Как можно реализовать сохранение результата после отрисовки графика?
Вот получаю график, а как теперь сохранить график как изображение?
import sys
from PyQt5.Qt import *
from matplotlib.backends.backend_qt5agg import FigureCanvasQTAgg as FigureCanvas
from matplotlib.figure import Figure
import numpy as np
import pylab
import time
class PlotCanvas(FigureCanvas):
def __init__(self, rbtns, parent=None, width=5, height=4, dpi=100):
self.fig = Figure(figsize=(width, height), dpi=dpi)
self.axes = self.fig.add_subplot(111)
super().__init__(self.fig)
self.p = parent
self.rbtns = rbtns
def e1(self, u, v):
return self.p.a11 + self.p.a12 * u * v
def e2(self, u, v):
return self.p.a21 + self.p.a22 * u * v
def f1(self, u, v):
return u * (self.p.m1-self.p.d1) + v * self.p.d1 - self.p.c1 * u * u - self.p.h1 * u - self.p.b1
def f2(self, u, v):
return v * (self.p.m2-self.p.d2) + u * self.p.d2 - self.p.c2 * v * v
def Rs(self, x):
if self.rbtns[2].isChecked():
return 0.5*np.sin(3*np.pi*x/2.)+0.5*np.sin(1*np.pi*x/3.)+np.sin(1.*np.pi*x/2.)
elif self.rbtns[3].isChecked():
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.)
elif self.rbtns[4].isChecked():
return 1.2 * np.sin(3 * np.pi * x / 2.) + 0.5 * np.sin(np.pi * x / 3.) * np.sin(np.pi * x / 2.)
elif self.rbtns[0].isChecked():
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.)
elif self.rbtns[1].isChecked():
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 plot(self):
self.axes.cla()
plt = self.axes
tst = time.perf_counter()
self.p.a[0] = 0.
self.p.b[0] = 0.
for i in range(0, self.p.N1+1):
self.p.x[i] = i * self.p.h
self.p.y[i] = self.p.ky1 * np.exp(self.p.ky2 * \
(((i * self.p.h / self.p.ky3) -self.p.ky4) ** self.p.ky5))
self.p.v[i] = self.p.kv1 * np.exp(self.p.kv2 * \
(((i * self.p.h / self.p.kv3) - self.p.kv4) ** self.p.kv5))
self.p.x = np.linspace(0, self.p.l, self.p.N1+1)
R = self.Rs(self.p.x)
plt.axis([0., self.p.l, 0.0, 2.5])
plt.plot(self.p.x, self.p.y, 'b-', label='$u^0(x)$')
plt.plot(self.p.x, self.p.v, 'g--', label='$v^0(x)$')
plt.plot(self.p.x, R, 'k-.', label='$r(x)$')
plt.legend(loc=0)
plt.set_xlabel('$x$')
plt.set_ylabel('$u,v,r$')
plt.grid(True)
pylab.ion()
self.p.x = np.linspace(0, self.p.l, self.p.N1+1)
for j in range(1, self.p.N2+1):
for i in range(1, self.p.N1):
e11 = (self.e1(self.p.y[i], self.p.v[i]) + self.e1(self.p.y[i+1], self.p.v[i+1])) / 2.
e12 = (self.e1(self.p.y[i], self.p.v[i]) + self.e1(self.p.y[i-1], self.p.v[i-1])) / 2.
aa = e12 / self.p.rr
bb = e11 / self.p.rr
cc = aa + bb + 1
r12 = self.p.p1 / self.p.rr
self.p.a[i] = bb / (cc-aa*self.p.a[i-1])
d = self.p.t*self.f1(self.p.y[i], self.p.v[i])-r12*0.5 * \
((self.p.y[i]+self.p.y[i+1])*(self.p.v[i+1]-self.p.v[i]) - \
(self.p.y[i]+self.p.y[i-1])*(self.p.v[i]-self.p.v[i-1]))+self.p.y[i]- \
(self.p.q1/self.p.rr)*0.5*((self.p.y[i]+self.p.y[i+1]) * \
(R[i+1]-R[i]) - (self.p.y[i]+self.p.y[i-1])*(R[i]-R[i-1]))
self.p.b[i] = (aa*self.p.b[i-1]+d)/(cc-aa*self.p.a[i-1])
for ii in range(1, self.p.N1+1):
i = self.p.N1-ii
self.p.y[i] = self.p.a[i]*self.p.y[i+1]+self.p.b[i]
for i in range(0,self.p.N1+1):
if self.p.y[i]<0: self.p.y[i]=0
for i in range(1,self.p.N1):
e21 = (self.e2(self.p.y[i],self.p.v[i])+self.e2(self.p.y[i+1],self.p.v[i+1]))/2.
e22 = (self.e2(self.p.y[i],self.p.v[i])+self.e2(self.p.y[i-1],self.p.v[i-1]))/2.
aa = e22 / self.p.rr
bb = e21 / self.p.rr
cc = aa + bb + 1
r12 = self.p.p2 / self.p.rr
self.p.a[i] = bb / (cc-aa*self.p.a[i-1])
d = self.p.t*self.f2(self.p.y[i],self.p.v[i])-r12*0.5 * \
((self.p.v[i]+self.p.v[i+1])*(self.p.y[i+1]-self.p.y[i]) - \
(self.p.v[i]+self.p.v[i-1])*(self.p.y[i]-self.p.y[i-1]))+self.p.v[i]- \
(self.p.q2/self.p.rr)*0.5*((self.p.v[i]+self.p.v[i+1]) * \
(R[i+1]-R[i]) - (self.p.v[i]+self.p.v[i-1])*(R[i]-R[i-1]))
self.p.b[i] = (aa*self.p.b[i-1]+d)/(cc-aa*self.p.a[i-1])
for ii in range(1,self.p.N1+1):
i = self.p.N1 - ii
self.p.v[i] = self.p.a[i] * self.p.v[i+1] + self.p.b[i]
for i in range(0, self.p.N1+1):
if self.p.v[i]<0: self.p.v[i]=0
plt.plot(self.p.x, R, 'k-.')
plt.grid(True)
plt.axis([0., self.p.l, 0.0, 2.5])
plt.axis([0., self.p.l, 0.0, 2.5])
plt.plot(self.p.x, self.p.y, 'b-', label='$u$')
plt.plot(self.p.x, self.p.v, 'g--', label='$v$')
plt.plot(self.p.x, R, 'k-.', label='$r$')
app.processEvents()
self.draw()
if not self.p.flag:
break
dt = time.perf_counter() - tst
print("N2 = %i, N1 = %i, time solution = %1.3e, h = %1.3e" % (self.p.N2, self.p.N1, dt, self.p.h))
class App(QWidget):
def __init__(self):
super().__init__()
self._global()
self.layout = QGridLayout(self)
self.flag = True
self.initUI()
def _global(self):
self.ky1 = 0.8
self.ky2 = -80.0
self.ky3 = 1.99
self.ky4 = 0.3
self.ky5 = 2.0
self.kv1 = 0.9
self.kv2 = -80.0
self.kv3 = 1.8
self.kv4 = 0.8
self.kv5 = 2.0
self.N1 = 50
self.tt = 20.
self.l = 2.
self.h = self.l / self.N1
self.N2 = 50
self.t = self.tt / self.N2
self.hh = self.h * self.h
self.rr = self.hh / self.t
self.a11 = 0.03
self.a12 = 0.01
self.p1 = 0.03
self.a21 = 0.03
self.a22 = 0.01
self.p2 = 0.04
self.q1 = 0.09
self.q2 = 0.05
self.m1 = 0.75
self.m2 = 1.1
self.d1 = 0.7
self.d2 = 0.5
self.c1 = 0.25
self.c2 = 0.65
self.h1 = 0.15
self.b1 = 0.35
self.x = np.zeros((self.N1+1), 'float')
self.y = np.zeros((self.N1+1), 'float')
self.v = np.zeros((self.N1+1), 'float')
self.a = np.zeros((self.N1), 'float')
self.b = np.zeros((self.N1), 'float')
self.z = np.zeros((self.N1+1), 'float')
self.rbtns = [
QRadioButton('z11'),
QRadioButton('z12'),
QRadioButton('z21'),
QRadioButton('z22'),
QRadioButton('z23'),
]
self.rbtns[1].setChecked(True)
self.group_rb = QButtonGroup(self)
self.h_layout = QHBoxLayout()
for rb in self.rbtns:
self.h_layout.addWidget(rb)
self.group_rb.addButton(rb)
def initUI(self):
self.m = PlotCanvas(self.rbtns, self, width=5, height=4)
self.layout.addWidget(self.m, 0, 0)
self.le_ky1 = QLineEdit('0.8', self)
self.le_ky2 = QLineEdit('-80.0', self)
self.le_ky3 = QLineEdit('1.99', self)
self.le_ky4 = QLineEdit('0.3', self)
self.le_ky5 = QLineEdit('2.0', self)
self.le_kv1 = QLineEdit('0.9', self)
self.le_kv2 = QLineEdit('-80.0', self)
self.le_kv3 = QLineEdit('1.8', self)
self.le_kv4 = QLineEdit('0.8', self)
self.le_kv5 = QLineEdit('2.0', self)
self.le_a11 = QLineEdit('0.03',self)
self.le_a12 = QLineEdit('0.01',self)
self.le_p1 = QLineEdit('0.03',self)
self.le_a21 = QLineEdit('0.03',self)
self.le_a22 = QLineEdit('0.01',self)
self.le_p2 = QLineEdit('0.04',self)
self.le_q1 = QLineEdit('0.09',self)
self.le_q2 = QLineEdit('0.05',self)
self.le_m1 = QLineEdit('0.75',self)
self.le_m2 = QLineEdit('1.1',self)
self.le_d1 = QLineEdit('0.7',self)
self.le_d2 = QLineEdit('0.5',self)
self.le_c1 = QLineEdit('0.25',self)
self.le_c2 = QLineEdit('0.65',self)
self.le_h1 = QLineEdit('0.15',self)
self.le_b1 = QLineEdit('0.35',self)
button = QPushButton('Start', self)
button.clicked.connect(self.initVars)
formLayout = QFormLayout()
formLayout.setVerticalSpacing(1)
formLayout.addRow('ky1:', self.le_ky1)
formLayout.addRow('ky2:', self.le_ky2)
formLayout.addRow('ky3:', self.le_ky3)
formLayout.addRow('ky4:', self.le_ky4)
formLayout.addRow('ky5:', self.le_ky5)
formLayout.addRow('kv1:', self.le_kv1)
formLayout.addRow('kv2:', self.le_kv2)
formLayout.addRow('kv3:', self.le_kv3)
formLayout.addRow('kv4:', self.le_kv4)
formLayout.addRow('kv5:', self.le_kv5)
formLayout.addRow('a11:', self.le_a11)
formLayout.addRow('a12:', self.le_a12)
formLayout.addRow('p1:', self.le_p1)
formLayout.addRow('a21:', self.le_a21)
formLayout.addRow('a22:', self.le_a22)
formLayout.addRow('p2:', self.le_p2)
formLayout.addRow('q1:', self.le_q1)
formLayout.addRow('q2:', self.le_q2)
formLayout.addRow('m1:', self.le_m1)
formLayout.addRow('m2:', self.le_m2)
formLayout.addRow('d1:', self.le_d1)
formLayout.addRow('d2:', self.le_d2)
formLayout.addRow('c1:', self.le_c1)
formLayout.addRow('c2:', self.le_c2)
formLayout.addRow('h1:', self.le_h1)
formLayout.addRow('b1:', self.le_b1)
formLayout.addRow(QLabel(
'<h3 style="color: red;">Выберите ресурс</h3>', alignment=Qt.AlignCenter))
formLayout.addRow(self.h_layout)
formLayout.addRow('', button)
self.layout.addLayout(formLayout, 0, 1)
self.layout.setColumnStretch(0, 1)
self.layout.setColumnStretch(1, 0)
def initVars(self):
self.ky1 = float(self.le_ky1.text())
self.ky2 = float(self.le_ky2.text())
self.ky3 = float(self.le_ky3.text())
self.ky4 = float(self.le_ky4.text())
self.ky5 = float(self.le_ky5.text())
self.kv1 = float(self.le_kv1.text())
self.kv2 = float(self.le_kv2.text())
self.kv3 = float(self.le_kv3.text())
self.kv4 = float(self.le_kv4.text())
self.kv5 = float(self.le_kv5.text())
self.a11 = float(self.le_a11.text())
self.a12 = float(self.le_a12.text())
self.p1 = float(self.le_p1 .text())
self.a21 = float(self.le_a21.text())
self.a22 = float(self.le_a22.text())
self.p2 = float(self.le_p2 .text())
self.q1 = float(self.le_q1 .text())
self.q2 = float(self.le_q2 .text())
self.m1 = float(self.le_m1 .text())
self.m2 = float(self.le_m2 .text())
self.d1 = float(self.le_d1 .text())
self.d2 = float(self.le_d2 .text())
self.c1 = float(self.le_c1 .text())
self.c2 = float(self.le_c2 .text())
self.h1 = float(self.le_h1 .text())
self.b1 = float(self.le_b1 .text())
if self.kv4 > 2 or self.kv4 < 0:
QMessageBox.about(self, "Ошибка", "Значение kv4 должно быть от 0 до 2")
else:
self.h = self.l / self.N1
self.t = self.tt / self.N2
self.hh = self.h * self.h
self.rr = self.hh / self.t
self.x = np.zeros((self.N1+1), 'float')
self.y = np.zeros((self.N1+1), 'float')
self.v = np.zeros((self.N1+1), 'float')
self.a = np.zeros((self.N1), 'float')
self.b = np.zeros((self.N1), 'float')
self.z = np.zeros((self.N1+1), 'float')
self.m.plot()
def closeEvent(self, event):
self.flag = False
if __name__ == '__main__':
app = QApplication(sys.argv)
ex = App()
ex.resize(800, 600)
ex.show()
sys.exit(app.exec_())
