibrates delta height, endstops and delta radius,
                 leaves the tower angle corrections unaltered.
G33 Auto Calibrate
Checking... AC
.Height:297.78    Ex:+0.00  Ey:+0.00  Ez:+0.00    Radius:100.00
Iteration : 01                                    std dev:0.317
.Height:297.65    Ex:-0.15  Ey:-0.16  Ez:+0.00    Radius:100.80
Iteration : 02                                    std dev:0.059
.Height:297.66    Ex:-0.17  Ey:-0.13  Ez:+0.00    Radius:100.91
Calibration OK                                    std dev:0.042
.Height:297.66    Ex:-0.17  Ey:-0.13  Ez:+0.00    Radius:100.91
Save with M500 and/or copy to Configuration.h

G33 P2 : probes center and tower positions and
         calibrates delta height, endstops and delta radius.
G33 Auto Calibrate
Checking... AC
.Height:297.78    Ex:+0.00  Ey:+0.00  Ez:+0.00    Radius:100.00
Iteration : 01                                    std dev:0.374
.Height:297.68    Ex:-0.14  Ey:-0.15  Ez:+0.00    Radius:101.09
Iteration : 02                                    std dev:0.054
.Height:297.68    Ex:-0.14  Ey:-0.14  Ez:+0.00    Radius:101.23
Iteration : 03                                    std dev:0.007
.Height:297.69    Ex:-0.13  Ey:-0.14  Ez:+0.00    Radius:100.92
Calibration OK                                    rolling back.
.Height:297.68    Ex:-0.14  Ey:-0.14  Ez:+0.00    Radius:101.23
Save with M500 and/or copy to Configuration.h

G33 P1 : probes the center and sets the delta height only.
G33 Auto Calibrate
Checking... AC
.Height:295.00
Calibration OK
.Height:297.78
Save with M500 and/or copy to Configuration.h

note: Height = delta height; Ex, Ey, Ez = end-stop corrections; Radius = delta radius; Tx, Ty, Tz = tower angular corrections; c, x, y, z, yz, zx, xy = probe results at center, towers and opposite to towers; std dev = standard deviation of the probe results towards the zero plane.

G38.x Straight Probe (CNC specific)

G38.2 probe toward workpiece, stop on contact, signal error if failure

G38.3 probe toward workpiece, stop on contact

G38.4 probe away from workpiece, stop on loss of contact, signal error if failure

G38.5 probe away from workpiece, stop on loss of contact

G40: Compensation Off (CNC specific)

G40 turns off cutter compensation. If tool compensation was on the next move must be a linear move and longer than the tool diameter. It is OK to turn compensation off when it is already off.

G42: Move to Grid Point

G42 does a fast move in XY to any of the intersection points in the bed calibration grid. This is useful during calibration to align the nozzle or probe.

Parameters

Inn Grid X index (zero-based). If omitted, the nearest latitude.

Jnn Grid Y index (zero-based). If omitted, the nearest longitude.

P Probe flag. Moves the probe to the grid point (instead of the nozzle).

Fnnn Feedrate (mm/m)

Example

G42 I3 J4 P F3000 ; Move the probe to grid coordinate 3, 4

G54..59: Coordinate System Select (CNC specific)

See linuxcnc.org for more help

G60: save current position to slot

Usage

G60 Snn

Parameters

Snn <nn> specifies memory slot # (0-based) to save into (default 0)

G61: Apply/restore saved coordinates to the active extruder.

Usage

G61 Xnnn Ynnn Znnn Ennn Fnnn Snn

Parameters

Xnnn X coordinate

Ynnn Y coordinate

Znnn Z coordinate

Ennn E coordinate

Fnnn F Set Feedrate

Snn S specifies memory slot # (0-based)

G80: Cancel Canned Cycle (CNC specific)

It cancel canned cycle modal motion. G80 is part of modal group 1, so programming any other G code from modal group 1 will also cancel the canned cycle.

G90: Set to Absolute Positioning

Example

G90

All coordinates from now on are absolute relative to the origin of the machine. (This is the RepRap default.)

G91: Set to Relative Positioning

Example

G91

All coordinates from now on are relative to the last position. Note: RepRapFirmware latest revision firmware uses M83 to set the extruder to relative mode: extrusion is NOT set to relative by ReprapFirmware on G91: only X,Y and Z are set to relative. By contrast, Marlin (for example) DOES also set extrusion to relative on a G91 command, as well as setting X, Y and Z.

G92: Set Position

Parameters

This command can be used without any additional parameters.

Xnnn new X axis position

Ynnn new Y axis position

Znnn new Z axis position

Ennn new extruder position

Example

G92 X10 E90

Allows programming of absolute zero point, by reseting the current position to the values specified. This would set the machine's X coordinate to 10, and the extrude coordinate to 90. No physical motion will occur.

A G92 without coordinates will reset all axes to zero.

G92.x: Reset Coordinate System Offsets (CNC specific)

• G92.1 - reset axis offsets to zero and set parameters 5211 - 5219 to zero. (X Y Z A B C U V W)
• G92.2 - reset axis offsets to zero.

G93: Feed Rate Mode (Inverse Time Mode) (CNC specific)

G93 is Inverse Time Mode. In inverse time feed rate mode, an F word means the move should be completed in (one divided by the F number) minutes. For example, if the F number is 2.0, the move should be completed in half a minute.

When the inverse time feed rate mode is active, an F word must appear on every line which has a G1, G2, or G3 motion, and an F word on a line that does not have G1, G2, or G3 is ignored. Being in inverse time feed rate mode does not affect G0 (rapid move) motions.

G94: Feed Rate Mode (Units per Minute) (CNC specific)

G94 is Units per Minute Mode. In units per minute feed mode, an F word is interpreted to mean the controlled point should move at a certain number of inches per minute, millimeters per minute, or degrees per minute, depending upon what length units are being used and which axis or axes are moving.

G100: Calibrate floor or rod radius

Parameters

X Flag to set floor for X axis

Y Flag to set floor for Y axis

Z Flag to set floor for Z axis

Rnnn Radius to add

Examples

G100 X Y Z ; set floor for argument passed in. Number ignored and may be absent.
G100 R5    ; Add 5 to radius. Adjust to be above floor if necessary
G100 R0    ; Set radius based on current z measurement. Moves all axes to zero

G130: Set digital potentiometer value

Example

G130 X10 Y18 Z15 A20 B12

Set the digital potentiometer value for the given axes. This is used to configure the current applied to each stepper axis. The value is specified as a value from 0-127; the mapping from current to potentimeter value is machine specific.

G131: Remove offset

G132: Calibrate endstop offsets

G133: Measure steps to top

G161: Home axes to minimum

Parameters

X Flag to home the X axis to its minimum position

Y Flag to home the Y axis to its minimum position

Z Flag to home the Z axis to its minimum position

Fnnn Desired feedrate for this command

Example

G161 X Y Z F1800

Instruct the machine to home the specified axes to their minimum position. Similar to G28, which decides on its own in which direction to search endstops.

G162: Home axes to maximum

Parameters

X Flag to home the X axis to its maximum position

Y Flag to home the Y axis to its maximum position

Z Flag to home the Z axis to its maximum position

Fnnn Desired feedrate for this command

Example

G162 X Y Z F1800

Instruct the machine to home the specified axes to their maximum position.

M-commands

M0: Stop or Unconditional stop

Parameters

This command can be used without any additional parameters.

Pnnn Time to wait, in milliseconds¹

Snnn Time to wait, in seconds²

Example

M0

The RepRap machine finishes any moves left in its buffer, then shuts down. All motors and heaters are turned off. It can be started again by pressing the reset button on the master microcontroller, although this step is not mandatory on RepRapFirmware. See also M1, M112.

The Marlin Firmware does wait for user to press a button on the LCD, or a specific time. "M0 P2000" waits 2000 milliseconds, "M0 S2" waits 2 seconds.

RepRapFirmware executes macro file stop.g before everything is turned off. Apart from that, RepRapFirmware (v1.09n-ch) accepts an extra 'H' parameter, whose value must be non-zero, to keep all heaters active. This is what Duet Web Control v1.07 sends to cancel a paused print.

Notes

¹Not available in RepRapFirmware, but as a work-around G4 can be run before M0.

²Only available on Marlin.

M1: Sleep or Conditional stop

Example

M1

The RepRap machine finishes any moves left in its buffer, then shuts down. All motors and heaters are turned off. It can still be sent G and M codes, the first of which will wake it up again. See also M0, M112.

The Marlin Firmware does the same as M0.

If Marlin is emulated in RepRapFirmware, this does the same as M25 if the code was read from a serial or Telnet connection, else the macro file sleep.g is run before all heaters and drives are turned off.

M2: Program End

Example

M2

Teacup firmware does the same as M84.

M3: Spindle On, Clockwise (CNC specific)

Parameters

Snnn Spindle RPM

Example

M3 S4000

The spindle is turned on with a speed of 4000 RPM.

Teacup firmware turn extruder on (same as M101).

RepRapFirmware interprets this code only if a Roland mill has been configured.

In Repetier-Firmware in laser mode you need S0..S255 to set laser intensity. Normally you use S255 to turn it on full power for moves. Laser will only fire during G1/G2/G3 moves and in laser mode (M452).

M4: Spindle On, Counter-Clockwise (CNC specific)

Example

M4 S4000

The spindle is turned on with a speed of 4000 RPM.

M5: Spindle Off (CNC specific)

Example

M5

The spindle is turned off.

Teacup firmware turn extruder off (same as M103).

M6: Tool change

Example

M6

M7: Mist Coolant On (CNC specific)

Example

M7

Mist coolant is turned on (if available)

Teacup firmware turn on the fan, and set fan speed (same as M106).

M8: Flood Coolant On (CNC specific)

Example

M8

Flood coolant is turned on (if available)

M9: Coolant Off (CNC specific)

Example

M9

All coolant systems are turned off.

M10: Vacuum On (CNC specific)

Example

M10

Dust collection vacuum system turned on.

M11: Vacuum Off (CNC specific)

Example

M11

Dust collection vacuum system turned off.

M17: Enable/Power all stepper motors

Example

M17

M18: Disable all stepper motors

Parameters

This command can be used without any additional parameters.¹

X X axis

Y Y axis

Z Z axis

E Extruder drive(s)²

Examples

M18
M18 X E0

Disables stepper motors and allows axes to move 'freely.'

Notes

¹Some firmware implementations do not support parameters to be passed, but at least Marlin and RepRapFirmware do.

²RepRapFirmware allows stepper motors to be disabled selectively. For example, M18 X E0:2 will disable the X, extruder 0 and extruder 2 motors.

M20: List SD card

Parameters

This command can be used without any additional parameters.

Snnn Output style¹

Pnnn Directory to list²

Examples

M20
M20 S2 P/gcodes/subdir

This code lists all files in the root folder or G-code directory of the SD card to the serial port. One name per line, like:

ok
SQUARE.G
SQCOM.G
ZCARRI~2.GCO
CARRIA~1.GCO

On Marlin, a file list response is usually encapsulated. Standard configurations of RepRapFirmware mimic this style in emulation mode:

Begin file list:
SQUARE.G
ZCARRI~2.GCO
End file list
ok

If RepRapFirmware emulates no firmware compatibility, a typical response looks like:

GCode files:
"Traffic cone.g","frog.gcode","calibration piece.g"

Note that some firmwares list file names in upper case, but - when sent to the M23 command (below) they must be in lower case. Teacup and RepRapFirmware have no such trouble and accept both. RepRapFirmware always returns long filenames in the case in which they are stored.

Notes

¹If the S2 parameter is used on RepRapFirmware, then the file list is returned in JSON format as a single array called "files" with each name that corresponds to a subdirectory preceded by an asterisk, and the directory is returned in variable "dir".

Example

M20 S2 P/gcodes
{"dir":"\/gcodes","files":["4-piece-1-2-3-4.gcode","Hinged_Box.gcode","Hollow_Dodecahedron_190.gcode","*Calibration pieces"]}

²This parameter is only supported by RepRapFirmware and defaults to the 0:/gcodes directory, which is the directory that printable gcode files are normally stored in.

M21: Initialize SD card

Parameters

Pnnn SD card number (RepRapFirmware only, default 0)

Examples

M21
M21 P1

The specified SD card is initialized. If an SD card is loaded when the machine is switched on, this will happen by default. SD card must be initialized for the other SD functions to work.

M22: Release SD card

Parameters

Pnnn SD card number (RepRapFirmware only, default 0)

Examples

M22
M22 P1

The specified SD card is released, so further (accidental) attempts to read from it are guaranteed to fail. Helpful, but not mandatory before removing the card physically.

M23: Select SD file

Example

M23 filename.gco

The file specified as filename.gco (8.3 naming convention is supported) is selected ready for printing. RepRapFirmware supports long filenames as well as 8.3 format.

M24: Start/resume SD print

Example

M24

The machine prints from the file selected with the M23 command. If the print was previously paused with M25, printing is resumed from that point. To restart a file from the beginning, use M23 to reset it, then M24.

When this command is used to resume a print that was paused, RepRapFirmware runs macro file resume.g prior to resuming the print.

M25: Pause SD print

Example

M25

The machine pauses printing at the current position within the file. To resume printing, use M24. Do not use this code to pause the print in a G-code file, use M226 instead.

Prior to pausing, RepRapFirmware runs macro file pause.g. This allows the head to be moved away from the print, filament to be retracted, etc.

M26: Set SD position

Parameters

Snnn File position from start of file in bytes

Pnnn (Optional, RepRapFirmware only) Proportion of the first move to be skipped, default 0.0, must be less than 1.0

Example

M26 S49315

Set the file offset in bytes from the start of the SD card file selected by M23. The offset must correspond to the start of a GCode command.

M27: Report SD print status

Example

M27

Report SD print status.

Marlin and recent forks of RepRapFirmware report the number of bytes processed in this format, which can be processed by Pronterface:

SD printing byte 2134/235422

If no file is being printed, only this message is reported:

Not SD printing.

M28: Begin write to SD card

Example

M28 filename.gco

File specified by filename.gco is created (or overwritten if it exists) on the SD card and all subsequent commands sent to the machine are written to that file.

M29: Stop writing to SD card

Example

M29 filename.gco

File opened by M28 command is closed, and all subsequent commands sent to the machine are executed as normal.

M30: Delete a file on the SD card

Example

> M30 filename.gco
> filename.gco is deleted.

M30 in grbl

M30 exchange pallet shuttles and end the program. Pressing cycle start will start the program at the beginning of the file.

M31: Output time since last M109 or SD card start to serial

Example

M31

The response looks like:

 echo:54 min, 38 sec

M32: Select file and start SD print

Example

M32 filename.gco

It can be used when printing from SD card and does the same as M23 and M24.

tba available in marlin(14/6/2014)

M33: Get the long name for an SD card file or folder

Get the long name for a file or folder on the SD card from a dos path. Introduced in Marlin firmware 1.1.0 September 2015.

M33: Stop and Close File and save restart.gcode

Stop the printing from SD and save all position in restart.gcode for restart printing in future

M34: Set SD file sorting options

Enable and disable SD card file-sorting, and/or set the folder sorting order. Proposed by Marlin firmware, May 2015.

M35: Upload firmware NEXTION from SD

M36: Return file information

Example

M36 filename.gco

Returns information for the specified SD card file in JSON format. A sample response is:

{"err":0,"size":457574,"height":4.00,"layerHeight":0.25,"filament":[6556.3],"generatedBy":"Slic3r 1.1.7 on 2014-11-09 at 17:11:32"}

The "err" field is zero if successful, nonzero if the file was not found or an error occurred while processing it. The "size" field should always be present if the operation was successful. The presence or absence of other fields depends on whether the corresponding values could be found by reading the file. The "filament" field is an array of the filament lengths required from each spool. The size is in bytes, all other values are in mm. The fields may appear in any order, and additional fields may be present.

If the file name parameter is not supplied and a file on the SD card is currently being printed, then information for that file is returned including additional field "fileName". This feature is used by the web interface and by PanelDue, so that if a connection is made when a file is already being printed, the name and other information about that file can be shown.

M37: Simulation mode

Used to switch between printing mode and simulation mode. Simulation mode allows the electronics to compute an accurate printing time, taking into account the maximum speeds, accelerations etc. that are configured.

M37 S1 enters simulation mode. All G and M codes will not be acted on, but the time they take to execute will be calculated.

M37 S0 leaves simulation mode.

M37 with no S parameter prints the time taken by the simulation, from the time it was first entered using M37 S1, up to the current point (if simulation mode is still active) or the point that the simulation was ended (if simulation mode is no longer active).

M38 Compute SHA1 hash of target file

Used to compute a hash of a file on the SD card. Examples:

> M38 gcodes/myfile.g
> Cannot find file
> M38 www/reprap.htm
> 91199139dbfadac15a18cfb962dfd4853db83999

Returns a hexadecimal string which is the SHA1 of the file. If the file cannot be found, then the string "Cannot find file" is returned instead.

M40: Eject

If your RepRap machine can eject the parts it has built off the bed, this command executes the eject cycle. This usually involves cooling the bed and then performing a sequence of movements that remove the printed parts from it. The X, Y and Z position of the machine at the end of this cycle are undefined (though they can be found out using the M114 command, q.v.).

See also M240 and M241 below.

M41: Loop

Example

M41

If the RepRap machine was building a file from its own memory such as a local SD card (as opposed to a file being transmitted to it from a host computer) this goes back to the beginning of the file and runs it again. So, for example, if your RepRap is capable of ejecting parts from its build bed then you can set it printing in a loop and it will run and run. Use with caution - the only things that will stop it are:

1. When you press the reset button,
2. When the build material runs out (if your RepRap is set up to detect this), and
3. When there's an error (such as a heater failure).

M42: Switch I/O pin

Parameters

Pnnn Pin number

Snnn Pin value

Example

M42 P7 S255

M42 switches a general purpose I/O pin. Use M42 Px Sy to set pin x to value y, when omitting Px the LEDPIN will be used.

In Teacup, general purpose devices are handled like a heater, see M104.

In RepRapFirmware, the S field may be in the range 0..1 or 0..255. The pin reference is an internal firmware reference named "digital pin", see Duet pinout. It maps on different connector pins depending the hardware. On Duet 0.6 and 0.8.5 hardware using pre-1.16 firmware, the supported pin numbers and their names on the expansion connector are:

Duet M42 P value to Expansion Port Pin Mapping

P	Name	Expansion Port Pin
16	TXD1	11
17	RXD1	12
18	TXD0	13
19	RXD0	14
20	TWD1	35
21	TWCK1	36
23	PA14	10
36	PC4	18
52	AD14	41
67	PB16	32

In firmware 1.16, the pin numbering has changed.

Duet 0.6 and 0.8.5 v1.16+ M42 P value to Expansion Port Pin Mapping

P	Name	Expansion Port Pin
60	PA10/RXD0	14
61	PA11/TXD0	13
62	PA12/RXD1	12
63	PA13/TXD1	11
64	PA14/RTS1	10
65	PB12/TWD1	35
66	PB13/TWCK1	36
67	PB16/DAC1*	32
68	PB21/AD14	41
69	PC4	18

• Also used as CS signal on external SD card socket

Duet WiFi v1.16+ M42 P value to Expansion Port Pin Mapping

P	Signal Name	Expansion Connector Label	Expansion Pin
60	CS5	CS5	50
61	CS6	E3_STOP	9
62	CS7	E4_STOP	14
63	CS8	E5_STOP	19

See Using servos and controlling unused I/O pins for all pin definitions.

Pre-1.16 example:

M42 P20 S1 ;set the connector pin 35 to high.

On RADDS hardware running RepRapFirmware-dc42, the supported Arduino Due pin numbers and their names are:

5 TIOA6, 6 PWML7, 39 PWMH2, 58 AD3, 59 AD2, 66 DAC0, 67 DAC1, 68 CANRX0, 69 CANTX0, 70 SDA1, 71 SCL1, 72 RX LED, 73 TX LED.

See also M583.

M43: Stand by on material exhausted

Example

M43

If your RepRap can detect when its material runs out, this decides the behaviour when that happens. The X and Y axes are zeroed (but not Z), and then the machine shuts all motors and heaters off except the heated bed, the temperature of which is maintained. The machine will still respond to G and M code commands in this state.

M43: Pin report and debug

Usage

M43 En Pnnn Wn In

Parameters

En Enable / disable background endstop monitoring

Pnnn Pin to read or watch. If omitted, read/watch all pins

Wn bool watch pins -reporting changes- until reset, click, or M108

In bool Flag to ignore pin protection

Note

You must have PINS_DEBUGGING uncommented in your Configuration_adv.h file for M43 to work.

M48: Measure Z-Probe repeatability

Parameters

Pnnn number of points

Xnnn position on the X axis

Ynnn position on the Y axis

Vnnn verbosity

E engage

Lnnn legs of travel

S schizoid

As with G29, the E flag causes the probe to stow after each probe.

The S flag will result is a random sized, 5 pointed star, being traced (X and Y axis) between each sample. Usually a user will get worse repeat-ability numbers with S specified because the X axis and Y axis movements will add to the machine's positioning errors.

M70: Display message

Example

M70 P200 Message

Instruct the machine to display a message on its interface LCD. P is the time to display message for.

M72: Play a tone or song

Example

M72 P2

Instruct the machine to play a preset song. Acceptable song IDs are machine specific. P is the ID of the song to play.

M73: Set build percentage

Example

M73 P50

Instruct the machine that the build has progressed to the specified percentage. The machine is expected to display this on it's interface board. If the percentage is exactly 0, then a Build Start Notification is sent. If the percentage is exactly 100, then a Build End notification is sent.

M80: ATX Power On

Examples

M80    ; Turn on the power supply
M80 S  ; Report power supply state (Marlin 1.1.1)

Turns on the ATX power supply from standby mode to fully operational mode. No-op on electronics without standby mode.

Notes

• Marlin requires the POWER_SUPPLY configuration option to be set to a non-zero value to enable M80.
• Some firmwares (e.g., Teacup) handle power on/off automatically, so this is redundant there. Also, see RAMPS wiring for ATX on/off.

M81: ATX Power Off

Example

M81

Turns off the ATX power supply. Counterpart to M80.

For redeem, adding 'P' will quit the daemon (redeem). Adding parameter 'R' will restart the daemon.

M82: Set extruder to absolute mode

Example

M82

Makes the extruder interpret extrusion as absolute positions.

This is the default in repetier.

M83: Set extruder to relative mode

Example

M83

Makes the extruder interpret extrusion values as relative positions.

M84: Stop idle hold

Parameters

This command can be used without any additional parameters.

Innn Reset flags¹

Example

M84

Stop the idle hold on all axis and extruder. In some cases the idle hold causes annoying noises, which can be stopped by disabling the hold. Be aware that by disabling idle hold during printing, you will get quality issues. This is recommended only in between or after printjobs.

On Marlin, Repetier and RepRapFirmware, M84 can also be used to configure or disable the idle timeout. For example, "M84 S10" will idle the stepper motors after 10 seconds of inactivity. "M84 S0" will disable idle timeout; steppers will remain powered up regardless of activity.

Notes

¹RepRapFirmware-dc42 and other firmware may not support this parameter.

M85: Set inactivity shutdown timer

Example

M85 S30

Set inactivity shutdown timer with parameter S<seconds>. "M85 S0" will disable the inactivity shutdown time (default)

M92: Set axis_steps_per_unit

Parameters

Xnnn Steps per unit for the X drive

Ynnn Steps per unit for the Y drive

Znnn Steps per unit for the Z drive

Ennn Steps per unit for the extruder drive(s)

Examples

M92 X87.489 Y87.489 Z87.489
M92 E420:420

Allows programming of steps per unit (usually mm) for motor drives. These values are reset to firmware defaults on power on, unless saved to EEPROM if available (M500 in Marlin) or in the configuration file (config.g in RepRapFirmware). Very useful for calibration.

RepRapFirmware will report the current steps/mm if you send M92 without any parameters.

M93: Send axis_steps_per_unit

M98: Call Macro/Subprogram

Parameters

Pnnn Macro filename

Example

M98 Pmymacro.g

Runs the macro in the file mymacro.g. In conventional G Codes for CNC machines the P parameter normally refers to a line number in the program itself (P2000 would run the Macro starting at line O2000, say). For RepRap, which almost always has some sort of mass storage device inbuilt, it simply refers to the name of a GCode file that is executed by the G98 call. That GCode file does not need to end with an M99 (return) as the end-of-file automatically causes a return. Macro calls cannot usually be nested or be recursive; i.e. you can't call a macro from a macro, although RepRapFirmware explicitly supports this.

RepRapFirmware also allows the filename to include a path to a subdirectory. For relative paths, the default folder is /sys, but some implementations may check the /macros directory too. Absolute file paths are supported on RepRapFirmware as well.

M99: Return from Macro/Subprogram

Example

M99

Returns from an M98 call.

RepRapFirmware closes the currently active macro file. If a nested macro is being run, RepRapFirmware goes up one stack level.

M98: Get axis_hysteresis_mm

Deprecated - clashes with the G Code standard M98 above

Example

M98

Report the current hysteresis values in mm for all of the axis.

Proposed for Marlin

M99: Set axis_hysteresis_mm

Deprecated - clashes with the G Code standard M99 above

Example

M99 X<mm> Y<mm> Z<mm> E<mm>

Allows programming of axis hysteresis. Mechanical pulleys, gears and threads can have hysteresis when they change direction. That is, a certain number of steps occur before movement occurs. You can measure how many mm are lost to hysteresis and set their values with this command. Every time an axis changes direction, these extra mm will be added to compensate for the hysteresis.

Proposed for Marlin

M101: Turn extruder 1 on (Forward), Undo Retraction

in Teacup firmware: If a DC extruder is present, turn that on. Else, undo filament retraction, which means, make the extruder ready for extrusion. Complement to M103.

in BFB/RapMan: Turn extruder on (forward/filament in).

in RepRapFirmware: undo filament retraction. The length and speed are set by the M207 command. RepRapFirmware supports this command for compatibility with Simplify3D.

in other firmwares: Deprecated. Regarding filament retraction, see G10, G11, M207, M208, M227, M228, M229.

M102: Turn extruder 1 on (Reverse)

In BFB/RapMan firmware: Turn extruder on Reverse (Still to add)

In other firmwares: Deprecated.

M103: Turn all extruders off, Extruder Retraction

In Teacup firmware: If a DC extruder is present, turn that off. Else, retract the filament in the hope to prevent nozzle drooling. Complement to M101.

In BFB/RapMan firmware: Turn extruder off.

In RepRapFirmware: retract filament. The length and speed are set by the M207 command. RepRapFirmware supports this command for compatibility with Simplify3D.

in other firmwares: Deprecated. Regarding filament retraction, see G10, G11, M207, M208, M227, M228, M229.

M104: Set Extruder Temperature

Parameters

Snnn Target temperature

Example

M104 S190

Set the temperature of the current extruder to 190^oC and return control to the host immediately (i.e. before that temperature has been reached by the extruder). Duet-dc42 and other firmware also supports the optional T parameter (as generated by slic3r) to specify which tool the command applies to. See also M109.

This is deprecated because temperatures should be set using the G10 and T commands (q.v.).

Deprecation is subject to discussion. --Traumflug 11:33, 19 July 2012 (UTC)

M104 in Teacup Firmware

In Teacup Firmware, M104 can be additionally used to handle all devices using a temperature sensor. It supports the additional P parameter, which is a zero-based index into the list of sensors in config.h. For devices without a temp sensor, see M106.

Example

M104 P1 S100

Set the temperature of the device attached to the second temperature sensor to 100°C.

M105: Get Extruder Temperature

Parameters

This command can be used without any additional parameters.

Rnnn Response sequence number¹

Snnn Response type¹

Examples

M105
M105 S2

Request the temperature of the current extruder and the build base in degrees Celsius. The temperatures are returned to the host computer. For example, the line sent to the host in response to this command looks like:

ok T:201 B:117

Expansion/generalization of M105 to be considered using S1 parameter as noted in Pronterface I/O Monitor

In Repetier you can add X0 to get raw values as well:

M105 X0
==> 11:05:48.910 : T:23.61 /0 @:0 T0:23.61 /0 @0:0 RAW0:3922 T1:23.89 /0 @1:0 RAW1:3920

Recent versions of RepRapFirmware also report the current and target temperatures of all active heaters.

Notes

¹These parameters are only supported by RepRapFirmware, which returns a JSON-formatted response if parameter S2 or S3 is specified. Additionally, parameter Rnn may be provided, where nn is the sequence number of the most recent G-code response that the client has already received. M105 S2 is equivalent to M408 S0, and M105 S3 is equivalent to M408 S2. Usage of these forms of M105 is deprecated, please use M408 instead.

M106: Fan On

Parameters

Pnnn Fan number (optional, defaults to 0)²

Snnn Fan speed (0 to 255; RepRapFirmware also accepts 0.0 to 1.0))

Extra Parameters

Innn Invert signal, or disable fan¹

Fnnn Set fan PWM frequency, in Hz¹

Lnnn Set minimum fan speed (0 to 255 or 0.0 to 1.0)¹

Bnnn Blip time - fan will be run at full PWM for this number of seconds when started from standstill¹

Hnn:nn:nn... Select heaters monitored when in thermostatic mode¹

Rnnn Restore fan speed to the value it has when the print was paused¹

Tnnn Set thermostatic mode trigger temperature¹

Example

M106 S127

Examples (RepRapFirmware)

M106 P1 I1 S87
M106 P1 T45 H1:2
M106 P2 B0.1 L0.05

The first example turns on the default cooling fan at half speed. The second one inverts the cooling fan signal of the second fan and sets its value to 1/3 of its maximum. The third one sets the second fan to a thermostatic fan for heaters 1 and 2 (e.g. the extruder heaters in a dual-nozzle machine) such that the fan will be on when either hot end is at or above 45C.

Mandatory parameter 'S' declares the PWM value (0-255). M106 S0 turns the fan off. In some implementations like RepRapFirmware the PWM value may alternatively be specified as a real fraction: M106 S0.7.

Notes

¹These parameters are only available in RepRapFirmware.

²Marlin only supports fan 0, all values above 0 will be interpreted as 0

M106 in RepRapFirmware

If an S parameter is provided but no other parameter is present, then the speeds of the print cooling fans associated with the current tool will be set (see the F parameter in the M563 command). If no tool is active then the speed of Fan 0 will be set. Either way, the speed is remembered so that it can be recalled using the R2 parameter (see below).

If no S parameter is given but the R1 parameter is used, the fan speed when the print was last paused will be set. If the R2 parameter is used, then the speeds of the print cooling fans associated with the current tool will be set to the remembered value (see above).

The T and H parameters allow a fan to be configured to operate in thermostatic mode, for example to use one of the fan channels to control the hot end fan. In this mode the fan will be fully on when the temperature of any of the heaters listed in the H parameter is at or above the trigger temperature set by the T parameter, and off otherwise. Thermostatic mode can be disabled using parameter H-1.

The B parameter sets the time for which the fan will be operated at full PWM when started from cold, to allow low fan speeds t be used. A value of 0.1 seconds is usually sufficient.

The L parameter defines the minimum PWM value that is usable with this fan. If a lower value is commanded that is not zero, it will be rounded up to this value.

The I parameter causes the fan output signal to be inverted if its value is greater than zero. This makes the cooling fan output suitable for feeding the PWM input of a 4-wire fan via a diode. If the parameter is present and zero, the output is not inverted. If the I parameter is negative then in RRF 1.16 and later the fan is disabled, which frees up the pin for use as a general purpose I/O pin that can be controlled using M42.

M106 in Teacup Firmware

Additionally to the above, Teacup Firmware uses M106 to control general devices. It supports the additional P parameter, which is an zero-based index into the list of heaters/devices in config.h.

Example

M106 P2 S255

Turn on device #3 at full speed/wattage.

Note: When turning on a temperature sensor equipped heater with M106 and M104 at the same time, temperature control will override the value given in M106 quickly.

Note well: The ambiguous text in the note above needs to be reworded by someone who knows the actual functioning. Below is my interpretation based on language use, not practical experience or code inspection.

Note: If M104 is (or becomes) active on a heater (or other device) with a feedback sensor it will correct any M106 initiated control output value change in the time it takes for the PID (of other feedback) loop to adjust it back to minimum error. It may not be easy to observe a change in the temperature (process value) due to this brief change in the control value

M107: Fan Off

Deprecated in Teacup firmware and in RepRapFirmware. Use M106 S0 instead.

M108: Cancel Heating (Marlin)

Breaks out of an M109 or M190 wait-for-temperature loop, continuing the print job. Use this command with caution! If cold extrusion prevention is enabled (see M302) and the temperature is too low, this will start "printing" without extrusion. If cold extrusion prevention is disabled and the hot-end temperature is too low, the extruder may jam.

This command was introduced in Marlin 1.1.0. As with other emergency commands [e.g., M112] this requires the host to leave space in the command buffer, or the command won't be executed until later.

M108: Set Extruder Speed (BFB)

Sets speed of extruder motor. (Deprecated in FiveD firmware, see M113)

M109: Set Extruder Temperature and Wait

Parameters

Snnn minimum target temperature, waits until heating

Rnnn maximum target temperature, waits until cooling (Sprinter)

Rnnn accurate target temperature, waits until heating and cooling (Marlin)

Example

M109 S215

M109 in Teacup

Not needed. To mimic Marlin behaviour, use M104 followed by M116.

M109 in Marlin, Sprinter (ATmega port), RepRapFirmware

Set extruder heater temperature in degrees celsius and wait for this temperature to be achieved.

Example

M109 S185

RepRapFirmware also supports the optional T parameter (as generated by slic3r) to specify which tool the command refers to (see below).

M109 in Sprinter (4pi port)

Parameters: S (optional), set target temperature value. If not specified, waits for the temperature set by M104. R (optional), sets target temperature range maximum value.

Example

M109 S185 R240 ; set extruder temperature to 185 and wait for the temperature to be between 185 - 240.

If you have multiple extruders, use T or P parameter to specify which extruder you want to set/wait.

Another way to do this is to use G10.

M109 in MakerBot

Example

M109 S70 T0

Sets the target temperature for the current build platform. S is the temperature to set the platform to, in degrees Celsius. T is the platform to heat.

M110: Set Current Line Number

Parameters

Nnnn Line number

Example

M110 N123

This example sets the current line number to 123. Thus the expected next line after this command will be 124.

M111: Set Debug Level

Parameters

Pnnn Debug module¹

Snnn Debug on/off

Examples

M111 S6
M111 P1 S1

Enable or disable debugging features in the firmware. The implementation may look different per firmware.

Notes

¹This parameter is only available in RepRapFirmware.

M111 in RepRapFirmware

RepRapFirmware allows debugging to be set for each module. If the optional 'P' parameter is not specified, debugging will be enabled for all modules. For a list of modules, send M111 S1 P15.

M111 in Repetier

Set the level of debugging information transmitted back to the host to level 6. The level is the OR of three bits:

#define DEBUG_ECHO (1<<0)
#define DEBUG_INFO (1<<1)
#define DEBUG_ERRORS (1<<2)
#define DEBUG_DRYRUN (1<<3) // repetier-firmware
#define DEBUG_COMMUNICATION (1<<4) // repetier-firmware

Thus 6 means send information and errors, but don't echo commands. (This is the RepRap default.)

For firmware that supports ethernet and web interfaces M111 S9 will turn web debug information on without changing any other debug settings, and M111 S8 will turn it off. Web debugging usually means that HTTP requests will be echoed to the USB interface, as will the responses.

M112: Emergency Stop

Example

M112

Any moves in progress are immediately terminated, then RepRap shuts down. All motors and heaters are turned off. It can be started again by pressing the reset button on the master microcontroller. See also M0 and M1.

M113: Set Extruder PWM

Example

M113

Set the PWM for the currently-selected extruder. On its own this command sets RepRap to use the on-board potentiometer on the extruder controller board to set the PWM for the currently-selected extruder's stepper power. With an S field:

M113 S0.7

it causes the PWM to be set to the S value (70% in this instance). M113 S0 turns the extruder off, until an M113 command other than M113 S0 is sent.

M114: Get Current Position

Example

M114

This causes the RepRap machine to report its current X, Y, Z and E coordinates to the host.

For example, the machine returns a string such as:

ok C: X:0.00 Y:0.00 Z:0.00 E:0.00

In Marlin first 3 numbers is the position for the planner. The other positions are the positions from the stepper function. This helps for debugging a previous stepper function bug.

X:0.00 Y:0.00 RZ:0.00 LZ:0.00 Count X:0.00 Y:0.00 RZ:41.02 LZ:41.02

M115: Get Firmware Version and Capabilities

Parameters

This command can be used without any additional parameters.

Pnnn Electronics type¹

Examples

M115
M115 P2

Request the Firmware Version and Capabilities of the current microcontroller The details are returned to the host computer as key:value pairs separated by spaces and terminated with a linefeed.

sample data from firmware:

ok PROTOCOL_VERSION:0.1 FIRMWARE_NAME:FiveD FIRMWARE_URL:http%3A//reprap.org MACHINE_TYPE:Mendel EXTRUDER_COUNT:1

This M115 code is inconsistently implemented, and should not be relied upon to exist, or output correctly in all cases. An initial implementation was committed to svn for the FiveD Reprap firmware on 11 Oct 2010. Work to more formally define protocol versions is currently (October 2010) being discussed. See M115_Keywords for one draft set of keywords and their meanings. See the M408 command for a more comprehensive report on machine capabilities supported by RepRapFirmware.

Notes

¹This parameter is supported only in RepRapFirmware and can be used tell the firmware about the hardware on which it is running. If the P parameter is present then the integer argument specifies the hardware being used. The following are currently supported:

M115 P0   Automatic board type selection if supported, or default if not
M115 P1   Duet 0.6
M115 P2   Duet 0.7
M115 P3   Duet 0.85

M116: Wait

Parameters

This command can be used without any additional parameters.¹

Pnnn Tool number

Hnnn Heater number

Cnnn Chamber number

Examples

M116
M116 P1

Wait for all temperatures and other slowly-changing variables to arrive at their set values if no parameters are specified. See also M109.

Notes

¹Most implementations don't support any parameters, but RepRapFirmware version 1.04 and later supports an optional 'P' parameter that is used to specify a tool number. If this parameter is present, then the system only waits for temperatures associated with that tool to arrive at their set values. This is useful during tool changes, to wait for the new tool to heat up without necessarily waiting for the old one to cool down fully.

Recent versions of RepRapFirmware also allow a list of the heaters to be specified using the 'H' parameter, and if the 'C' parameter is present, this will indicate that the chamber heater should be waited for.

M117: Get Zero Position

Example

M117

This causes the RepRap machine to report the X, Y, Z and E coordinates in steps not mm to the host that it found when it last hit the zero stops for those axes. That is to say, when you zero X, the x coordinate of the machine when it hits the X endstop is recorded. This value should be 0, of course. But if the machine has drifted (for example by dropping steps) then it won't be. This command allows you to measure and to diagnose such problems. (E is included for completeness. It doesn't normally have an endstop.)

M117: Display Message

Example

M117 Hello World

This causes the given message to be shown in the status line on an attached LCD. The above command will display Hello World. If RepRapFirmware is used and no LCD is attached, this message will be reported on the web interface.

M118: Echo message on host

Use this code to print a visible message to the host console, preceded by 'echo:'.

Example

M118 Color changing to blue

M118: Negotiate Features

Example

M118 P42

This M-code is for future proofing. NO firmware or hostware supports this at the moment. It is used in conjunction with M115's FEATURES keyword.

See Protocol_Feature_Negotiation for more info.

M119: Get Endstop Status

Example

M119

Returns the current state of the configured X, Y, Z endstops. Takes into account any 'inverted endstop' settings, so one can confirm that the machine is interpreting the endstops correctly.

In redeem, M119 can also be used to invert end stops.

Example

M119 X1 1

This will invert end stop X1 (Inverted means switch is connected in Normally Open state (NO))

M120: Push

Example

M120

Push the state of the RepRap machine onto a stack. Exactly what variables get pushed depends on the implementation (as does the depth of the stack - a typical depth might be 5). A sensible minimum, however, might be

1. Current feedrate, and
2. Whether moves (and separately extrusion) are relative or absolute

RepRapFirmware calls this automatically when a macro file is run. In addition to the variables above, it pushes the following values on the stack:

1. Current feedrate
2. Extruder positions

M121: Pop

Example

M121

Recover the last state pushed onto the stack.

M120: Enable endstop detection

M121: Disable endstop detection

M122: Diagnose

Example

M122

Sending an M122 causes the RepRap to transmit diagnostic information, for eaxmple via a USB serial link.

If RepRapFirmware is used and debugging is enabled for the Network module, this will also print LWIP stats to the host via USB.

M123: Tachometer value

Sending an M123 causes the RepRap to transmit filament tachometer values from all extruders.

M124: Immediate motor stop

Immediately stops all motors.

M126: Open Valve

Example

M126 P500

Open the extruder's valve (if it has one) and wait 500 milliseconds for it to do so.

M126 in MakerBot

Example

M126 T0

Enables an extra output attached to a specific toolhead (e.g. fan)

M127: Close Valve

Example

M127 P400

Close the extruder's valve (if it has one) and wait 400 milliseconds for it to do so.

M127 in MakerBot

Example

M127 T0

Disables an extra output attached to a specific toolhead (e.g. fan)

M128: Extruder Pressure PWM

Example

M128 S255

PWM value to control internal extruder pressure. S255 is full pressure.

M129: Extruder pressure off

Example

M129 P100

In addition to setting Extruder pressure to 0, you can turn the pressure off entirely. P400 will wait 100ms to do so.

M130: Set PID P value

Parameters

Pnnn heater number

Snnn proportional (Kp)

Example

M130 P0 S8.0  ; Sets heater 0 P factor to 8.0

Teacup can control multiple heaters with independent PID controls. For the default shown at https://github.com/Traumflug/Teacup_Firmware/blob/master/config.default.h, heater 0 is the extruder (P0), and heater 1 is the bed (P1).

Teacup's PID proportional units are in pwm/255 counts per quarter C, so to convert from counts/C, you would divide by 4. Conversely, to convert from count/qC to count/C, multiply by 4. In the above example, S=8 represents a Kp=8*4=32 counts/C.

M131: Set PID I value

Parameters

Pnnn heater number

Snnn integral (Ki)

Example

M131 P1 S0.5  ; Sets heater 1 I factor to 0.5

Teacup's PID integral units are in pwm/255 counts per (quarter C*quarter second), so to convert from counts/qCqs, you would divide by 16. Conversely, to convert from count/qCqs to count/Cs, multiply by 16. In the above example, S=0.5 represents a Ki=0.5*16=8 counts/Cs.

M132: Set PID D value

Parameters

Pnnn heater number

Snnn derivative (Kd)

Example

M132 P0 S24  ; Sets heater 0 D factor to 24.0

Teacup's PID derivative units are in pwm/255 counts per (quarter degree per 2 seconds), so to convert from counts/C, you would divide by 4. Conversely, to convert from count/qC to count/C, multiply by 8. In the above example, S=24 represents a Kd=24*8=194 counts/(C/s).

M132 in MakerBot

Example

M132 X Y Z A B

Loads the axis offset of the current home position from the EEPROM and waits for the buffer to empty.

M133: Set PID I limit value

Parameters

Pnnn heater number

Snnn integral limit (Ki)

Example

M133 P1 S264  ; Sets heater 1 I limit value to 264

Teacup's PID integral limit units are in quarter-C*quarter-seconds, so to convert from C-s, you would multiply by 16. Conversely, to convert from qC*qs to C*s, divide by 16. In the above example, S=264 represents an integral limit of 16.5 C*s.

M133 in MakerBot

Example

M133 T0 P500

Instruct the machine to wait for the toolhead to reach its target temperature. T is the extruder to wait for. P if present, sets the time limit.

M134: Write PID values to EEPROM

Example

M134

M134 in MakerBot

Example

M134 T0 P500

Instruct the machine to wait for the platform to reach its target temperature. T is the platform to wait for. P if present, sets the time limit.

M135: Set PID sample interval

Parameters

Snnn Heat sample time in seconds

Example

M135 S300

Set the PID to measure temperatures and calculate the power to send to the heaters every 300ms.

M135 in MakerBot

Example

M135 T0

Instructs the machine to change its toolhead. Also updates the State Machine's current tool_index. T is the toolhead for the machine to switch to and the new tool_index for the state machine to use.

M136: Print PID settings to host

Example

M136 P1  ; print heater 0 PID parameters to host

M140: Set Bed Temperature (Fast)

Parameters

Snnn Target temperature

Hnnn Heater number¹

Example

M140 S55

Set the temperature of the build bed to 55^oC and return control to the host immediately (i.e. before that temperature has been reached by the bed). There is an optional R field that sets the bed standby temperature: M140 S65 R40.

RepRapFirmware allows the bed heater to be switched off if the absolute negative temperature (-273.15) is passed as target temperature. In this case the current bed temperature is not affected¹:

M140 S-273.15

Recent versions of RepRapFirmware also provide an optional 'H' parameter to set the hot bed heater number. If no heated bed is present, a negative value may be specified to disable it.

M141: Set Chamber Temperature (Fast)

Parameters

Snnn Target temperature

Hnnn Heater number¹

Examples

M141 S30
M141 H0

Set the temperature of the chamber to 30^oC and return control to the host immediately (i.e. before that temperature has been reached by the chamber).

Notes

¹This parameter is only available in RepRapFirmware.

M142: Holding Pressure

Example

M142 S1

Set the holding pressure of the bed to 1 bar.

The holding pressure is in bar. For hardware which only has on/off holding, when the holding pressure is zero, turn off holding, when the holding pressure is greater than zero, turn on holding.

M143: Maximum heater temperature

Parameters

H Heater number (RepRapFirmware 1.17 and later, default 1 which is normally the first hot end)

S Maximum temperature

Examples

M143 S275      ; set the maximum temperature of the hot-end to 275°C
M143 H0 S125   ; set the maximum bed temperature to 125C

The default maximum temperature for all heaters was 300°C prior to RepRapFirmware version 1.13, and 262°C from 1.13 onwards. From RepRapFirmware 1.17 onwards, the default maximum temperatures are 262C for extruders and 125C for the bed.

When the temperature of the heater exceeds this value, countermeasures will be taken.

M144: Bed Standby

Example

M144

Switch the bed to its standby temperature. M140 turns it back to its active temperature; no need for any arguments for that use of M140.

M146: Set Chamber Humidity

Parameters

Rnnn Relative humidity in percent

Example

M146 R60

Set the relative humidity of the chamber to 60% and return control to the host immediately (i.e. before that humidity has been reached by the chamber).

M149: Set temperature units

Parameters

C Flag to treat temperature as degrees Celsius

K Flag to treat temperature as Kelvin

Example

M149 K

It affects the S or R values in the codes M104, M109, M140, M141, M143, M190 and G10. The default is M149 C.

M150: Set display color

Parameters

Rnnn red

Unnn green

Bnnn blue

Example

M150 R255 U128 B192

Set BlinkM Color via I2C. Range for values: 0-255

M155: Automatically send temperatures

Parameters

Snnn enable sending temperatures = 1, disable = 0

Example

M155 S1

Hosts normally monitor printer temperatures by sending M105 every x seconds. This not only adds traffic, but also only works while printer is not blocked by waiting commands. So frequency more depends on frequency you can send new commands and creates extra traffic. As a solution, firmware can be told to automatically send temperatures every second. This function is disabled by default for best compatibility with existing hosts. To indicate the availability of this function, M115 will add an extra line:

Cap:AUTOREPORT_TEMP:1

so hosts know about the presence of the function.

M160: Number of mixed materials

Example

M160 S4

This command has been superseded by the tool definition command M563 (see below).

Set the number of materials, N, that the current extruder can handle to the number specified. The default is 1.

When N >= 2, then the E field that controls extrusion requires N values separated by colons ":" after it like this:

M160 S4
G1 X90.6 Y13.8 E2.24:2.24:2.24:15.89
G1 X70.6 E0:0:0:42.4
G1 E42.4:0:0:0

The second line moves straight to the point (90.6, 13.8) extruding a total of 22.4mm of filament. The mix ratio for the move is 0.1:0.1:0.1:0.7.

The third line moves back 20mm in X extruding 42.4mm of filament.

The fourth line has no physical effect.

M163: Set weight of mixed material

Parameters

Snnn extruder number

Pnnn weight

Set weight for this mixing extruder drive.
See Repetier Color Mixing for more informations.

M164: Store weights

Parameters

Snnn virtual extruder number

Pnnn store to eeprom (P0 = no, P1 = yes)

Store weights as virtual extruder S.

M165: Set multiple mix weights

Parameters A B C D H I

A[factor] Mix factor for extruder stepper 1

B[factor] Mix factor for extruder stepper 2

C[factor] Mix factor for extruder stepper 3

D[factor] Mix factor for extruder stepper 4

H[factor] Mix factor for extruder stepper 5

I[factor] Mix factor for extruder stepper 6

• Set multiple mix factors for a mixing extruder.
• Factors that are left out will be set to 0.
• All factors together must add up to 1.0.

M190: Wait for bed temperature to reach target temp

Parameters

Snnn minimum target temperature, waits until heating

Rnnn accurate target temperature, waits until heating and cooling (Marlin)

Example

M190 S60

This will wait until the bed temperature reaches 60 degrees, printing out the temperature of the hot end and the bed every second.

M191: Wait for chamber temperature to reach target temp

Example

M191 P60

Set the temperature of the build chamber to 60 °C and wait for the temperature to be reached.

In MK4duo:

Parameters

Snnn minimum target temperature, waits until heating

Rnnn accurate target temperature, waits until heating and cooling (Marlin)

Example

M191 S60

M200: Set filament diameter

RepRapFirmware:

Parameters

Daaa:bbb:ccc... Sets filament diameter to aaa for extruder 0, bbb for extruder 1 and so on. If any of aaa, bbb etc. are zero then volumetric extrusion is disabled for that extruder.

Daaa Sets filament diameter (or disables volumetric extrusion) for all extruders

Examples

M200 D0  ; disable volumetric extrusion on all extruders

M200 D1.75  ; set al extruder filament diameters to 1.75mm

M200 D1.75:3.0:1.75  ; set extruder 0 to 1.75mm, extruder 1 to 3.0mm and all remaining extruders to 1.75mm

Volumetric extrusion is an option you can set in some slicers whereby all extrusion amounts are specified in mm³ (cubic millimetres) of filament instead of mm of filament. This makes the gcode independent of the filament diameter, potentially allowing the same gcode to run on different printers. The purpose of the M200 command is to inform the firmware that the gcode input files have been sliced for volumetric extrusion, and to provide the filament diameter so that the firmware can adjust the requested extrusion amount accordingly.

Sending M200 without parameters reports the current volumetric extrusion state and (where appropriate) filament diameter for each extruder.

Note that if you use slicer-commanded retraction, the retraction amounts must be specified in mm³ too. If instead you use firmware retraction, then the firmware retraction amounts specified using the M207 command are still interpreted as mm.

Other firmwares:

Without parameters loads default grid, and with specified extension attempts to load the specified grid. If not available will not modify the current grid. If Z was saved with the grid file, it will load the saved Z with the grid.

M200 Dm.mmm sets the filament diameter to m.mmm millimeters. It is used with 'volumetric calibration' and G-code generated for an ideal 1.128mm diameter filament, which has a volume of 1mm^3 per millimeter. The intention is to be able to generate filament-independent g-code. (See Triffid_Hunter's_Calibration_Guide#Optional:_Switch_to_volumetric_E_units and http://wooden-mendel.blogspot.com/2011/09/volumetric-stage-two.html for more information.)

M200 D0 or M200 D1.128 ; reset E multiplier to 1, since sqrt(1 / pi) * 2 = 1.128

See also Gcode#M119:_Get_Endstop_Status

Question: what does a firmware do with filament diameter? Has this an effect on how much an E command moves the extruder motor? --Traumflug 11:34, 14 October 2012 (UTC) Yes, Marlin uses this to set a 'volumetric_multiplier' by which the E-steps of a move are scaled in the planner. DaveX (talk) 16:44, 12 April 2014 (PDT) Smoothie implements the same thing as Marlin --Arthurwolf (talk) 05:23, 10 November 2014 (PST)

M201: Set max printing acceleration

Parameters

Xnnn Acceleration for X axis

Ynnn Acceleration for Y axis

Znnn Acceleration for Z axis

Ennn Acceleration for extruder drives

Example

M201 X1000 Y1000 Z100 E2000

Sets the acceleration that axes can do in units/second^2 for print moves. For consistency with the rest of G Code movement this should be in units/(minute^2), but that gives really silly numbers and one can get lost in all the zeros. So for this we use seconds.

RepRapFirmware expects these values to be in mm/s².

M202: Set max travel acceleration

Set max travel acceleration in units/s^2 for travel moves (M202 X1000 Y1000). Unused in Marlin!!

M203: Set maximum feedrate

Parameters

Xnnn Maximum feedrate for X axis

Ynnn Maximum feedrate for Y axis

Znnn Maximum feedrate for Z axis

Ennn Maximum feedrate for extruder drives

Example

M203 X6000 Y6000 Z300 E10000

Sets the maximum feedrates that your machine can do in mm/min (Marlin uses mm/sec).

M203 Repetier

Set temperature monitor to Sx.

M204: Set default acceleration

Parameters (RepRapFimware)

Pnnn Acceleration for printing moves

Tnnn Acceleration for travel moves

Example

M204 P500 T2000

Use M201 to set per-axis accelerations and extruder accelerations. RepRapFirmware applies the M204 accelerations to the move as a whole, and also applies the limits set by M201 to each axis and extruder.

Other firmwares:

S normal moves T filament only moves (M204 S3000 T7000) im mm/sec^2 also sets minimum segment time in ms (B20000) to prevent buffer underruns and M20 minimum feedrate

Marlin notes: After Mar11-2015, the M204 options have changed in Marlin:

P = Printing moves

R = Retract only (no X, Y, Z) moves

T = Travel (non printing) moves

The command M204 P800 T3000 R9000 sets the acceleration for printing movements to 800mm/s^2, for travels to 3000mm/s^2 and for retracts to 9000mm/s^2.

M204 Repetier

Usage

M204 X[Kp] Y[Ki] Z[Kd]

Set PID parameter. Values are 100*real value.

M205: Advanced settings

Sprinter / Marlin

Minimum travel speed = S[printing] T[travel]

B[min segment time] X[max XY jerk] Z[max Z jerk] E[max E jerk]

Sprinter / Marlin Example

M205 X30 Z5 ; Set X/Y Jerk to 30mm/s, Z jerk to 5mm/s

Smoothieware uses a different algorithm: [1]

X[xy junction deviation] Z[z junction deviation] S[minimum planner speed].

Z junction deviation only applies to z only moves

0 disables junction deviation for Z

-1 uses global junction deviation

Smoothie example

M205 X0.05  ; set X/Y Junction Deviation

M205 Repetier

Output EEPROM settings.

M206: Offset axes

Parameters

Xnnn X axis offset

Ynnn Y axis offset

Znnn Z axis offset

Example

M206 X10.0 Y10.0 Z-0.4

The values specified are added to the endstop position when the axes are referenced. The same can be achieved with a G92 right after homing (G28, G161).

With Marlin firmware, this value can be saved to EEPROM using the M500 command.

A similar command is G10, aligning these two is subject to discussion.

With Marlin 1.0.0 RC2 a negative value for z lifts(!) your printhead.

M206 in Repetier: Set eeprom value

M206 T[type] P[pos] [Sint(long] [Xfloat] Set eeprom value

Example

M206 T3 P39 X19.9

Set Jerk to 19.9

M207: Calibrate z axis by detecting z max length

Example

M207

After placing the tip of the nozzle in the position you expect to be considered Z=0, issue this command to calibrate the Z axis. It will perform a z axis homing routine and calculate the distance traveled in this process. The result is stored in EEPROM as z_max_length. For using this calibration method the machine must be using a Z MAX endstop.

This procedure is usually more reliable than mechanical adjustments of a Z MIN endstop.

M207: Set retract length

Parameters

Snnn positive length to retract, in mm

Rnnn positive or negative additional length to un-retract, in mm (RepRapFirmware only)

Fnnn retraction feedrate, in mm/min

Tnnn feedrate for un-retraction if different from retraction, mm/min (RepRapFirmware 1.16 and later only)

Znnn additional zlift/hop

Example

M207 S4.0 F2400 Z0.075

Sets the retract length used by the G10 and G11 commands, stays in mm regardless of M200 setting

M208: Set axis max travel

Parameters

Snnn 0 = set axis maximum (default), 1 = set axis minimum

Xnnn X axis limit

Ynnn Y axis limit

Znnn Z axis limit

Example

M208 X200 Y200 Z90 ; set axis maxima

M208 X-5 Y0 Z0 S1 ; set axis minima

The values specified set the software limits for axis travel in the specified direction. The axis limits you set are also the positions assumed when an endstop is triggered.

M208: Set unretract length

Parameters

Snnn positive length surplus to the M207 Snnn, in mm

Fnnn feedrate, in mm/sec

Sets recover=unretract length.

M209: Enable automatic retract

Example

M209 S1

This boolean value S 1=true or 0=false enables automatic retract detect if the slicer did not support G10/G11: every normal extrude-only move will be classified as retract depending on the direction.

M210: Set homing feedrates

Example

M210 X1000 Y1500

Set the feedrates used for homing to the values specified in mm per minute.

M211: Disable/Enable software endstops

The boolean value S 1=enable or 0=disable controls state of software endstop.

The boolean value X, Y or Z 1=max endstop or 0=min endstop selects which endstop is controlled.

Example

M211 X1 Y1 Z1 S0

Disables X,Y,Z max endstops

Example

M211 X0 S1

Enables X min endstop

Example

M211

Prints current state of software endstops.

M212: Set Bed Level Sensor Offset

This G-Code command is known to be available in the newer versions of PrintrBot's branch of Marlin. It may not be available in other firmware.

Example

M212 Z-0.2

Set the Z home to 0.2 mm lower than where the sensor says Z home is. This is extremely useful when working with printers with hard-to-move sensors, like the PrintrBot Metal Plus.

PrintrBot suggests that the user make minor (0.1-0.2) adjustments between attempts and immediately executes M500 & M501 after setting this.

M218: Set Hotend Offset

Sets hotend offset (in mm): T<extruder_number> X<offset_on_X> Y<offset_on_Y>.

Example

M218 T1 X50 Y0.5

M220: Set speed factor override percentage

Parameters

Snnn Speed factor override percentage (0..100 or higher)

Example

M220 S80

Sets the speed factor override percentage.

M221: Set extrude factor override percentage

Parameters

Snnn Extrude factor override percentage (0..100 or higher), default 100%

Dnnn Extruder drive number (RepRapFirmware only), default 0

Example

M221 S70
M221 S95 D1

Sets extrude factor override percentage. In the case of RepRapFirmware, sets the extrusion factor percentage for the specified extruder drive only.

M220: Turn off AUX V1.0.5

M221: Turn on AUX V1.0.5

M222: Set speed of fast XY moves

M223: Set speed of fast Z moves

M224: Enable extruder during fast moves

M225: Disable on extruder during fast moves

M226: Gcode Initiated Pause

Example

M226

Initiates a pause in the same way as if the pause button is pressed. That is, program execution is stopped and the printer waits for user interaction. This matches the behaviour of M1 in the NIST RS274NGC G-code standard and M0 in Marlin firmware.

M226: Wait for pin state

Parameters

Pnnn pin number

Snnn pin state

Example

M226 P2 S1

Wait for a pin to be in some state.

M227: Enable Automatic Reverse and Prime

Example

M227 P1600 S1600

P and S are steps.

"Reverse and Prime" means, the extruder filament is retracted some distance when not in use and pushed forward the same amount before going into use again. This shall help to prevent drooling of the extruder nozzle. Teacup firmware implements this with M101/M103.

M228: Disable Automatic Reverse and Prime

Example

M228

See also M227.

M229: Enable Automatic Reverse and Prime

Example

M229 P1.0 S1.0

P and S are extruder screw rotations. See also M227.

M230: Disable / Enable Wait for Temperature Change

Example

M230 S1

S1 Disable wait for temperature change S0 Enable wait for temperature change

M231: Set OPS parameter

M231 S[OPS_MODE] X[Min_Distance] Y[Retract] Z[Backslash] F[RetractMove]

M232: Read and reset max. advance values

M240: Trigger camera

Example

M240

Triggers a camera to take a photograph. (Add to your per-layer GCode.)

M240: Start conveyor belt motor / Echo off

Example

M240

The conveyor belt allows to start mass production of a part with a reprap.

Echoing may be controlled in some firmwares with M111.

M241: Stop conveyor belt motor / echo on

Example

M241

Echoing may be controlled in some firmwares with M111.

M245: Start cooler

Example

M245

used to cool parts/heated-bed down after printing for easy remove of the parts after print

M246: Stop cooler

Example

M246

M250: Set LCD contrast

Example

M250 C20

Sets LCD contrast C<contrast value> (value 0..63), if available.

M251: Measure Z steps from homing stop (Delta printers)

Examples

M251 S0 ; Reset
M251 S1 ; Print
M251 S2 ; Store to Z length (also EEPROM if enabled)

(This is a Repetier-Firmware only feature.)

M260: i2c Send Data

Buffer and send data over the i2c bus. Use A to set the address from 0-127. Add up to 32 bytes to the buffer with each B. Send and reset the buffer with S.

Examples

M260 A5 B65 S ; Send 'A' to Address 5 now
M260 A0       ; Set address to 0 (broadcast)
M260 B77  ; M
M260 B97  ; a
M260 B114 ; r
M260 B108 ; l
M260 B105 ; i
M260 B110 ; n
M260 S1   ; Send the current buffer

M261: i2c Request Data

Request data from an i2c slave device. This command simply relays the received data to the host.

Example

M261 A99 B5 ; Request 5 bytes from Address 99

Both M260 and M261 are commands demonstrating use of the i2c bus (TWIBus class) in Marlin Firmware. Developers and vendors can make Marlin an i2c master device by enabling EXPERIMENTAL_I2CBUS, and Marlin can act as a slave device by setting I2C_SLAVE_ADDRESS from 8-127. This class can be used to divide up processing responsibilities between multiple instances of Marlin running on multiple boards. For example, one board might control a Z axis with 4 independent steppers to create a self-leveling system, or a second board could drive the graphical display while the first board handles printing.

M280: Set servo position

Set servo position absolute.

Parameters

Pnnn Servo index

Snnn Angle or microseconds

I1 Invert polarity (RepRapFirmware only)

Example

M280 P1 S50

Marlin and RepRapFirmware treat S values below 200 as angles, and 200 or greater as the pulse width in microseconds.

In RepRapFirmware, the servo index is the same as the pin number for the M42 command. See https://duet3d.com/wiki/Using_servos_and_controlling_unused_I/O_pins for details.

RepRapFirmware supports the optional I1 parameter, which if present causes the polarity of the servo pulses to be inverted compared to normal for that output pin. The I parameter is not remembered between M280 commands (unlike the I parameter in M106 commands), so if you need inverted polarity then you must include I1 in every M280 command you send.

Duet 0.8.5 M280 P value to Expansion Port Pin Mapping

P	Name	Expansion Port Pin
Use M307 H# A-1 C-1 D-1 before using these pins
3	PC23_PWML6	21
4	PC22_PWML5	22
5	PC21_PWML4	23

On the Duet 0.6, pin 18 is controlled by heater 2. On the 0.8.5, pin 18 is controlled by heater 6, but is also shared with fan1. In order to use this pin, the fan must be disabled (M106 P1 I-1). See Using servos and controlling unused I/O pins

M290: Babystepping

Parameters (RepRapFirmware)

Snnn Amount to baby step in mm. Positive values raise the head, negative values lower it.

Example

M290 S0.05

Additional Parameters (Marlin 1.1.7 and later)

Xnnn Amount to babystep X in current units. (Requires BABYSTEP_XY)

Ynnn Amount to babystep Y in current units. (Requires BABYSTEP_XY)

Znnn Amount to babystep Z in current units. Synonym for 'S' parameter.

Example

M290 X0.2 Z0.05 ; Babystep X by 0.2mm, Z by 0.05mm

This command tells the printer to move the axis (or axes) transparently to the motion system. This is like physically moving the axes by force, but much nicer to the machine.

In RepRapFirmware M290 with no parameters reports the accumulated baby stepping offset. Marlin doesn't track accumulated babysteps.

The babystepping offset is reset when the printer is homed or the bed is probed.

Note: If the BABYSTEP_ZPROBE_OFFSET option is used in Marlin, this command also affects the Z probe offset (as set by M851) and that offset will be saved to EEPROM.

M291: Display message and optionally wait for response

Parameters

P"message" The message to display, which must be enclosed in double quotation marks. If the message itself contains a double quotation mark, use two double quotation marks to represent it.

R"message" Optional title for the message box. Must be enclosed in double quotation marks too.

Sn Message box mode (defaults to 1)

Tn Timeout in seconds, only legal for S=0 and S=1. The message will be cancelled after this amount of time, if the user does not cancel it before then. A zero or negative value means that the message does not time out (it may still be cancelled by the user). In RepRapFirmware, the default timeout for messages that do not require acknowledgement is 10 seconds.

Zn 0 = no special action, 1 = display Z jog buttons alongside the message to allow the user to adjust the height of the print head

Examples

M291 P"Please do something and press OK when done" S2
M291 P"This message will be closed after 10 seconds" T10

This command provides a more flexible alternative to M117, in particular messages that time out, messages that suspend execution until the user acknowledges them, and messages that allow the user to adjust the height of the print head before acknowledging them.

Allowed message box modes include:

0. No buttons are displayed (non-blocking)
1. Only "Close" is displayed (non-blocking)
2. Only "OK" is displayed (blocking, send M292 to resume the execution)
3. "OK" and "Cancel" are displayed  (blocking, send M292 to resume the execution or M292 P1 to cancel the operation in progress)

M292: Acknowledge message

Parameters

Pn Whether the current operation shall be cancelled. Only legal if M291 was called with S=3 (optional)

This command is sent by the user interface when the user acknowledges a message that was displayed because of a M291 command with parameter S=2 or S=3.

M300: Play beep sound

Parameters

Snnn frequency in Hz

Pnnn duration in milliseconds

Example

M300 S300 P1000

Play beep sound, use to notify important events like the end of printing. See working example on R2C2 electronics.

If an LCD device is attached to RepRapFirmware, a sound is played via the add-on touch screen control panel. Else the web interface will play a beep sound.

M301: Set PID parameters

Parameters

Hnnn heater number (Smoothie uses 'S', Redeem uses 'E')

Pnnn proportional (Kp)

Innn integral (Ki)

Dnnn derivative (Kd)

Examples

M301 H1 P1 I2 D3 ; Marlin
M301 H1 P1 I2 D3 T0.2 B20 W127 S0.8 ; RepRapFirmware (v1.09 onwards), Duet-dc42
M301 S0 P30 I10 D10 ; Smoothie
M301 E0 P30 I10 D10 ; Redeem (E = Extruder, -1=Bed, 0=E, 1=H, 2=A, 3=B, 4=C, default = 0)

Sets Proportional (P), Integral (I) and Derivative (D) values for hot end. See also PID Tuning.

Marlin

Hot end only; see M304 for bed PID. H is the heater number, default 1 (i.e. first extruder heater).

RepRapFirmware (v1.09 onwards)

• H Is the heater number, and is compulsory. H0 is the bed, H1 is the first hot end, H2 the second etc.
• P Interprets a negative P term as indicating that bang-bang control should be used instead of PID (not recommended for the hot end, but OK for the bed heater).
• I Integral value
• D Derivative value
• T Is the approximate additional PWM (on a scale of 0 to 255) needed to maintain temperature, per degree C above room temperature. Used to preset the I-accumulator when switching from heater fully on/off to PID.
• S PWM scaling factor, to allow for variation in heater power and supply voltage. Is designed to allow a correction to be made for a change in heater power and/or power supply voltage without having to change all the other parameters. For example, an S factor of 0.8 means that the final output of the PID controller should be scaled to 0.8 times the standard value, which would compensate for a heater that is 25% more powerful than the standard one or a supply voltage that is 12.5% higher than standard.
• W Wind-up. Sets the maximum value of I-term, must be high enough to reach 245C for ABS printing.
• B PID Band. Errors larger than this cause heater to be on or off.

An example using all of these would be:

M301 H1 P20 I0.5 D100 T0.4 S1 W180 B30

Smoothie

S0<code> is 0 for the hotend, and 1 for the bed, other numbers may apply to your configuration, depending on the order in which you declare temperature control modules.

Other implementations

W: Wind-up. Sets the maximum value of I-term, so it does not overwhelm other PID values, and the heater stays on. (Check firmware support - Sprinter, Marlin?)

Example

M301 W125

Teacup

See <code>M130, M131, M132, M133 for Teacup's codes for setting the PID parameters.

M302: Allow cold extrudes

Parameters

Snnn Cold extrude minimum temperature

Pnnn Cold extrude allow state (RepRapFirmware)

Examples (RepRapFirmwre)

M302       ; Report current state
M302 P1    ; Allow cold extrusion

Examples (Others)

M302 S0    ; Allow extrusion at any temperature
M302 S170  ; Allow extrusion above 170

This tells the printer to allow movement of the extruder motor above a certain temperature, or if disabled, to allow extruder movement when the hotend is below a safe printing temperature.

Notes

¹RepRapFirmware uses the P[0|1] parameter instead of S[temperature], and for M302 with no parameters it will report the current cold extrusion state.

M303: Run PID tuning

PID Tuning refers to a control algorithm used in some repraps to tune heating behavior for hot ends and heated beds. This command generates Proportional (Kp), Integral (Ki), and Derivative (Kd) values for the hotend or bed (E-1). Send the appropriate code and wait for the output to update the firmware.

Hot end usage:

M303 S<temperature> C<cycles>

Bed usage (repetier, not sure whether cycles work here):

M303 P1 S<temperature>

Bed usage (others):

M303 E-1 C<cycles> S<temperature>

Example

M303 C8 S175

Smoothie's syntax, where E0 is the first temperature control module (usually the hot end) and E1 is the second temperature control module (usually the bed):

M303 E0 S190

In RepRapFirmware, this command computes the process model parameters (see M307), which are in turn used to calculate the PID constants. H is the heater number, P is the PWM to use (default 0.5), and S is the maximum allowable temperature (default 225). Tuning is performed asynchronously. Run M303 with no parameters to see the current tuning state or the last tuning result.

Example

M303 H1 P0.4 S240 ; tune heater 1 using 40% PWM, quit if temperature exceeds 240C

Notes

In Marlin Firmware you can add the U1 parameter to apply the PID results to current settings upon completion.

M304: Set PID parameters - Bed

Parameters

Pnnn proportional (Kp)

Innn integral (Ki)

Dnnn derivative (Kd)

Examples

M304 P1 I2 D3 ; set kP=3, kI=2, kD=3
M304 P1 I2 D3 T0.7 B20 W127 ; RepRapFirmware
M304          ; Report parameters

Sets Proportional, Integral and Derivative values for bed. RepRapFirmware interprets a negative P term as indicating that bang-bang control should be used instead of PID. In RepRapFirmware, this command is identical to M301 except that the H parameter (heater number) defaults to zero.

See also PID Tuning.

M304 in RepRapPro version of Marlin: Set thermistor values

In the RepRapPro version of Marlin ( https://github.com/reprappro/Marlin ) M304 is used to set thermistor values (as M305 is in later firmwares). RRP Marlin calculates temperatures on the fly, rather than using a temperature table. M304 Sets the parameters for temperature measurement.

Example

M304 H1 B4200 R4800 T100000

This tells the firmware that for heater 1 (H parameter: 0 = heated bed, H = first extruder), the thermistor beta (B parameter) is 4200, the thermistor series resistance (R parameter) is 4.8Kohms, the thermistor 25C resistance (T parameter) is 100Kohms. All parameters other than H are optional. If only the H parameter is given, the currently-used values are displayed. They are also displayed within the response to M503.

M305: Set thermistor and ADC parameters

Parameters

Pnnn Heater number, or virtual heater number

S"name" Heater name (optional, RepRapFirmware only)

Tnnn (for thermistor sensors) Thermistor resistance at 25^oC

T"c" (for MAX31856-based thermocouple sensors) The thermistor type letter, default K

Bnnn Beta value, or the reciprocal of the Steinhart-Hart thermistor model B coefficient

Cnnn Steinhart-Hart C coefficient (RepRapFirmware 1.17 and later), default 0

Rnnn Series resistor value

Lnnn ADC low offset correction, default 0

Hnnn ADC high offset correction, default 0

Xnnn Heater ADC channel, or thermocouple or PT100 or current loop adapter channel, defaults to the same value as the P parameter

Fnn (where nn is 50 or 60) If the sensor interface uses a MAX31856 thermocouple chip or MAX31865 PT100 chip, this is the local mains frequency. Readings will be timed to optimise rejection of interference at this frequency.

Example

M305 P1 T100000 R1000 B4200

Sets the parameters for temperature measurement. The example above tells the firmware that for heater 1 (P parameter: 0 = heated bed, 1 = first extruder) the thermistor 25C resistance (T parameter) is 100Kohms, the thermistor series resistance (R parameter) is 1Kohms, the thermistor beta (B parameter) is 4200. All parameters other than P are optional. If only the P parameter is given, the existing values are displayed.

Example

M305 P1 T100000 R1000 B4200 H14 L-11 X2

The H correction affects the reading at high ADC input voltages, so it has the greatest effect at low temperatures. The L correction affects the reading at low input voltages, which correspond to high temperatures.

The X parameter tells the firmware to use the thermistor input corresponding to a different heating channel. RepRapFirmware also allow an external SPI thermocouple interface (such as the MAX31855) or PT100 interface (MAX31865) to be configured. MAX31855 thermocouple channels are numbered from 100, MAX31856 thermocouple channels are numbered from 150, PT100 channels from 200 and current loop channels from 300. Channel 1000 is the CPU temperature indication, 1001 is the temperature of the hottest stepper motor driver on the main board, and 1001 is the temperature of the hottest drivers on the expansion board.

In the above example, the ADC high end correction (H parameter) is 14, the ADC low end correction (L parameter) is -11, and thermistor input #2 is used to measure the temperature of heater #1.

M306: Set home offset calculated from toolhead position

Example

M306 Z0

The values specified are added to the calculated end stop position when the axes are referenced. The calculated value is derived from the distance of the toolhead from the current axis zero point.

The user would typically place the toolhead at the zero point of the axis and issue the M306 command.

This value can be saved to EEPROM using the M500 command (as M206 value).

Implemented in Smoothieware

M307: Set or report heating process parameters

Parameters

Hn Heater number (0 is usually the bed heater)

Annn gAin, expressed as ultimate temperature rise obtained in degC divided by the PWM fraction. For example, if G=180 then at 50% PWM the ultimate temperature rise would be 90C.

Cnnn dominant time Constant of the heating process in seconds

Dnnn Dead time in seconds

Two additional parameters help control the heating process

Bn selects Bang-bang control instead of PID if non-zero. Default at power-up is 0 for extruder heaters, 1 for the bed heater.

Snnn maximum PWM to be used used with this heater on a scale of 0 to 1. Default 1.0.

Examples

M307 H0 ; report the process parameters for heater 0
M307 H1 A346.2 C140 D5.3 B0 S0.8 ; set process parameters for heater 1, use PID, and limit heater 1 PWM to 80%

Each heater and its corresponding load may be approximated as a first order process with dead time, which is characterised by the gain, time constant and dead time parameters. The model can used to calculate optimum PID parameters (including using different values for the heating or cooling phase and the steady state phase), to better detect heater faults, and to calculate feed-forward terms to better respond to changes in the load. Normally these model parameters are found by auto tuning - see M303.

RepRapFirmware 1.16 and later allow the PID controller for a heater to be disabled by setting the A, C, and D parameters to -1. This frees up the corresponding heater control pin for use as a general purpose I/O pin.

M320: Activate autolevel (Repetier)

Usage

M320

M320 S1

Parameters

Snnn if greater than 0, activate and store persistently in EEPROM

Examples

M320    ; temporarily activate auto leveling
M320 S1 ; permanently activate auto leveling

Parameter Snnn is optional.

(Repetier only)

M321: Deactivate autolevel (Repetier)

Usage

M321

M321 S1

Parameters

Snnn if greater than 0, deactivate and store persistently in EEPROM

Examples

M321    ; temporarily deactivate auto leveling
M321 S1 ; permanently deactivate auto leveling

Parameter Snnn is optional.

(Repetier only)

M322: Reset autolevel matrix (Repetier)

Usage

M322

M322 S1

Parameters

Snnn if greater than 0, also reset the matrix values saved EEPROM

Examples

M322    ; temporarily reset auto level matrix
M322 S1 ; permanently reset auto level matrix

Parameter Snnn is optional.

(Repetier only)

M323: Distortion correction on/off (Repetier)

Usage

M323

M323 Snnn

M323 Snnn Pnnn

Parameters

Snnn 0 (disable correction) or 1 (enable correction)

Pnnn 1 (store correction state persistently in EEPROM)

Examples

M323       ; Show if distortion correction is enabled
M323 S0    ; Disable distortion correction temporarily
M323 S1 P1 ; Enable distortion correction permanently

(Repetier only) Controls distortion correction feature after having set it up using G33.

M340: Control the servos

(Repetier only ,Marlin see M280)

M340 P<servoId> S<pulseInUS> / ServoID = 0..3 pulseInUs = 500..2500

Servos are controlled by a pulse width normally between 500 and 2500 with 1500ms in center position. 0 turns servo off.

M350: Set microstepping mode

Sets microstepping mode.

Warning: Steps per unit remains unchanged; except that in RepRapFirmware the steps/mm will be adjusted automatically.

Usage

M350 Snn Xnn Ynn Znn Enn Bnn

Parameters

Not all parameters need to be used, but at least one should be used. As with other commands, RepRapFirmware reports the current settings if no parameters are used.

Snn Set stepping mode for all drivers (not supported by RepRapFirmware)

Xnn Set stepping mode for the X axis

Ynn Set stepping mode for the Y axis

Znn Set stepping mode for the Z axis

Enn Set stepping mode for Extruder 0 (for RepRapFirmware use Enn:nn:nn etc. for multiple extruders)

Bnn Set stepping mode for Extruder 1 (not supported by RepRapFirmware, see above)

Inn Enable (nn=1) or disable (nn=0) microstep interpolation mode for the specified drivers, if they support it (RepRapFirmware only)

Modes (nn)

1 = full step

2 = half step

4 = quarter step

8 = 1/8 step

16 = 1/16 step

64 = 1/64 step

128 = 1/128 step

256 = 1/256 step

Examples

M350 S16    ; reset all drivers to the default 1/16 micro-stepping - not supported by RepRapFirmware
M350 Z1     ; set the Z-axis' driver to use full steps
M350 E4 B4  ; set both extruders to use quarter steps - Marlin/Repetier
M350 E4:4:4 ; set extruders 0-2 to use quarter steps - RepRapFirmware

M351: Toggle MS1 MS2 pins directly

Example

M351

M355: Turn case lights on/off

Examples

M355 S1 ; Enable lights
M355 S0 ; Disable lights
M355    ; Report status

Every call or change over LCD menu sends a state change for connected hosting software like:

Case lights on
Case lights off
No case lights

M360: Report firmware configuration

Target

This command helps hosting software to detect configuration details, which the user would need to enter otherwise. It should reduce configuration time considerably if supported.

Example

M360

Response

Config:Baudrate:250000
Config:InputBuffer:127
Config:NumExtruder:2
Config:MixingExtruder:0
Config:HeatedBed:0
Config:SDCard:1
Config:Fan:1
Config:LCD:1
Config:SoftwarePowerSwitch:1
Config:XHomeDir:-1
Config:YHomeDir:-1
Config:ZHomeDir:-1
Config:SupportG10G11:1
Config:SupportLocalFilamentchange:1
Config:CaseLights:0
Config:ZProbe:1
Config:Autolevel:0
Config:EEPROM:1
Config:PrintlineCache:24
Config:JerkXY:30.00
Config:JerkZ:0.30
Config:RetractionLength:3.00
Config:RetractionLongLength:13.00
Config:RetractionSpeed:40.00
Config:RetractionZLift:0.00
Config:RetractionUndoExtraLength:0.00
Config:RetractionUndoExtraLongLength:0.00
Config:RetractionUndoSpeed:0.00
Config:XMin:0.00
Config:YMin:0.00
Config:ZMin:0.00
Config:XMax:250.00
Config:YMax:150.00
Config:ZMax:90.00
Config:XSize:250.00
Config:YSize:150.00
Config:ZSize:90.00
Config:XPrintAccel:250.00
Config:YPrintAccel:250.00
Config:ZPrintAccel:100.00
Config:XTravelAccel:250.00
Config:YTravelAccel:250.00
Config:ZTravelAccel:100.00
Config:PrinterType:Cartesian
Config:MaxBedTemp:120
Config:Extr.1:Jerk:50.00
Config:Extr.1:MaxSpeed:100.00
Config:Extr.1:Acceleration:10000.00
Config:Extr.1:Diameter:0.00
Config:Extr.1:MaxTemp:220
Config:Extr.2:Jerk:50.00
Config:Extr.2:MaxSpeed:100.00
Config:Extr.2:Acceleration:10000.00
Config:Extr.2:Diameter:0.00
Config:Extr.2:MaxTemp:220

SCARA calibration codes (Morgan)

In order to ease calibration of Reprap Morgan, the following M-codes are used to set the machine up

M360: Move to Theta 0 degree position

The arms move into a position where the Theta steering arm is parallel to the top platform edge. The user then calibrates the position by moving the arms with the jog buttons in software like pronterface until it is perfectly parallel. Using M114 will then display the calibration offset that can then be programmed into the unit using M206 (Home offset) X represents Theta.

Smoothieware: M360 P0 will take the current position as parallel to the platform edge, and store the offset in the homing trim offset (M666) No further user interaction is needed.

M361: Move to Theta 90 degree position

Theta move to 90 degrees with platform edge. User calibrates by using jog arms to place exactly 90 degrees. Steps per degree can then be read out by using M114, and programmed using M92. X represents Theta. Program Y (Psi) to the same value initially. Remember to repeat M360 after adjusting steps per degree.

Smoothieware: M360 P0 will accept the current position as 90deg to platform edge. New steps per angle is calculated and entered into memory (M92) No further user interaction is required, except to redo M360.

M362: Move to Psi 0 degree position

Arms move to Psi 0 degree. Check only after other Theta calibrations

M363: Move to Psi 90 degree position

Arms move to Psi 90 degree. Check only after other Theta calibrations

M364: Move to Psi + Theta 90 degree position

Move arms to form a 90 degree angle between the inner and outer Psi arms. Calibrate by moving until angle is exactly 90 degree. Read out with M114, and calibrate value into Home offset M206. Psi is represented by Y.

Smoothieware: M364 P0 will accept the current position as 90deg between arms. The offset is stored as a trim offset (M666) and no further user interaction is required except to save all changes via M500.

M365: SCARA scaling factor