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chaos_pendulum.py
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chaos_pendulum.py
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#Let's implement a chaos pendulum (double pendulum)
import numpy as np
from PIL import Image, ImageDraw, ImageFont,ImageOps
import matplotlib.pyplot as plt
import cv2
import os
#---music libraries
# import librosa
# import librosa.display
# from routines import *
import time
import argparse
def str2bool(v):
if isinstance(v, bool):
return v
if v.lower() in ('yes', 'true', 't', 'y', '1'):
return True
elif v.lower() in ('no', 'false', 'f', 'n', '0'):
return False
else:
raise argparse.ArgumentTypeError('Boolean value expected.')
parser = argparse.ArgumentParser()
parser.add_argument('--mode')
parser.add_argument('--img_res', type=float, default=1)
parser.add_argument('--max_iter', type=int, default=500)
opt = parser.parse_args()
print(opt)
def pil_list_to_cv2(pil_list):
#converts a list of pil images to a list of cv2 images
png_list=[]
for pil_img in pil_list:
pil_img.save('trash_image.png',format='png')
png_list.append(cv2.imread('trash_image.png'))
os.remove('trash_image.png')
return png_list
def generate_video(cv2_list,path='double_pendulum.avi',fps=10):
#makes a video from a given cv2 image list
if len(cv2_list)==0:
raise ValueError('the given png list is empty!')
video_name = path
frame=cv2_list[0]
# setting the frame width, height width
# the width, height of first image
height, width, layers = frame.shape
video = cv2.VideoWriter(video_name, 0, fps, (width, height))
# Appending the images to the video one by one
for cv2_image in cv2_list:
video.write(cv2_image)
# Deallocating memories taken for window creation
cv2.destroyAllWindows()
video.release() # releasing the video generated
def get_theta_dd(theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g):
#----theta1_dd-----
num1=-g*((2*m1+m2)*np.sin(theta1)+m2*np.sin(theta1-2*theta2))
num2=-2*np.sin(theta1-theta2)*m2*(theta2_d**2*l2+theta1_d**2*l1*np.cos(theta1-theta2))
denum1=2*m1+m2-m2*np.cos(2*theta1-2*theta2)
denum=l1*denum1
theta1_dd=(num1+num2)/denum
#----theta2_dd----
num1=2*np.sin(theta1-theta2)
num2=theta1_d**2*l1*(m1+m2)+g*(m1+m2)*np.cos(theta1)+theta2_d**2*l2*m2*np.cos(theta1-theta2)
denum=l2*denum1
theta2_dd=num1*num2/denum
return theta1_dd,theta2_dd
def explicite_euler(dt,theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g):
theta1_dd,theta2_dd=get_theta_dd(theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g)
return theta1+dt*theta1_d,theta2+dt*theta2_d,theta1_d+dt*theta1_dd,theta2_d+dt*theta2_dd
def calculate_trajectory(n_iter,dt,theta1_init,theta2_init,theta1_d_init,theta2_d_init,m1=1,m2=1,l1=1,l2=0.5,g=10,add_energy=None):
phase_traject=np.zeros((n_iter,4))#phase-space trajectory
phase_traject[0,:]=np.array([theta1_init,theta2_init,theta1_d_init,theta2_d_init])
for i in range(n_iter-1):
if (i+1)%100000==0:
print('progress: '+str(i)+'/'+str(n_iter-1))
if add_energy is not None:
phase_traject[i,2]+=np.sign(phase_traject[i,2])*add_energy
#---explicite Euler ----
# theta1,theta2,theta1_d,theta2_d=explicite_euler(dt,phase_traject[i,0],phase_traject[i,1],phase_traject[i,2],phase_traject[i,3],m1,m2,l1,l2,g)
# phase_traject[i+1,:]=np.array([theta1,theta2,theta1_d,theta2_d])
#---explicite midpoint method ----
theta1_d_i=phase_traject[i,2]
theta2_d_i=phase_traject[i,3]
theta11,theta22,theta11_d,theta22_d=explicite_euler(dt/2,phase_traject[i,0],phase_traject[i,1],theta1_d_i,theta2_d_i,m1,m2,l1,l2,g)
theta11_dd,theta22_dd=get_theta_dd(theta11,theta22,theta11_d,theta22_d,m1,m2,l1,l2,g)
theta1_dd,theta2_dd=get_theta_dd(theta11,theta22,theta11_d,theta22_d,m1,m2,l1,l2,g)
theta1_d=theta1_d_i+dt*theta1_dd
theta2_d=theta2_d_i+dt*theta2_dd
phase_traject[i+1,:]=np.array([phase_traject[i,0]+dt/2*(theta1_d_i+theta1_d),phase_traject[i,1]+dt/2*(theta2_d_i+theta2_d),theta1_d,theta2_d])
return phase_traject
def get_energy(theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g):
y1=l1*np.cos(theta1)
y2=y1+l2*np.cos(theta2)
e_pot=np.array([-m1*g*y1,-m2*g*y2])
e_kin_1=m1/2*(l1*theta1_d)**2
e_kin_2=(l1*theta1_d)**2
e_kin_2+=(l2*theta2_d)**2
e_kin_2+=2*l1*l2*theta1_d*theta2_d*(np.cos(theta1)*np.cos(theta2)+np.sin(theta1)*np.sin(theta2))
e_kin_2*=m2/2
e_kin=np.array([e_kin_1,e_kin_2])
return e_pot,e_kin
def get_corrected_theta2_d(energy,theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g):
y1=l1*np.cos(theta1)
y2=y1+l2*np.cos(theta2)
a=-l2**2
b=-2*l1*l2*theta1_d*(np.cos(theta1)*np.cos(theta2)+np.sin(theta1)*np.sin(theta2))
c=2*(energy+m1*g*y1+m2*g*y2-m1/2*(l1*theta1_d)**2)/m2-(l1*theta1_d)**2
sqrt_term=b**2-4*a*c
if sqrt_term<0:
print(sqrt_term)
#raise ValueError('the sqrt_term is negative!')
sqrt_term=0
else:
sqrt_term=np.sqrt(sqrt_term)
theta2_d_corrected=(-b+sqrt_term)/(2*a)
if np.sign(theta2_d_corrected)!=np.sign(theta2_d):
theta2_d_corrected=(-b-sqrt_term)/(2*a)
return theta2_d_corrected
def rotation(alpha,v):
c=np.cos(alpha)
s=np.sin(alpha)
R=np.array([[c,-s],[s,c]])
return np.dot(R,v)
def draw_arrow(draw,start_coord,end_coord,flank_length=2):
#start_coord and end_coord should be a 2-d numpy vector
delta=end_coord-start_coord
flank_1=rotation(3*np.pi/4,delta)
flank_2=rotation(-3*np.pi/4,delta)
flank_1=flank_length*flank_1/np.linalg.norm(flank_1)
flank_2=flank_length*flank_2/np.linalg.norm(flank_2)
flank_point_1=end_coord+flank_1
flank_point_2=end_coord+flank_2
draw.line([(start_coord[0],start_coord[1]),(end_coord[0],end_coord[1]),(int(flank_point_1[0]),int(flank_point_1[1])),(end_coord[0],end_coord[1]),(int(flank_point_2[0]),int(flank_point_2[1]))], fill=(0,0,0))#drawing arrow
def distance_in_phase_space(phase_point):
phase_point[0:2]=np.mod(phase_point[0:2],2*np.pi)
if phase_point[0]>np.pi:
phase_point[0]=2*np.pi-phase_point[0]
if phase_point[1]>np.pi:
phase_point[1]=2*np.pi-phase_point[1]
return np.linalg.norm(phase_point)
def render_phase_traject(phase_traject,img_res=1,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',take_frame_every=1,second_phase_traject=None,draw_phase=True,draw_marker=True,max_points=500,frames_per_second=20,show_energy=False):
frames=[]
e_pot=[]#the potential energy of each of the masses: e_pot=-m*g*y
e_kin=[]#the kinetic energy of each of the masses: e_kin=m*l**2*theta_d**2/2
h=int(img_res*200)
if draw_phase:
w=2*h
w_34=int(3*w/4)
else:
w=h
x0=int(h/2)
y0=int(h/2)
h_red=int(0.4*h)
l_tot=l1+l2
l1_ratio=l1/l_tot
l2_ratio=l2/l_tot
L1=l1_ratio*h_red
L2=l2_ratio*h_red
d=int(0.02*h)
d1=d*m1**(1/3)
d2=d*m2**(1/3)
d_4=d/4
e_pot_0,e_kin_0=get_energy(phase_traject[0,0],phase_traject[0,1],phase_traject[0,2],phase_traject[0,3],m1,m2,l1,l2,g)
energy=np.sum(e_pot_0)+np.sum(e_kin_0)
print('initial energy: '+str(energy))
prev_points=[]
prev_phase=[]
if second_phase_traject is not None:
distance_scale=0.05
prev_distances=[distance_scale*distance_in_phase_space(second_phase_traject[0,:]-phase_traject[0,:])]
# max_theta2_d=1.2*np.max(np.abs(phase_traject[:,3]))
max_theta2_d=20
base=np.exp(np.log(0.01)/max_points)
for i in range(phase_traject.shape[0]):
if i%10000==0:
print('rendering iteration: '+str(i)+'/'+str(phase_traject.shape[0]))
if i%take_frame_every==0:
theta1=phase_traject[i,0]
theta2=phase_traject[i,1]
theta1_d=phase_traject[i,2]
theta2_d=phase_traject[i,3]
prev_phase.append((theta1,theta1_d,theta2,theta2_d))
# theta2_d=get_corrected_theta2_d(energy,theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g)
#----transform to cartesian coordinates---
x1=x0+L1*np.sin(theta1)
y1=y0+L1*np.cos(theta1)
x2=x1+L2*np.sin(theta2)
y2=y1+L2*np.cos(theta2)
prev_points.append([np.array([x1,y1]),np.array([x2,y2])])
#---draw the image ----
img = Image.new("RGB", (w, h), "white")
draw = ImageDraw.Draw(img)
n_prev=min(max_points,len(prev_points))
if draw_phase:
draw_arrow(draw,np.asarray([int(9*h/8),int(h/2)]),np.asarray([int(15*h/8),int(h/2)]),flank_length=int(h/50))#horizontal
draw_arrow(draw,np.asarray([w_34,int(7*h/8)]),np.asarray([w_34,int(1*h/8)]),flank_length=int(h/50))#vertical
font = ImageFont.truetype("arial.ttf", int(h/20))
draw.text((w_34-h/7,int(1*h/16)), 'angular velocity', font=font, fill=(0,0,0))
draw.text((int(14*h/8),int(h/2+h/30)), 'angle', font=font, fill=(0,0,0))
for k in range(n_prev-1):
idx=n_prev-k
point=prev_points[-idx]
xx2=point[1][0]
yy2=point[1][1]
point=prev_points[-idx+1]
xxx2=point[1][0]
yyy2=point[1][1]
intensity=int(255*(1-base**idx))
if draw_marker:
draw.line([(xx2,yy2),(xxx2,yyy2)],fill=(intensity,intensity,255),width=2)
if draw_phase:
if np.abs((prev_phase[-idx][0]+np.pi)%(2*np.pi)-(prev_phase[-idx+1][0]+np.pi)%(2*np.pi))<np.pi:
phase_x=w_34+x0*((prev_phase[-idx][0]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_y=y0+y0*prev_phase[-idx][1]/max_theta2_d
phase_xx=w_34+x0*((prev_phase[-idx+1][0]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_yy=y0+y0*prev_phase[-idx+1][1]/max_theta2_d
draw.line([(phase_x,phase_y),(phase_xx,phase_yy)],fill=(255,intensity,intensity),width=2)
if idx==2:
draw.ellipse([(phase_xx-d1,phase_yy-d1),(phase_xx+d1,phase_yy+d1)], fill=(255,0,0), outline=None)
if np.abs((prev_phase[-idx][2]+np.pi)%(2*np.pi)-(prev_phase[-idx+1][2]+np.pi)%(2*np.pi))<np.pi:
phase_x=w_34+x0*((prev_phase[-idx][2]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_y=y0+y0*prev_phase[-idx][3]/max_theta2_d
phase_xx=w_34+x0*((prev_phase[-idx+1][2]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_yy=y0+y0*prev_phase[-idx+1][3]/max_theta2_d
draw.line([(phase_x,phase_y),(phase_xx,phase_yy)],fill=(intensity,intensity,255),width=2)
if idx==2:
draw.ellipse([(phase_xx-d2,phase_yy-d2),(phase_xx+d2,phase_yy+d2)], fill=(0,0,255), outline=None)
if second_phase_traject is not None:
x11=x0+L1*np.sin(second_phase_traject[i,0])
y11=y0+L1*np.cos(second_phase_traject[i,0])
x22=x11+L2*np.sin(second_phase_traject[i,1])
y22=y11+L2*np.cos(second_phase_traject[i,1])
draw.line([(x0,y0),(x11,y11)],fill=(255,0,0),width=1)
draw.ellipse([(x11-d1,y11-d1),(x11+d1,y11+d1)], fill=(255,0,0), outline=None)
draw.line([(x11,y11),(x22,y22)],fill=(255,0,0),width=1)
draw.ellipse([(x22-d2,y22-d2),(x22+d2,y22+d2)], fill=(255,0,0), outline=None)
distance=distance_scale*distance_in_phase_space(second_phase_traject[i,:]-phase_traject[i,:])
prev_distances.append(distance)
text=['Distance in phase space: '+str(distance)[:4]]
dy=2
font = ImageFont.truetype("arial.ttf", int(h/20))
for k in range(len(text)):
draw.text((int(0.05*h),int(3+0.05*h+dy)), text[k], font=font, fill=(0,0,0))
dy+=1.1*font.getsize(text[k])[1]
idx=0
dx=1
bias=int(h/10)
bias_y=-10
draw.line([(bias,int(bias_y+h/4*2)),(bias,int(h/6)),(bias-2,int(h/6+2)),(bias,int(h/6)),(bias+2,int(h/6+2))], fill=(0,0,0))#drawing arrow
draw.ellipse([(bias-2,int(bias_y+h/4*(2-prev_distances[-1])-2)),(bias+2,int(bias_y+h/4*(2-prev_distances[-1])+2))], fill=(0,0,0), outline=None)
while ((bias+dx*idx)<(h-bias) and idx<len(prev_distances)-1):
intensity=int(255*(1-0.99**idx))
draw.line([(bias+dx*idx,int(bias_y+h/4*(2-prev_distances[-idx-1]))),(bias+dx*(idx+1),int(bias_y+h/4*(2-prev_distances[-idx-2])))],fill=(intensity,intensity,255),width=2)
idx+=1
draw.line([(x0,y0),(x1,y1)],fill=(0,0,0),width=2)
draw.line([(x1,y1),(x2,y2)],fill=(0,0,0),width=2)
if second_phase_traject is None:
draw.ellipse([(x1-d1,y1-d1),(x1+d1,y1+d1)], fill=(255,0,0), outline=None)
draw.ellipse([(x2-d2,y2-d2),(x2+d2,y2+d2)], fill=(0,0,255), outline=None)
else:
draw.ellipse([(x1-d1,y1-d1),(x1+d1,y1+d1)], fill=(0,0,0), outline=None)
draw.ellipse([(x2-d2,y2-d2),(x2+d2,y2+d2)], fill=(0,0,0), outline=None)
#----calculate the energies----
e_pot_i,e_kin_i=get_energy(theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g)
if show_energy:
font = ImageFont.truetype("arial.ttf", int(h/20))
draw.text((int(h/20),int(h/10)), 'energy: '+str(np.sum(e_pot_i)+np.sum(e_kin_i))[:4], font=font, fill=(0,0,0))
e_pot.append(e_pot_i)
e_kin.append(e_kin_i)
frames.append(img)
#frames[0].save(save_path+'double_pendulum.gif',
#save_all=True,
#append_images=frames[1:],
#duration=40,
#loop=0)
cv2_list=pil_list_to_cv2(frames)
generate_video(cv2_list,path=save_path+'double_pendulum.avi',fps=frames_per_second)
e_pot=np.asarray(e_pot)
e_kin=np.asarray(e_kin)
print('final energy: '+str(np.sum(e_pot[-1,:])+np.sum(e_kin[-1,:])))
return e_pot,e_kin
def represent_set_of_trajectories(trajectory_list,img_res=1,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',take_frame_every=1,frames_per_second=20):
frames=[]
h=int(img_res*200)
w=2*h
w_34=int(3*w/4)
x0=int(h/2)
y0=int(h/2)
h_red=int(0.4*h)
d=int(0.02*h)
# max_theta2_d=1.2*np.max(np.abs(phase_traject[:,3]))
max_theta2_d=10
for i in range(1,trajectory_list[0].shape[0]):
if i%10000==0:
print('rendering iteration: '+str(i)+'/'+str(trajectory_list[0].shape[0]))
if i%take_frame_every==0:
#---draw the image ----
img = Image.new("RGB", (w, h), "white")
draw = ImageDraw.Draw(img)
if i<400:
#--theta1 submanifold
draw_arrow(draw,np.asarray([int(1*h/8),int(h/2)]),np.asarray([int(7*h/8),int(h/2)]),flank_length=int(h/50))#horizontal
draw_arrow(draw,np.asarray([int(h/2),int(7*h/8)]),np.asarray([int(h/2),int(1*h/8)]),flank_length=int(h/50))#vertical
font = ImageFont.truetype("arial.ttf", int(h/24))
draw.text((h/2-3*h/14,int(1*h/16)), 'inner angular velocity', font=font, fill=(0,0,0))
draw.text((int(6*h/8),int(h/2+h/30)), 'inner angle', font=font, fill=(0,0,0))
#--theta2 submanifold
draw_arrow(draw,np.asarray([int(9*h/8),int(h/2)]),np.asarray([int(15*h/8),int(h/2)]),flank_length=int(h/50))#horizontal
draw_arrow(draw,np.asarray([w_34,int(7*h/8)]),np.asarray([w_34,int(1*h/8)]),flank_length=int(h/50))#vertical
font = ImageFont.truetype("arial.ttf", int(h/24))
draw.text((w_34-3*h/14,int(1*h/16)), 'outer angular velocity', font=font, fill=(0,0,0))
draw.text((int(14*h/8),int(h/2+h/30)), 'outer angle', font=font, fill=(0,0,0))
for phase_traject in trajectory_list:
phase_x1=x0+x0*((phase_traject[i,0]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_y1=y0+y0*phase_traject[i,2]/max_theta2_d
if np.abs((phase_traject[i,0]+np.pi)%(2*np.pi)-(phase_traject[i-1,0]+np.pi)%(2*np.pi))<np.pi:
phase_xx1=x0+x0*((phase_traject[i-1,0]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_yy1=y0+y0*phase_traject[i-1,2]/max_theta2_d
draw.line([(phase_x1,phase_y1),(phase_xx1,phase_yy1)],fill=(255,150,150),width=1)
phase_x2=w_34+x0*((phase_traject[i,1]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_y2=y0+y0*phase_traject[i,2]/max_theta2_d
if np.abs((phase_traject[i,1]+np.pi)%(2*np.pi)-(phase_traject[i-1,1]+np.pi)%(2*np.pi))<np.pi:
phase_xx2=w_34+x0*((phase_traject[i-1,1]+np.pi)%(2*np.pi)-np.pi)/(2*np.pi)
phase_yy2=y0+y0*phase_traject[i-1,2]/max_theta2_d
draw.line([(phase_x2,phase_y2),(phase_xx2,phase_yy2)],fill=(150,150,255),width=1)
draw.point((phase_x1,phase_y1), fill=(255,0,0))
draw.point((phase_x2,phase_y2), fill=(0,0,255))
frames.append(img)
frames[0].save(save_path+'point_cloud.gif',
save_all=True,
append_images=frames[1:],
duration=40,
loop=0)
cv2_list=pil_list_to_cv2(frames)
generate_video(cv2_list,path=save_path+'point_cloud.avi',fps=frames_per_second)
def reflect_y_axis(im):
return ImageOps.mirror(im).rotate(180,expand=True)
def get_color(ratio,gray=False):
black=np.array([0,0,0])
blue=np.array([72,118,255])
indigo=np.array([75,0,130])
purple=np.array([128,0,128])
orchid=np.array([218,112,214])
plum=np.array([221,160,221])
white=np.array([255,255,255])
if gray:
if ratio<=1:
color=ratio*black+(1-ratio)*white
return tuple(color.astype(int))
else:
return tuple(black.astype(int))
else:
if ratio<0.1:
delta=ratio/0.1
color=delta*plum+(1-delta)*white
return tuple(color.astype(int))
elif 0.1<=ratio<0.2:
delta=(ratio-0.1)/0.1
color=delta*orchid+(1-delta)*plum
return tuple(color.astype(int))
elif 0.2<=ratio<0.4:
delta=(ratio-0.2)/0.2
color=delta*purple+(1-delta)*orchid
return tuple(color.astype(int))
elif 0.4<=ratio<0.7:
delta=(ratio-0.4)/0.3
color=delta*indigo+(1-delta)*purple
return tuple(color.astype(int))
elif 0.7<=ratio<1:
delta=(ratio-0.7)/0.3
color=delta*blue+(1-delta)*indigo
return tuple(color.astype(int))
else:
delta=(ratio-1)
color=delta*blue+(1-delta)*black
return tuple(color.astype(int))
def energy_condition(theta1,theta2,a,b):
return a*np.cos(theta1)+b*np.cos(theta2)<=a-b
def test_flip(theta1,theta2,theta1_d,theta2_d,max_iter,m1,m2,l1,l2,g,draw_inner=True,gray=False):
n_iter=0
max_theta2=0
phase_traject=[]
flip=False
while not flip and n_iter<max_iter:
n_iter+=1
#---explicite midpoint method ----
theta11,theta22,theta11_d,theta22_d=explicite_euler(dt/2,theta1,theta2,theta1_d,theta2_d,m1,m2,l1,l2,g)
theta11_dd,theta22_dd=get_theta_dd(theta11,theta22,theta11_d,theta22_d,m1,m2,l1,l2,g)
theta1_dd,theta2_dd=get_theta_dd(theta11,theta22,theta11_d,theta22_d,m1,m2,l1,l2,g)
theta1_d_new=theta1_d+dt*theta1_dd
theta2_d_new=theta2_d+dt*theta2_dd
theta1+=dt/2*(theta1_d+theta1_d_new)
theta2+=dt/2*(theta2_d+theta2_d_new)
theta1_d=theta1_d_new
theta2_d=theta2_d_new
phase_traject.append(np.array([theta1,theta2,theta1_d,theta2_d]))
abs_theta2=np.abs(theta2)
if not abs_theta2<np.pi:
flip=True
elif abs_theta2>max_theta2:
max_theta2=abs_theta2
if not flip:
if draw_inner:
rgb_color=get_color(1+max_theta2/np.pi,gray=gray)
else:
rgb_color=get_color(1,gray=gray)
else:
rgb_color=get_color(n_iter/max_iter,gray=gray)
return rgb_color,np.asarray(phase_traject)
def get_illustration(rgb_color,old_pixels,phase_traject,ww,hh,W,H,m1,m2,l1,l2,g,take_frame_every,img_res=1.6):
h=int(img_res*200)
w=2*h
w_34=int(3*w/4)
x0=int(h/2)
y0=int(h/2)
h_red=int(0.4*h)
l_tot=l1+l2
l1_ratio=l1/l_tot
l2_ratio=l2/l_tot
L1=l1_ratio*h_red
L2=l2_ratio*h_red
d=int(0.02*h)
d1=d*m1**(1/3)
d2=d*m2**(1/3)
frames=[]
delta_w=int(0.8*h/W)
delta_h=int(0.8*h/H)
proto_img=Image.new("RGB", (w, h), "white")
px=proto_img.load()
for op in old_pixels:
for u in range(delta_w):
for v in range(delta_h):
px[op[0]+u,op[1]+v]=op[2]
draw = ImageDraw.Draw(proto_img)
draw.ellipse([(int(w_34-0.4*h+(ww+1/2)*delta_w-d),int(0.1*h+(hh+1/2)*delta_h-d)),(int(w_34-0.4*h+(ww+1/2)*delta_w+d),int(0.1*h+(hh+1/2)*delta_h+d))], fill=(255,255,0), outline=(0,0,0))
for i in range(phase_traject.shape[0]):
if i%take_frame_every==0:
theta1=phase_traject[i,0]
theta2=phase_traject[i,1]
theta1_d=phase_traject[i,2]
theta2_d=phase_traject[i,3]
#----transform to cartesian coordinates---
x1=x0+L1*np.sin(theta1)
y1=y0+L1*np.cos(theta1)
x2=x1+L2*np.sin(theta2)
y2=y1+L2*np.cos(theta2)
#---draw the image ----
img = proto_img.copy()
draw = ImageDraw.Draw(img)
draw_arrow(draw,np.asarray([int(9*h/8),int(h/2+delta_h/2)]),np.asarray([int(15*h/8),int(h/2+delta_h/2)]),flank_length=int(h/50))#horizontal
draw_arrow(draw,np.asarray([int(delta_w/2+w_34),int(7*h/8)]),np.asarray([int(delta_w/2+w_34),int(1*h/8)]),flank_length=int(h/50))#vertical
font = ImageFont.truetype("arial.ttf", int(h/20))
draw.text((w_34-h/7+delta_w/2,int(1*h/16)), 'outer angle', font=font, fill=(0,0,0))
draw.text((int(27*h/16),int(h/2+h/30+delta_h/2)), 'inner angle', font=font, fill=(0,0,0))
draw.text((int(h/16),int(h/16)), 'Iterations: '+str(i), font=font, fill=(0,0,0))
draw.line([(x0,y0),(x1,y1)],fill=(0,0,0),width=2)
draw.line([(x1,y1),(x2,y2)],fill=(0,0,0),width=2)
draw.ellipse([(x1-d1,y1-d1),(x1+d1,y1+d1)], fill=(0,0,0), outline=None)
draw.ellipse([(x2-d2,y2-d2),(x2+d2,y2+d2)], fill=(0,0,0), outline=None)
px=img.load()
if i>=phase_traject.shape[0]-1-take_frame_every:
for u in range(delta_w):
for v in range(delta_h):
px[int(w_34-0.4*h+ww*delta_w+u),int(0.1*h+hh*delta_h+v)]=rgb_color
old_pixels.append([int(w_34-0.4*h+ww*delta_w),int(0.1*h+hh*delta_h),rgb_color])
if i<take_frame_every:
for j in range(10):
frames.append(img)
frames.append(img)
for j in range(10):
frames.append(img)
return frames,old_pixels
def draw_fractal_illustration(dt=0.01,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=1,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',max_iter=300,frames_per_second=20,take_frame_every=5):
start_time = time.time()
H=int(200*img_res)
W=H
delta1=(theta1_higher-theta1_lower)/W
delta2=(theta2_higher-theta2_lower)/H
p=0
frames=[]
old_pixels=[]
a=l1*(m1+m2)
b=l2*m2
fac=1
for w in range(W):
for h in range(H):
p+=1
print('iteration: '+str(p)+'/'+str(W*H))
theta1=theta1_lower+w*delta1
theta2=theta2_lower+h*delta2
theta1_d=0
theta2_d=0
flip=False
n_iter=0
max_theta2=0
if energy_condition(theta1,theta2,-a,-b):
rgb_color,phase_traject=test_flip(theta1,theta2,theta1_d,theta2_d,max_iter,m1,m2,l1,l2,g,draw_inner=False,gray=True)
else:
rgb_color,phase_traject=test_flip(theta1,theta2,theta1_d,theta2_d,max_iter,m1,m2,l1,l2,g,draw_inner=True,gray=True)
if 5<p<10:
fac=2
elif 10<=p:
fac=4
frame_set,old_pixels=get_illustration(rgb_color,old_pixels,phase_traject,w,h,W,H,m1,m2,l1,l2,g,take_frame_every*fac)
frames+=frame_set
cv2_list=pil_list_to_cv2(frames)
generate_video(cv2_list,path='trash_figures/fractal_illustration'+str(img_res)+'.avi',fps=frames_per_second)
def draw_fractal(dt=0.005,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=1,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',is_symmetric=False,max_iter=300,draw_inner=True,show_limit=False,gray=False,draw_pendelum_shape=False):
start_time = time.time()
H=int(200*img_res)
W=H
if draw_pendelum_shape:
w_bias=int(0.5*H)
else:
w_bias=0
delta1=(theta1_higher-theta1_lower)/W
delta2=(theta2_higher-theta2_lower)/H
img = Image.new("RGB", (W+w_bias, H), "white")
if draw_pendelum_shape:
x0=int(0.15*H)
y0=int(H/4)
l_tot=l1+l2
l1_ratio=l1/l_tot
l2_ratio=l2/l_tot
L1=l1_ratio*int(H/2)
L2=l2_ratio*int(H/2)
d=int(0.02*H)
d1=d*m1**(1/3)
d2=d*m2**(1/3)
x1=x0
y1=y0+L1
x2=x0
y2=y1+L2
draw = ImageDraw.Draw(img)
font = ImageFont.truetype("arial.ttf", int(H/20))
draw.text((int(H/20),int(H/16)), 'l1='+str(l1_ratio)[:4]+', l2='+str(l2_ratio)[:4], font=font, fill=(0,0,0))
draw.text((int(H/20),int(H/8)), 'm1='+str(m1)[:4]+', m2='+str(m2)[:4], font=font, fill=(0,0,0))
draw.line([(x0,y0),(x1,y1)],fill=(0,0,0),width=1)
draw.line([(x1,y1),(x2,y2)],fill=(0,0,0),width=1)
draw.ellipse([(x1-d1,y1-d1),(x1+d1,y1+d1)], fill=(255,0,0), outline=None)
draw.ellipse([(x2-d2,y2-d2),(x2+d2,y2+d2)], fill=(0,0,255), outline=None)
px=img.load()
p=0
a=l1*(m1+m2)
b=l2*m2
frames=[]
for w in range(W):
for h in range(H):
if h<=H/2 or not is_symmetric:
if p%100==0:
print('calculate pixel '+str(p)+'/'+str(W*H))
p+=1
theta1=theta1_lower+w*delta1
theta2=theta2_lower+h*delta2
theta1_d=0
theta2_d=0
flip=False
n_iter=0
max_theta2=0
if energy_condition(theta1,theta2,-a,-b) and not draw_inner:
rgb_color=get_color(1)
else:
rgb_color,phase_traject=test_flip(theta1,theta2,theta1_d,theta2_d,max_iter,m1,m2,l1,l2,g,gray=gray,draw_inner=draw_inner)
px[w_bias+w,h]=rgb_color
if is_symmetric:
px[w_bias+W-w-1,H-h-1]=rgb_color
frames.append(reflect_y_axis(img))
if show_limit:
img_limit=img.copy()
px_limit=img_limit.load()
for w in range(W):
theta1=theta1_lower+w*delta1
argument=a/b*(1-np.cos(theta1))-1
if -1<argument<1:
theta2_crit=np.arccos(argument)
h_crit=round((theta2_crit-theta2_lower)/delta2)
if h_crit<=H-1:
px_limit[w_bias+w,h_crit]=(255,255,0)
px_limit[w_bias+w,-h_crit+H]=(255,255,0)
for h in range(H):
theta2=theta2_lower+h*delta2
argument=b/a*(-1-np.cos(theta2))+1
if -1<argument<1:
theta1_crit=np.arccos(argument)
w_crit=round((theta1_crit-theta1_lower)/delta1)
if w_crit<=W-1:
px_limit[w_bias+w_crit,h]=(255,255,0)
px_limit[w_bias+-w_crit+W,h]=(255,255,0)
img_limit=reflect_y_axis(img_limit)
if not draw_pendelum_shape:
img_limit.save('trash_figures/fractal_limit_'+opt.mode+str(img_res)+'.png',format='png')
if not draw_pendelum_shape:
img=reflect_y_axis(img)
img.save('trash_figures/fractal_'+opt.mode+str(img_res)+'.png',format='png')
# cv2_list=pil_list_to_cv2(frames)
# generate_video(cv2_list,path='trash_figures/fractal_'+opt.mode+str(img_res)+'.avi',fps=10)
print("--- %s seconds ---" % (time.time() - start_time))
return img
theta1_init=4*np.pi/8
theta2_init=1*np.pi/8
theta1_d_init=0
theta2_d_init=0
dt=0.01
frames_per_second=20
take_frame_every=int(1/(dt*frames_per_second))
n_iter=3000
m2=1
#---draw star_dance---
# phase_traject_list=[]
# for i in range(1000):
# if i%20==0:
# print('trajectory: '+str(i))
# r=np.random.rand(4)*2e-2
# phase_traject=calculate_trajectory(n_iter,dt,theta1_init+r[0],theta2_init+r[1],theta1_d_init+r[2],theta2_d_init+r[3],m2=m2,l1=1,l2=0.5)
# phase_traject_list.append(phase_traject)
# represent_set_of_trajectories(phase_traject_list,img_res=2,m2=m2,l1=1,l2=0.5,save_path='trash_figures/',take_frame_every=take_frame_every,frames_per_second=int(frames_per_second/2))
#---draw fractal
if opt.mode=='draw_gray':
img=draw_fractal(dt=dt,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=opt.img_res,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',is_symmetric=True,max_iter=opt.max_iter,draw_inner=False,show_limit=True,gray=True)
elif opt.mode=='draw_color_no_inner':
img=draw_fractal(dt=dt,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=opt.img_res,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',is_symmetric=True,max_iter=opt.max_iter,draw_inner=False,show_limit=True,gray=False)
elif opt.mode=='draw_color_inner':
img=draw_fractal(dt=dt,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=opt.img_res,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',is_symmetric=True,max_iter=opt.max_iter,draw_inner=True,show_limit=True,gray=False)
elif opt.mode=='draw_fractal_morph':
frames=[]
l2=1
m2=1
N=80
for i in range(N):
img=draw_fractal(dt=dt,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=opt.img_res,m1=1,m2=m2,l1=1,l2=l2,g=10,save_path='trash_figures/',is_symmetric=True,max_iter=opt.max_iter,draw_inner=True,show_limit=True,gray=False,draw_pendelum_shape=True)
frames.append(img)
l2-=0.8/N
for i in range(N):
img=draw_fractal(dt=dt,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=opt.img_res,m1=1,m2=m2,l1=1,l2=l2,g=10,save_path='trash_figures/',is_symmetric=True,max_iter=opt.max_iter,draw_inner=True,show_limit=True,gray=False,draw_pendelum_shape=True)
frames.append(img)
m2-=0.9/N
cv2_list=pil_list_to_cv2(frames)
generate_video(cv2_list,path='trash_figures/fractal_morph'+opt.mode+str(opt.img_res)+'.avi',fps=10)
else:
raise ValueError('the mode is not known')
#---draw fractal illustration
# draw_fractal_illustration(dt=dt,theta1_lower=-3,theta1_higher=3,theta2_lower=-3,theta2_higher=3,img_res=0.03,m1=1,m2=1,l1=1,l2=0.5,g=10,save_path='trash_figures/',max_iter=600,frames_per_second=frames_per_second,take_frame_every=take_frame_every)
#---render phase traject
# phase_traject=calculate_trajectory(n_iter,dt,theta1_init,theta2_init,theta1_d_init,theta2_d_init,m2=m2,l1=1,l2=0.5)
# phase_traject_2=calculate_trajectory(n_iter,dt,theta1_init+1e-2,theta2_init+1e-2,theta1_d_init,theta2_d_init,m2=m2,l1=1,l2=0.5,add_energy=None)
# e_pot,e_kin=render_phase_traject(phase_traject,img_res=2,take_frame_every=take_frame_every,m2=m2,l1=1,l2=0.5,second_phase_traject=None,draw_phase=False,draw_marker=True,max_points=500,frames_per_second=frames_per_second,show_energy=False)
# plt.plot(np.sum(e_pot,axis=1)+np.sum(e_kin,axis=1))
# plt.ylabel('energy')
# plt.show()
#---audio---
# phase_traject=calculate_trajectory(n_iter,dt,theta1_init,theta2_init,theta1_d_init,theta2_d_init,m2=m2)
# render_phase_traject(phase_traject,img_res=0.5,take_frame_every=int(2/dt/100),m2=m2)
# samples=np.sin(phase_traject[0::30,0])
# plt.plot(samples)
# plt.show()
# fs=20000
# librosa.output.write_wav('chaos_sound.mp3', samples, fs,norm=True)
# time_step=0.05#ms
# ns=time_step*fs
# STFT=classic_STFT(ns=ns,N=256)
# spec=STFT.get_energy_spec(samples)
# plt.imshow(np.log(spec+1),origin='lower')
# plt.show()