# ##########################################################
# FlatCAM: 2D Post-processing for Manufacturing #
# File Author: Marius Adrian Stanciu (c) #
# Date: 3/10/2019 #
# MIT Licence #
# ##########################################################
from PyQt5 import QtWidgets, QtGui
from appTool import AppTool
from appGUI.GUIElements import FCSpinner, FCDoubleSpinner, NumericalEvalEntry, FCLabel, RadioSet, FCButton
import math
import gettext
import appTranslation as fcTranslate
import builtins
fcTranslate.apply_language('strings')
if '_' not in builtins.__dict__:
_ = gettext.gettext
class ToolCalculator(AppTool):
def __init__(self, app):
AppTool.__init__(self, app)
self.app = app
self.decimals = self.app.decimals
# #############################################################################
# ######################### Tool GUI ##########################################
# #############################################################################
self.ui = CalcUI(layout=self.layout, app=self.app)
self.toolName = self.ui.toolName
self.units = ''
# ## Signals
self.ui.mm_entry.editingFinished.connect(self.on_calculate_inch_units)
self.ui.inch_entry.editingFinished.connect(self.on_calculate_mm_units)
self.ui.reset_button.clicked.connect(self.set_tool_ui)
self.ui.area_sel_radio.activated_custom.connect(self.on_area_calculation_radio)
def run(self, toggle=True):
self.app.defaults.report_usage("ToolCalculators()")
if toggle:
# if the splitter is hidden, display it
if self.app.ui.splitter.sizes()[0] == 0:
self.app.ui.splitter.setSizes([1, 1])
# if the Tool Tab is hidden display it, else hide it but only if the objectName is the same
found_idx = None
for idx in range(self.app.ui.notebook.count()):
if self.app.ui.notebook.widget(idx).objectName() == "tool_tab":
found_idx = idx
break
# show the Tab
if not found_idx:
self.app.ui.notebook.addTab(self.app.ui.tool_tab, _("Tool"))
# focus on Tool Tab
self.app.ui.notebook.setCurrentWidget(self.app.ui.tool_tab)
try:
if self.app.ui.tool_scroll_area.widget().objectName() == self.toolName and found_idx:
# if the Tool Tab is not focused, focus on it
if not self.app.ui.notebook.currentWidget() is self.app.ui.tool_tab:
# focus on Tool Tab
self.app.ui.notebook.setCurrentWidget(self.app.ui.tool_tab)
else:
# else remove the Tool Tab
self.app.ui.notebook.setCurrentWidget(self.app.ui.properties_tab)
self.app.ui.notebook.removeTab(2)
# if there are no objects loaded in the app then hide the Notebook widget
if not self.app.collection.get_list():
self.app.ui.splitter.setSizes([0, 1])
except AttributeError:
pass
else:
if self.app.ui.splitter.sizes()[0] == 0:
self.app.ui.splitter.setSizes([1, 1])
AppTool.run(self)
self.set_tool_ui()
self.app.ui.notebook.setTabText(2, _("Calc. Tool"))
def install(self, icon=None, separator=None, **kwargs):
AppTool.install(self, icon, separator, shortcut='Alt+C', **kwargs)
def set_tool_ui(self):
self.units = self.app.defaults['units'].lower()
# ## Initialize form
self.ui.mm_entry.set_value('%.*f' % (self.decimals, 0))
self.ui.inch_entry.set_value('%.*f' % (self.decimals, 0))
length = self.app.defaults["tools_calc_electro_length"]
width = self.app.defaults["tools_calc_electro_width"]
density = self.app.defaults["tools_calc_electro_cdensity"]
growth = self.app.defaults["tools_calc_electro_growth"]
self.ui.pcblength_entry.set_value(length)
self.ui.pcbwidth_entry.set_value(width)
self.ui.area_entry.set_value(self.app.defaults["tools_calc_electro_area"])
self.ui.cdensity_entry.set_value(density)
self.ui.growth_entry.set_value(growth)
self.ui.cvalue_entry.set_value(0.00)
self.ui.time_entry.set_value(0.0)
tip_dia = self.app.defaults["tools_calc_vshape_tip_dia"]
tip_angle = self.app.defaults["tools_calc_vshape_tip_angle"]
cut_z = self.app.defaults["tools_calc_vshape_cut_z"]
self.ui.tipDia_entry.set_value(tip_dia)
self.ui.tipAngle_entry.set_value(tip_angle)
self.ui.cutDepth_entry.set_value(cut_z)
self.on_calculate_tool_dia()
self.ui.area_sel_radio.set_value('d')
self.on_area_calculation_radio(val='d')
self.on_calculate_eplate()
self.ui_disconnect()
self.ui_connect()
def on_area_calculation_radio(self, val):
if val == 'a':
self.ui.pcbwidthlabel.hide()
self.ui.pcbwidth_entry.hide()
self.ui.width_unit.hide()
self.ui.pcblengthlabel.hide()
self.ui.pcblength_entry.hide()
self.ui.length_unit.hide()
self.ui.area_label.show()
self.ui.area_entry.show()
self.ui.area_unit.show()
else:
self.ui.pcbwidthlabel.show()
self.ui.pcbwidth_entry.show()
self.ui.width_unit.show()
self.ui.pcblengthlabel.show()
self.ui.pcblength_entry.show()
self.ui.length_unit.show()
self.ui.area_label.hide()
self.ui.area_entry.hide()
self.ui.area_unit.hide()
def on_calculate_tool_dia(self):
self.ui_disconnect()
# Calculation:
# Manufacturer gives total angle of the the tip but we need only half of it
# tangent(half_tip_angle) = opposite side / adjacent = part_of _real_dia / depth_of_cut
# effective_diameter = tip_diameter + part_of_real_dia_left_side + part_of_real_dia_right_side
# tool is symmetrical therefore: part_of_real_dia_left_side = part_of_real_dia_right_side
# effective_diameter = tip_diameter + (2 * part_of_real_dia_left_side)
# effective diameter = tip_diameter + (2 * depth_of_cut * tangent(half_tip_angle))
tip_diameter = float(self.ui.tipDia_entry.get_value())
half_tip_angle = float(self.ui.tipAngle_entry.get_value()) / 2.0
cut_depth = float(self.ui.cutDepth_entry.get_value())
cut_depth = -cut_depth if cut_depth < 0 else cut_depth
tool_diameter = tip_diameter + (2 * cut_depth * math.tan(math.radians(half_tip_angle)))
self.ui.effectiveToolDia_entry.set_value(self.app.dec_format(tool_diameter, self.decimals))
self.app.inform.emit('[success] %s' % _("Cut width (tool diameter) calculated."))
self.ui_connect()
def on_calculate_cutz(self):
self.ui_disconnect()
# Calculation:
# Manufacturer gives total angle of the the tip but we need only half of it
# tangent(half_tip_angle) = opposite side / adjacent = part_of _real_dia / depth_of_cut
# effective_diameter = tip_diameter + part_of_real_dia_left_side + part_of_real_dia_right_side
# tool is symmetrical therefore: part_of_real_dia_left_side = part_of_real_dia_right_side
# effective_diameter = tip_diameter + (2 * part_of_real_dia_left_side)
# effective diameter = tip_diameter + (2 * depth_of_cut * tangent(half_tip_angle))
tip_diameter = float(self.ui.tipDia_entry.get_value())
half_tip_angle = float(self.ui.tipAngle_entry.get_value()) / 2.0
tooldia = self.ui.effectiveToolDia_entry.get_value()
if tip_diameter > tooldia:
self.ui.cutDepth_entry.set_value(self.app.dec_format(0.0, self.decimals))
self.app.inform.emit('[ERROR_NOTCL] %s' %
_("Tool diameter (cut width) cannot be smaller than the tip diameter."))
self.ui_connect()
return
cut_depth = (tooldia - tip_diameter) / (2 * math.tan(math.radians(half_tip_angle))) * -1
self.ui.cutDepth_entry.set_value(self.app.dec_format(cut_depth, self.decimals))
self.app.inform.emit('[success] %s' % _("Cut depth (Cut Z) calculated."))
self.ui_connect()
def on_calculate_inch_units(self):
mm_val = float(self.ui.mm_entry.get_value())
self.ui.inch_entry.set_value('%.*f' % (self.decimals, (mm_val / 25.4)))
def on_calculate_mm_units(self):
inch_val = float(self.ui.inch_entry.get_value())
self.ui.mm_entry.set_value('%.*f' % (self.decimals, (inch_val * 25.4)))
def on_calculate_current(self):
"""
:return:
"""
'''
Example: If you are plating a 12" by 9", double-sided board, with a current density of 20 ASF, you will need:
[(12" x 9" x 2 sides)/144] x 20 = 30 Amps = C
In Metric, for a 10cm by 10cm, double sided board, with a current density of 20 ASF, you will need:
[(10cm x 10cm x 2 sides]/929.0304359661127] x 20 =~ 4.3 Amps = C
or written differently:
[(10cm x 10cm x 2 sides] * 0.001076391] x 20 =~ 4.3 Amps = C
or:
(10cm x 10cm) * 0.0021527820833419] x 20 =~ 4.3 Amps = C
'''
self.ui_disconnect()
area_calc_sel = self.ui.area_sel_radio.get_value()
length = self.ui.pcblength_entry.get_value()
width = self.ui.pcbwidth_entry.get_value()
area = self.ui.area_entry.get_value()
density = self.ui.cdensity_entry.get_value()
if area_calc_sel == 'd':
calculated_current = (length * width * density) * 0.0021527820833419
else:
calculated_current = (area * density) * 0.0021527820833419
self.ui.cvalue_entry.set_value('%.2f' % calculated_current)
self.ui_connect()
def on_calculate_time(self):
"""
:return:
"""
'''
Calculated time for a copper growth of 10 microns is:
[10um / (28um/hr)] x 60 min/hr = 21.42 minutes = TC (at 20ASF)
or:
10 um * 2.142857142857143 min/um = 21.42 minutes = TC (at 20ASF)
or:
10 * 2.142857142857143 min * (20/new_density) = 21.42 minutes = TC
(with new_density = 20ASF amd copper groth of 10 um)
'''
self.ui_disconnect()
density = self.ui.cdensity_entry.get_value()
growth = self.ui.growth_entry.get_value()
calculated_time = growth * 2.142857142857143 * float(20 / density)
self.ui.time_entry.set_value('%.1f' % calculated_time)
self.ui_connect()
def on_calculate_eplate(self):
self.on_calculate_time()
self.on_calculate_current()
self.app.inform.emit('[success] %s' % _("Done."))
def on_calculate_growth(self):
self.ui_disconnect()
density = self.ui.cdensity_entry.get_value()
time = self.ui.time_entry.get_value()
growth = time / (2.142857142857143 * float(20 / density))
self.ui.growth_entry.set_value(self.app.dec_format(growth, self.decimals))
self.app.inform.emit('[success] %s' % _("Done."))
self.ui_connect()
def ui_connect(self):
# V-Shape Calculator
self.ui.cutDepth_entry.valueChanged.connect(self.on_calculate_tool_dia)
self.ui.cutDepth_entry.returnPressed.connect(self.on_calculate_tool_dia)
self.ui.effectiveToolDia_entry.valueChanged.connect(self.on_calculate_cutz)
self.ui.effectiveToolDia_entry.returnPressed.connect(self.on_calculate_cutz)
self.ui.tipDia_entry.returnPressed.connect(self.on_calculate_tool_dia)
self.ui.tipAngle_entry.returnPressed.connect(self.on_calculate_tool_dia)
self.ui.calculate_vshape_button.clicked.connect(self.on_calculate_tool_dia)
# Electroplating Calculator
self.ui.cdensity_entry.valueChanged.connect(self.on_calculate_eplate)
self.ui.cdensity_entry.returnPressed.connect(self.on_calculate_eplate)
self.ui.growth_entry.valueChanged.connect(self.on_calculate_time)
self.ui.growth_entry.returnPressed.connect(self.on_calculate_time)
self.ui.area_entry.valueChanged.connect(self.on_calculate_current)
self.ui.area_entry.returnPressed.connect(self.on_calculate_current)
self.ui.time_entry.valueChanged.connect(self.on_calculate_growth)
self.ui.time_entry.returnPressed.connect(self.on_calculate_growth)
self.ui.calculate_plate_button.clicked.connect(self.on_calculate_eplate)
def ui_disconnect(self):
# V-Shape Calculator
try:
self.ui.cutDepth_entry.valueChanged.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.cutDepth_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
# ##
try:
self.ui.effectiveToolDia_entry.valueChanged.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.effectiveToolDia_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
# ###
try:
self.ui.tipDia_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.tipAngle_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.calculate_vshape_button.clicked.disconnect()
except (AttributeError, TypeError):
pass
# Electroplating Calculator
# Density
try:
self.ui.cdensity_entry.valueChanged.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.cdensity_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
# Growth
try:
self.ui.growth_entry.valueChanged.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.growth_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
# Area
try:
self.ui.area_entry.valueChanged.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.area_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
# Time
try:
self.ui.time_entry.valueChanged.disconnect()
except (AttributeError, TypeError):
pass
try:
self.ui.time_entry.returnPressed.disconnect()
except (AttributeError, TypeError):
pass
# Calculate
try:
self.ui.calculate_plate_button.clicked.disconnect()
except (AttributeError, TypeError):
pass
class CalcUI:
toolName = _("Calculators")
v_shapeName = _("V-Shape Tool Calculator")
unitsName = _("Units Calculator")
eplateName = _("ElectroPlating Calculator")
def __init__(self, layout, app):
self.app = app
self.decimals = self.app.decimals
self.layout = layout
self.units = self.app.defaults['units'].lower()
# ## Title
title_label = FCLabel("%s" % self.toolName)
title_label.setStyleSheet("""
QLabel
{
font-size: 16px;
font-weight: bold;
}
""")
self.layout.addWidget(title_label)
# #####################
# ## Units Calculator #
# #####################
self.unists_spacer_label = FCLabel(" ")
self.layout.addWidget(self.unists_spacer_label)
# ## Title of the Units Calculator
units_label = FCLabel("%s" % self.unitsName)
self.layout.addWidget(units_label)
# Grid Layout
grid_units_layout = QtWidgets.QGridLayout()
self.layout.addLayout(grid_units_layout)
inch_label = FCLabel(_("INCH"))
mm_label = FCLabel(_("MM"))
grid_units_layout.addWidget(mm_label, 0, 0)
grid_units_layout.addWidget(inch_label, 0, 1)
self.inch_entry = NumericalEvalEntry(border_color='#0069A9')
# self.inch_entry.setFixedWidth(70)
# self.inch_entry.setAlignment(QtCore.Qt.AlignRight | QtCore.Qt.AlignVCenter)
self.inch_entry.setToolTip(_("Here you enter the value to be converted from INCH to MM"))
self.mm_entry = NumericalEvalEntry(border_color='#0069A9')
# self.mm_entry.setFixedWidth(130)
# self.mm_entry.setAlignment(QtCore.Qt.AlignRight | QtCore.Qt.AlignVCenter)
self.mm_entry.setToolTip(_("Here you enter the value to be converted from MM to INCH"))
grid_units_layout.addWidget(self.mm_entry, 1, 0)
grid_units_layout.addWidget(self.inch_entry, 1, 1)
# #############################################################################################################
# ################################ V-shape Tool Calculator ####################################################
# #############################################################################################################
grid_vshape = QtWidgets.QGridLayout()
grid_vshape.setColumnStretch(0, 0)
grid_vshape.setColumnStretch(1, 1)
self.layout.addLayout(grid_vshape)
self.v_shape_spacer_label = FCLabel(" ")
grid_vshape.addWidget(self.v_shape_spacer_label, 0, 0, 1, 2)
# ## Title of the V-shape Tools Calculator
v_shape_title_label = FCLabel("%s" % self.v_shapeName)
grid_vshape.addWidget(v_shape_title_label, 2, 0, 1, 2)
# Tip Diameter
self.tipDia_label = FCLabel('%s:' % _("Tip Diameter"))
self.tipDia_label.setToolTip(
_("This is the tool tip diameter.\n"
"It is specified by manufacturer.")
)
self.tipDia_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.tipDia_entry.set_precision(self.decimals)
self.tipDia_entry.set_range(0.0, 10000.0000)
self.tipDia_entry.setSingleStep(0.1)
grid_vshape.addWidget(self.tipDia_label, 4, 0)
grid_vshape.addWidget(self.tipDia_entry, 4, 1)
# Tip Angle
self.tipAngle_label = FCLabel('%s:' % _("Tip Angle"))
self.tipAngle_label.setToolTip(_("This is the angle of the tip of the tool.\n"
"It is specified by manufacturer."))
self.tipAngle_entry = FCSpinner(callback=self.confirmation_message_int)
self.tipAngle_entry.set_range(0, 180)
self.tipAngle_entry.set_step(5)
grid_vshape.addWidget(self.tipAngle_label, 6, 0)
grid_vshape.addWidget(self.tipAngle_entry, 6, 1)
# Cut Z
self.cutDepth_label = FCLabel('%s:' % _("Cut Z"))
self.cutDepth_label.setToolTip(_("This is the depth to cut into the material.\n"
"In the CNCJob is the CutZ parameter."))
self.cutDepth_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.cutDepth_entry.set_range(-10000.0000, 10000.0000)
self.cutDepth_entry.set_precision(self.decimals)
grid_vshape.addWidget(self.cutDepth_label, 8, 0)
grid_vshape.addWidget(self.cutDepth_entry, 8, 1)
# Tool Diameter
self.effectiveToolDia_label = FCLabel('%s:' % _("Tool Diameter"))
self.effectiveToolDia_label.setToolTip(_("This is the tool diameter to be entered into\n"
"FlatCAM Gerber section.\n"
"In the CNCJob section it is called >Tool dia<."))
self.effectiveToolDia_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.effectiveToolDia_entry.set_precision(self.decimals)
grid_vshape.addWidget(self.effectiveToolDia_label, 10, 0)
grid_vshape.addWidget(self.effectiveToolDia_entry, 10, 1)
# ## Buttons
self.calculate_vshape_button = FCButton(_("Calculate"))
self.calculate_vshape_button.setIcon(QtGui.QIcon(self.app.resource_location + '/calculator16.png'))
self.calculate_vshape_button.setToolTip(
_("Calculate either the Cut Z or the effective tool diameter,\n "
"depending on which is desired and which is known. ")
)
grid_vshape.addWidget(self.calculate_vshape_button, 12, 0, 1, 2)
# #############################################################################################################
# ############################## ElectroPlating Tool Calculator ###############################################
# #############################################################################################################
grid_electro = QtWidgets.QGridLayout()
grid_electro.setColumnStretch(0, 0)
grid_electro.setColumnStretch(1, 1)
self.layout.addLayout(grid_electro)
grid_electro.addWidget(FCLabel(""), 0, 0, 1, 2)
# ## Title of the ElectroPlating Tools Calculator
plate_title_label = FCLabel("%s" % self.eplateName)
plate_title_label.setToolTip(
_("This calculator is useful for those who plate the via/pad/drill holes,\n"
"using a method like graphite ink or calcium hypophosphite ink or palladium chloride.")
)
grid_electro.addWidget(plate_title_label, 2, 0, 1, 2)
# Area Calculation
self.area_sel_label = FCLabel('%s:' % _("Area Calculation"))
self.area_sel_label.setToolTip(
_("Choose how to calculate the board area.")
)
self.area_sel_radio = RadioSet([
{'label': _('Dimensions'), 'value': 'd'},
{"label": _("Area"), "value": "a"}
], stretch=False)
grid_electro.addWidget(self.area_sel_label, 4, 0)
grid_electro.addWidget(self.area_sel_radio, 6, 0, 1, 2)
# BOARD LENGTH
self.pcblengthlabel = FCLabel('%s:' % _("Board Length"))
self.pcblengthlabel.setToolTip(_('This is the board length. In centimeters.'))
self.pcblength_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.pcblength_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.pcblength_entry.set_precision(self.decimals)
self.pcblength_entry.set_range(0.0, 10000.0000)
self.length_unit = FCLabel('%s' % _("cm"))
self.length_unit.setMinimumWidth(25)
l_hlay = QtWidgets.QHBoxLayout()
l_hlay.addWidget(self.pcblength_entry)
l_hlay.addWidget(self.length_unit)
grid_electro.addWidget(self.pcblengthlabel, 8, 0)
grid_electro.addLayout(l_hlay, 8, 1)
# BOARD WIDTH
self.pcbwidthlabel = FCLabel('%s:' % _("Board Width"))
self.pcbwidthlabel.setToolTip(_('This is the board width.In centimeters.'))
self.pcbwidth_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.pcbwidth_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.pcbwidth_entry.set_precision(self.decimals)
self.pcbwidth_entry.set_range(0.0, 10000.0000)
self.width_unit = FCLabel('%s' % _("cm"))
self.width_unit.setMinimumWidth(25)
w_hlay = QtWidgets.QHBoxLayout()
w_hlay.addWidget(self.pcbwidth_entry)
w_hlay.addWidget(self.width_unit)
grid_electro.addWidget(self.pcbwidthlabel, 10, 0)
grid_electro.addLayout(w_hlay, 10, 1)
# AREA
self.area_label = FCLabel('%s:' % _("Area"))
self.area_label.setToolTip(_('This is the board area.'))
self.area_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.area_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.area_entry.set_precision(self.decimals)
self.area_entry.set_range(0.0, 10000.0000)
self.area_unit = FCLabel('%s2' % _("cm"))
self.area_unit.setMinimumWidth(25)
a_hlay = QtWidgets.QHBoxLayout()
a_hlay.addWidget(self.area_entry)
a_hlay.addWidget(self.area_unit)
grid_electro.addWidget(self.area_label, 12, 0)
grid_electro.addLayout(a_hlay, 12, 1)
separator_line = QtWidgets.QFrame()
separator_line.setFrameShape(QtWidgets.QFrame.HLine)
separator_line.setFrameShadow(QtWidgets.QFrame.Sunken)
grid_electro.addWidget(separator_line, 14, 0, 1, 2)
# DENSITY
self.cdensity_label = FCLabel('%s:' % _("Current Density"))
self.cdensity_label.setToolTip(_("Current density to pass through the board. \n"
"In Amps per Square Feet ASF."))
self.cdensity_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.cdensity_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.cdensity_entry.set_precision(self.decimals)
self.cdensity_entry.set_range(0.0, 10000.0000)
self.cdensity_entry.setSingleStep(0.1)
density_unit = FCLabel('%s' % "ASF")
density_unit.setMinimumWidth(25)
d_hlay = QtWidgets.QHBoxLayout()
d_hlay.addWidget(self.cdensity_entry)
d_hlay.addWidget(density_unit)
grid_electro.addWidget(self.cdensity_label, 16, 0)
grid_electro.addLayout(d_hlay, 16, 1)
# COPPER GROWTH
self.growth_label = FCLabel('%s:' % _("Copper Growth"))
self.growth_label.setToolTip(_("How thick the copper growth is intended to be.\n"
"In microns."))
self.growth_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.growth_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.growth_entry.set_precision(self.decimals)
self.growth_entry.set_range(0.0, 10000.0000)
self.growth_entry.setSingleStep(0.01)
growth_unit = FCLabel('%s' % _("um"))
growth_unit.setMinimumWidth(25)
g_hlay = QtWidgets.QHBoxLayout()
g_hlay.addWidget(self.growth_entry)
g_hlay.addWidget(growth_unit)
grid_electro.addWidget(self.growth_label, 18, 0)
grid_electro.addLayout(g_hlay, 18, 1)
# CURRENT
self.cvaluelabel = FCLabel('%s:' % _("Current Value"))
self.cvaluelabel.setToolTip(_('This is the current intensity value\n'
'to be set on the Power Supply. In Amps.'))
self.cvalue_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.cvalue_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.cvalue_entry.set_precision(self.decimals)
self.cvalue_entry.set_range(0.0, 10000.0000)
self.cvalue_entry.setSingleStep(0.1)
current_unit = FCLabel('%s' % "A")
current_unit.setMinimumWidth(25)
self.cvalue_entry.setReadOnly(True)
c_hlay = QtWidgets.QHBoxLayout()
c_hlay.addWidget(self.cvalue_entry)
c_hlay.addWidget(current_unit)
grid_electro.addWidget(self.cvaluelabel, 20, 0)
grid_electro.addLayout(c_hlay, 20, 1)
# TIME
self.timelabel = FCLabel('%s:' % _("Time"))
self.timelabel.setToolTip(_('This is the calculated time required for the procedure.\n'
'In minutes.'))
self.time_entry = FCDoubleSpinner(callback=self.confirmation_message)
self.time_entry.setSizePolicy(QtWidgets.QSizePolicy.MinimumExpanding, QtWidgets.QSizePolicy.Preferred)
self.time_entry.set_precision(self.decimals)
self.time_entry.set_range(0.0, 10000.0000)
self.time_entry.setSingleStep(0.1)
time_unit = FCLabel('%s' % "min")
time_unit.setMinimumWidth(25)
# self.time_entry.setReadOnly(True)
t_hlay = QtWidgets.QHBoxLayout()
t_hlay.addWidget(self.time_entry)
t_hlay.addWidget(time_unit)
grid_electro.addWidget(self.timelabel, 22, 0)
grid_electro.addLayout(t_hlay, 22, 1)
# ## Buttons
self.calculate_plate_button = FCButton(_("Calculate"))
self.calculate_plate_button.setIcon(QtGui.QIcon(self.app.resource_location + '/calculator16.png'))
self.calculate_plate_button.setToolTip(
_("Calculate the current intensity value and the procedure time,\n"
"depending on the parameters above")
)
grid_electro.addWidget(self.calculate_plate_button, 24, 0, 1, 2)
self.layout.addStretch(1)
# ## Reset Tool
self.reset_button = FCButton(_("Reset Tool"))
self.reset_button.setIcon(QtGui.QIcon(self.app.resource_location + '/reset32.png'))
self.reset_button.setToolTip(
_("Will reset the tool parameters.")
)
self.reset_button.setStyleSheet("""
QPushButton
{
font-weight: bold;
}
""")
self.layout.addWidget(self.reset_button)
# #################################### FINSIHED GUI ###########################
# #############################################################################
def confirmation_message(self, accepted, minval, maxval):
if accepted is False:
self.app.inform[str, bool].emit('[WARNING_NOTCL] %s: [%.*f, %.*f]' % (_("Edited value is out of range"),
self.decimals,
minval,
self.decimals,
maxval), False)
else:
self.app.inform[str, bool].emit('[success] %s' % _("Edited value is within limits."), False)
def confirmation_message_int(self, accepted, minval, maxval):
if accepted is False:
self.app.inform[str, bool].emit('[WARNING_NOTCL] %s: [%d, %d]' %
(_("Edited value is out of range"), minval, maxval), False)
else:
self.app.inform[str, bool].emit('[success] %s' % _("Edited value is within limits."), False)