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Python-Programs-for-Nonlinear-Dynamics/DoublePendulum.py
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Double pendulum
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| #!/usr/bin/env python3 | |
| # -*- coding: utf-8 -*- | |
| """ | |
| Created on Wed Apr 18 06:03:32 2018 | |
| @author: nolte | |
| """ | |
| import numpy as np | |
| from scipy import integrate | |
| from matplotlib import pyplot as plt | |
| import time | |
| plt.close('all') | |
| E = 1. # 1 | |
| def flow_deriv(x_y_z_w,tspan): | |
| x, y, z, w = x_y_z_w | |
| A = w**2*np.sin(y-x); | |
| B = -2*np.sin(x); | |
| C = z**2*np.sin(y-x)*np.cos(y-x); | |
| D = np.sin(y)*np.cos(y-x); | |
| EE = 2 - (np.cos(y-x))**2; | |
| FF = w**2*np.sin(y-x)*np.cos(y-x); | |
| G = -2*np.sin(x)*np.cos(y-x); | |
| H = 2*z**2*np.sin(y-x); | |
| I = 2*np.sin(y); | |
| JJ = (np.cos(y-x))**2 - 2; | |
| a = z | |
| b = w | |
| c = (A+B+C+D)/EE | |
| d = (FF+G+H+I)/JJ | |
| return[a,b,c,d] | |
| repnum = 75 | |
| np.random.seed(1) | |
| for reploop in range(repnum): | |
| px1 = 2*(np.random.random((1))-0.499)*np.sqrt(E); | |
| py1 = -px1 + np.sign(np.random.random((1))-0.499)*np.sqrt(2*E - px1**2); | |
| xp1 = 0.1 | |
| yp1 = -0.2 | |
| x_y_z_w0 = [xp1, yp1, px1, py1] | |
| tspan = np.linspace(1,1000,10000) | |
| x_t = integrate.odeint(flow_deriv, x_y_z_w0, tspan) | |
| siztmp = np.shape(x_t) | |
| siz = siztmp[0] | |
| if reploop % 50 == 0: | |
| plt.figure(2) | |
| lines = plt.plot(x_t[:,0],x_t[:,1]) | |
| plt.setp(lines, linewidth=0.5) | |
| plt.show() | |
| time.sleep(0.1) | |
| #os.system("pause") | |
| y1 = np.mod(x_t[:,0]+np.pi,2*np.pi) - np.pi | |
| y2 = np.mod(x_t[:,1]+np.pi,2*np.pi) - np.pi | |
| y3 = np.mod(x_t[:,2]+np.pi,2*np.pi) - np.pi | |
| y4 = np.mod(x_t[:,3]+np.pi,2*np.pi) - np.pi | |
| py = np.zeros(shape=(10*repnum,)) | |
| yvar = np.zeros(shape=(10*repnum,)) | |
| cnt = -1 | |
| last = y1[1] | |
| for loop in range(2,siz): | |
| if (last < 0)and(y1[loop] > 0): | |
| cnt = cnt+1 | |
| del1 = -y1[loop-1]/(y1[loop] - y1[loop-1]) | |
| py[cnt] = y4[loop-1] + del1*(y4[loop]-y4[loop-1]) | |
| yvar[cnt] = y2[loop-1] + del1*(y2[loop]-y2[loop-1]) | |
| last = y1[loop] | |
| else: | |
| last = y1[loop] | |
| plt.figure(3) | |
| lines = plt.plot(yvar,py,'o',ms=1) | |
| plt.show() | |
| plt.savefig('DPen') |