Macro Geodesic Dome/fr

Description
Cette macro crée la coque d'un dôme géodésique paramétrique. Le rayon du dôme et les paramètres de fréquence sont définis au moment de la création.



Utilisation
1. Installez la macro en utilisant le gestionnaire (menu Outils → Addon Manager). Sur l'onglet "Macros", sélectionnez "GeodesicDome", cliquez sur "Installer". Fermez ensuite Addon Manager.

2. Exécutez GeodesicDome.FCMacro. Une fenêtre de dialogue devrait apparaître

3. Spécifiez les paramètres et cliquez sur.

La forme d'un dôme devrait apparaître. Vous pouvez ensuite modifier les paramètres du dôme en modifiant les propriétés de l'objet GeoDome.

Script
(Il s'agit d'une ancienne version non paramétrique du script. La version à jour est dans le référentiel FreeCAD-macros, here ! )

Macro_Geodesic_Dome.FCMacro

QtGui.QDialogButtonBox.Ok)  self.buttonBox.setObjectName("buttonBox")    self.gridLayout.addWidget(self.buttonBox, 2, 1, 1, 1)

self.retranslateUi(Dialog) QtCore.QObject.connect(self.buttonBox, \     QtCore.SIGNAL("accepted"), self.makeSomething) QtCore.QObject.connect(self.buttonBox, \     QtCore.SIGNAL("rejected"), self.makeNothing) QtCore.QMetaObject.connectSlotsByName(Dialog)

def retranslateUi(self, Dialog): # original code commented 2019/06/16 # Dialog.setWindowTitle(QtGui.QApplication.translate \   #   ("Dialog", "Geodesic Dome Creator",  \ #  None, QtGui.QApplication.UnicodeUTF8)) # self.label.setText(QtGui.QApplication.translate \   #   ("Dialog", "Dome Radius", None, QtGui.QApplication.UnicodeUTF8)) # self.label_2.setText(QtGui.QApplication.translate \   #   ("Dialog", "Frequency Parameter\n(Integer between 1 to 10)", \ #  None,QtGui.QApplication.UnicodeUTF8)) # self.label_3.setText(QtGui.QApplication.translate \   #   ("Dialog", "This Macro creates \na full geodesic dome shell.\nX-Y-symmetry plane \nfor even frequencies", \ #  None, QtGui.QApplication.UnicodeUTF8)) ####   # replacement code  2019/06/16 Dialog.setWindowTitle("Geodesic Dome Creator") self.label.setText("Dome Radius") self.label_2.setText("Frequency Parameter\n(Integer between 1 to 10)") self.label_3.setText("This Macro creates \na full geodesic dome shell.\nX-Y-symmetry plane \nfor even frequencies") ####

def makeSomething(self): print( "accepted! Dome radius: ", self.lineEdit.property("text"), \     " with Frequency: ", int(self.lineEdit_2.text))

doc=App.activeDocument label = "GeodesicDome"

theDome = doc.addObject("Part::Feature",label) radius = self.lineEdit.property("text") frequency = int(self.lineEdit_2.text) self.dia.close self.makeDome(theDome, radius, frequency) doc.recompute def makeNothing(self): print( "rejected!!") self.dia.close

def makeDome(self, obj, domeRad_str, ny): def makeFreqFaces(fPt, sPt, thPt, ny = 1): # makes the geodesic dome faces out of the points of an     # icosahedron triangle b = self.a/ny # length of frequent triangles # definition of direction vectors growVec = (sPt - fPt) # growVec = (fPt - sPt) growVec.multiply(1.0/ny) crossVec = (thPt - sPt) # crossVec = (sPt - thPt) crossVec.multiply(1.0/ny) for k in range(ny): kThirdPt = fPt + growVec * (k+0.0) dThirdPt = Base.Vector(kThirdPt.x, kThirdPt.y, kThirdPt.z)       dThirdPt = dThirdPt.normalize.multiply(domeRad.Value) kSecPt = fPt + growVec * (k+1.0) dSecPt = Base.Vector(kSecPt.x, kSecPt.y, kSecPt.z)       dSecPt = dSecPt.normalize.multiply(domeRad.Value) # thirdEdge = Part.makeLine(kSecPt, kThirdPt) # thirdEdge = Part.makeLine(dSecPt, dThirdPt) for l in range(k+1): firstPt = kSecPt + crossVec *(l+1.0) dFirstPt = firstPt.normalize.multiply(domeRad.Value) secPt = kSecPt + crossVec *(l+0.0) dSecPt =secPt.normalize.multiply(domeRad.Value) thirdPt = kThirdPt + crossVec *(l+0.0) dThirdPt = thirdPt.normalize.multiply(domeRad.Value) #thirdEdge = Part.makeLine(secPt, thirdPt) thirdEdge = Part.makeLine(dSecPt, dThirdPt) # Part.show(thirdEdge) if l > 0: print( "in l: ", l, " mod 2: ", l%2) # What to do here? #secEdge = Part.makeLine(oThirdPt,thirdPt) secEdge = Part.makeLine(doThirdPt,dThirdPt) # Part.show(secEdge) #thirdEdge = Part.makeLine(secPt, thirdPt) #thirdEdge = Part.makeLine(dSecPt, dThirdPt) # Part.show(thirdEdge) triWire = Part.Wire([firstEdge, secEdge, thirdEdge]) # Part.show(triWire) triFace = Part.Face(triWire) self.domeFaces.append(triFace) #Part.show(triFace) oThirdPt = thirdPt doThirdPt = oThirdPt.normalize.multiply(domeRad.Value) # oFirstPt = firstPt #firstEdge = Part.makeLine(thirdPt,firstPt) firstEdge = Part.makeLine(dThirdPt,dFirstPt) oFirstEdge = firstEdge #secEdge = Part.makeLine(firstPt,secPt) secEdge = Part.makeLine(dFirstPt,dSecPt) #Part.show(firstEdge) #Part.show(secEdge) #Part.show(thirdEdge) triWire = Part.Wire([firstEdge, secEdge, thirdEdge]) triFace = Part.Face(triWire) self.domeFaces.append(triFace) #Part.show(triFace) domeRad = FreeCAD.Units.Quantity(domeRad_str) # self.a = Strutlength of underlying icosahedron: self.a=(4.0*domeRad.Value)/math.sqrt(2.0*math.sqrt(5.0)+10.0) # icoAngle: angle of vertices of icosahedron points # not a north or south pole self.icoAngle = math.atan(0.5) self.icoLat = domeRad.Value * math.sin(self.icoAngle) self.latRad = domeRad.Value * math.cos(self.icoAngle) self.ang36 = math.radians(36.0) # Calculation all points of the icosahedron self.icoPts = [] self.icoPts.append(Base.Vector(0.0, 0.0, domeRad.Value)) for i in range(10): self.icoCos = self.latRad * math.cos(i*self.ang36) self.icoSin = self.latRad * math.sin(i*self.ang36) if i%2 == 0: self.icoPts.append(Base.Vector(self.icoSin, self.icoCos, self.icoLat)) else: self.icoPts.append(Base.Vector(self.icoSin, self.icoCos, -self.icoLat)) self.icoPts.append(Base.Vector(0.0, 0.0, -domeRad.Value)) # making the faces of the icosahedron self.icoFaces = [] # collects faces of the underlying icosahedron self.domeFaces = [] # collects the faces of the geodesic dome thirdPt = self.icoPts[9] thirdEdge = Part.makeLine(self.icoPts[0],thirdPt) for i in range(5): j = i*2+1 firstEdge = Part.makeLine(thirdPt,self.icoPts[j]) secEdge = Part.makeLine(self.icoPts[j],self.icoPts[0]) triWire = Part.Wire([firstEdge, secEdge, thirdEdge]) triFace = Part.Face(triWire) self.icoFaces.append(triFace) # Part.show(triFace) makeFreqFaces(self.icoPts[j], self.icoPts[0], thirdPt, ny) thirdEdge = Part.makeLine(self.icoPts[0],self.icoPts[j]) thirdPt = self.icoPts[j] thirdPt = self.icoPts[9] secPt = self.icoPts[10] thirdEdge = Part.makeLine(secPt,thirdPt) for i in range(10): j = i+1 firstEdge = Part.makeLine(thirdPt,self.icoPts[j]) secEdge = Part.makeLine(self.icoPts[j],secPt) triWire = Part.Wire([firstEdge, secEdge, thirdEdge]) triFace = Part.Face(triWire) self.icoFaces.append(triFace) #Part.show(triFace) makeFreqFaces(self.icoPts[j], secPt, thirdPt, ny) thirdPt = secPt secPt = self.icoPts[j] thirdEdge = Part.makeLine(secPt,thirdPt) thirdPt = self.icoPts[10] thirdEdge = Part.makeLine(self.icoPts[11],thirdPt) for i in range(5): j = i*2+2 firstEdge = Part.makeLine(thirdPt,self.icoPts[j]) secEdge = Part.makeLine(self.icoPts[j],self.icoPts[11]) triWire = Part.Wire([firstEdge, secEdge, thirdEdge]) triFace = Part.Face(triWire) self.icoFaces.append(triFace) #Part.show(triFace) makeFreqFaces(self.icoPts[j], self.icoPts[11], thirdPt, ny) thirdEdge = Part.makeLine(self.icoPts[11],self.icoPts[j]) thirdPt = self.icoPts[j] # Shell of a corresponding icosahedron newShell = Part.Shell(self.icoFaces) #Part.show(newShell) # Shell of the geodesic dome #self.domeShell = Part.Shell(self.domeFaces) #Part.show(self.domeShell) obj.Shape = Part.Shell(self.domeFaces) # Shere with radius of geodesic dome for debugging purposes testSphere = Part.makeSphere(domeRad.Value) #Part.show(testSphere)

d = QtGui.QWidget d.ui = Ui_Dialog d.ui.setupUi(d) d.ui.lineEdit_2.setText("2") d.ui.lineEdit.setProperty("text", "2 m")

d.show

Link
Forum Designing geodesic dome