Всем добрый день, добавляю gui для одной программы, программа сама без интерфейса нормально рисует, причем быстро, и можно крутить моделью после работы программы
а вот после добавления gui'а сама прорисовка стала очень медленной и просто невозможной для прокрутки модели
,
я скорее всего предполагаю из за всех глобалов которые я добавил в моем коде, но с моими знаниями(я новичок в python) это мой максимальный результат, пожалуйста помогите возможно ли, как то ускорить анимацию?
import sys
from PyQt5.QtWidgets import QApplication, QMainWindow, QMenu, QVBoxLayout, QSizePolicy, QLabel, QPushButton, QLineEdit, QMessageBox
from PyQt5.QtGui import QIcon, QValidator, QDoubleValidator
from matplotlib.backends.backend_qt5agg import FigureCanvasQTAgg as FigureCanvas
from matplotlib.figure import Figure
import matplotlib.pyplot as plt
import numpy as np
import threading
import matplotlib.cm
from mpl_toolkits.mplot3d import Axes3D
from scipy.interpolate import griddata
import pylab
import time
#ky1 = 0.8
#ky2 = -80.0
#ky3 = 1.99
#ky4 = 0.3
#ky5 = 2.0
#kv1 = 1.9
#kv2 = -80.0
#kv3 = 1.8
#kv4 = 0.5
#kv5 = 2.0
N1 = 40
tt = 3.0
l = 2.
h = l/N1
N2 = 50
t=tt/N2
t2=t/2.0
hh=h*h
rr=hh/t
a11=0.03
a12=0.01
p1=-0.05
a21=0.03
a22=0.01
p2=-0.03
q1=0.0
q2=0.0
m1=0.95
m2=1.2
d1=0.7
d2=0.5
c1=0.25
c2=0.65
h1=0.55
b1=0.1
#x =np.zeros((N1+1), 'float')
#y =np.zeros((N1+1), 'float')
#v =np.zeros((N1+1), 'float')
#a =np.zeros((N1), 'float')
#b =np.zeros((N1), 'float')
#z =np.zeros((N1+1), 'float')
x1 = np.zeros((N1+1), 'float')
x2 = np.zeros((N1+1), 'float')
y = np.zeros((N1+1, N1+1), 'float')
y0 = np.zeros((N1+1, N1+1), 'float')
v = np.zeros((N1+1, N1+1), 'float')
v0 = np.zeros((N1+1, N1+1), 'float')
a = np.zeros((N1+1), 'float')
b = np.zeros((N1+1), 'float')
z = np.zeros((N1+1), 'float')
R = np.zeros((N1+1, N1+1), 'float')
class App(QMainWindow):
def __init__(self):
super().__init__()
self.left = 10
self.top = 10
self.title = ''
self.width = 1280
self.height = 720
self.initUI()
def initVars(self):
#global ky1
#global ky2
#global ky3
#global ky4
#global ky5
#global kv1
#global kv2
#global kv3
#global kv4
#global kv5
global N1
global tt
global l
global h
global N2
global t
global t2
global hh
global rr
global a11
global a12
global p1
global a21
global a22
global p2
global q1
global q2
global m1
global m2
global d1
global d2
global c1
global c2
global h1
global b1
global x1
global x2
global y
global y0
global v
global v0
global a
global b
global z
global R
#ky1 = float(self.le_ky1.text())
#ky2 = float(self.le_ky2.text())
#ky3 = float(self.le_ky3.text())
#ky4 = float(self.le_ky4.text())
#ky5 = float(self.le_ky5.text())
#kv1 = float(self.le_kv1.text())
#kv2 = float(self.le_kv2.text())
#kv3 = float(self.le_kv3.text())
#kv4 = float(self.le_kv4.text())
#kv5 = float(self.le_kv5.text())
N1 = int(self.le_N1 .text())
tt = float(self.le_tt .text())
l = float(self.le_l .text())
N2 = int(self.le_N2 .text())
a11 = float(self.le_a11.text())
a12 = float(self.le_a12.text())
p1 = float(self.le_p1 .text())
a21 = float(self.le_a21.text())
a22 = float(self.le_a22.text())
p2 = float(self.le_p2 .text())
q1 = float(self.le_q1 .text())
q2 = float(self.le_q2 .text())
m1 = float(self.le_m1 .text())
m2 = float(self.le_m2 .text())
d1 = float(self.le_d1 .text())
d2 = float(self.le_d2 .text())
c1 = float(self.le_c1 .text())
c2 = float(self.le_c2 .text())
h1 = float(self.le_h1 .text())
b1 = float(self.le_b1 .text())
#if kv4 > 2 or kv4 < 0:
# QMessageBox.about(self, "Ошибка", "Значение kv4 должно быть от 0 до 2")
#else:
h = l/N1
t=tt/N2
t2=t/2.0
hh=h*h
rr=hh/t
x1 = np.zeros((N1+1), 'float')
x2 = np.zeros((N1+1), 'float')
y = np.zeros((N1+1, N1+1), 'float')
y0 = np.zeros((N1+1, N1+1), 'float')
v = np.zeros((N1+1, N1+1), 'float')
v0 = np.zeros((N1+1, N1+1), 'float')
a = np.zeros((N1+1), 'float')
b = np.zeros((N1+1), 'float')
z = np.zeros((N1+1), 'float')
R = np.zeros((N1+1, N1+1), 'float')
self.m.plot()
def initUI(self):
self.setWindowTitle(self.title)
self.setGeometry(self.left, self.top, self.width, self.height)
self.m = PlotCanvas(self, width=8, height=6)
self.m.move(0,0)
y = 0
#label = QLabel('ky1:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('ky2:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('ky3:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('ky4:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('ky5:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('kv1:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('kv2:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('kv3:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('kv4:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
#label = QLabel('kv5:', self)
#label.move(850, y)
#label.resize(50, 20)
#y += 20
label = QLabel('N1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('tt:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('l:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('N2:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('a11:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('a12:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('p1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('a21:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('a22:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('p2:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('q1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('q2:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('m1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('m2:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('d1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('d2:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('c1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('c2:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('h1:', self)
label.move(850, y)
label.resize(50, 20)
y += 20
label = QLabel('b1:', self)
label.move(850, y)
label.resize(50, 20)
y = 0
#self.le_ky1 = QLineEdit('0.8', self)
#self.le_ky1.move(890, y)
#self.le_ky1.resize(50, 20)
#y += 20
#self.le_ky2 = QLineEdit('-80.0', self)
#self.le_ky2.move(890, y)
#self.le_ky2.resize(50, 20)
#y += 20
#self.le_ky3 = QLineEdit('1.99', self)
#self.le_ky3.move(890, y)
#self.le_ky3.resize(50, 20)
#y += 20
#self.le_ky4 = QLineEdit('0.3', self)
#self.le_ky4.move(890, y)
#self.le_ky4.resize(50, 20)
#y += 20
#self.le_ky5 = QLineEdit('2.0', self)
#self.le_ky5.move(890, y)
#self.le_ky5.resize(50, 20)
#y += 20
#self.le_kv1 = QLineEdit('1.9', self)
#self.le_kv1.move(890, y)
#self.le_kv1.resize(50, 20)
#y += 20
#self.le_kv2 = QLineEdit('-80.0', self)
#self.le_kv2.move(890, y)
#self.le_kv2.resize(50, 20)
#y += 20
#self.le_kv3 = QLineEdit('1.8', self)
#self.le_kv3.move(890, y)
#self.le_kv3.resize(50, 20)
#y += 20
#self.le_kv4 = QLineEdit('0.5', self)
#self.le_kv4.move(890, y)
#self.le_kv4.resize(50, 20)
#y += 20
#self.le_kv5 = QLineEdit('2.0', self)
#self.le_kv5.move(890, y)
#self.le_kv5.resize(50, 20)
#y += 20
self.le_N1 = QLineEdit('40', self)
self.le_N1.move(890, y)
self.le_N1.resize(50, 20)
y += 20
self.le_tt = QLineEdit('3.0', self)
self.le_tt.move(890, y)
self.le_tt.resize(50, 20)
y += 20
self.le_l = QLineEdit('2',self)
self.le_l.move(890, y)
self.le_l.resize(50, 20)
y += 20
self.le_N2 = QLineEdit('50',self)
self.le_N2.move(890, y)
self.le_N2.resize(50, 20)
y += 20
self.le_a11 = QLineEdit('0.03',self)
self.le_a11.move(890, y)
self.le_a11.resize(50, 20)
y += 20
self.le_a12 = QLineEdit('0.01',self)
self.le_a12.move(890, y)
self.le_a12.resize(50, 20)
y += 20
self.le_p1 = QLineEdit('0.05',self)
self.le_p1.move(890, y)
self.le_p1.resize(50, 20)
y += 20
self.le_a21 = QLineEdit('0.03',self)
self.le_a21.move(890, y)
self.le_a21.resize(50, 20)
y += 20
self.le_a22 = QLineEdit('0.01',self)
self.le_a22.move(890, y)
self.le_a22.resize(50, 20)
y += 20
self.le_p2 = QLineEdit('0.03',self)
self.le_p2.move(890, y)
self.le_p2.resize(50, 20)
y += 20
self.le_q1 = QLineEdit('0.00',self)
self.le_q1.move(890, y)
self.le_q1.resize(50, 20)
y += 20
self.le_q2 = QLineEdit('0.00',self)
self.le_q2.move(890, y)
self.le_q2.resize(50, 20)
y += 20
self.le_m1 = QLineEdit('0.95',self)
self.le_m1.move(890, y)
self.le_m1.resize(50, 20)
y += 20
self.le_m2 = QLineEdit('1.2',self)
self.le_m2.move(890, y)
self.le_m2.resize(50, 20)
y += 20
self.le_d1 = QLineEdit('0.7',self)
self.le_d1.move(890, y)
self.le_d1.resize(50, 20)
y += 20
self.le_d2 = QLineEdit('0.5',self)
self.le_d2.move(890, y)
self.le_d2.resize(50, 20)
y += 20
self.le_c1 = QLineEdit('0.25',self)
self.le_c1.move(890, y)
self.le_c1.resize(50, 20)
y += 20
self.le_c2 = QLineEdit('0.65',self)
self.le_c2.move(890, y)
self.le_c2.resize(50, 20)
y += 20
self.le_h1 = QLineEdit('0.55',self)
self.le_h1.move(890, y)
self.le_h1.resize(50, 20)
y += 20
self.le_b1 = QLineEdit('0.1',self)
self.le_b1.move(890, y)
self.le_b1.resize(50, 20)
y += 20
button = QPushButton('Start', self)
button.move(840,y)
button.resize(50,25)
button.clicked.connect(self.initVars)
self.show()
class PlotCanvas(FigureCanvas):
def e1(self,u,v):
return a11+a12*u*v
def e2(self,u,v):
return a21+a22*u*v
def f1(self,u,v):
return u*(m1-d1)+v*d1-c1*u*u-h1*u-b1
def f2(self,u,v):
return v*(m2-d2)+u*d2-c2*v*v
def Rs(self, x, y):
return 4
#2 zone
#return 0.5*np.sin(3*np.pi*x/2.)+0.5*np.sin(np.pi*x/3.)+np.sin(np.pi*x/2.)
#return 1.5*np.sin(np.pi*x/2.)+0.5*np.sin(1*np.pi*x/2.)*np.sin(2.*np.pi*x/1.)
#return 1.2 * np.sin(3 * np.pi * x / 2.) + 0.5 * np.sin(np.pi * x / 3.) * np.sin(np.pi * x / 2.)
#1 zone
#return 0.5*np.sin(3*np.pi*x/2.)-0.2*np.sin(2*np.pi*x/2.)-np.sin(3.*np.pi*x/3.)
#return 1.5*np.sin(np.pi*x/2.)-0.5*np.sin(1*np.pi*x/2.)*np.sin(2.*np.pi*x/2.)
def y_0(self, x,y):
return 1.5 * np.exp(-20.0*(((x/2.0)-0.5)**2 + (y-0.5)**2))
def v_0(self, x,y):
return 1.5 * np.exp(-20.0*(((x/2.0)-0.5)**2 + (y-1.5)**2))
def __init__(self, parent=None, width=5, height=4, dpi=100):
fig = Figure(figsize=(width, height), dpi=dpi)
self.axes = fig.add_subplot(111)
FigureCanvas.__init__(self, fig)
self.setParent(parent)
FigureCanvas.setSizePolicy(self,
QSizePolicy.Expanding,
QSizePolicy.Expanding)
FigureCanvas.updateGeometry(self)
def plot(self):
self.axes.cla()
plt = self.figure.add_subplot(111)
global N1
global tt
global l
global h
global N2
global t
global t2
global hh
global rr
global a11
global a12
global p1
global a21
global a22
global p2
global q1
global q2
global m1
global m2
global d1
global d2
global c1
global c2
global h1
global b1
global x1
global x2
global y
global y0
global v
global v0
global a
global b
global z
global R
tst = time.perf_counter()
for i1 in range(0,N1+1):
x1[i1]=i1*h
for i2 in range(0,N1+1):
x2[i2]=i2*h
for i1 in range(0, N1+1):
for i2 in range(0, N1+1):
y0[i1, i2] = self.y_0(x1[i1], x2[i2])
v0[i1, i2] = self.v_0(x1[i1], x2[i2])
R[i1, i2] = self.Rs(x1[i1], x2[i2])
y[i1, i2] = y0[i1, i2]
v[i1, i2] = v0[i1, i2]
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
X1,X2 = np.meshgrid(x1, x2)
plt.set_xlabel('X')
plt.set_ylabel('Y')
g = np.linspace(0., 2., 21)
cmap1 = matplotlib.cm.get_cmap('Blues')
cmap2 = matplotlib.cm.get_cmap('BuGn')
plt.clabel(plt.contour(x1,x2,y0,g,colors='gray'), inline=True, fontsize=8)
plt.contourf(x1,x2,y0,g,cmap=cmap1)
plt.clabel(plt.contour(x1,x2,v0,g,colors='gray'), inline=True, fontsize=8)
contourf_ = plt.contourf(x1,x2,v0,g,cmap=cmap2)
self.figure.colorbar(contourf_)
self.draw()
for j in range(1,N2+1):
# y[k+1/2] to x1
for i2 in range(0,N1+1):
#a[0]=0.
#b[0]=0.
e210 = self.e1((y[1,i2]+y[0,i2])/2.00,(v[1,i2]+v[0,i2])/2.00)
a[0] = e210/(e210+rr/2.0)
FD0 = (-p1/rr)*(y[1,i2]+y[0,i2])*(v[1,i2]-v[0,i2])- \
(q1/rr)*(y[1,i2]+y[0,i2])*(R[1,i2]-R[0,i2])+self.f1(y[0,i2],v[0,i2])*t2
b[0] = (y[0,i2]+FD0)/(1+2.0*e210/rr)
for i1 in range(1,N1):
e11 = self.e1((y[i1,i2]+y[i1-1,i2])/2.00,(v[i1,i2]+v[i1-1,i2])/2.00)
e12 = self.e1((y[i1,i2]+y[i1+1,i2])/2.00,(v[i1,i2]+v[i1+1,i2])/2.00)
aa = e11/rr
bb = e12/rr
cc = aa+bb+1
a[i1] = bb/(cc-aa*a[i1-1])
r11 = (1.0/rr)*(y[i1,i2]+y[i1-1,i2])/2.00
r12 = (1.0/rr)*(y[i1,i2]+y[i1+1,i2])/2.00
L1v = p1*(r12*(v[i1+1,i2]-v[i1,i2]) - r11*(v[i1,i2]-v[i1-1,i2]))
L1R = q1*(r12*(R[i1+1,i2]-R[i1,i2]) - r11*(R[i1,i2]-R[i1-1,i2]))
d = y[i1,i2] + self.f1(y[i1,i2],v[i1,i2])*t2 - L1v - L1R
b[i1]=(aa*b[i1-1]+d)/(cc-aa*a[i1-1])
#y[N1,i2]=b[N1-1]/(1-a[N1-1])
#y[N1,i2]=0.
e22n = self.e1((y[N1,i2]+y[N1-1,i2])/2.00,(v[N1,i2]+v[N1-1,i2])/2.00)
FDn = p1*(y[N1,i2]+y[N1-1,i2])*(v[N1,i2]-v[N1-1,i2])/2.0 + \
q1*(y[N1,i2]+y[N1-1,i2])*(R[N1,i2]-R[N1-1,i2])/2.0 + \
self.f1(y[N1,i2],v[N1,i2])*hh/4.0
y[N1,i2]=(e22n*b[N1-1] + rr*y[N1,i2]/2.0 + FDn)/(e22n*(1-a[N1-1])+rr/2.0)
for ii in range(1,N1+1):
i1=N1-ii
y[i1,i2] = a[i1]*y[i1+1,i2]+b[i1]
# v[k+1/2] to x1
e210 = self.e1((y[1,i2]+y[0,i2])/2.00,(v[1,i2]+v[0,i2])/2.00)
a[0] = e210/(e210+rr/2.0)
FD0 = (-p2/rr)*(v[1,i2]+v[0,i2])*(y[1,i2]-y[0,i2])- \
(q2/rr)*(v[1,i2]+v[0,i2])*(R[1,i2]-R[0,i2])+self.f2(y[0,i2],v[0,i2])*t2
b[0] = (v[0,i2]+FD0)/(1+2.0*e210/rr)
for i1 in range(1,N1):
e21=self.e2((y[i1,i2]+y[i1-1,i2])/2.00,(v[i1,i2]+v[i1-1,i2])/2.00)
e22=self.e2((y[i1,i2]+y[i1+1,i2])/2.00,(v[i1,i2]+v[i1+1,i2])/2.00)
aa = e21/rr
bb = e22/rr
cc = aa+bb+1
a[i1] = bb/(cc-aa*a[i1-1])
r11 = (1.0/rr)*(v[i1,i2]+v[i1-1,i2])/2.
r12 = (1.0/rr)*(v[i1,i2]+v[i1+1,i2])/2.
L1y = p2*(r12*(y[i1+1,i2]-y[i1,i2]) - r11*(y[i1,i2]-y[i1-1,i2]))
L1R = q2*(r12*(R[i1+1,i2]-R[i1,i2]) - r11*(R[i1,i2]-R[i1-1,i2]))
d = v[i1,i2] + self.f2(y[i1,i2],v[i1,i2])*t2 - L1y - L1R
b[i1]=(aa*b[i1-1]+d)/(cc-aa*a[i1-1])
#v[N1,i2]=b[N1-1]/(1-a[N1-1])
#v[N1,i2]=0.
e22n = self.e2((y[N1,i2]+y[N1-1,i2])/2.00,(v[N1,i2]+v[N1-1,i2])/2.00)
FDn = p2*(v[N1,i2]+v[N1-1,i2])*(y[N1,i2]-y[N1-1,i2])/2.0 + \
q2*(v[N1,i2]+v[N1-1,i2])*(R[N1,i2]-R[N1-1,i2])/2.0 + \
self.f2(y[N1,i2],v[N1,i2])*hh/4.0
v[N1,i2]=(e22n*b[N1-1] + rr*v[N1,i2]/2.0 + FDn)/(e22n*(1-a[N1-1])+rr/2.0)
for ii in range(1,N1+1):
i1=N1-ii
v[i1,i2] = a[i1]*v[i1+1,i2]+b[i1]
# y[k+1] to x2
for i1 in range(0,N1+1):
a[0]=0.
b[0]=0.
#e210 = e1((y[i1,1]+y[i1,0])/2.00,(v[i1,1]+v[i1,0])/2.00)
#FD0 = (-p1/rr)*(y[i1,1]+y[i1,0])*(v[i1,1]-v[i1,0])- \
# (q1/rr)*(y[i1,1]+y[i1,0])*(R[i1,1]-R[i1,0])+f1(y[i1,0],v[i1,0])*t2
#b[0] = (y[i1,0]+FD0)/(1+2.0*e210/rr)
for i2 in range(1,N1):
e21 = self.e1((y[i1,i2]+y[i1,i2-1])/2.00,(v[i1,i2]+v[i1,i2-1])/2.00)
e22 = self.e1((y[i1,i2]+y[i1,i2+1])/2.00,(v[i1,i2]+v[i1,i2+1])/2.00)
aa = e21/rr
bb = e22/rr
cc = aa+bb+1
a[i2] = bb/(cc-aa*a[i2-1])
r21 = (1.0/rr)*(y[i1,i2]+y[i1,i2-1])/2.
r22 = (1.0/rr)*(y[i1,i2]+y[i1,i2+1])/2.
L2v = p1*(r22*(v[i1,i2+1]-v[i1,i2]) - r21*(v[i1,i2]-v[i1,i2-1]))
L2R = q1*(r22*(R[i1,i2+1]-R[i1,i2]) - r21*(R[i1,i2]-R[i1,i2-1]))
d = y[i1,i2] + self.f1(y[i1,i2],v[i1,i2])*t2 - L2v - L2R
b[i2]=(aa*b[i2-1]+d)/(cc-aa*a[i2-1])
y[i1,N1]=0.
#e22n = e1((y[i1,N1]+y[i1,N1-1])/2.00,(v[i1,N1]+v[i1,N1-1])/2.00)
#FDn = p1*(y[i1,N1]+y[i1,N1-1])*(v[i1,N1]-v[i1,N1-1])/2.0 + \
# q1*(y[i1,N1]+y[i1,N1-1])*(R[i1,N1]-R[i1,N1-1])/2.0 + \
# f1(y[i1,N1],v[i1,N1])*hh/4.0
#y[i1,N1]=(e22n*b[N1-1] + rr*y[i1,N1]/2.0 + FDn)/(e22n*(1-a[N1-1])+rr/2.0)
for ii in range(1,N1+1):
i2=N1-ii
y[i1,i2] = a[i2]*y[i1,i2+1]+b[i2]
for i2 in range(0,N1+1):
if y[i1,i2]<0: y[i1,i2]=0.0
# v[k+1] to x2
#e210 = e2((y[i1,1]+y[i1,0])/2.00,(v[i1,1]+v[i1,0])/2.00)
#a[0] = e210/(e210+rr/2.0)
#FD0 = (-p2/rr)*(v[i1,1]+v[i1,0])*(y[i1,1]-y[i1,0])- \
# (q2/rr)*(v[i1,1]+v[i1,0])*(R[i1,1]-R[i1,0])+f2(y[i1,0],v[i1,0])*t2
#b[0] = (v[i1,0]+FD0)/(1+2.0*e210/rr)
for i2 in range(1,N1):
e21=self.e2((y[i1,i2]+y[i1,i2-1])/2.00,(v[i1,i2]+v[i1,i2-1])/2.00)
e22=self.e2((y[i1,i2]+y[i1,i2+1])/2.00,(v[i1,i2]+v[i1,i2+1])/2.00)
aa = e21/rr
bb = e22/rr
cc = aa+bb+1
a[i2] = bb/(cc-aa*a[i2-1])
r21 = (1.0/rr)*(v[i1,i2]+v[i1,i2-1])/2.
r22 = (1.0/rr)*(v[i1,i2]+v[i1,i2+1])/2.
L2y = p2*(r22*(y[i1,i2+1]-y[i1,i2])-r21*(y[i1,i2]-y[i1,i2-1]))
L2R = q2*(r22*(R[i1,i2+1]-R[i1,i2])-r21*(R[i1,i2]-R[i1,i2-1]))
d = v[i1,i2] + self.f2(y[i1,i2],v[i1,i2])*t2 - L2y - L2R
b[i2]=(aa*b[i2-1]+d)/(cc-aa*a[i2-1])
v[i1,N1]=0.
#e22n = e2((y[i1,N1]+y[i1,N1-1])/2.00,(v[i1,N1]+v[i1,N1-1])/2.00)
#FDn = p2*(v[i1,N1]+v[i1,N1-1])*(y[i1,N1]-y[i1,N1-1])/2.0 + \
# q2*(v[i1,N1]+v[i1,N1-1])*(R[i1,N1]-R[i1,N1-1])/2.0 + \
# f2(y[i1,N1],v[i1,N1])*hh/4.0
#v[i1,N1]=(e22n*b[N1-1] + rr*v[i1,N1]/2.0 + FDn)/(e22n*(1-a[N1-1])+rr/2.0)
for ii in range(1,N1+1):
i2=N1-ii
v[i1,i2] = a[i2]*v[i1,i2+1]+b[i2]
for i2 in range(0,N1+1):
if v[i1,i2]<0: v[i1,i2]=0.0
#graphics
pylab.clf()
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
#fig = plt.figure()
ax = Axes3D(plt.figure)
X1, X2 = np.meshgrid(x1, x2)
plt.set_xlabel('X')
plt.set_ylabel('Y')
ax.plot_surface(X1, X2, y, rstride=1, cstride=1, cmap='Blues')
ax.plot_surface(X1, X2, v, rstride=1, cstride=1, cmap='BuGn')
ax.plot_wireframe(X1, X2, y, rstride=1, cstride=1)
app.processEvents()
self.draw()
ax = Axes3D(plt.figure)
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
X1,X2 = np.meshgrid(x1, x2)
plt.set_xlabel('X')
plt.set_ylabel('Y')
ax.plot_surface(X1, X2, y, rstride=1, cstride=1, cmap='Blues')
ax.plot_surface(X1, X2, v, rstride=1, cstride=1, cmap='BuGn')
ax.plot_wireframe(X1, X2, y, rstride=1, cstride=1)
self.draw()
if __name__ == '__main__':
app = QApplication(sys.argv)
ex = App()
sys.exit(app.exec_())
