debounce probe pin and remove python2 use

3040T.hal

@@ -9,22 +9,24 @@ loadrt timedelay count=2
 loadrt or2 count=3
 loadrt xor2 count=2
 loadrt mux_generic config="bb2"
+loadrt dsmono count=1
+loadrt timedelta count=1
 
 addf parport.0.read base-thread
 addf stepgen.make-pulses base-thread
 addf parport.0.write base-thread
 addf parport.0.reset base-thread
 addf mux-gen.00 base-thread
+addf timedelta.0 base-thread
 
 addf stepgen.capture-position servo-thread
 addf motion-command-handler servo-thread
 addf motion-controller servo-thread
 addf stepgen.update-freq servo-thread
+addf dsmono.0 servo-thread
 
 #Pin Assignments
 
-net probe-in => motion.probe-input
-
 net estop-out       => parport.0.pin-01-out
 net xstep           => parport.0.pin-02-out
 setp parport.0.pin-02-out-reset 1
@@ -43,7 +45,13 @@ net estop-ext       <= parport.0.pin-10-in
 net min-home-x      <= parport.0.pin-11-in-not
 net min-home-y      <= parport.0.pin-12-in-not
 net max-home-z      <= parport.0.pin-13-in-not
-net probe-in        <= parport.0.pin-15-in-not
+
+#Probe
+setp dsmono.0.deadtime-ns 50000000
+net probe-in <= parport.0.pin-15-in-not
+net probe-in => dsmono.0.in
+net probe-debounced <= dsmono.0.out
+net probe-debounced => motion.probe-input
 
 #X-Axis
 setp stepgen.0.position-scale [JOINT_0]SCALE
@@ -139,6 +147,7 @@ net amp-enable halui.machine.is-on => cncextension.wr0
 #Main Spindle Control
 net spindle-main-fwd spindle.0.forward
 net spindle-main-fwd => cncextension.ch0
+net spindle-main-fwd => cncextension.ch2
 net spindle-main-fwd => cncextension.opt
 
 addf timedelay.0 servo-thread
@@ -210,7 +219,7 @@ net zpos-abs-cmd joint.2.pos-cmd => collisionavoid.zaxis
 net collision-stop collisionavoid.stop => halui.estop.activate
 
 #Autolevel
-loadusr -Wn compensation python2 compensation.py probe-results.txt cubic
+loadusr -Wn compensation python3 compensation.py probe-results.txt cubic
 net xpos-abs-cmd => compensation.x-pos
 net ypos-abs-cmd => compensation.y-pos
 net zpos-abs-cmd => compensation.z-pos
@@ -218,4 +227,3 @@ net eoffset-enable compensation.enable-out  => axis.z.eoffset-enable
 net eoffset-scale  compensation.scale       => axis.z.eoffset-scale
 net eoffset-counts compensation.counts      => axis.z.eoffset-counts
 net eoffset-clear  compensation.clear       => axis.z.eoffset-clear
-

3040T.ini

@@ -52,7 +52,7 @@ FEATURES=12
 [EMCMOT]
 EMCMOT = motmod
 COMM_TIMEOUT = 1.0
-BASE_PERIOD = 35000
+BASE_PERIOD = 45000
 SERVO_PERIOD = 1000000
 
 [TASK]
@@ -69,8 +69,9 @@ MDI_COMMAND = M600
 MDI_COMMAND = G0 X0 Y0
 MDI_COMMAND = G53 G0 X0 Y0 Z0
 MDI_COMMAND = G53 g0 z0
+MDI_COMMAND = G53 g0 z-40
 MDI_COMMAND = G10 L20 p0 x0 y0 z0
-MDI_COMMAND = G10 L20 p0 x36.575 y-38.364
+MDI_COMMAND = G10 L20 p0 x-36.257 y-49.488
 MDI_COMMAND = G10 L2 p0 x261.3 y286.9
 MDI_COMMAND = M400
 MDI_COMMAND = o<rectangle_probe> call
@@ -109,7 +110,6 @@ STEPGEN_MAXACCEL = 1875.0
 SCALE = -400.0
 FERROR = 1
 MIN_FERROR = .25
-MIN_FERROR = 10.25
 MIN_LIMIT = -0.001
 MAX_LIMIT = 290.0
 HOME_OFFSET = -1.000000
@@ -146,15 +146,15 @@ HOME_SEQUENCE = 1
 MIN_LIMIT = -75
 MAX_LIMIT = 0.001
 MAX_VELOCITY = 50
-MAX_ACCELERATION = 2000.0
+MAX_ACCELERATION = 1500.0
 OFFSET_AV_RATIO = 0.2
 
 [JOINT_2]
 TYPE = LINEAR
 HOME = 0.0
 MAX_VELOCITY = 50
-MAX_ACCELERATION = 2000.0
-STEPGEN_MAXACCEL = 2500.0
+MAX_ACCELERATION = 1500.0
+STEPGEN_MAXACCEL = 1875.0
 SCALE = -400.0
 FERROR = 1
 MIN_FERROR = .25

compensation.py

@@ -1,5 +1,6 @@
 #!/usr/bin/env python2
 """Copyright (C) 2020 Scott Alford, scottalford75@gmail.com
+Copyright (C) 2022-2024 Carl Klemm, carl@uvos.xyz
 
 This program is free software; you can redistribute it and/or modify
 it under the terms of the GNU 2 General Public License as published by
@@ -16,47 +17,50 @@ along with this program; if not, write to the Free Software
 Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA  02111-1307  USA
 """
 
-update = 0.025	# this is how often the z external offset value is updated based on current x & y position 
-safeOffset = 20
-
 import sys
-import os.path, time
+import os.path
 import numpy as np
 from scipy.interpolate import griddata
 from enum import Enum, unique
-
 import linuxcnc
+import hal
+import time
+
+# this is how often the z external offset value is updated based on current x & y position
+update = 0.025
+safeOffset = 20
+
 
 @unique
 class States(Enum):
-    START = 1
-    IDLE = 2
-    LOADMAP = 3
-    RUNNING = 4
-    RESET = 5
-    STOP = 6
+	START = 1
+	IDLE = 2
+	LOADMAP = 3
+	RUNNING = 4
+	RESET = 5
+	STOP = 6
 
 
-class Compensation :
-	def __init__(self) :
+class Compensation:
+	def __init__(self):
 		self.comp = {}
-		if len(sys.argv)<2:
-			print "ERROR! No input file name specified!"
+		if len(sys.argv) < 2:
+			print("ERROR! No input file name specified!")
 			sys.exit()
 
 		self.filename = sys.argv[1]
 		self.method = sys.argv[2]
-		
+
 		# default to cubic if not specified
-		if self.method == "" : self.methond = "cubic"
+		if self.method == "":
+			self.methond = "cubic"
 
-
-	def loadMap(self) :
+	def loadMap(self):
 		# data coordinates and values
 		self.data = np.loadtxt(self.filename, dtype=float, delimiter=" ", usecols=(0, 1, 2))
-		self.x_data = np.around(self.data[:,0],1)
-		self.y_data = np.around(self.data[:,1],1)
-		self.z_data = self.data[:,2]
+		self.x_data = np.around(self.data[:, 0], 1)
+		self.y_data = np.around(self.data[:, 1], 1)
+		self.z_data = self.data[:, 2]
 
 		# get the x and y, min and max values from the data
 		self.xMin = int(np.min(self.x_data))
@@ -64,51 +68,45 @@ class Compensation :
 		self.yMin = int(np.min(self.y_data))
 		self.yMax = int(np.max(self.y_data))
 
-		print "	xMin = ", self.xMin
-		print "	xMax = ", self.xMax
-		print "	yMin = ", self.yMin
-		print "	yMax = ", self.yMax
+		print("	xMin = ", self.xMin)
+		print("	xMax = ", self.xMax)
+		print("	yMin = ", self.yMin)
+		print("	yMax = ", self.yMax)
 
 		# target grid to interpolate to, 1 grid per mm
-		self.xSteps = (self.xMax-self.xMin)+1
-		self.ySteps = (self.yMax-self.yMin)+1
+		self.xSteps = (self.xMax - self.xMin) + 1
+		self.ySteps = (self.yMax - self.yMin) + 1
 		self.x = np.linspace(self.xMin, self.xMax, self.xSteps)
 		self.y = np.linspace(self.yMin, self.yMax, self.ySteps)
-		self.xi,self.yi = np.meshgrid(self.x,self.y)
-		print "	xSteps = ", self.xSteps
-		print "	ySteps = ", self.ySteps
-		print "	x = ", self.x
+		self.xi, self.yi = np.meshgrid(self.x, self.y)
+		print("	xSteps = ", self.xSteps)
+		print("	ySteps = ", self.ySteps)
+		print("	x = ", self.x)
 
 		# interpolate, zi has all the offset values but need to be transposed
-		self.zi = griddata((self.x_data,self.y_data),self.z_data,(self.xi,self.yi),method=self.method)
+		self.zi = griddata((self.x_data, self.y_data), self.z_data, (self.xi, self.yi), method=self.method)
 		self.zi = np.transpose(self.zi)
 
-		
-	def compensate(self) :
+	def compensate(self):
 		# get our nearest integer position
 		self.xpos = int(round(self.h['x-pos']))
 		self.ypos = int(round(self.h['y-pos']))
-		
+
 		zo = safeOffset
-		
-		if self.xpos >= self.xMin and self.xpos <= self.xMax and self.ypos >= self.yMin and self.ypos <= self.yMax :
+
+		if self.xpos >= self.xMin and self.xpos <= self.xMax and self.ypos >= self.yMin and self.ypos <= self.yMax:
 			self.Xn = self.xpos - self.xMin
 			self.Yn = self.ypos - self.yMin
-		
-			# get the nearest compensation offset and convert to counts (s32) with a scale (float) 
-			# Requested offset == counts * scale
-			zo = self.zi[self.Xn,self.Yn]
-			if np.isnan(zo) :
+
+			zo = self.zi[self.Xn, self.Yn]
+			if np.isnan(zo):
 				zo = safeOffset
 
 		self.scale = 0.001
 		compensation = int(zo / self.scale)
 		return compensation
 
-
-	def run(self) :
-		import hal, time
-		
+	def run(self):
 		self.h = hal.component("compensation")
 		self.h.newpin("enable-in", hal.HAL_BIT, hal.HAL_IN)
 		self.h.newpin("enable-out", hal.HAL_BIT, hal.HAL_OUT)
@@ -120,113 +118,114 @@ class Compensation :
 		self.h.newpin("z-pos", hal.HAL_FLOAT, hal.HAL_IN)
 		self.h.newpin("fade-height", hal.HAL_FLOAT, hal.HAL_IN)
 		self.h.ready()
-		
+
 		s = linuxcnc.stat()
-		
+
 		currentState = States.START
 		prevState = States.STOP
 
 		try:
 			while True:
 				time.sleep(update)
-				
+
 				# get linuxcnc task_state status for machine on / off transitions
 				s.poll()
-				
-				if currentState == States.START :
-					if currentState != prevState :
+
+				if currentState == States.START:
+					if currentState != prevState:
 						print("\nCompensation entering START state")
 						prevState = currentState
-						
+
 					# do start-up tasks
 					print(" %s last modified: %s" % (self.filename, time.ctime(os.path.getmtime(self.filename))))
-					
+
 					prevMapTime = 0
-					
+
 					self.h["counts"] = 0
-					
+
 					# transition to IDLE state
 					currentState = States.IDLE
-				
-				elif currentState == States.IDLE :
-					if currentState != prevState :
+
+				elif currentState == States.IDLE:
+					if currentState != prevState:
 						print("\nCompensation entering IDLE state")
 						prevState = currentState
-						
+
 					# stay in IDLE state until compensation is enabled
-					if self.h["enable-in"] :
+					if self.h["enable-in"]:
 						currentState = States.LOADMAP
-			
-				elif currentState == States.LOADMAP :
-					if currentState != prevState :
+
+				elif currentState == States.LOADMAP:
+					if currentState != prevState:
 						print("\nCompensation entering LOADMAP state")
 						prevState = currentState
-			
+
 					mapTime = os.path.getmtime(self.filename)
-			
+
 					if mapTime != prevMapTime:
 						self.loadMap()
 						print("	Compensation map loaded")
 						prevMapTime = mapTime
-					
+
 					# transition to RUNNING state
 					currentState = States.RUNNING
-				
-				elif currentState == States.RUNNING :
-					if currentState != prevState :
+
+				elif currentState == States.RUNNING:
+					if currentState != prevState:
 						print("\nCompensation entering RUNNING state")
 						prevState = currentState
-			
-					if self.h["enable-in"] :
+
+					if self.h["enable-in"]:
 						# enable external offsets
 						self.h["enable-out"] = 1
-						
+
 						fadeHeight = self.h["fade-height"]
 						zPos = self.h["z-pos"]
-						
-						if fadeHeight == 0 :
+
+						if fadeHeight == 0:
 							compScale = 1
 						elif zPos < fadeHeight:
-							compScale = (fadeHeight - zPos)/fadeHeight
-							if compScale > 1 :
+							compScale = (fadeHeight - zPos) / fadeHeight
+							if compScale > 1:
 								compScale = 1
-						else :
+						else:
 							compScale = 0
-							
-						if s.task_state == linuxcnc.STATE_ON :
+
+						if s.task_state == linuxcnc.STATE_ON:
 							# get the compensation if machine power is on, else set to 0
-							# otherwise we loose compensation eoffset if machine power is cycled 
+							# otherwise we loose compensation eoffset if machine power is cycled
 							# when copensation is enable
 							compensation = self.compensate()
 							self.h["counts"] = compensation * compScale
 							self.h["scale"] = self.scale
-						else :
+						else:
 							self.h["counts"] = 0
-						
-					else :
+
+					else:
 						# transition to RESET state
 						currentState = States.RESET
-						
-				elif currentState == States.RESET :
-					if currentState != prevState :
+
+				elif currentState == States.RESET:
+					if currentState != prevState:
 						print("\nCompensation entering RESET state")
 						prevState = currentState
 
 					# reset the eoffsets counts register so we don't accumulate
 					self.h["counts"] = 0
 					# toggle the clear output
-					self.h["clear"] = 1;
+					self.h["clear"] = 1
 					time.sleep(0.1)
-					self.h["clear"] = 0;
+					self.h["clear"] = 0
 
 					# disable external offsets
-					#self.h["enable-out"] = 0
-					
+					# self.h["enable-out"] = 0
+
 					# transition to IDLE state
 					currentState = States.IDLE
 
 		except KeyboardInterrupt:
-	  	  raise SystemExit
+			raise SystemExit
+
 
 comp = Compensation()
 comp.run()

custom_postgui.hal

@@ -30,10 +30,11 @@ net m600 halui.mdi-command-00 <= pyvcp.m600-btn
 net g0x0y0 halui.mdi-command-01 <= pyvcp.x0y0-btn
 net g53g0x0y0z0 halui.mdi-command-02 <= pyvcp.g53g0x0y0z0-btn
 net g53g0z0 halui.mdi-command-03 <= pyvcp.g53g0z0-btn
-net g10l20x0y0z0 halui.mdi-command-04 <= or2.2.out
-net g10l20x20y20 halui.mdi-command-05 <= pyvcp.microscope-btn
-net g53g10l20pin halui.mdi-command-06 <= pyvcp.touchoffpin-btn
-net touchofzpin halui.mdi-command-07 <= pyvcp.touchofz-btn
+net microscopeHightBtn halui.mdi-command-04 <= pyvcp.g53g0z-40-btn
+net g10l20x0y0z0 halui.mdi-command-05 <= or2.2.out
+net g10l20x20y20 halui.mdi-command-06 <= pyvcp.microscope-btn
+net g53g10l20pin halui.mdi-command-07 <= pyvcp.touchoffpin-btn
+net touchofzpin halui.mdi-command-08 <= pyvcp.touchofz-btn
 
 #Collisionavoid
 
@@ -43,10 +44,15 @@ setp pyvcp.chuck-chkbtn.changepin 1
 
 #Autolevel
 net levelpin pyvcp.level-chkbtn => compensation.enable-in
-net runalprobe halui.mdi-command-08 <= pyvcp.alprobe-btn
+net runalprobe halui.mdi-command-09 <= pyvcp.alprobe-btn
 
 #Autolevel spinbox display
 net alprsx pyvcp.alprsx => pyvcp.alprsxDisp
 net alprsy pyvcp.alprsy => pyvcp.alprsyDisp
 net alintervl pyvcp.alintervl => pyvcp.alintervlDisp
 net alheight pyvcp.alheight => pyvcp.alheightDisp
+
+net jitter <= timedelta.0.jitter
+net jitter => pyvcp.jitter-disp
+net jitter-reset <= pyvcp.jitter-rst-btn
+net jitter-reset => timedelta.0.reset

tool-change.ngc

@@ -7,7 +7,7 @@ O<tool-change> SUB
 #<_ProbeY> =            24.5     ( machine Y coordinate of switch/touch-off plate )
 #<_ProbeFastZ> =        -20    ( machine Z coord to move to before starting probe, longest tool should not touch switch at this Z )
 #<_ProbeMinZ> =       -70     ( machine Z coord to stop probe, shortest tool must touch switch at this Z, must be > min Z )
-#<_ProbeRetract> =      0.2     ( small distance to retract before approaching switch/touch-off plate second time )
+#<_ProbeRetract> =      0.5     ( small distance to retract before approaching switch/touch-off plate second time )
 #<_ProbeFastFeed> =   3000     ( feed rate for moving to _ProbeFastZ )
 #<_ProbeFeed1> =       750    ( feed rate for touching switch/touch-off plate first time )
 #<_ProbeFeed2> =       3     ( feed rate for touching switch/touch-off plate second time )
@@ -75,6 +75,7 @@ O102 ELSE
         M[7 + #<_MistOnDuringProbe> - 1]           ( turn on mist/coolant )
     O104 ENDIF
     G38.2 Z[#<_ProbeMinZ> - #<_ProbeFastZ>] F[#<_ProbeFeed1>]     ( trip switch slowly )
+    G4 P0.1
     G0 Z[#<_ProbeRetract>]                       ( go up slightly )
     G38.2 Z[#<_ProbeRetract>*-1.25] F[#<_ProbeFeed2>]   ( trip switch very slowly )
     M9                                           ( turn off mist )

touchoff-z-to-bead.ngc

@@ -4,7 +4,7 @@ o<touchoff-z-to-Bead> sub
 #<_ProbeY> =            24.5     ( machine Y coordinate of switch/touch-off plate )
 #<_ProbeFastZ> =        -20    ( machine Z coord to move to before starting probe, longest tool should not touch switch at this Z )
 #<_ProbeMinZ> =       -70     ( machine Z coord to stop probe, shortest tool must touch switch at this Z, must be > min Z )
-#<_ProbeRetract> =      0.2     ( small distance to retract before approaching switch/touch-off plate second time )
+#<_ProbeRetract> =      0.5     ( small distance to retract before approaching switch/touch-off plate second time )
 #<_ProbeFastFeed> =   3000     ( feed rate for moving to _ProbeFastZ )
 #<_ProbeFeed1> =       750    ( feed rate for touching switch/touch-off plate first time )
 #<_ProbeFeed2> =       3     ( feed rate for touching switch/touch-off plate second time )
@@ -25,6 +25,7 @@ G53 G1 F[#<_ProbeFastFeed>] Z[#<_ProbeFastZ>]		( move tool closer to switch -- w
 G54 G1 F[#<_ProbeFeed1>] G91                 		( use relative positioning )
 
 G38.2 Z[#<_ProbeMinZ> - #<_ProbeFastZ>] F[#<_ProbeFeed1>]    ( trip switch slowly )
+G4 P0.1
 G0 Z[#<_ProbeRetract>]      	     	            ( go up slightly )
 G38.2 Z[#<_ProbeRetract>*-1.25] F[#<_ProbeFeed2>]   ( trip switch very slowly )
 G90                      	            	        ( use absolute positioning )