cyclone-pcb-factory/Software/gcode_Z_adjust/Send.py

269 lines
7.4 KiB
Python

#!/usr/bin/python
# AUTHOR:
# Carlosgs (http://carlosgs.es)
# LICENSE:
# Attribution - Share Alike - Creative Commons (http://creativecommons.org/licenses/by-sa/3.0/)
#
# DISCLAIMER:
# This software is provided "as is", and you use the software at your own risk. Under no
# circumstances shall Carlosgs be liable for direct, indirect, special, incidental, or
# consequential damages resulting from the use, misuse, or inability to use this software,
# even if Carlosgs has been advised of the possibility of such damages.
# Begin configuration
BAUDRATE = 115200
DEVICE = "/dev/ttyUSB2"
Emulate = 1
# End configuration
# Begin modules
import sys
from datetime import datetime
import time
import numpy as np
from scipy import interpolate
import matplotlib.pyplot as plt
sys.path.append("../CycloneHost")
import GcodeViewer as gcv
import CycloneHost as cy
from helper import *
# End modules
filePath = "../GcodeGenerators/pyGerber2Gcode_CUI/out/"
fileName = "printshield" # sys.argv[1]
# Display the Gcode that is going to be etched
(etch_moves, travel_moves, gcodeviewer) = gcv.view(filePath,fileName,showEdge=1)
figId = gcodeviewer.number
def pltShowNonBlocking():
plt.ion() # Enable real-time plotting to avoid blocking behaviour for plt.show()
plt.show()
plt.ioff() # Disable real-time plotting
toolPos_point = []
def toolPos_draw(x, y, etching=0):
if etching:
color = 'r'
else:
color = 'g'
toolPos_point.set_data(x, y)
toolPos_point.set_color(color)
gcodeviewer.canvas.draw()
toolRefreshSteps = 1
toolRefresh = 0
def toolPos_refresh(x, y, etching=0):
global toolRefresh
if toolRefresh >= toolRefreshSteps:
toolPos_draw(toolPos_X, toolPos_Y, etching)
toolRefresh = 0
toolRefresh = toolRefresh + 1
def drawTool(x, y):
global toolPos_point
plt.figure(figId)
toolPos_point, = plt.plot(0, 0, markersize=12, c='g', marker='x')
pltShowNonBlocking()
F_slowMove = 200 # Move speed [mm/min]
F_fastMove = 700
F_drillMove = 50
F_edgeMove = 25
F_etchMove = 100
cy.connect(BAUDRATE, DEVICE, Emulate)
cy.sendCommand("G90\n") # Set absolute positioning
cy.homeZXY() # Home all the axis
drawTool(10, 20) # Show a marker on the gcode plot
# Warning: Do not lower too much or you will potentially cause damage!
initial_Z_lowering_distance = -20
cy.moveZrelSafe(initial_Z_lowering_distance,F_slowMove/2) # Move Z towards the PCB (saves some probing time for the first coord)
Z_origin_offset = cy.probeZ()
print "Z offset:", Z_origin_offset
Z_workbed_surface = []
def probingResults():
global Z_workbed_surface
x_points = [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_points = [0.0, 16.8, 33.6, 50.400000000000006, 67.2, 84.0]
probe_result = [[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]]
duration = 346.076061
# Show our grid
# print "--- Probing results ---"
# print "-> X points:", x_points
# print "-> Y points:", y_points
# print "-> Grid:", probe_result
# print "-> Duration:", duration
# Must be converted into arrays to use scipy
x_points = np.array(x_points)
y_points = np.array(y_points)
probe_result = np.array(probe_result)
# plt.figure()
# plt.pcolor(x_points, y_points, probe_result)
# plt.colorbar()
# plt.title("Z probing results [mm]")
# plt.axis('equal') # 1:1 aspect ratio
# pltShowNonBlocking()
# 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)
z_points = Z_workbed_surface(y_points,x_points)
plt.figure()
plt.pcolor(x_points, y_points, z_points)
plt.colorbar()
plt.title("Z probing results (interpolated) [mm]")
plt.axis('equal') # 1:1 aspect ratio
pltShowNonBlocking()
def getZoffset(x,y):
return Z_workbed_surface(y,x)[0][0]
probingResults()
print "Must be zero:",floats(getZoffset(0,0))
toolPos_X = 0
toolPos_Y = 0
toolPos_Z = 0
toolPos_F = F_fastMove
X_dest = 0
Y_dest = 0
Z_dest = 0
F_dest = F_fastMove
cy.moveZrelSafe(5,F_slowMove)
toolPos_Z = 5
plt.figure(figId)
Zlift = 1.0
Z_manual_offset = 0.0
maxDistance = 3**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
def splitLongEtchMove(distance):
global toolPos_X, toolPos_Y, toolPos_Z, toolPos_F, X_dest, Y_dest, Z_dest, F_dest
X_dest_tmp = toolPos_X
Y_dest_tmp = toolPos_Y
Z_dest_tmp = toolPos_Z
F_dest_tmp = toolPos_Z
#distance = distance**0.5 # [mm]
N_steps = int((distance/maxDistance)**0.5) # **must be** >= 1
print "Splitting", distance**0.5, "mm segment into", N_steps, "steps"
# print "Orig:", toolPos_X, toolPos_Y, toolPos_Z, "Dest:", X_dest, Y_dest, Z_dest
X_step = (X_dest-toolPos_X)/float(N_steps)
Y_step = (Y_dest-toolPos_Y)/float(N_steps)
Z_step = (Z_dest-toolPos_Z)/float(N_steps)
F_step = (F_dest-toolPos_F)/float(N_steps)
for i in range(N_steps) :
X_dest_tmp = toolPos_X + X_step
Y_dest_tmp = toolPos_Y + Y_step
Z_dest_tmp = toolPos_Z + Z_step
F_dest_tmp = toolPos_F + F_step
Z_real = Z_dest_tmp+Z_origin_offset+getZoffset(X_dest_tmp, Y_dest_tmp)+Z_manual_offset
cy.moveXYZ(X_dest_tmp, Y_dest_tmp, Z_real, F_dest_tmp)
toolPos_refresh(X_dest_tmp, Y_dest_tmp, etching=1)
# print "Move:",X_dest_tmp, Y_dest_tmp, Z_dest_tmp
toolPos_X = X_dest_tmp
toolPos_Y = Y_dest_tmp
toolPos_Z = Z_dest_tmp
toolPos_F = F_dest_tmp
raw_input("Turn on the spindle and press enter to begin...")
for path in etch_moves :
toolRefresh = 0
toolPos_draw(toolPos_X, toolPos_Y, etching=0)
cy.moveZ(Z_origin_offset+getZoffset(X_dest, Y_dest)+Z_manual_offset+Zlift,F_fastMove) # Raise and move to next point
print " travel Z:",Z_manual_offset+Zlift
X_dest = path[0][0]
Y_dest = path[0][1]
F_dest = F_fastMove
cy.moveXY(X_dest, Y_dest, F_dest)
toolPos_draw(X_dest, Y_dest, etching=0)
Z_dest = path[0][2]
if Z_dest > 0:
F_dest = F_slowMove
else:
F_dest = path[0][3] # We set the original speed if it is etching/drill
cy.moveZ(Z_dest+Z_origin_offset+getZoffset(X_dest, Y_dest)+Z_manual_offset,F_dest)
print "Speed:",F_dest
print " drill Z:",Z_dest+Z_manual_offset
toolPos_X = X_dest
toolPos_Y = Y_dest
toolPos_Z = Z_dest # Not sure..
toolPos_F = F_dest
# print path
for coord in path[1:] :
X_dest = coord[0]
Y_dest = coord[1]
Z_dest = coord[2]
F_dest = coord[3]
distance = (X_dest-toolPos_X)**2+(Y_dest-toolPos_Y)**2
if distance >= maxDistance :
splitLongEtchMove(distance)
if distance < minDistance and (Z_dest-toolPos_Z)**2 < 0.001**2 : # Make sure it is not a Z movement
print "Ignoring", distance**0.5, "mm segment!"
continue
Z_real = Z_dest+Z_origin_offset+getZoffset(X_dest, Y_dest)+Z_manual_offset
cy.moveXYZ(X_dest, Y_dest, Z_real, F_dest)
print "Coords: Speed:",F_dest
toolPos_refresh(X_dest, Y_dest, etching=1)
toolPos_X = X_dest
toolPos_Y = Y_dest
toolPos_Z = Z_dest
toolPos_F = F_dest
cy.homeZXY()
cy.close() # Close the serial port connection
raw_input("Done. Press enter to exit...")