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Всем добрый день помогите запустить этот код(2d моделирование), препод дал задание сделать gui, но после запуска программы выходит такая формавведите сюда описание изображения

но чтоб началась само моделирование надо закрыть форму и вот тут начинается вся беда, начинается открываться несколько форм и выходит такая ошибка:

RuntimeWarning: More than 20 figures have been opened. Figures created through the pyplot interface (matplotlib.pyplot.figure) are retained until explicitly closed and may consume too much memory. (To control this warning, see the rcParam figure.max_open_warning). fig = plt.figure()

line 309, in plt.show(1)

line 353, in show return _backend_mod.show(*args, **kwargs) TypeError: show() takes 1 positional argument but 2 were given

Пожалуйста помогите решить эту проблему, так как в питоне я вообще новичок и не понимаю, как решить эту проблему. У самого питон 3.9 и пишу код в pycharm'е. У препода все работает, но у него питон 2.7 стоит. Возможно ли вообще запустить такой код на 3.9?

#import idlelib.PyShell
#import sys
import time
import pylab
import numpy as np
#import sys, idlelib.PyShell; idlelib.PyShell.warning_stream = sys.stderr
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d import Axes3D

#idlelib.PyShell.warning_stream = sys.stderr

N1 = 40
tt =3.0
l = 2.00
h = l/N1
N2 = 50
t=tt/N2
t2=t/2.0
hh=h*h
#rr=hh/t2
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

def e1(u,v):
    return a11+a12*u*v
def e2(u,v):
    return a21+a22*u*v

def f1(u,v):
    return u*(m1-d1)+v*d1-c1*u*u-h1*u-b1
def f2(u,v):
    return v*(m2-d2)+u*d2-c2*v*v

def Rs(x,y):
    return 4
    #return 2.*np.sin(np.pi*y/3.)+0.3*np.sin(3*np.pi*y/3.)*np.sin(2.*np.pi*y/3.)+np.sin(np.pi*x/2.)
    #return 2.*np.sin((np.pi*y/3.)+0.2)+0.8*np.sin((3.*np.pi*y/3.)+1.0)*np.sin((1.*np.pi*y/3.)+2.0)+np.sin(np.pi*x/2.)
    #return 2.*np.sin((np.pi*y/3.)+0.5)+0.8*np.sin((3.*np.pi*y/3.))*np.sin((1.*np.pi*y/3.)+2.)+np.sin(np.pi*x/2.)
    #return np.exp((y/2)*np.sin(3.*np.pi*y/2.)) * np.sin((1.*np.pi*x/3.)+0.1)

def y_0(x,y):
    return 1.5 * np.exp(-30.0*(((x/1.8)-0.55)**2 + (y-0.35)**2))
def v_0(x,y):
    return 1.5 * np.exp(-15.0*(((x/2.0)-0.5)**2 + (y-1.35)**2))

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')

#Computation of y,v
tst = time.clock()

for i1 in range(0,N1+1):
    x1[i1]=i1*h
for i2 in range(0,N1+1):
    x2[i2]=i2*h

#for i2 in range(0,N1+1):
    #for i1 in range(0,N1+1):
        #if i2*h<0.62: y[i1,i2] = 0.0
        #elif i2*h<1.27: y[i1,i2]=-21.30*(i2*h)*(i2*h)+40.26*(i2*h)-16.77
        #else: y[i1,i2]=0.0
        #if i2*h<1.32: v[i1,i2] = 0.0
        #elif i2*h<1.96: v[i1,i2]=-21.30*(i2*h)*(i2*h)+69.65*(i2*h)-54.69
        #else: v[i1,i2]=0.0

for i1 in range(0, N1+1):
    for i2 in range(0, N1+1):
        y0[i1, i2] = y_0(x1[i1], x2[i2])
        v0[i1, i2] = v_0(x1[i1], x2[i2])
        R[i1, i2] = Rs(x1[i1], x2[i2])
        y[i1, i2] = y0[i1, i2]
        v[i1, i2] = v0[i1, i2]

fig = plt.figure()
#ax = Axes3D(fig)
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
X1,X2 = np.meshgrid(x1, x2)
plt.xlabel('X')
plt.ylabel('Y')
#ax.plot_surface(X1, X2, y0, rstride=1, cstride=1, cmap='Blues')
#ax.plot_surface(X1, X2, v0, rstride=1, cstride=1, cmap='BuGn')
#ax.plot_wireframe(X1, X2, R, rstride=1, cstride=1)
#ax.plot_surface(X1, X2, R, rstride=1, cstride=1, cmap='summer')

          #Liniya urovnya ('ax' turn off before activation)

g = np.linspace(0., 2., 21)
#plt.clabel(plt.contour(x1,x2,y0,g,colors='gray'), inline=True, fontsize=8)
#plt.contourf(x1,x2,y0,g,cmap=plt.cm.Blues)
plt.clabel(plt.contour(x1,x2,v0,g,colors='gray'), inline=True, fontsize=8)
plt.contourf(x1,x2,v0,g,cmap=plt.cm.BuGn)
plt.colorbar()

plt.show()
pylab.ion()

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 = 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])+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 = e1((y[i1,i2]+y[i1-1,i2])/2.00,(v[i1,i2]+v[i1-1,i2])/2.00)
            e12 = 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] + 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 = 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 + \
              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 = 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])+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=e2((y[i1,i2]+y[i1-1,i2])/2.00,(v[i1,i2]+v[i1-1,i2])/2.00)
            e22=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] + 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 = 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 + \
              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 = e1((y[i1,i2]+y[i1,i2-1])/2.00,(v[i1,i2]+v[i1,i2-1])/2.00)
            e22 = 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] + 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=e2((y[i1,i2]+y[i1,i2-1])/2.00,(v[i1,i2]+v[i1,i2-1])/2.00)
            e22=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] + 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(fig)
    X1, X2 = np.meshgrid(x1, x2)
    plt.xlabel('X')
    plt.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)
    #plt.contourf(XX1, XX2, y, cmap=plt.cm.gray)
    #plt.colorbar()
    #plt.show()
    pylab.draw()

fig = plt.figure()
#ax = Axes3D(fig)
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
X1,X2 = np.meshgrid(x1, x2)
plt.xlabel('X')
plt.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')

          #Liniya urovnya ('ax' turn off before activation)

g = np.linspace(0., 2.0, 21)
plt.clabel(plt.contour(x1,x2,y,g,colors='gray'), inline=True, fontsize=8)
plt.contourf(x1,x2,y,g,cmap=plt.cm.Blues)
#plt.clabel(plt.contour(x1,x2,v,g,colors='gray'), inline=True, fontsize=8)
#plt.contourf(x1,x2,v,g,cmap=plt.cm.BuGn)
plt.colorbar()

plt.show()
plt.show(1)
f1 = open('rezy.txt','w')
for i in range(0,N1+1):
    for j in range(0,N1+1):
        f1.write("%f\n" % y[i,j])
f1.close()
f2 = open('rezv.txt','w')
for i in range(0,N1+1):
    for j in range(0,N1+1):
        f2.write("%f\n" % v[i,j])
    f2.write("\n") 
f2.close()

dt = time.clock() - tst
print "N2 = %i, N1 = %i, time solution = %1.3e, h = %1.3e" % (N2, N1, dt, h)





2
  • Это не ошибка, это предупреждение. Вообще сколько графиков должно выйти? Я в Google Colab в итоге вижу 3 картинки - ту и ещё две потом. Просто надо подождать потом ещё.
    – CrazyElf
    10 июн в 10:34
  • 2
    @CrazyElf Может в Colab'е старый питон? Я у себя на 3.7 действительно вижу мельтишение окон. И потом, я думаю, там фишка в показе анимации, а не конечной картинке. А иначе зачем там рисование во внешнем цикле.
    – GrAnd
    10 июн в 11:10
3

Вот, поковырял чутка. Какую-то анимацию роста горбиков показывает. Python 3.7.4 под Windows 7. И Python 3.9.0 под Windows 10.

#import idlelib.PyShell
#import sys
import time
#import pylab
import numpy as np
#import sys, idlelib.PyShell; idlelib.PyShell.warning_stream = sys.stderr
import matplotlib.pyplot as plt
from mpl_toolkits.mplot3d import Axes3D

#idlelib.PyShell.warning_stream = sys.stderr

N1 = 40
tt =3.0
l = 2.00
h = l/N1
N2 = 50
t=tt/N2
t2=t/2.0
hh=h*h
#rr=hh/t2
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

def e1(u,v):
    return a11+a12*u*v
def e2(u,v):
    return a21+a22*u*v

def f1(u,v):
    return u*(m1-d1)+v*d1-c1*u*u-h1*u-b1
def f2(u,v):
    return v*(m2-d2)+u*d2-c2*v*v

def Rs(x,y):
    return 4
    #return 2.*np.sin(np.pi*y/3.)+0.3*np.sin(3*np.pi*y/3.)*np.sin(2.*np.pi*y/3.)+np.sin(np.pi*x/2.)
    #return 2.*np.sin((np.pi*y/3.)+0.2)+0.8*np.sin((3.*np.pi*y/3.)+1.0)*np.sin((1.*np.pi*y/3.)+2.0)+np.sin(np.pi*x/2.)
    #return 2.*np.sin((np.pi*y/3.)+0.5)+0.8*np.sin((3.*np.pi*y/3.))*np.sin((1.*np.pi*y/3.)+2.)+np.sin(np.pi*x/2.)
    #return np.exp((y/2)*np.sin(3.*np.pi*y/2.)) * np.sin((1.*np.pi*x/3.)+0.1)

def y_0(x,y):
    return 1.5 * np.exp(-30.0*(((x/1.8)-0.55)**2 + (y-0.35)**2))
def v_0(x,y):
    return 1.5 * np.exp(-15.0*(((x/2.0)-0.5)**2 + (y-1.35)**2))

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')

#Computation of y,v
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 i2 in range(0,N1+1):
    #for i1 in range(0,N1+1):
        #if i2*h<0.62: y[i1,i2] = 0.0
        #elif i2*h<1.27: y[i1,i2]=-21.30*(i2*h)*(i2*h)+40.26*(i2*h)-16.77
        #else: y[i1,i2]=0.0
        #if i2*h<1.32: v[i1,i2] = 0.0
        #elif i2*h<1.96: v[i1,i2]=-21.30*(i2*h)*(i2*h)+69.65*(i2*h)-54.69
        #else: v[i1,i2]=0.0

for i1 in range(0, N1+1):
    for i2 in range(0, N1+1):
        y0[i1, i2] = y_0(x1[i1], x2[i2])
        v0[i1, i2] = v_0(x1[i1], x2[i2])
        R[i1, i2] = Rs(x1[i1], x2[i2])
        y[i1, i2] = y0[i1, i2]
        v[i1, i2] = v0[i1, i2]

fig = plt.figure()
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
X1,X2 = np.meshgrid(x1, x2)
plt.xlabel('X')
plt.ylabel('Y')
#ax.plot_surface(X1, X2, y0, rstride=1, cstride=1, cmap='Blues')
#ax.plot_surface(X1, X2, v0, rstride=1, cstride=1, cmap='BuGn')
#ax.plot_wireframe(X1, X2, R, rstride=1, cstride=1)
#ax.plot_surface(X1, X2, R, rstride=1, cstride=1, cmap='summer')

          #Liniya urovnya ('ax' turn off before activation)

g = np.linspace(0., 2., 21)
plt.clabel(plt.contour(x1,x2,y0,g,colors='gray'), inline=True, fontsize=8)
plt.contourf(x1,x2,y0,g,cmap=plt.cm.Blues)
plt.clabel(plt.contour(x1,x2,v0,g,colors='gray'), inline=True, fontsize=8)
plt.contourf(x1,x2,v0,g,cmap=plt.cm.BuGn)
plt.colorbar()
plt.show()
plt.ion()
fig = plt.figure()


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 = 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])+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 = e1((y[i1,i2]+y[i1-1,i2])/2.00,(v[i1,i2]+v[i1-1,i2])/2.00)
            e12 = 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] + 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 = 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 + \
              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 = 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])+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=e2((y[i1,i2]+y[i1-1,i2])/2.00,(v[i1,i2]+v[i1-1,i2])/2.00)
            e22=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] + 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 = 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 + \
              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 = e1((y[i1,i2]+y[i1,i2-1])/2.00,(v[i1,i2]+v[i1,i2-1])/2.00)
            e22 = 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] + 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=e2((y[i1,i2]+y[i1,i2-1])/2.00,(v[i1,i2]+v[i1,i2-1])/2.00)
            e22=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] + 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
    plt.clf()
    x1 = np.linspace(0., l, N1+1)
    x2 = np.linspace(0., l, N1+1)
    #fig = plt.figure()
    ax = Axes3D(fig, auto_add_to_figure=False)
    fig.add_axes(ax)
    X1, X2 = np.meshgrid(x1, x2)
    plt.xlabel('X')
    plt.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)
    #plt.contourf(XX1, XX2, y, cmap=plt.cm.gray)
    #plt.colorbar()
    #plt.show()
    #plt.draw()
    plt.pause(0.01)

plt.ioff()
fig = plt.figure()
#ax = Axes3D(fig)
x1 = np.linspace(0., l, N1+1)
x2 = np.linspace(0., l, N1+1)
X1,X2 = np.meshgrid(x1, x2)
plt.xlabel('X')
plt.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')

          #Liniya urovnya ('ax' turn off before activation)

g = np.linspace(0., 2.0, 21)
plt.clabel(plt.contour(x1,x2,y,g,colors='gray'), inline=True, fontsize=8)
plt.contourf(x1,x2,y,g,cmap=plt.cm.Blues)
#plt.clabel(plt.contour(x1,x2,v,g,colors='gray'), inline=True, fontsize=8)
#plt.contourf(x1,x2,v,g,cmap=plt.cm.BuGn)
plt.colorbar()

plt.show()
#plt.show()
f1 = open('rezy.txt','w')
for i in range(0,N1+1):
    for j in range(0,N1+1):
        f1.write("%f\n" % y[i,j])
f1.close()
f2 = open('rezv.txt','w')
for i in range(0,N1+1):
    for j in range(0,N1+1):
        f2.write("%f\n" % v[i,j])
    f2.write("\n") 
f2.close()

dt = time.perf_counter() - tst
print(f"N2 = {N2}, N1 = {N1}, time solution = {dt:1.3e}, h = {h:1.3e}")

-

4
  • Спасибо только, вот у меня теперь на это ругается ax = Axes3D(fig, auto_add_to_figure=False) line 996, in update raise AttributeError(f"{type(self).__name__!r} object " AttributeError: 'Axes3D' object has no property 'auto_add_to_figure'
    – Gltockus
    10 июн в 12:11
  • @Gltockus Можете попробовать без него. У меня без него работает, но пишет test.py:276: MatplotlibDeprecationWarning: Axes3D(fig) adding itself to the figure is deprecated since 3.4. Pass the keyword argument auto_add_to_figure=False and use fig.add_axes(ax) to suppress this warning. The default value of auto_add_to_figure will change to False in mpl3.5 and True values will no longer work in 3.6. This is consistent with other Axes classes. ax = Axes3D(fig). Либо, наверное, надо обновить модуль.
    – GrAnd
    10 июн в 12:52
  • а можно узнать что именно вы изменили?
    – Gltockus
    10 июн в 17:15
  • @Gltockus Выкинул pylab и везде заменил его на plt, clock() заменил на perf_counter(), вынес создание figure() из тела цикла, добавил pause() для отрисовки. Собственно, из значимого это всё. Или вот наглядное сравнение изменений.
    – GrAnd
    10 июн в 20:33

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