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Posts Tagged Sherline

Logitech Dual Action Gamepads: Mac vs. PC

Posted by Ed in Home Ec, Oddities, PC Tweakage, Software on 6-May-2013

Turns out that there’s no difference between the Mac and PC versions of the Logitech Dual Action Gamepad:

Logitech Dual Action Gamepads - Mac vs PC

Logitech Dual Action Gamepads – Mac vs PC

I picked up a Mac version cheap from the usual eBay seller and discovered that LinuxCNC / HAL was perfectly happy. That wasn’t too surprising; they have the same model and part numbers. Most likely, the only difference was the CD and maybe the Quick Start Guide that I didn’t get in the opened retail box…

So now I have either a hot backup for the Joggy Thing or one for a different box.

Most likely, it was cheap because nobody wants a blue-and-black peripheral next to their shiny white Mac…

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G-Code and M-Code Grand Master List

Posted by Ed in Machine Shop, Software on 14-March-2013

Here’s a combined and sorted list of all the G-Code and M-Code commands for (as many of) the Free Software G-Code interpreters (that I could find) relevant to DIY 3D printing. With any luck, I now know:

  • What a given command does
  • What other interpreters do with that command

The short descriptions come from tables on the original source pages, perhaps with a bit of massaging to make things more uniform; I did as little rearranging and editing as possible.

If you see anything wrong or have another G-Code interpreter I should include, let me know…

3D Printer G-Code and M-Code Commands

27 Feb 2013
Ed Nisley - KE4ZNU

V3 - NIST RS274NGC V3- http://www.nist.gov/manuscript-publication-search.cfm?pub_id=823374
LC - LinuxCNC - http://www.linuxcnc.org/docs/2.5/html/
RG - ReplicatorG - http://replicat.org/gcodes and /mcodes
JF - Jetty Firmware - http://replicat.org/mcodes at bottom
RR - RepRap - http://reprap.org/wiki/G_codes (cross-linked from many G-Code pages)
MF - Marlin Firmware dialect of RR (via Dan Newman)

G0  LC  Coordinated Straight Motion Rapid
G0  MF  same as G1
G0  RG  Rapid Motion
G0  RR  Rapid move
G0  V3  rapid positioning
G1  LC  Coordinated Straight Motion Feed Rate
G1  MF  Coordinated Movement X Y Z E
G1  RG  Coordinated Motion
G1  RR  Controlled move
G1  V3  linear interpolation
G2  LC  Coordinated Helical Motion Feed Rate
G2  MF  CW ARC
G2  RG  Arc - Clockwise
G2  V3  circular/helical interpolation (clockwise)
G3  LC  Coordinated Helical Motion Feed Rate
G3  MF  CCW ARC
G3  RG  Arc - Counter Clockwise
G3  V3  circular/helical interpolation (counterclockwise)
G4  LC  Dwell
G4  MF  Dwell S<seconds> or P<milliseconds>
G4  RG  Dwell
G4  RR  Dwell
G4  V3  dwell
G5.1    LC  Quadratic B-Spline
G5.2    LC  NURBs Block Open
G5.3    LC  NURBs Block Close
G7  LC  Diameter Mode (lathe)
G8  LC  Radius Mode (lathe)
G10 LC  L10 Set Tool Table, Calculated, Workpiece
G10 LC  L11 Set Tool Table, Calculated, Fixture
G10 LC  L1  Set Tool Table Entry
G10 LC  L20 Coordinate System Origin Setting Calculated
G10 LC  L2  Coordinate System Origin Setting
G10 RG  Create Coordinate System Offset from the Absolute one
G10 RR  Head Offset
G10 V3  coordinate system origin setting
G17 LC  Arc plane XY
G17 RG  Select XY plane (default)
G17 V3  XY-plane selection
G17.1   LC  Arc plane UV
G18 LC  Arc plane ZX
G18 RG  Select XZ plane (not implemented)
G18 V3  XZ-plane selection
G18.1   LC  Arc plane WU
G19 LC  Arc plane YZ
G19 RG  Select YX plane (not implemented)
G19 V3  YZ-plane selection
G19.1   LC  Arc plane VW
G20 LC  Unit of Measure - inch
G20 RG  Inches as units
G20 RR  Set Units to Inches
G20 V3  inch system selection
G21 LC  Unit of Measure - millimeter
G21 RG  Millimeters as units
G21 RR  Set Units to Millimeters
G21 V3  millimeter system selection
G28 LC  Go to Predefined Position
G28 MF  Home all Axis
G28 RG  Home given Axes to maximum
G28 RR  Move to Origin
G28 V3  return to home
G28.1   LC  Store Predefined Position
G29-G32 RR  Bed probing
G30 LC  Go to Predefined Position
G30 RG  Go Home via Intermediate Point (not implemented)
G30 V3  return to secondary home
G30.1   LC  Store Predefined Position
G31 RG  Single probe (not implemented)
G32 RG  Probe area (not implemented)
G33 LC  Spindle Synchronized Motion
G33.1   LC  Rigid Tapping
G38.2   LC  Probe toward, stop on contact, error
G38.2   V3  straight probe
G38.3   LC  Probe toward, stop on contact
G38.4   LC  Probe away, stop on release, error
G38.5   LC  Probe away, stop on release
G40 LC  Cancel Cutter Compensation
G40 V3  cancel cutter radius compensation
G41 LC  Cutter Compensation - left
G41 V3  start cutter radius compensation left
G41.1   LC  Dynamic Cutter Compensation - left
G42 LC  Cutter Compensation - right
G42 V3  start cutter radius compensation right
G42.1   LC  Dynamic Cutter Compensation - right
G43 LC  Use Tool Length Offset from Tool Table
G43 V3  tool length offset (plus)
G43.1   LC  Dynamic Tool Length Offset
G49 LC  Cancel Tool Length Offset
G49 V3  cancel tool length offset
G53 LC  Motion in Machine Coordinate System
G53 RG  Set absolute coordinate system
G53 V3  motion in machine coordinate system
G54-G59 RG  Use coordinate system from G10 P0-5
G54 LC  Select Coordinate System 1
G54 V3  use preset work coordinate system 1
G55 LC  Select Coordinate System 2
G55 V3  use preset work coordinate system 2
G56 LC  Select Coordinate System 3
G56 V3  use preset work coordinate system 3
G57 LC  Select Coordinate System 4
G57 V3  use preset work coordinate system 4
G58 LC  Select Coordinate System 5
G58 V3  use preset work coordinate system 5
G59 LC  Select Coordinate System 6
G59 V3  use preset work coordinate system 6
G59.1   LC  Select Coordinate System 7
G59.1   V3  use preset work coordinate system 7
G59.2   LC  Select Coordinate System 8
G59.2   V3  use preset work coordinate system 8
G59.3   LC  Select Coordinate System 9
G59.3   V3  use preset work coordinate system 9
G61 LC  Path Control Mode - exact path
G61 V3  set path control mode: exact path
G61.1   LC  Path Control Mode - exact stop (same as G61)
G61.1   V3  set path control mode: exact stop
G64 LC  Path Control Mode - Optional Tolerance
G64 V3  set path control mode: continuous
G73 LC  Drilling Cycle with Chip Breaking
G76 LC  Multi-pass Threading Cycle (Lathe)
G80 LC  Cancel Motion Modes
G80 V3  cancel motion mode (including any canned cycle)
G81 LC  Drilling Cycle
G81 V3  canned cycle: drilling
G82 LC  Drilling Cycle with Dwell
G82 V3  canned cycle: drilling with dwell
G83 LC  Drilling Cycle with Peck
G83 V3  canned cycle: peck drilling
G84 V3  canned cycle: right hand tapping
G85 LC  Boring Cycle, No Dwell, Feed Out
G85 V3  canned cycle: boring, no dwell, feed out
G86 LC  Boring Cycle, Stop, Rapid Out
G86 V3  canned cycle: boring, spindle stop, rapid out
G87 V3  canned cycle: back boring
G88 V3  canned cycle: boring, spindle stop, manual out
G89 LC  Boring Cycle, Dwell, Feed Out
G89 V3  canned cycle: boring, dwell, feed out
G90 LC  G91 Distance Mode
G90 MF  Use Absolute Coordinates
G90 RG  Absolute Positioning
G90 RR  Set to Absolute Positioning
G90 V3  absolute distance mode
G90.1   LC  Arc Distance Mode - absolute IJK
G91 MF  Use Relative Coordinates
G91 RG  Relative Positioning
G91 RR  Set to Relative Positioning
G91 V3  incremental distance mode
G91.1   LC  Arc Distance Mode - incremental IJK
G92.1   V3  cancel offset coordinate systems and set parameters to zero
G92 LC  Coordinate System Offset
G92 MF  Set current position to cordinates given
G92 RG  Define current position on axes
G92 RR  Set Position
G92 V3  offset coordinate systems and set parameters
G92.1   LC  Cancel Coordinate System Offsets
G92.2   LC  Cancel Coordinate System Offsets
G92.2   V3  cancel offset coordinate systems but do not reset parameters
G92.3   LC  Restore Axis Offsets
G92.3   V3  apply parameters to offset coordinate systems
G93 LC  Feed Mode - Inverse time
G93 V3  inverse time feed rate mode
G94 LC  Feed Mode - Units per minute
G94 RG  Feed rate mode (not implemented)
G94 V3  units per minute feed rate mode
G95 LC  Feed Mode - Units per revolution
G96 LC  Constant Surface Speed
G97 LC  RPM Mode
G97 RG  Spindle speed rate
G98 LC  Canned Cycle Z Retract Mode
G98 V3  initial level return in canned cycles
G99 LC  Canned Cycle Z Retract Mode
G99 V3  R-point level return in canned cycles
G161    RG  Home negative
G162    RG  Home positive

M0  LC  Program Pause
M0  RG  Unconditional Halt (not supported on SD)
M0  RR  Stop
M0  V3  program stop
M1  LC  Program Pause - optional
M1  RG  Optional Halt (not supported on SD)
M1  RR  Sleep
M1  V3  optional program stop
M2  LC  Program End
M2  RG  End program
M2  V3  program end
M3  LC  Spindle Control - clockwise ON
M3  RG  spindle on, CW
M3  RR  Spindle On, Clockwise (CNC specific)
M3  V3  turn spindle clockwise
M4  LC  Spindle Control - counterclockwise ON
M4  RG  spindle on, CCW
M4  RR  Spindle On, Counter-Clockwise (CNC specific)
M4  V3  turn spindle counterclockwise
M5  LC  Spindle Control - OFF
M5  RG  spindle off
M5  RR  Spindle Off (CNC specific)
M5  V3  stop spindle turning
M6  LC  Tool Change
M6  RG  Tool change. This code waits until the toolhead is ready before proceeding. This is often used to wait for a toolhead to reach the its set temperature before beginning a print. ReplicatorG also supports giving a timeout with M6 P<secs>.
M6  V3  tool change
M7  LC  Coolant Control - mist ON
M7  RG  coolant A on (flood coolant)
M7  RR  Mist Coolant On (CNC specific)
M7  V3  mist coolant on
M8  LC  Coolant Control - flood ON
M8  RG  cooland B on (mist coolant)
M8  RR  Flood Coolant On (CNC specific)
M8  V3  flood coolant on
M9  LC  Coolant Control - OFF
M9  RG  all coolants off
M9  RR  Coolant Off (CNC specific)
M9  V3  mist and flood coolant off
M10 RG  close clamp
M10 RR  Vacuum On (CNC specific)
M11 RG  open clamp
M11 RR  Vacuum Off (CNC specific)
M13 RG  spindle CW and coolant A on
M14 RG  spindle CCW and coolant A on
M17 MF  Enable/Power all stepper motors
M17 RG  enable motor(s)
M17 RR  Enable/Power all stepper motors
M18 MF  Disable all stepper motors; same as M84
M18 RG  disable motor(s)
M18 RR  Disable all stepper motors
M20 MF  List SD card
M20 RR  List SD card
M21 MF  Init SD card
M21 RG  open collet
M21 RR  Initialize SD card
M22 MF  Release SD card
M22 RG  close collet
M22 RR  Release SD card
M23 MF  Select SD file (M23 filename.g)
M23 RR  Select SD file
M24 MF  Start/resume SD print
M24 RR  Start/resume SD print
M25 MF  Pause SD print
M25 RR  Pause SD print
M26 MF  Set SD position in bytes (M26 S12345)
M26 RR  Set SD position
M27 MF  Report SD print status
M27 RR  Report SD print status
M28 MF  Start SD write (M28 filename.g)
M28 RR  Begin write to SD card
M29 MF  Stop SD write
M29 RR  Stop writing to SD card
M30 LC  Program End - exchange pallet shuttles
M30 MF  Delete file from SD (M30 filename.g)
M30 RG  program rewind
M30 RR  Delete a file on the SD card
M30 V3  program end, pallet shuttle, and reset
M31 MF  Output time since last M109 or SD card start to serial
M40-M46 RG  change gear ratio (0 - 6)
M40 RR  Eject
M41 RR  Loop
M42 MF  Change pin status via gcode
M42 RR  Stop on material exhausted / Switch I/O pin
M43 RR  Stand by on material exhausted
M48 LC  Feed & Spindle Overrides - Enable
M48 V3  enable speed and feed overrides
M49 LC  Feed & Spindle Overrides - Disable
M49 V3  disable speed and feed overrides
M50 LC  Feed Override Control
M50 RG  read spindle speed
M51 LC  Spindle Override Control
M52 LC  Adaptive Feed Control
M53 LC  Feed Stop Control
M60 LC  Pallet Change Pause
M60 V3  pallet shuttle and program stop
M61 LC  Set Current Tool Number
M62 LC  Output Control - synchronized ON
M63 LC  Output Control - synchronized OFF
M64 LC  Output Control - immediate ON
M65 LC  Output Control - immediate OFF
M66 LC  Input Control - wait
M67 LC  Analog Output Control - synchronized
M68 LC  Analog Output Control - immediate
M70 RG  Display message on machine, with optional timeout specified by P-code in seconds
M71 RG  Pause activity and display message, resuming build on button push. Optional timeout specified by P-code in seconds. If timeout is specified and no button is pushed, machine should shut down or reset.
M72 RG  Play a song or tone defined by the machine, by a P-code specifying a song type. Default songs are Error Sound (P0), a Ta-da sound (P1), and a warning sound (P2). all other sounds are user or machine specific, with P2 the default for unknown sounds.
M73 RG  Manually set build percentage. Valid P values are 0 to 100, values over 100 are rounded down to 100
M80 MF  Turn on Power Supply
M80 RR  ATX Power On
M81 MF  Turn off Power Supply
M81 RR  ATX Power Off
M82 MF  Set E codes absolute (default)
M82 RR  set extruder to absolute mode
M83 MF  Set E codes relative while in Absolute Coordinates (G90) mode
M83 RR  set extruder to relative mode
M84 MF  Disable steppers until next move, or use S<seconds> to specify an inactivity timeout, after which the steppers will be disabled.  S0 to disable the timeout.
M84 RR  Stop idle hold
M85 MF  Set inactivity shutdown timer with parameter S<seconds>. To disable set zero (default)
M92 MF  Set axis_steps_per_unit - same syntax as G92
M92 RR  Set axis_steps_per_unit
M98 RR  Get axis_hysteresis_mm
M99 RR  Set axis_hysteresis_mm
M100    LC  through M199   User Defined M codes
M101    RR  Extruder on, fwd
M101    RR  Turn extruder 1 on Forward / Undo Extruder Retraction
M102    RR  Extruder on, reverse
M102    RR  Turn extruder 1 on Reverse
M103    RR  Extruder off
M103    RR  Turn all extruders off / Extruder Retraction
M104    MF  Set extruder target temp
M104    RR  Set Extruder Temperature
M104    RR  Snn set temperature in degrees Celsius
M105    MF  Read current temp
M105    RR  get extruder temperature
M105    RR  Get Extruder Temperature
M106    MF  Fan on
M106    RR  Fan On
M106    RR  turn fan on
M107    MF  Fan off
M107    RR  Fan Off
M107    RR  turn fan off
M108    RR  Set Extruder's Max Speed (Rnnn = RPM, Pnnn = PWM)
M108    RR  Set Extruder Speed
M109    MF  Wait for extruder current temp to reach target temp.
M109    RR  Set Extruder Temperature and Wait
M109    RR  Snnn set build platform temperature in degrees Celsuis
M110    RR  Set Current Line Number
M110    RR  Snnn set chamber temperature in degrees Celsius
M111    RR  Set Debug Level
M112    RR  Emergency Stop
M113    RR  Set Extruder PWM
M114    MF  Display current position
M114    MF  Output current position to serial port
M114    RR  Get Current Position
M115    MF  Capabilities string
M115    RR  Get Firmware Version and Capabilities
M116    RR  Wait
M117    MF  display message
M117    RR  Get Zero Position
M118    RR  Negotiate Features
M119    MF  Output Endstop status to serial port
M119    RR  Get Endstop Status
M120    RR  M121, M122 Snnn set the PID gain for the temperature regulator (not currently supported by ReplicatorG)
M123    RR  M124 Snnn set iMax and iMin windup guard for the PID controller (not currently supported by ReplicatorG)
M126    JF  use acceleration for subsequent instructions
M126    RG  valve open (acceleration on for subsequent instructions in the Jetty Firmware)
M126    RR  Open Valve
M127    JF  disable acceleration for subsequent instructions
M127    RG  valve close (acceleration off for subsequent instructions in the Jetty Firmware)
M127    RR  Close Valve
M128    RR  Extruder Pressure PWM
M128    RR  get position
M129    RR  Extruder pressure off
M129    RR  get range (not currently supported by ReplicatorG)
M130    RR  Set PID P value
M130    RR  set range (not currently supported by ReplicatorG)
M131    RR  Set PID I value
M132    RR  Set PID D value
M133    RR  Set PID I limit value
M134    RR  Write PID values to EEPROM
M136    RR  Print PID settings to host
M140    MF  Set bed target temp
M140    RR  Bed Temperature (Fast)
M141    RR  Chamber Temperature (Fast)
M142    RR  Holding Pressure
M143    RR  Maximum hot-end temperature
M160    RR  Number of mixed materials
M190    MF  Wait for bed current temp to reach target temp.
M190    RR  Wait for bed temperature to reach target temp
M200    JF  reset (to pick up changes)
M200    MF  Set filament diameter
M200    RR  reset driver
M200    RR  Set filament diameter / Get Endstop Status
M201    JF  set maximum rates of acceleration/deceleration
M201    MF  Set max acceleration in units/s^2 for print moves (M201 X1000 Y1000)
M201    RR  Set max printing acceleration
M202    MF  Set max acceleration in units/s^2 for travel moves (M202 X1000 Y1000) Unused in Marlin!!
M202    RR  clear buffer (not currently supported by ReplicatorG)
M202    RR  Set max travel acceleration
M203    JF  set maximum feed rates
M203    MF  Set maximum feedrate that your machine can sustain (M203 X200 Y200 Z300 E10000) in mm/sec
M203    RR  Set maximum feedrate
M204    JF  set default rates of acceleration
M204    MF  Set default acceleration: 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
M204    RR  Set default acceleration
M205    JF  set minimum feed rates and planner speed
M205    MF   advanced settings:  minimum travel speed S=while printing T=travel only,  B=minimum segment time X= maximum xy jerk, Z=maximum Z jerk, E=maximum E jerk
M205    RR  advanced settings
M206    JF  set extruded noodle diameter, extruder maximum reverse feed rate, extruder deprime, slowdown limit, and direction of extruder feed
M206    MF  set additional homeing offset
M206    RR  set home offset
M207    JF  set JKN Advance parameters K and K2
M207    RR  calibrate z axis by detecting z max length
M208    JF  set extruder steps per millimeter
M208    RR  set axis max travel
M209    JF  turn acceleration planner on or off; enable or disable override of gcode temperature settings
M209    RR  enable automatic retract
M215    JF  set steps per millimeter for each axis
M216    JF  set maximum speed changes for each axis
M220    MF  S<factor in percent> set speed factor override percentage
M220    RR  Set speed factor override percentage
M221    MF  S<factor in percent> set extrude factor override percentage
M221    RR  set extrude factor override percentage
M226    RR  Gcode Initiated Pause
M227    RR  Enable Automatic Reverse and Prime
M228    RR  Disable Automatic Reverse and Prime
M229    RR  Enable Automatic Reverse and Prime
M230    RR  Disable / Enable Wait for Temperature Change
M240    MF  Trigger a camera to take a photograph
M240    RR  Start conveyor belt motor / Echo off
M241    RR  Stop conveyor belt motor / echo on
M245    RR  Start cooler
M246    RR  Stop cooler
M300    RR  Play beep sound
M300    RR  Snnn set servo 1 position
M301    MF  Set PID parameters P I and D
M301    RR  Set PID parameters - Hot End
M301    RR  Snnn set servo 2 position
M302    MF  Allow cold extrudes
M303    MF  PID relay autotune S<temperature> sets the target temperature. (default target temperature = 150C)
M304    RR  Set PID parameters - Bed
M310    RG  (filepath) logging
M311    RG  stop logging
M312    RG  (message) log message
M320    RG  acceleration on for subsequent instructions
M321    RG  acceleration off for subsequent instructions
M400    MF  Finish all moves
M420    RR  Set RGB Colors as PWM
M500    MF  stores paramters in EEPROM
M500    RR  stores paramters in EEPROM
M501    MF  reads parameters from EEPROM (if you need reset them after you changed them temporarily).
M501    RR  reads parameters from EEPROM
M502    MF  reverts to the default "factory settings".  You still need to store them in EEPROM afterwards if you want to.
M502    RR  reverts to the default "factory settings".
M503    MF  print the current settings (from memory not from eeprom)
M503    RR  Print settings
M999    MF  Restart after being stopped by error

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Eagle HAL Configuration: Sherline HAL File

Posted by Ed in Machine Shop, Software on 6-March-2013

More hal-config.lbr tweakage produced enough HAL blocks to completely define the Sherline CNC mill’s HAL connections, all wired up in a multi-page schematic (Eagle-LinuxCNC-Sherline.zip.odt) that completely replaces all the disparate *.hal files I’d been using, plus a new iteration of the hal-write-2.5.ulp Eagle-to-HAL conversion script.

The first sheet (clicky for more dots) defines the manually configured userspace and realtime modules:

Sherline Schematic - 1

Sherline Schematic – 1

That sheet has three types of Eagle devices:

  • Generalized LoadRT – devices like trivkins that require only a loadrt line
  • Dedicated LoadRT – devices like motion that require functions connected to a realtime thread
  • Generalized LoadUsr – devices like hal_input with a HAL device, but no function pins

The device’s NAME field contains either the module name (for the specialized devices with functions) or a generic MODULE for everything else, preceded by an optional index that imposes an ordering on the output lines. The device’s VALUE field contains the text that will become the loadrt or loadusr line in the HAL file. Trailing underscores act as separators, but are discarded by the conversion script.

The immensely long line is the VALUE field that plugs a bunch of variables from the Sherline.ini file into the motion controller.

The conversion script doesn’t do anything special for those devices, other than transfer the VALUE field to the HAL file. Ordinary HAL devices, the ones with functions that don’t require any special setup, must appear in the conversion script’s list of device names, so that it can recognize them and deal with their connections.

That sheet produces this part of the HAL file:

####################################################
# Load realtime and userspace modules
loadrt trivkins
loadrt [EMCMOT]EMCMOT key=[EMCMOT]SHMEM_KEY num_joints=[TRAJ]AXES base_period_nsec=[EMCMOT]BASE_PERIOD servo_period_nsec=[EMCMOT]SERVO_PERIOD traj_period_nsec=[EMCMOT]SERVO_PERIOD
loadrt probe_parport
loadrt hal_parport cfg=&quot;[PARPORT]ADDRESS out&quot;
loadrt stepgen step_type=0,0,0,0
loadrt pwmgen output_type=0
loadusr -W hal_manualtoolchange
loadusr -W hal_input -KA Dual
loadrt logic count=1 personality=0x104

The conversion script counts the other schematic devices and automagically produces these lines to load their corresponding modules:

loadrt constant		count=13
loadrt and2		count=17
loadrt conv_float_s32		count=1
loadrt flipflop		count=4
loadrt mux2		count=5
loadrt mux4		count=1
loadrt not		count=8
loadrt or2		count=14
loadrt scale		count=7
loadrt timedelay		count=1
loadrt toggle		count=1

Next, the parallel port configuration, which uses the D525′s system board hardware:

Sherline Schematic - 2

Sherline Schematic – 2

The stepconf configuration utility buries the parallel port configuration values in the default HAL file as magic numbers. I moved them to a new stanza in the INI file, although the syntax may not be robust enough to support multiple cards, ports, and configurations. This, however, works for now:

[PARPORT]
ADDRESS = 0x378
RESET_TIME = 10000
STEPLEN = 25000
STEPSPACE = 25000
DIRSETUP = 50000
DIRHOLD = 50000

That LOGIC block is new and serves as an AND gate that produces a combined enable signal for the parallel port. The stepconf utility uses the X axis enable signal, but, seeing as how the Sherline controller doesn’t use the result, none of that matters on my system.

The tool height probe and manual tool change wiring:

Sherline Schematic - 3

Sherline Schematic – 3

I’m not convinced the Emergency Stop polarity is correct, but it matches what was in the original HAL file. As before, the Sherline driver box ignores that output, so none of that matters right now.

Four very similar pages define the XYZA step-and-direction generators. This is the X axis driver:

Sherline Schematic - 4

Sherline Schematic – 4

You can imagine what the next three pages for the YZA logic look like, right? There are also a few blank pages in the schematic, so the numbers jump abruptly.

The magic part of this is having Eagle manage all the tedious renumbering and counting. If you remember to adjust the name of the first module from, say, AXIS.1 to AXIS.0, then the rest get the proper numbers as you go along.

The remainder of the schematic implements the Joggy Thing’s logic, much as described there. I discovered, quite the hard way, that copy-and-pasting an entire schematic from elsewhere does horrible things to the device numbering, but I’m not sure how to combine two schematics to limit the damage. In any event, manually adjusting a few pages wasn’t the worst thing I’ve ever had to do; starting with a unified schematic should eliminate that task in the future.

The miscellaneous buttons:

Sherline Schematic - 11

Sherline Schematic – 11

The joystick and hat values:

Sherline Schematic - 12

Sherline Schematic – 12

The joystick deadband logic now uses the (new with HAL 2.5, I think) input.n.abs-x-flat pins, which eliminated a tangle of window comparator logic.

The jog speed adjustment logic that sets the fast and crawl speeds:

Sherline Schematic - 13

Sherline Schematic – 13

I should probably put the speed ratios in the INI file, but that’s in the nature of fine tuning.

The lockout logic that remembers which axis started moving first on a given joystick and locks out the other axis, which greatly simplifies jogging up to an edge without bashing into something else:

Sherline Schematic - 14

Sherline Schematic – 14

Combine all those signals into values that actually tell HAL to jog the axes:

Sherline Schematic - 15

Sherline Schematic – 15

The last page connects all the realtime function pins to the appropriate threads:

Sherline Schematic - 16

Sherline Schematic – 16

The LinuxCNC documentation diverges slightly from the implementation, but a few iterations resolved all the conflicts and had the additional benefit that I had to carefully think through what was actually going on.

A deep and sincere tip o’ the cycling helmet to the folks making LinuxCNC happen!

Although the Sherline mill doesn’t have more than a few minutes of power-on time with the new HAL file, the Joggy Thing behaves as it used to and the axes move correctly, so I think the schematic came out pretty close to the original HAL file.

The next step: draw a new schematic to bring up and exercise a different set of steppers…

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Gratuitous Engine Jeweling

Posted by Ed in Electronics Workbench, Machine Shop, PC Tweakage on 2-March-2013

While pondering whether I should use the carcass of an old Dell PC to house the stepper drivers and control logic for the LinuxCNC M2 project, I bandsawed a scrap of aluminum sheet to about the right size. It had some truly nasty gouges and bonded-on crud, so I chucked up a wire brush cup in the drill press and had at it:

Machine jeweled baseplate

Machine jeweled baseplate

It’s obvious I haven’t done jeweling in a long time, isn’t it? Even a crude engine jeweling job spiffs things right up, though, even if a cough showcase job like this deserves straighter lines and more precise spacing. The aluminum sheet is far too large for the Sherline, which put CNC right out of consideration, and I’m not up for sufficient crank spinning on the big manual mill.

I match-marked mounting holes directly from the harvested motherboard and drilled them, whereupon I discovered that the aluminum is a dead-soft gummy alloy that doesn’t machine cleanly: it won’t become the final baseplate.

Memo to Self: Use the shop vacuum with the nozzle spinward of the brush, fool.

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Eagle 6.4 Schematics for LinuxCNC 2.5 HAL Configuration: Device Creation Checklist

Posted by Ed in Machine Shop, Software on 28-February-2013

I’m updating the Eagle-to-HAL script and library I used to get the Joggy Thing working, with the intent of getting a Nostromo N52 working on another LinuxCNC box.

To that end, here’s a checklist for creating a new Eagle device corresponding to a HAL module.

Remember: although this process has a tremendous number of moving parts, you do it exactly once when you need a device that doesn’t already exist. After that, you just click to add an existing device to your schematic, wire it up, then the tedious write-only HAL overhead happens automagically.

Cross-check the documentation with the actual component code!

The man page lists the names, pins, parameters, and suchlike, but may have typos. This isn’t a criticism, it’s a fact of life.

Before investing a ton o’ time creating an Eagle device, load the module and find out what’s really there:

halrun
halcmd: loadrt conv_float_s32
halcmd: show all
Loaded HAL Components:
ID      Type  Name                                      PID   State
     4  RT    conv_float_s32                                  ready
     3  User  halcmd2395                                 2395 ready

Component Pins:
Owner   Type  Dir         Value  Name
     4  float IN              0  conv-float-s32.0.in
     4  s32   OUT             0  conv-float-s32.0.out
     4  bit   OUT         FALSE  conv-float-s32.0.out-of-range

... snippage ...

Parameters:
Owner   Type  Dir         Value  Name
     4  bit   RW          FALSE  conv-float-s32.0.clamp
     4  s32   RO              0  conv-float-s32.0.time
     4  s32   RW              0  conv-float-s32.0.tmax

... snippage ...

Exported Functions:
Owner   CodeAddr  Arg       FP   Users  Name
 00004  fc0a9000  fc0630b8  YES      0   conv-float-s32.0
... snippage ...

Achtung!

  • The module name uses underscores as separators: loadrt conv_float_s32
  • The function name uses h-y-p-h-e-n-s as separators: conv-float-s32.0
  • Unlike in the Linux kernel, the two characters are not equivalent

Add the HAL Module to the Conversion Script

The hal-write.ulp script contains a table of all the module names, so you must update the script in parallel with the hal-config.lbr Eagle library.

However, you can create an Eagle device that is not a HAL module by omitting it from the script. In that case, the Eagle device name will become part of the net names that define and interconnect the pins, but the script will not create a statement to load a module. For example, the hal_input userspace program creates a set of pins for each input device that start with input.n, but there’s no corresponding HAL module. I’ll put up an example of all this in a bit.

Create a Schematic Symbol

  • The name of the symbol is not critical: CONVERT.sym
    • use either dashes or hyphens as you prefer
  • The >NAME string must be on layer 95-Names
  • No need for a >VALUE string, but put it on layer 96-Values if present
  • HAL pins become symbol pins
    • Use the HAL pin name, with hyphens
    • Set Visibility to Pin
    • Set Direction to in / out / io to match the HAL description
    • Set Function to None to indicate an ordinary net connection
  • Verify the pins against the HAL device!

Create a HAL Schematic Device

  • The new device name must match the HAL module name, with underscores, as entered in the conversion script table
    • CONV_FLOAT_S32.dev
  • Set the Prefix to the HAL function name, plus a trailing period, with hyphens
    • CONV-FLOAT-S32.
  • Create the Description using copy-and-paste from the HTML source: use the man page in the LinuxCNC doc
    • Ctrl-U in Firefox reveals the HTML source, Ctrl-A and Ctrl-C, flip windows, then Ctrl-V
    • Delete all the boilerplate at the top, leave the centered Title, ditch the reference links
  • Add the symbol you created earlier or reuse an existing symbol
    • Set the symbol NAME to a single underscore: _
    • Change the Add level to must
  • Add a PIN_FUNCTION symbol to the device
    • Change the symbol name from G$1 (or whatever) to a single period: .
    • Change the Add Level to must
  • Add PIN_PARAMETER symbols as needed
    • Change the symbol name from G$1 (or whatever) to the parameter name preceded by a single period: .CLAMP
    • Change the Add Level to request
    • Change the Direction as needed
  • Add the DUMMY physical package, then connect all the pins to pads

Create a non-HAL Schematic Device

  • The new device name may be anything that’s not in the conversion script table
  • The Prefix must match the desired pin names, plus a trailing period. For hal_input pins:
    • INPUT.
  • Create the Description as above
  • Add the symbol you created earlier
    • Set the symbol NAME to a single underscore: _
    • Change the Add level to must
  • Do not add a PIN_FUNCTION symbol, because it has no corresponding module
  • Add PIN_PARAMETER symbols as needed
    • Change the symbol name from G$1 (or whatever) to the parameter name preceded by a single period: .CLAMP
    • Change the Add Level to request
    • Change the Direction as needed
  • Add the DUMMY physical package, then connect all the pins to pads

Devices may have multiple Symbols, with different Add Level options; can seems appropriate. As nearly as I can tell, you must name each Symbol as a suffix to the full name to differentiate them within the Device; I use a hyphen before the suffix, so that -KEYS generates INPUT.0-KEYS. Those suffixes don’t appear elsewhere in the generated HAL configuration file.

Save the library, update it in the schematic editor (Library → Update ...), and you’re set.

Although it’s tempting, do not include a version number in the library file name, because Eagle stores the file name inside the schematic file along with the devices from that file. As a result, when you bump the library version number and use devices from the new library file, the schematic depends on both library files and there’s no way within Eagle to migrate devices from one library to the other; you must delete the existing devices from the schematic and re-place them from the new library. Or you can do like I did: hand-edit the XML fields inside the library file.

Eagle HAL Device

Eagle HAL Device

You’ll almost certainly drive this procedure off the rails, so let me know what I’ve screwed up. It does, in fact, work wonderfully well and, as far as I’m concerned, makes HAL usable, if only because HAL is a write-only language to start with and now you need not read it to modify it.

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Hall Effect Current Sensor: Winding and Armoring the Toroid

Posted by Ed in Electronics Workbench, Machine Shop on 22-January-2013

Winding a slit ferrite toroid poses no challenge, so putting 25 turns of 26 AWG wire on it didn’t take long at all:

F50-61 toroid - 25 turns 26 AWG

F50-61 toroid – 25 turns 26 AWG

However, a ferrite toroid doesn’t take kindly to being dropped and I figured that a slit toroid would crack under a stern look, so I decided to wrap some armor around it. A small squeeze bottle offered a cap just slightly larger than the winding, so I used that slitting saw to cut off a suitable ring.  The first step was to grab it in the 3 jaw chuck and align its axis parallel to the spindle:

Aligning bottle cap in 3-jaw chuck

Aligning bottle cap in 3-jaw chuck

I wanted to cut off a slightly taller ring, but the clamping screw on the saw arbor just barely cleared the chuck for a 5 mm ring. I jogged around the chuck jaws to cut two slits in the cap that eventually joined near the back:

Slicing ring from bottle cap

Slicing ring from bottle cap

That was about 1000 rpm, no coolant, and slow feed, but also a totally non-critical cut in plastic.

I put a snippet of foam rubber in the slot, put the ring on a Kapton-covered build platform from the Thing-O-Matic, filled it with hot-melt glue, gooshed the toroid in place, and waited for cooling. Trimming and cleaning out the slit produced a hideously ugly, but (I hope) much more durable assembly:

Slit ferrite toroid - with armor

Slit ferrite toroid – with armor

I’m reasonably sure I didn’t crack the ferrite while cleaning out the slit; that hot-melt glue is tenaciously gummy stuff!

Now, to find out whether it actually works…

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Slitting a Ferrite Toroid

Posted by Ed in Electronics Workbench, Machine Shop on 21-January-2013

The object of the game: cut a slit into a ferrite toroid that will accommodate a Hall effect sensor. Those doodles showed that an FT50 (half-inch OD) toroid would be about right for the cheap AH49/EH49 Hall effect sensors on hand and those doodles shows that the permeability of the ferrite mix doesn’t make much difference. Not being quite sure how this would work out, I figured I’d start with the simplest possible setup and complexicate things until it worked…

A fold of cereal box cardboard cushioned the brittle ferrite in the Sherline’s clamp and the vacuum hose in the background collects airborne grit. I touched off X=Y=Z=0 with the wheel at the center of the toroid’s equator:

Slitting ferrite toroid - first pass

Slitting ferrite toroid – first pass

The first pass went swimmingly, with the diamond wheel far more concentric than I expected, using manual jogging along a 0.5 mm deep cut. The wheel is slightly over 0.5 mm thick, measured on the grit, and showed no sign of strain on a 1 mm deep cut at 100 mms/min, so I used manual CNC to run the wheel back and forth along the cut.

After clearing the slot, I moved the wheel upward to + 0.5 mm, repeated the passes with a 1.5 mm depth of cut, then did the same at -0.5 mm. The end result was a nice slot with parallel sides:

Slitting ferrite toroid - complete

Slitting ferrite toroid – complete

The actual gap measured 1.72 mm, not the 1.5 I wanted, which means the flux density will be lower than the previous calculations predict. Assuming the Z axis backlash compensation works as it should, then the kerf is 0.72 mm. Of course, that also assumes the arbor runs true and the wheel cuts symmetrically, neither of which I’d put (or, heck, have put) a lot of money behind. On the other paw, the sensors are 1.5 mm thick (just under the datasheet’s 1.6 mm spec), so +0.1 mm clearance on each side works a whole lot better for me than, say, -0.1 mm.

All in all, there was no excitement, no muss, no fuss, no chipping, no breakage:

FT50 ferrite toroid with slit

FT50 ferrite toroid with slit

Talk about beginner’s luck!

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