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from filtre_gui import *
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from math import *
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#lancer le calcul
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def signals(self):
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self.calculer_pushbutton.clicked.connect(self.calc)
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def calc(self):
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frequence = int(self.freqCp_lineedit.text())
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amplitude = float(self.amplitude_lineedit.text())
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impedance = float(self.impEntree_lineedit.text())
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ordre = int(self.ordre_lineedit.text())
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w = calcul_w( frequence)
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b=calcul_b(amplitude)
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gamma = calcul_gamma(b,ordre)
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ak=calcul_ak(ordre)
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bk = calcul_bk(ordre,gamma)
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gk = calcul_gk(ordre,ak,bk,gamma)
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ck,lk=ck_lk_calcul(ordre,impedance,w,gk)
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r = calcul_r(ordre,impedance,b)
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rn=calcul_Rn(r,impedance)
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textdecompletion=''
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for i in range (ordre//2):
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textdecompletion= textdecompletion + "L" +str(i) + "= " + str("%.3e"%lk[i]) + " \n"
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self.resultatlk_textedit.setText(textdecompletion)
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textdecompletion=''
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for i in range (ordre//2):
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textdecompletion= textdecompletion + "C" + str(i) + "= " + str("%.3e"%ck[i]) + " \n"
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self.resultatck_textedit.setText(textdecompletion)
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self.resultatrn_lineedit.setText(str("%.3e"%rn))
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#self.resultat_lineedit.setText('lk ='+str(lk)+'\nck='+str(ck)+'\nrn ='+str(rn))
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#Calcul de wc
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def calcul_w(frequence):
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wc=2.*pi*frequence
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return wc
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#Calcul de b
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def calcul_b(amplitude):
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b=log(cosh(amplitude/17.37)/sinh(amplitude/17.37))
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#b=log((exp(2*(impedance/17.37))+1)/((exp(2*(impedance/17.37))-1)))
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#b=0.002745
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return b
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#Calcul de rn
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def calcul_r(ordre,impedance,b):
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if ordre==1:
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r=1.*impedance
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else:
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r=pow((tanh(b/4.)),2)
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return r
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#Calcul de gamma
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def calcul_gamma(b,ordre):
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gamma=sinh(b/(2*ordre))
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return gamma
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#Cacule de ak
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def calcul_ak(ordre):
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ak=[0]*ordre
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for i in range(ordre):
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ak[i]=sin(((2.*(i+1)-1)*pi)/(2.*ordre))
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return ak
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#Calcul de bk
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def calcul_bk(ordre,gamma):
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bk=[0]*ordre
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for i in range(ordre):
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bk[i]=gamma*gamma+sin(((i+1)*pi)/ordre)*sin(((i+1)*pi)/ordre)
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return bk
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#Calcul de gk
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def calcul_gk(ordre,ak,bk,gamma):
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gk=[0]*ordre
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gk[0] = ((2.*ak[0])/gamma)
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#print("GK0")
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#print(gk[0])
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for j in range(1,ordre):
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gk[j]=((4.*ak[j-1]*ak[j])/float((bk[j-1]*gk[j-1])))
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return gk
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#Calcul de cl et lk
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def ck_lk_calcul(ordre, impedance, wc, gk):
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ck=[0]*ordre
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lk=[0]*ordre
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if (ordre%2)==0:
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for i in range(ordre//2):
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lk[i]=(impedance/wc)*gk[i]
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for i in range(ordre//2):
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ck[i]=(1./impedance)*(1./wc)*gk[i]
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else:
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for i in range(ordre//2):
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lk[i]=(impedance/wc)*gk[i]
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for i in range((ordre//2)+1):
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ck[i]=(1./impedance)*(1./wc)*gk[i]
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return(ck,lk)
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def calcul_Rn(r,impedance):
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rn=r*impedance
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return rn
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Ui_MainWindow.signals = signals #edite les atibuts de Ui_MainWindow
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Ui_MainWindow.calc = calc #test = resultat du test
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if __name__ == "__main__": # A library or a stand-alone program
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import sys
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app = QtWidgets.QApplication(sys.argv) # Must create a QApplication object, sys.argv allows passing parameters in command line
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MainWindow = QtWidgets.QMainWindow() # Create a main window instance.
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ui = Ui_MainWindow() # Create a Ui_MainWindow instance
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ui.setupUi(MainWindow) # Add widgets to the main window
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ui.signals() # Connect signals with the appropriate functions
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MainWindow.show() # Show the main window
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sys.exit(app.exec_()) # If a termination signal is captured, exit the program.
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