def __init__(self):

super(Window,self).__init__()

self.creategridbox()

self.createpic()

self.createpic2()

self.pixmap=QPixmap('1.png')

self.lb=QLabel(self)

self.lb.setPixmap(self.pixmap)

self.hbox=QHBoxLayout()

self.vbox1=QVBoxLayout()

self.vbox2=QVBoxLayout()

self.vbox1.addWidget(self.lb)

self.vbox1.addWidget(self.picbox)

self.vbox2.addWidget(self.gridbox)

self.vbox2.addWidget(self.picbox2)

self.hbox.addLayout(self.vbox2)

self.hbox.addStretch(1)

self.hbox.addLayout(self.vbox1)

self.setLayout(self.hbox)

self.setWindowTitle('Pre-PPDEM V1.0')

self.setWindowIcon(QIcon('dragon.ico'))

self.setGeometry(100, 50, 750,900)

self.center() #获取显示屏幕大小动态设置

self.x1=[]

self.y1=[]

self.dd=[] #随机分布后顺序半径

self.an=[]

self.cac=[]

self.coord=[]

self.infodic={}

self.num=0

self.ifplot=0

def creategridbox(self):

self.gridbox=QGroupBox()

grid=QGridLayout()

'''

self.fig = Figure(figsize=(5, 10), dpi=100)

self.canvas=FigureCanvas(self.fig)

self.toolbar=MyCostumToolbar(self.canvas,self)

btn=QPushButton('Grading Curve')

btn.clicked.connect(self.plot)

'''

self.btr=QPushButton('Read File')

self.btr.clicked.connect(self.readfile)

self.bth=QPushButton('Help')

self.bth.clicked.connect(self.helpfile)

self.TB1=QTextEdit('Grading')

self.TB1.setFixedSize(150,250)

#设置TextEdit行高

text_format=QTextBlockFormat()

text_format.setBottomMargin(0)

text_format.setLineHeight(15,QTextBlockFormat.FixedHeight)

text_cursor=self.TB1.textCursor()

text_cursor.setBlockFormat(text_format)

self.TB1.setTextCursor(text_cursor)

Lbn=QLabel('Particle Number') #不少于100个

self.LEn=QLineEdit('200')

Lbr=QLabel('Specimen Slenderness')

self.LEr=QLineEdit('2')

Lbe=QLabel('Estimated Void Ratio')

self.LEe=QLineEdit('0.5')

self.LEn.setFixedWidth(100)

self.LEr.setFixedWidth(100)

self.LEe.setFixedWidth(100)

#set the layout

grid.addWidget(self.btr,0,0,1,1)

grid.addWidget(self.bth,0,6,1,1)

grid.addWidget(self.TB1,1,0,15,4)

grid.addWidget(Lbn,1,5,1,1)

grid.addWidget(self.LEn,1,6,1,1)

grid.addWidget(Lbr,2,5,1,1)

grid.addWidget(self.LEr,2,6,1,1)

grid.addWidget(Lbe,3,5,1,1)

grid.addWidget(self.LEe,3,6,1,1)

grid.setHorizontalSpacing(15)

self.gridbox.setLayout(grid)

self.gridbox.setWindowTitle('test')

def createpic(self):

self.picbox=QGroupBox()

hbox1=QHBoxLayout()

hbox2=QHBoxLayout()

vbox=QVBoxLayout()

self.fig2 = Figure(figsize=(5,30), dpi=100)

self.canvas2=FigureCanvas(self.fig2)

self.cb=QComboBox()

self.cb.addItems(['circle','ellipse','triangle','rectangle','pentagon'])

self.cb.currentIndexChanged.connect(self.comvisi)

toolbar=MyCostumToolbar(self.canvas2,self)

btn=QPushButton('Simulation')

btn.clicked.connect(self.plot2)

self.Lbc=QLabel('invisible')

self.Lbc.hide()

self.LEc=QLineEdit('2')

self.LEc.hide()

self.LEc.setFixedWidth(100)

self.Lbc2=QLabel('Roundness(0-1)')

self.Lbc2.hide()

self.LEc2=QLineEdit('0')

self.LEc2.hide()

self.LEc2.setFixedWidth(100)

btnp=QPushButton('Output')

btnp.clicked.connect(self.output)

hbox1.addWidget(toolbar)

hbox1.addWidget(self.cb)

hbox1.addWidget(btn)

hbox2.addWidget(self.Lbc)

hbox2.addWidget(self.LEc)

hbox2.addWidget(self.Lbc2)

hbox2.addWidget(self.LEc2)

hbox2.addStretch(1)

hbox2.addWidget(btnp)

vbox.addLayout(hbox1)

vbox.addLayout(hbox2)

vbox.addStretch(1)

vbox.addWidget(self.canvas2)

self.picbox.setLayout(vbox)

def createpic2(self):

self.picbox2=QGroupBox()

hbox1=QHBoxLayout()

vbox=QVBoxLayout()

self.fig = Figure(figsize=(5,5), dpi=100)

self.canvas=FigureCanvas(self.fig)

toolbar=MyCostumToolbar(self.canvas,self)

btn=QPushButton('Grading Curve')

btn.clicked.connect(self.plot)

hbox1.addWidget(toolbar)

hbox1.addWidget(btn)

vbox.addLayout(hbox1)

vbox.addStretch(1)

vbox.addWidget(self.canvas)

self.picbox2.setLayout(vbox)

def helpfile(self):

fo=open(webbrowser.open("readme.docx"))

def readfile(self):

self.infodic.clear()

filename=QFileDialog.getOpenFileName(self, 'Open File Dialog', 'C:',"Txt files(*.txt)")

ch=[]

i=0

f=open(filename[0],'r')

#重置输出框

self.TB1.setText('Grading\n d\tper')

#设置TextEdit行高

text_format=QTextBlockFormat()

text_format.setBottomMargin(0)

text_format.setLineHeight(15,QTextBlockFormat.FixedHeight)

text_cursor=self.TB1.textCursor()

text_cursor.setBlockFormat(text_format)

self.TB1.setTextCursor(text_cursor)

try:

while True:

lines=f.readline()

if not lines.strip():

break

d_tmp,p_tmp=[float(i) for i in lines.split()]

self.TB1.append(str(d_tmp)+'\t'+str(p_tmp)+'\n')

self.infodic[d_tmp]=p_tmp

f.close()

except:

QMessageBox.warning(self, 'Warning', 'Invalid Input Format',QMessageBox.Yes)

return

def center(self):

index=QDesktopWidget().primaryScreen()

screen = QDesktopWidget().availableGeometry(index)

size = self.frameGeometry()

self.move(screen.width()/2 - size.width()/1.5,

(screen.height() - size.height()) / 2)

def output(self):

if(self.ifplot==0):

self.plot2()

dir=None

try:

dir = QFileDialog.getExistingDirectory(self,

"Select File Directory",

"C:/") #起始路径

except:

return

if(dir==None):

return

note=("\t" +"4"+"\n"+

"-0.5825781033135710E+00 0.5574716361287161E+00 0.6345870624177348E+00 0.5574716361287161E+00"+"\n"+

"0.6345870624177348E+00 0.6162241217404306E+00 -0.5825781033135710E+00 0.6162241217404306E+00"+"\n"+

"-0.4172132111845057E-03 0.1198385011842817E+01 -0.4172132111845057E-03 -0.2468925397367039E-01"+"\n"+

"0.5242617231534830E-01 -0.2468925397367039E-01 0.5242617231534830E-01 0.1198385011842817E+01"+"\n"+

"0.3814697265625000E-05 0.2147483648000000E+10 0.1000000000000000E+01 0.5000000000000000E+00 0.1000000000000000E+01 0.1864399082996630E-03 0.0000000000000000E+00 0.0000000000000000E+00 0.0000000000000000E+00 0.8000000000000001E-04 0.0000000000000000E+00 0.1000000000000000E+02 0.0000000000000000E+00 0.2000000000000000E+03 0.0000000000000000E+00 0.5967993208922544E-02 0.0000000000000000E+00 0.2000000000000000E+00 0.2000000000000000E+00 0.2000000000000000E+00"+"\n"+

"dt E globDamping alpha beta maxGap tanTheta pX pY pInt gX gY xGravity yGravity CAC"

)

if self.cb.currentText()=='ellipse':

ra=int(self.LEc.text())

localtime=time.strftime("%Y-%m-%d %H.%M.%S",time.localtime())

fo=open(dir+"/ellipse "+localtime+".txt","w")

fo.writelines(str(self.num)+" "+"1"+"\n")

for i in range(0,self.x1.__len__()):

m=self.calelli(self.x1[i], self.y1[i], self.dd[i], self.dd[i]/ra, self.an[i])

str1=("4"+" "+str(m[0][0,0])+" "

+str(m[0][0,1])+" "+str(m[1][0,0])+" "

+str(m[1][0,1])+" "+str(m[2][0,0])+" "

+str(m[2][0,1])+" "+str(m[3][0,0])+" "

+str(m[3][0,1])+" "+str(self.cac[0])

+" "+str(self.cac[1])+" "+str(self.cac[2])

+" "+str(self.cac[3])

)

fo.writelines(str1+'\n')

fo.writelines(note+'\n')

fo.close()

elif self.cb.currentText()=='circle':

localtime=time.strftime("%Y-%m-%d %H.%M.%S",time.localtime())

fo=open(dir+"/circle "+localtime+".txt","w")

fo.writelines(str(self.num)+" "+"1"+"\n")

for i in range(0,self.x1.__len__()):

str1="2"+" "+(str(self.x1[i]/1000)+" "+str(self.y1[i]/1000)+" "+str(self.dd[i]/2000)+" "+str(self.dd[i]/2000))

fo.writelines(str1+'\n')

fo.writelines(note+'\n')

fo.close()

elif self.cb.currentText()=='triangle':

localtime=time.strftime("%Y-%m-%d %H.%M.%S",time.localtime())

fo=open(dir+"/triangle "+localtime+".txt","w")

roundness=float(self.LEc2.text())

fo.writelines(str(self.num)+" "+"1"+"\n")

for i in range(0,self.x1.__len__()):

str1=("3"+" "+str(self.coord[i][0,0])+" "+str(self.coord[i][0,1])+" "+str(self.coord[i][1,0])+" "+

str(self.coord[i][1,1])+" "+str(self.coord[i][2,0])+" "

+str(self.coord[i][2,1])

)

if(roundness==0):

str1+=" "+"0.1"+" "+"0.1"+" "+"0.1"

else:

str1+=" "+str(roundness*self.cac[i][0])+" "+str(roundness*self.cac[i][1])+" "+str(roundness*self.cac[i][2])

fo.writelines(str1+'\n')

fo.writelines(note+'\n')

fo.close()

elif self.cb.currentText()=='rectangle':

localtime=time.strftime("%Y-%m-%d %H.%M.%S",time.localtime())

fo=open(dir+"/rectangle "+localtime+".txt","w")

roundness=float(self.LEc2.text())

fo.writelines(str(self.num)+" "+"1"+"\n")

for i in range(0,self.x1.__len__()):

str1=("4"+" "+str(self.coord[i][0,0])+" "+str(self.coord[i][0,1])+" "+str(self.coord[i][1,0])+" "+

str(self.coord[i][1,1])+" "+str(self.coord[i][2,0])+" "

+str(self.coord[i][2,1])+" "+str(self.coord[i][3,0])+" "

+str(self.coord[i][3,1])

)

if(roundness==0):

str1+=" "+"0.1"+" "+"0.1"+" "+"0.1"+" "+"0.1"

else:

str1+=(" "+str(roundness*self.cac[i][0])+" "+str(roundness*self.cac[i][1])+" "+str(roundness*self.cac[i][2])

+" "+str(roundness*self.cac[i][3])

)

fo.writelines(str1+'\n')

fo.writelines(note+'\n')

fo.close()

elif self.cb.currentText()=='pentagon':

localtime=time.strftime("%Y-%m-%d %H.%M.%S",time.localtime())

fo=open(dir+"/pentagon "+localtime+".txt","w")

roundness=float(self.LEc2.text())

fo.writelines(str(self.num)+" "+"1"+"\n")

for i in range(0,self.x1.__len__()):

str1=("5"+" "+str(self.coord[i][0,0])+" "+str(self.coord[i][0,1])+" "+str(self.coord[i][1,0])+" "+

str(self.coord[i][1,1])+" "+str(self.coord[i][2,0])+" "

+str(self.coord[i][2,1])+" "+str(self.coord[i][3,0])+" "+str(self.coord[i][3,1])+" "

+str(self.coord[i][4,0])+" "+str(self.coord[i][4,1])

)

if(roundness==0):

str1+=" "+"0.1"+" "+"0.1"+" "+"0.1"+" "+"0.1"+" "+"0.1"

else:

str1+=(" "+str(roundness*self.cac[i][0])+" "+str(roundness*self.cac[i][1])+" "+str(roundness*self.cac[i][2])

+" "+str(roundness*self.cac[i][3])+" "+str(roundness*self.cac[i][4])

)

fo.writelines(str1+'\n')

fo.writelines(note+'\n')

fo.close()

self.ifplot=0

def comvisi(self):

if self.cb.currentText()=='ellipse':

self.Lbc.setText('L/D Ratio')

self.LEc.show()

self.Lbc.show()

elif (self.cb.currentText()=='triangle' or self.cb.currentText()=='rectangle' or self.cb.currentText()=='pentagon'):

self.Lbc.setText('Angular Offset（°）')

self.Lbc.show()

self.LEc.show()

self.Lbc2.show()

self.LEc2.show()

else:

self.Lbc.hide()

self.LEc.hide()

def plot(self):

d=[]

x=[]

y=[]

if not self.infodic:

QMessageBox.warning(self, 'Warning', 'Please select an input file',QMessageBox.Yes)

return

for element in self.infodic:

d.append(element)

x.append(log10(element))

y.append(self.infodic[element])

self.ax = self.fig.add_subplot(111)

self.fig.subplots_adjust(left=0.2,right=0.9,top=0.95,bottom=0.15)

self.ax.clear()

self.ax.hold(True)

#self.ax.set_xscale('log')

max=int(x[0])+1

min=int(x[x.__len__()-1])-1

xlabels=[]

for i in range(min,max):

xlabels.append(10**i)

xlabels.append(5*10**i)

xlabels.append(10**max)

xticks=[]

for element in xlabels:

xticks.append(log10(element))

self.ax.xaxis.set_major_locator(ticker.FixedLocator(xticks))

self.ax.xaxis.set_major_formatter(ticker.FixedFormatter(xlabels))

self.ax.xaxis.grid(b=True)

self.ax.set_xlabel(u'Grain Diameter/mm',fontproperties='Times New Roman')

self.ax.set_ylabel(u'Percentage Finer (%)',fontproperties='Times New Roman')

self.ax.set_xlim(xticks[0],xticks[xticks.__len__()-1])

self.ax.set_ylim(0,100)

self.ax.grid(True)

x.append(xticks[0])

y.append(0)

line1, = self.ax.plot(x, y, '-', linewidth=2, marker='^',

markersize=8, markerfacecolor=(0,0,0), label='Grading Curve')

self.ax.legend(loc='lower right')

xy=[]

for i in range(0,x.__len__()-1):

self.ax.text(x[i],y[i],str((d[i],y[i])),fontsize=12)

#str((xlabels[xlabels.__len__()-i-1]

# refresh canvas

self.canvas.draw()

def plot2(self):

if not self.infodic:

QMessageBox.warning(self, 'Warning', 'Please select an input file',QMessageBox.Yes)

return

projections.register_projection(My_Axes)

self.ax2 = self.fig2.add_subplot(111,projection='My_Axes')

self.ax2.clear()

self.ax2.hold(True)

m=self.cal()

N=m[0]

dmax=m[1]

w=int(m[2])

dic=m[3]

l=int(N/w)

N=int(w*l)

self.num=N

d=[]

x=[]

y=[]

"""

if(((w+1)/20*0.9)>0.1):

self.fig2.subplots_adjust(left=0.4*(1-(w+1)/20*0.9),right=0.6*(1+(w+1)/20*0.9),top=0.95,bottom=0.05)

elif(((w+1)/20*0.9)>0.1):

self.fig2.subplots_adjust(left=0,right=1,top=0.95,bottom=0.05)

else:

self.fig2.subplots_adjust(left=0.4,right=0.6,top=0.95,bottom=0.05)

"""

self.fig2.subplots_adjust(left=0.1,right=0.9,top=0.95,bottom=0.05)

for D in dic.keys():

for j in range(0,dic[D]):

d.append(D)

x.append(random.uniform(D/2,2*dmax-D/2))

y.append(random.uniform(D/2,2*dmax-D/2))

if self.cb.currentText()=='circle':

self.drawcircle(x, y, d, w, dmax, N, 'circle')

elif self.cb.currentText()=='ellipse':

self.drawellipse(x, y, d, w, dmax, N)

elif self.cb.currentText()=='triangle':

self.drawcircle(x, y, d, w, dmax, N, 'triangle')

elif self.cb.currentText()=='rectangle':

self.drawcircle(x, y, d, w, dmax, N, 'rectangle')

elif self.cb.currentText()=='pentagon':

self.drawcircle(x, y, d, w, dmax, N, 'pentagon')

xticks=[]

yticks=[]

for i in range(0,w+1):

xticks.append(2*dmax*i)

for i in range(0,l+1):

yticks.append(2*dmax*i)

xmajors=np.linspace(0,2*dmax*w,w+1)

self.ax2.xaxis.set_major_locator(ticker.FixedLocator(xmajors))

self.ax2.yaxis.set_major_locator(ticker.MaxNLocator(21))

yminors=np.linspace(0,2*dmax*l,l+1)

self.ax2.yaxis.set_minor_locator(ticker.FixedLocator(yminors))

for ymin in self.ax2.yaxis.get_minorticklocs():

self.ax2.axhline(y=ymin, ls='--',lw=0.1,color='0.2')

self.ax2.xaxis.grid(b=True)

self.ax2.axis('equal')

#self.ax2.set_aspect(1)

self.ax2.set_xbound(lower=-dmax,upper=2*dmax*(w+0.5))

self.ax2.set_ybound(lower=-dmax, upper=2*dmax*22.5)

self.canvas2.draw()

self.ifplot=1

def drawcircle(self,x,y,d,w,dmax,N,sh):

se=[]

self.x1.clear()

self.y1.clear()

self.dd.clear()

self.cac.clear()

self.coord.clear()

se=random.sample(range(0,N),N)

i=j=k=0

for n in se:

self.x1.append(x[n]+i*2*dmax)

self.y1.append(y[n]+j*2*dmax)

self.dd.append(d[n])

circle=mpatches.Circle((self.x1[k],self.y1[k]),d[n]/2)

if(sh=='triangle'):

circle.set_facecolor('none')

circle.set_edgecolor('b')

self.drawtriangle(self.x1[k], self.y1[k], d[n])

elif(sh=='rectangle'):

circle.set_facecolor('none')

circle.set_edgecolor('b')

self.drawrectangle(self.x1[k], self.y1[k], d[n])

elif(sh=='pentagon'):

circle.set_facecolor('none')

circle.set_edgecolor('b')

self.drawpentagon(self.x1[k], self.y1[k], d[n])

self.ax2.add_patch(circle)

i+=1

k+=1

if i==w:

i=0

j+=1 # 0 to 15 point radii

def drawellipse(self,x,y,d,w,dmax,N):

se=[]

se=random.sample(range(0,N),N)

self.x1.clear()

self.y1.clear()

self.dd.clear()

self.an.clear() #重置输出项

i=j=k=0

ra=float(self.LEc.text())

for n in se:

self.x1.append(x[n]+i*2*dmax) #添加顺序

self.y1.append(y[n]+j*2*dmax)

self.an.append(random.uniform(0,180))

self.dd.append(d[n])

elli=mpatches.Ellipse((self.x1[k],self.y1[k]),d[n],d[n]/ra,self.an[k])

self.ax2.add_patch(elli)

i+=1

k+=1

if i==w:

i=0

j+=1 # 0 to 15 point radii

def drawtriangle(self,x1,y1,d):

xy=[]

a=[0,120,240]

v=float(self.LEc.text())

va1=va2=0

va1=random.uniform(0,360)

for i in range(0,3):

va2=random.uniform(-1*v,v)

a[i]+=va1+va2

for j in range(i,0,-1):

if(a[j]==a[j-1]):

a[j]+=1

for i in range(0,3):

for j in range(i+1,3):

if(a[i]>a[j]):

temp=a[j]

a[j]=a[i]

a[i]=temp

for i in range(0,3):

a[i]=np.deg2rad(a[i])

xy.append(x1+d/2*np.cos(a[i]))

xy.append(y1+d/2*np.sin(a[i]))

Path = mpath.Path

path_data = [

(Path.MOVETO, (xy[0],xy[1])),

(Path.LINETO, (xy[2],xy[3])),

(Path.LINETO, (xy[4],xy[5])),

(Path.CLOSEPOLY, (xy[0],xy[1])),

]

codes, verts = zip(*path_data)

path = mpath.Path(verts, codes)

patch = mpatches.PathPatch(path, facecolor='r', alpha=0.5)

self.ax2.add_patch(patch)

self.coord.append(np.mat([[xy[0]/1000,xy[1]/1000],[xy[2]/1000,xy[3]/1000],[xy[4]/1000,xy[5]/1000]]))

cac1=[]

for i in range(0,2):

cac1.append(a[i+1]-a[i])

cac1.append((a[0]+2*pi)-a[2])

self.cac.append([cac1[0],cac1[1],cac1[2]])

def drawrectangle(self,x1,y1,d):

a=[0,90,180,270]

v=float(self.LEc.text())

va1=va2=0

va1=random.uniform(0,360)

for i in range(0,4):

va2=random.uniform(-1*v,v)

a[i]+=va1+va2

for i in range(0,4): #各点逆时针排序

for j in range(i+1,4):

if(a[i]>a[j]):

temp=a[j]

a[j]=a[i]

a[i]=temp

xy=[]

for i in range(0,4):

a[i]=np.deg2rad(a[i])

xy.append(x1+d/2*np.cos(a[i]))

xy.append(y1+d/2*np.sin(a[i]))

Path = mpath.Path

path_data = [

(Path.MOVETO, (xy[0],xy[1])),

(Path.LINETO, (xy[2],xy[3])),

(Path.LINETO, (xy[4],xy[5])),

(Path.LINETO, (xy[6],xy[7])),

(Path.CLOSEPOLY, (xy[0],xy[1])),

]

codes, verts = zip(*path_data)

path = mpath.Path(verts, codes)

patch = mpatches.PathPatch(path, facecolor='b', alpha=0.5)

self.ax2.add_patch(patch)

self.coord.append(np.mat([[xy[0]/1000,xy[1]/1000],[xy[2]/1000,xy[3]/1000],[xy[4]/1000,xy[5]/1000],

[xy[6]/1000,xy[7]/1000]])) #添加坐标点及圆心角数据

cac1=[]

for i in range(0,3):

cac1.append(a[i+1]-a[i])

cac1.append((a[0]+2*pi)-a[3])

self.cac.append([cac1[0],cac1[1],cac1[2],cac1[3]])

def drawpentagon(self,x1,y1,d):

a=[0,72,144,216,288]

v=float(self.LEc.text())

va1=va2=0

va1=random.uniform(0,360) #三点重合可能性

for i in range(0,5):

va2=random.uniform(-1*v,v)

a[i]+=va1+va2

for i in range(0,5):

for j in range(i+1,5):

if(a[i]>a[j]):

temp=a[j]

a[j]=a[i]

a[i]=temp

xy=[]

for i in range(0,5):

a[i]=np.deg2rad(a[i])

xy.append(x1+d/2*np.cos(a[i]))

xy.append(y1+d/2*np.sin(a[i]))

Path = mpath.Path

path_data = [

(Path.MOVETO, (xy[0],xy[1])),

(Path.LINETO, (xy[2],xy[3])),

(Path.LINETO, (xy[4],xy[5])),

(Path.LINETO, (xy[6],xy[7])),

(Path.LINETO, (xy[8],xy[9])),

(Path.CLOSEPOLY, (xy[0],xy[1])),

]

codes, verts = zip(*path_data)

path = mpath.Path(verts, codes)

patch = mpatches.PathPatch(path, facecolor='b', alpha=0.5)

self.ax2.add_patch(patch)

self.coord.append(np.mat([[xy[0]/1000,xy[1]/1000],[xy[2]/1000,xy[3]/1000],[xy[4]/1000,xy[5]/1000],[xy[6]/1000,xy[7]/1000],

[xy[8]/1000,xy[9]/1000]]))

cac1=[]

for i in range(0,4):

cac1.append(a[i+1]-a[i])

cac1.append((a[0]+2*pi)-a[4])

self.cac.append([cac1[0],cac1[1],cac1[2],cac1[3],cac1[4]])

def calelli(self,x,y,a,b,an):

self.cac=[]

an2=np.deg2rad(an)

trans=np.mat([[np.cos(an2),-np.sin(an2)],[np.sin(an2),np.cos(an2)]])

#备选计算公式

#c=sqrt(a**2+b**2)

#d=a-b

#cac1=np.arcsin(((a**2-b**2)+(c-b)*d+b*c)/(2*a*(b+(a**2-b**2)*c+(a**2+b**2)*d)/b/c))

#cac2=np.arcsin((c-d)/2/(a-((a**2-b**2)*c+(a**2+b**2)*d)/a/c))

h=(a-b)*(a+b+sqrt(a**2+6*a*b+b**2))/(a-b+sqrt(a**2+6*a*b+b**2))

k=(a-b)*(a+3*b+sqrt(a**2+6*a*b+b**2))/(4*b)

xj=h*((a-h)/sqrt(k**2+h**2)+1)

yj=k*(a-h)/sqrt(k**2+h**2)

xy1=np.mat([xj,yj])

xy1=xy1*trans

xy1=np.mat([xy1[0,0]+x,xy1[0,1]+y])

xy2=np.mat([-xj,yj])

xy2=xy2*trans

xy2=np.mat([xy2[0,0]+x,xy2[0,1]+y])

xy3=np.mat([-xj,-yj])

xy3=xy3*trans

xy3=np.mat([xy3[0,0]+x,xy3[0,1]+y])

xy4=np.mat([xj,-yj])

xy4=xy4*trans

xy4=np.mat([xy4[0,0]+x,xy4[0,1]+y])

cac1=2*np.arctan(yj/(xj-h))

cac2=pi-cac1

self.cac=[cac2,cac1,cac2,cac1]

return(xy1/1000,xy2/1000,xy3/1000,xy4/1000)

def cal(self):

N=int(self.LEn.text())

a=[]

d=[]

p=[]

for element in self.infodic:

d.append(element)

p.append(self.infodic[element])

for i in range(0,p.__len__()):

p[i]=float(p[i])

#确定计算粒径范围

ma=0

mi=p.__len__()-1

for i in range(0,p.__len__()):

if p[i]==100:

continue

else:

dmax=d[i-1]

ma=i-1

break

for i in range(1,p.__len__()):

if dmax/d[i]<=10:

continue

else:

dmin=d[i-1]

mi=i-1

break

for i in range(mi+1,p.__len__()):

p[i]=0

for i in range(0,p.__len__()-1):

temp=[]

for j in range(0,p.__len__()):

if(j==i):

temp.append(1-0.01*(p[i]-p[i+1]))

else:

temp.append(-0.01*(p[i]-p[i+1])*(d[j]**2)/(d[i]**2))

a.append(temp)

temp=[]

for i in range(0,p.__len__()):

temp.append(1)

a.append(temp)

a=np.array(a)

b=[]

for i in range(0,p.__len__()-1):

b.append(0)

b.append(1)

b=np.array(b)

x=np.linalg.solve(a,b)

c=[]

for i in range(0,p.__len__()):

t=int(round(x[i]*N))

c.append(t)

for i in range(0,p.__len__())[::-1]: #确定计算中最小粒径

if c[i]!=0:

break

s=0

for j in range(0,p.__len__()):

s+=c[j]

c[i]+=N-s

dic={}

for i in range(ma,mi+1):

dic[d[i]]=c[i]

vd=0

for element in dic:

vd+=dic[element]*pi*(element**2)/4

v=(1+float(self.LEe.text()))*vd

ra=float(self.LEr.text())

wid=sqrt(v/ra)

w=round(wid/(2*dmax))