Improvements in the GUI, Gcode Parser, Gcode Viewer and Bugfix in Cyclone Host. Now emulator works 100%

Software/CycloneHost/CycloneHost.py

@@ -140,6 +140,7 @@ def homeZXY():
 	if Emulate:
 		time.sleep(2)
 	lastDrillPos = [0,0,0]
+	print "Done homing"
 
 def moveXYZ(X, Y, Z, F):
 	global lastDrillPos
@@ -178,19 +179,25 @@ def moveZ(Z, F):
 	lastDrillPos = [lastDrillPos[0],lastDrillPos[1],Z]
 
 def moveZrel(Z, F):
+	global lastDrillPos
 #	print "Moving Z relative:"
 	if F <= 0:
 		print "ERROR: F <= 0"
 	sendCommand("G91\n") # Set relative positioning
-	moveZ(Z, F)
+	sendCommand("G1 Z"+floats(Z)+" F"+floats(F)+"\n")
+	if Emulate:
+		dist = abs(Z) # [mm]
+		speed = float(F)/60.0 # [mm/s]
+		time.sleep(float(dist)/speed)
+	lastDrillPos = [lastDrillPos[0],lastDrillPos[1],lastDrillPos[2]+Z] # Relative movement
 	sendCommand("G90\n") # Set absolute positioning
 
 def moveZrelSafe(Z, F):
 	if F <= 0:
 		print "ERROR: F <= 0"
+	print "Moving Z", Z, "mm safely..."
 	sendCommand("M121\n") # Enable endstops (for protection! usually it should **NOT** hit neither the endstop nor the PCB)
 	moveZrel(Z, F)
-	print "Moving Z safely..."
 	dist = abs(Z-lastDrillPos[2]) # [mm]
 	speed = float(F)/60.0 # [mm/s]
 	wait = float(dist)/speed # [s]

Software/CycloneHost/GcodeParser.py

@@ -20,13 +20,13 @@ import os.path
 
 def parseGcodeRaw(filePath, etch_definition = 0, close_shapes = 0): # Gcode parser from Etch_Z_adjust.1.8.py (modified by Carlosgs to output toolpaths)
 	
-	gcode_sizeXY = (0,0)
-	gcode_originXY = (0,0)
+	gcode_maxXY = (0,0)
+	gcode_minXY = (0,0)
 	travel_moves = []
 	etch_moves = []
 	
 	if os.path.isfile(filePath) == False :
-		return etch_moves, travel_moves, gcode_originXY, gcode_sizeXY
+		return etch_moves, travel_moves, gcode_minXY, gcode_maxXY
 	
 	gcode = open(filePath, "r")
 	
@@ -152,16 +152,17 @@ def parseGcodeRaw(filePath, etch_definition = 0, close_shapes = 0): # Gcode pars
 	if is_first_X == False :
 		# then there were etch moves so get to work!
 		
-		gcode_sizeXY = (X_max - X_min, Y_max - Y_min)
-		gcode_originXY = (X_min, Y_min)
+		gcode_maxXY = [X_max, Y_max]
+		gcode_minXY = [X_min, Y_min]
 		
-		print "Gcode XY origin:",str(gcode_originXY)
-		print "Gcode XY length:",str(gcode_sizeXY)
-	
-	else : print "No etch moves found!"
+		print "Gcode XY min:",str(gcode_minXY)
+		print "Gcode XY max:",str(gcode_maxXY)
 	
+	else :
+		print "No etch moves found!"
+		return etch_moves, travel_moves, [0,0], [0,0]
 	gcode.close()
-	return etch_moves, travel_moves, gcode_originXY, gcode_sizeXY
+	return etch_moves, travel_moves, gcode_minXY, gcode_maxXY
 
 def optimize(etch_moves_in, origin=[0,0], travel_height = 5): # Optimizes the toolpath using closest neighbour (author: Carlosgs)
 	

Software/CycloneHost/GcodeViewer.py

@@ -70,6 +70,15 @@ def view(filePath,fileName,showAll=0,showEtch=0,showEtch2=0,showEtch3=0,showDril
 	edge_color = 'b'
 	travel_color = 'c'
 	
+	gcode_minXY_global = [1e9,1e9]
+	gcode_maxXY_global = [-1e9,-1e9]
+	
+	def checkMinMax(gcode_minXY,gcode_maxXY):
+		if gcode_minXY[0] < gcode_minXY_global[0]: gcode_minXY_global[0] = gcode_minXY[0]
+		if gcode_minXY[1] < gcode_minXY_global[1]: gcode_minXY_global[1] = gcode_minXY[1]
+		if gcode_maxXY[0] > gcode_maxXY_global[0]: gcode_maxXY_global[0] = gcode_maxXY[0]
+		if gcode_maxXY[1] > gcode_maxXY_global[1]: gcode_maxXY_global[1] = gcode_maxXY[1]
+	
 	if draw:
 		plt.title("Gcode viewer")
 		plt.axis('equal') # 1:1 aspect ratio
@@ -78,40 +87,41 @@ def view(filePath,fileName,showAll=0,showEtch=0,showEtch2=0,showEtch3=0,showDril
 	if showAll or showEtch:
 		print "\n Loading etch..."
 		gcode_file = filePath+fileName+"_etch.gcode"
-		(etch_moves, travel_moves, gcode_originXY, grid_sizeXY) = gcp.parseGcodeRaw(gcode_file)
+		(etch_moves, travel_moves, gcode_minXY, gcode_maxXY) = gcp.parseGcodeRaw(gcode_file)
 		(etch_moves, travel_moves) = gcp.optimize(etch_moves)
 		if draw: plotPath(etch_moves, travel_moves, etch_color, travel_color, etch_diam, travel_diam)
+		checkMinMax(gcode_minXY,gcode_maxXY)
 	
 	if showAll or showEtch2:
 		print "\n Loading etch (2nd pass)..."
 		gcode_file = filePath+fileName+"_etch2pass.gcode"
-		(etch_moves, travel_moves, gcode_originXY, grid_sizeXY) = gcp.parseGcodeRaw(gcode_file)
+		(etch_moves, travel_moves, gcode_minXY, gcode_maxXY) = gcp.parseGcodeRaw(gcode_file)
 		(etch_moves, travel_moves) = gcp.optimize(etch_moves)
 		if draw: plotPath(etch_moves, travel_moves, etch2pass_color, travel_color, etch2pass_diam, travel_diam)
 	
 	if showAll or showEtch3:
 		print "\n Loading etch (3nd pass)..."
 		gcode_file = filePath+fileName+"_etch3pass.gcode"
-		(etch_moves, travel_moves, gcode_originXY, grid_sizeXY) = gcp.parseGcodeRaw(gcode_file)
+		(etch_moves, travel_moves, gcode_minXY, gcode_maxXY) = gcp.parseGcodeRaw(gcode_file)
 		(etch_moves, travel_moves) = gcp.optimize(etch_moves)
 		if draw: plotPath(etch_moves, travel_moves, etch3pass_color, travel_color, etch3pass_diam, travel_diam)
 	
 	if showAll or showDrill:
 		print "\n Loading drill..."
 		gcode_file = filePath+fileName+"_drill.gcode"
-		(etch_moves, travel_moves, gcode_originXY, grid_sizeXY) = gcp.parseGcodeRaw(gcode_file)
+		(etch_moves, travel_moves, gcode_minXY, gcode_maxXY) = gcp.parseGcodeRaw(gcode_file)
 		(etch_moves, travel_moves) = gcp.optimize(etch_moves)
 		if draw: plotPath(etch_moves, travel_moves, drill_color, travel_color, drill_diam, travel_diam)
 	
 	if showAll or showEdge:
 		print "\n Loading edge..."
 		gcode_file = filePath+fileName+"_edge.gcode"
-		(etch_moves, travel_moves, gcode_originXY, grid_sizeXY) = gcp.parseGcodeRaw(gcode_file)
+		(etch_moves, travel_moves, gcode_minXY, gcode_maxXY) = gcp.parseGcodeRaw(gcode_file)
 		(etch_moves, travel_moves) = gcp.optimize(etch_moves)
 		if draw: plotPath(etch_moves, travel_moves, edge_color, travel_color, edge_diam, travel_diam)
 	
 	#if draw : plt.hold(False)
 	if draw and newFigure: pltShowNonBlocking()
 	
-	return (etch_moves, travel_moves)
+	return (etch_moves, travel_moves, gcode_minXY_global, gcode_maxXY_global)
 

Software/gcode_Z_adjust/Send.py

@@ -25,6 +25,7 @@ import time
 import numpy as np
 from scipy import interpolate
 import matplotlib.pyplot as plt
+from matplotlib import cm
 
 sys.path.append("../CycloneHost")
 import GcodeViewer as gcv
@@ -56,7 +57,9 @@ def pltRefresh(fig):
 	fig.canvas.draw()
 
 def pltShow():
+	#plt.ion() # IMPORTANT: Enable real-time plotting
 	plt.draw()
+	#plt.ioff()
 
 
 
@@ -93,14 +96,15 @@ def probingResults(): # quick and dirty temporal code
 	# Interpolation
 	Z_workbed_surface = interpolate.RectBivariateSpline(y_points, x_points, probe_result)
 	
-	x_points = np.linspace(min(x_points),max(x_points),100) 
-	y_points = np.linspace(min(y_points),max(y_points),100) 
+	x_points = np.linspace(min(x_points),max(x_points),50) 
+	y_points = np.linspace(min(y_points),max(y_points),50) 
 	
 	z_points = Z_workbed_surface(y_points,x_points)
 	
 #	plt.figure()
 	plt.hold(True)
-	plt.pcolor(x_points, y_points, z_points)
+	
+	z_cf = plt.pcolor(x_points, y_points, z_points, alpha=0.2, cmap=cm.copper, edgecolors='k', linewidths=0) # Show Z probing height, with a light-tone colormap
 	plt.colorbar()
 #	plt.title("Z probing results (interpolated) [mm]")
 	plt.axis('equal') # 1:1 aspect ratio
@@ -111,30 +115,29 @@ def getZoffset(x,y):
 
 
 
-
-
-
-
 plt.ion() # IMPORTANT: Enable real-time plotting
 
-gcodeviewer = pltNewFig() # Define a new figure, this doesnt open a window by itself
-
+gcodeviewer = pltNewFig() # Define a new figure, this doesnt open a window by itself (real-time plotting disabled)
 
 probingResults()
 print "Must be zero:",floats(getZoffset(0,0))
 
-
 # Display the Gcode that is going to be etched
-(etch_moves, travel_moves) = gcv.view(filePath,fileName,showEtch=1)
+(etch_moves, travel_moves, gcode_minXY_global, gcode_maxXY_global) = gcv.view(filePath,fileName,showEtch=1)
 #(etch_moves, travel_moves) = gcv.view(filePath,fileName,showEtch1=1)
 #(etch_moves, travel_moves) = gcv.view(filePath,fileName,showEtch2=1)
 #(etch_moves, travel_moves) = gcv.view(filePath,fileName,showDrill=1)
 #(etch_moves, travel_moves) = gcv.view(filePath,fileName,showEdge=1)
 
+# Truncate the background to the dimensions of the PCB
+x_dat = [gcode_minXY_global[0],gcode_minXY_global[0],gcode_maxXY_global[0],gcode_maxXY_global[0],gcode_minXY_global[0]]
+y_dat = [gcode_minXY_global[1],gcode_maxXY_global[1],gcode_maxXY_global[1],gcode_minXY_global[1],gcode_minXY_global[1]]
+plt.plot(x_dat,y_dat)
+
 pltRefresh(gcodeviewer) # Draw the figure contents, still no window
 pltShow() # Open the window showing our figure
 
-plt.show() # THIS SHOULD BE COMMENTED, USE FOR DEBUG
+#plt.show() # THIS SHOULD BE COMMENTED, USE FOR DEBUG
 
 toolPos_point = []
 
@@ -211,8 +214,8 @@ Zlift = 1.0
 
 Z_manual_offset = 0.0
 
-maxDistance = 2**2 # [mm^2] 3mm (longer moves will be split to regulate Z)
-minDistance = 0.005**2 # [mm^2] 0.005mm is the smallest distance that will be sent
+maxDistance = 2**2 # [mm^2] 2mm (longer moves will be split to regulate Z)
+minDistance = 0.001**2 # [mm^2] 0.001mm is the smallest distance that will be sent
 
 def splitLongEtchMove(distance):
 	global toolPos_X, toolPos_Y, toolPos_Z, toolPos_F, X_dest, Y_dest, Z_dest, F_dest

Software/gcode_Z_adjust/test.py

@@ -1,55 +0,0 @@
-# -*- encoding: utf-8 -*-
-# Based on http://scipy-user.10969.n7.nabble.com/2D-Interpolation-td4248.html
-
-import scipy
-import scipy.interpolate 
-
-def pltShowNonBlocking():
-	plt.ion() # Enable real-time plotting to avoid blocking behaviour for plt.show()
-	plt.show()
-	plt.ioff() # Disable real-time plotting
-
-# the two axes 
-x = scipy.array([0.0, 12.272727272727273, 24.545454545454547, 36.81818181818182, 49.09090909090909, 61.36363636363637, 73.63636363636364, 85.9090909090909, 98.18181818181819, 110.45454545454547, 122.72727272727273, 135.0])
-y = scipy.array([0.0, 16.8, 33.6, 50.400000000000006, 67.2, 84.0])
-
-# make some pretend data 
-gridy, gridx = scipy.meshgrid(x,y) 
-z = scipy.array([[0.0, 0.2, 0.4, 0.53, 0.58, 0.6, 0.56, 0.53, 0.5, 0.44, 0.33, 0.2], [-0.03, 0.07, 0.16, 0.26, 0.32, 0.33, 0.33, 0.33, 0.29, 0.23, 0.15, 0.05], [-0.07, 0.0, 0.05, 0.12, 0.16, 0.2, 0.2, 0.22, 0.2, 0.16, 0.08, 0.0], [-0.07, -0.03, 0.04, 0.11, 0.15, 0.19, 0.2, 0.22, 0.22, 0.19, 0.11, 0.04], [0.0, 0.04, 0.08, 0.19, 0.23, 0.29, 0.33, 0.36, 0.37, 0.32, 0.2, 0.11], [0.13, 0.2, 0.27, 0.37, 0.44, 0.51, 0.55, 0.61, 0.64, 0.55, 0.41, 0.22]])
-
-# create a spline interpolator 
-spl = scipy.interpolate.RectBivariateSpline(y,x,z) 
-
-# make some new axes to interpolate to 
-nx = scipy.linspace(min(x),max(x),100) 
-ny = scipy.linspace(min(y),max(y),100) 
-
-# evaluate 
-nz = spl(ny, nx) 
-
-import matplotlib.pyplot as plt
-
-plt.figure()
-plt.pcolor(x, y, z)
-plt.title("Datos [mm]")
-plt.colorbar()
-plt.axis('equal') # 1:1 aspect ratio
-pltShowNonBlocking()
-
-plt.figure()
-plt.pcolor(nx, ny, nz)
-plt.title("Datos interpolados [mm]")
-plt.colorbar()
-plt.axis('equal') # 1:1 aspect ratio
-pltShowNonBlocking()
-
-# Comprobación de que el error es mínimo
-plt.figure()
-plt.pcolor(x, y, spl(y,x) - z)
-plt.title("Diferencia entre datos originales e interpolados (error) [mm]")
-plt.colorbar()
-plt.axis('equal') # 1:1 aspect ratio
-pltShowNonBlocking()
-
-raw_input("Press enter to exit...")
-