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demo_ThreeStageA.py
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import numpy as np
import matplotlib.pyplot as plt
import matplotlib.animation as animation
from matplotlib.widgets import Slider, Button
fig, ax = plt.subplots(figsize=(6,6))
plt.subplots_adjust(left=0.15, bottom=0.35)
ax.set_aspect('equal')
plt.xlim(-1.2*40,1.2*40)
plt.ylim(-1.2*40,1.2*40)
#plt.grid()
t = np.linspace(0, 2*np.pi, 4000)
delta = 1
## draw pin
num_pins = 61
pins = [ax.plot([], [], 'k-')[0] for n in range(num_pins)]
def draw_pin_init():
for p in pins:
p.set_data([0], [0])
def pin_update(n,d,D):
for i in range(int(n)):
x = (d/2*np.sin(t)+ D/2*np.cos(2*i*np.pi/n))
y = (d/2*np.cos(t) + D/2*np.sin(2*i*np.pi/n))
pins[i].set_data(x,y)
## draw inner_pin
num_inner_pins = 10
inner_pins = [ax.plot([], [], 'g-')[0] for n in range(num_inner_pins)]
def draw_inner_pin_init():
for p in inner_pins:
p.set_data([0], [0])
def inner_pin_update(n,N,rd,Rd,phi):
for i in range(int(n)):
x = (rd*np.sin(t)+ Rd*np.cos(2*i*np.pi/n))*np.cos(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3) - (rd*np.cos(t) + Rd*np.sin(2*i*np.pi/n))*np.sin(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3)
y = (rd*np.sin(t)+ Rd*np.cos(2*i*np.pi/n))*np.sin(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3) + (rd*np.cos(t) + Rd*np.sin(2*i*np.pi/n))*np.cos(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3)
inner_pins[i].set_data(x,y)
## draw drive_pin
d0, = ax.plot([0], [0],'k-', lw=2)
def drive_pin_update(r):
x = r*np.sin(t)
y = r*np.cos(t)
d0.set_data(x,y)
#inner circleA:
num_inner_circlesA = 10
inner_circlesA = [ax.plot([], [], 'r-')[0] for n in range(num_inner_circlesA)]
def draw_inner_circleA_init():
for p in inner_circlesA:
p.set_data([0], [0])
def update_inner_circleA(e,n,N,rd,Rd, phi):
for i in range(int(n)):
x = ((rd+e)*np.cos(t)+Rd*np.cos(2*i*np.pi/n))*np.cos(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3) - ((rd+e)*np.sin(t)+Rd*np.sin(2*i*np.pi/n))*np.sin(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3) + e*np.cos(phi)
y = ((rd+e)*np.cos(t)+Rd*np.cos(2*i*np.pi/n))*np.sin(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3) + ((rd+e)*np.sin(t)+Rd*np.sin(2*i*np.pi/n))*np.cos(-phi/(N-1)+ 3*np.pi/(N-1)-np.pi/3) + e*np.sin(phi)
inner_circlesA[i].set_data(x,y)
#inner circleB:
num_inner_circlesB = 10
inner_circlesB = [ax.plot([], [], 'b-')[0] for n in range(num_inner_circlesB)]
def draw_inner_circleB_init():
for p in inner_circlesB:
p.set_data([0], [0])
def update_inner_circleB(e,n,N,rd,Rd, phi):
for i in range(int(n)):
x = ((rd+e)*np.cos(t)+Rd*np.cos(2*i*np.pi/n))*np.cos(-phi/(N-1)+ 3*np.pi/(N-1) - np.pi/(3)) - ((rd+e)*np.sin(t)+Rd*np.sin(2*i*np.pi/n))*np.sin(-phi/(N-1)+ 3*np.pi/(N-1)- np.pi/(3)) - e*np.cos(phi-np.pi/3)
y = ((rd+e)*np.cos(t)+Rd*np.cos(2*i*np.pi/n))*np.sin(-phi/(N-1)+ 3*np.pi/(N-1)- np.pi/(3)) + ((rd+e)*np.sin(t)+Rd*np.sin(2*i*np.pi/n))*np.cos(-phi/(N-1)+ 3*np.pi/(N-1)- np.pi/(3)) - e*np.sin(phi-np.pi/3)
inner_circlesB[i].set_data(x,y)
#inner circleC:
num_inner_circlesC = 10
inner_circlesC = [ax.plot([], [], 'g-')[0] for n in range(num_inner_circlesC)]
def draw_inner_circleC_init():
for p in inner_circlesC:
p.set_data([0], [0])
def update_inner_circleC(e,n,N,rd,Rd, phi):
for i in range(int(n)):
x = ((rd+e)*np.cos(t)+Rd*np.cos(2*i*np.pi/n))*np.cos(-phi/(N-1) + 3*np.pi/(N-1) - np.pi/(3)) - ((rd+e)*np.sin(t)+Rd*np.sin(2*i*np.pi/n))*np.sin(-phi/(N-1) + 3*np.pi/(N-1)- np.pi/(3)) - e*np.cos(phi+np.pi/3)
y = ((rd+e)*np.cos(t)+Rd*np.cos(2*i*np.pi/n))*np.sin(-phi/(N-1) + 3*np.pi/(N-1)- np.pi/(3)) + ((rd+e)*np.sin(t)+Rd*np.sin(2*i*np.pi/n))*np.cos(-phi/(N-1) + 3*np.pi/(N-1)- np.pi/(3)) - e*np.sin(phi+np.pi/3)
inner_circlesC[i].set_data(x,y)
##inner pinA:
inner_pinA, = ax.plot([0],[0],'r-')
dotA, = ax.plot([0],[0], 'ro', ms=5)
def update_inner_pinA(e,Rm, phi):
x = (Rm+e)*np.cos(t)+e*np.cos(phi)
y = (Rm+e)*np.sin(t)+e*np.sin(phi)
inner_pinA.set_data(x,y)
x1 = (Rm+e)*np.cos(phi)+e*np.cos(phi)
y1 = (Rm+e)*np.sin(phi)+e*np.sin(phi)
dotA.set_data(x1, y1)
##inner pinB:
inner_pinB, = ax.plot([0],[0],'b-')
dotB, = ax.plot([0],[0], 'bo', ms=5)
def update_inner_pinB(e,Rm, phi):
x = (Rm+e)*np.cos(t)-e*np.cos(phi-np.pi/3)
y = (Rm+e)*np.sin(t)-e*np.sin(phi-np.pi/3)
inner_pinB.set_data(x,y)
x1 = (Rm+e)*np.cos(phi+2*np.pi/3)-e*np.cos(phi-np.pi/3)
y1 = (Rm+e)*np.sin(phi+2*np.pi/3)-e*np.sin(phi-np.pi/3)
dotB.set_data(x1, y1)
##inner pinC:
inner_pinC, = ax.plot([0],[0],'g-')
dotC, = ax.plot([0],[0], 'go', ms=5)
def update_inner_pinC(e,Rm, phi):
x = (Rm+e)*np.cos(t)-e*np.cos(phi+np.pi/3)
y = (Rm+e)*np.sin(t)-e*np.sin(phi+np.pi/3)
inner_pinC.set_data(x,y)
x1 = (Rm+e)*np.cos(phi-2*np.pi/3)-e*np.cos(phi+np.pi/3)
y1 = (Rm+e)*np.sin(phi-2*np.pi/3)-e*np.sin(phi+np.pi/3)
dotC.set_data(x1, y1)
##ehypocycloidA:
ehypocycloidA, = ax.plot([0], [0],'r-')
edotA, = ax.plot([0],[0], 'ro', ms=5)
def update_ehypocycloidA(e,n,D,d, phis):
RD=D/2
rd=d/2
rc = (n-1)*(RD/n)
rm = (RD/n)
xa = (rc+rm)*np.cos(t)-e*np.cos((rc+rm)/rm*t)
ya = (rc+rm)*np.sin(t)-e*np.sin((rc+rm)/rm*t)
dxa = (rc+rm)*(-np.sin(t)+(e/rm)*np.sin((rc+rm)/rm*t))
dya = (rc+rm)*(np.cos(t)-(e/rm)*np.cos((rc+rm)/rm*t))
x = (xa + rd/np.sqrt(dxa**2 + dya**2)*(-dya))*np.cos(-phis/(n-1))-(ya + rd/np.sqrt(dxa**2 + dya**2)*dxa)*np.sin(-phis/(n-1)) + e*np.cos(phis)
y = (xa + rd/np.sqrt(dxa**2 + dya**2)*(-dya))*np.sin(-phis/(n-1))+(ya + rd/np.sqrt(dxa**2 + dya**2)*dxa)*np.cos(-phis/(n-1)) + e*np.sin(phis)
ehypocycloidA.set_data(x,y)
edotA.set_data(x[0], y[0])
##ehypocycloidB:
ehypocycloidB, = ax.plot([0],[0],'b-')
edotB, = ax.plot([0],[0], 'bo', ms=5)
def update_ehypocycloidB(e,n,D,d, phis):
RD=D/2
rd=d/2
rc = (n-1)*(RD/n)
rm = (RD/n)
xa = (rc+rm)*np.cos(t)+e*np.cos((rc+rm)/rm*t)
ya = (rc+rm)*np.sin(t)+e*np.sin((rc+rm)/rm*t)
dxa = (rc+rm)*(-np.sin(t)-(e/rm)*np.sin((rc+rm)/rm*t))
dya = (rc+rm)*(np.cos(t)+(e/rm)*np.cos((rc+rm)/rm*t))
x = (xa + rd/np.sqrt(dxa**2 + dya**2)*(-dya))*np.cos(-phis/(n-1) + np.pi/3/(n-1))-(ya + rd/np.sqrt(dxa**2 + dya**2)*dxa)*np.sin(-phis/(n-1) + np.pi/3/(n-1)) - e*np.cos(phis-np.pi/3)
y = (xa + rd/np.sqrt(dxa**2 + dya**2)*(-dya))*np.sin(-phis/(n-1) + np.pi/3/(n-1))+(ya + rd/np.sqrt(dxa**2 + dya**2)*dxa)*np.cos(-phis/(n-1) + np.pi/3/(n-1)) - e*np.sin(phis-np.pi/3)
ehypocycloidB.set_data(x,y)
edotB.set_data(x[0], y[0])
##ehypocycloidC:
ehypocycloidC, = ax.plot([0],[0],'g-')
edotC, = ax.plot([0],[0], 'go', ms=5)
def update_ehypocycloidC(e,n,D,d, phis):
RD=D/2
rd=d/2
rc = (n-1)*(RD/n)
rm = (RD/n)
xa = (rc+rm)*np.cos(t)+e*np.cos((rc+rm)/rm*t)
ya = (rc+rm)*np.sin(t)+e*np.sin((rc+rm)/rm*t)
dxa = (rc+rm)*(-np.sin(t)-(e/rm)*np.sin((rc+rm)/rm*t))
dya = (rc+rm)*(np.cos(t)+(e/rm)*np.cos((rc+rm)/rm*t))
x = (xa + rd/np.sqrt(dxa**2 + dya**2)*(-dya))*np.cos(-phis/(n-1) - np.pi/3/(n-1))-(ya + rd/np.sqrt(dxa**2 + dya**2)*dxa)*np.sin(-phis/(n-1) - np.pi/3/(n-1)) - e*np.cos(phis+np.pi/3)
y = (xa + rd/np.sqrt(dxa**2 + dya**2)*(-dya))*np.sin(-phis/(n-1) - np.pi/3/(n-1))+(ya + rd/np.sqrt(dxa**2 + dya**2)*dxa)*np.cos(-phis/(n-1) - np.pi/3/(n-1)) - e*np.sin(phis+np.pi/3)
ehypocycloidC.set_data(x,y)
edotC.set_data(x[0], y[0])
axcolor = 'lightgoldenrodyellow'
ax_fm = plt.axes([0.25, 0.27, 0.5, 0.02], facecolor=axcolor)
ax_Rm = plt.axes([0.25, 0.24, 0.5, 0.02], facecolor=axcolor)
ax_n = plt.axes([0.25, 0.21, 0.5, 0.02], facecolor=axcolor)
ax_Rd = plt.axes([0.25, 0.18, 0.5, 0.02], facecolor=axcolor)
ax_rd = plt.axes([0.25, 0.15, 0.5, 0.02], facecolor=axcolor)
ax_e = plt.axes([0.25, 0.12, 0.5, 0.02], facecolor=axcolor)
ax_N = plt.axes([0.25, 0.09, 0.5, 0.02], facecolor=axcolor)
ax_d = plt.axes([0.25, 0.06, 0.5, 0.02], facecolor=axcolor)
ax_D = plt.axes([0.25, 0.03, 0.5, 0.02], facecolor=axcolor)
sli_fm = Slider(ax_fm, 'fm', 10, 100, valinit=50, valstep=delta)
sli_Rm = Slider(ax_Rm, 'Rm', 1, 10, valinit=5, valstep=delta)
sli_n = Slider(ax_n, 'n', 2, 10, valinit=6, valstep=delta)
sli_Rd = Slider(ax_Rd, 'Rd', 1, 40, valinit=20, valstep=delta)
sli_rd = Slider(ax_rd, 'rd', 1, 10, valinit=5, valstep=delta)
sli_e = Slider(ax_e, 'e', 0.1, 10, valinit=2, valstep=delta/10)
sli_N = Slider(ax_N, 'N', 3, 40, valinit=10, valstep=delta)
sli_d = Slider(ax_d, 'd', 2, 20, valinit=10,valstep=delta)
sli_D = Slider(ax_D, 'D', 5, 100, valinit=80,valstep=delta)
def update(val):
sfm = sli_Rm.val
sRm = sli_Rm.val
sRd = sli_Rd.val
sn = sli_n.val
srd = sli_rd.val
se = sli_e.val
sN = sli_N.val
sd = sli_d.val
sD = sli_D.val
ax.set_xlim(-1.2*0.5*sD,1.2*0.5*sD)
ax.set_ylim(-1.2*0.5*sD,1.2*0.5*sD)
sli_fm.on_changed(update)
sli_Rm.on_changed(update)
sli_Rd.on_changed(update)
sli_n.on_changed(update)
sli_rd.on_changed(update)
sli_e.on_changed(update)
sli_N.on_changed(update)
sli_d.on_changed(update)
sli_D.on_changed(update)
resetax = plt.axes([0.85, 0.001, 0.1, 0.04])
button = Button(resetax, 'Reset', color=axcolor, hovercolor='0.975')
def reset(event):
sli_fm.reset()
sli_Rm.reset()
sli_n.reset()
sli_rd.reset()
sli_Rd.reset()
sli_e.reset()
sli_N.reset()
sli_d.reset()
sli_D.reset()
button.on_clicked(reset)
def animate(frame):
sfm = sli_fm.val
sRm = sli_Rm.val
sRd = sli_Rd.val
sn = sli_n.val
srd = sli_rd.val
se = sli_e.val
sN = sli_N.val
sd = sli_d.val
sD = sli_D.val
frame = frame+1
phi = 2*np.pi*frame/sfm
draw_pin_init()
draw_inner_pin_init()
draw_inner_circleA_init()
draw_inner_circleB_init()
draw_inner_circleC_init()
pin_update(sN,sd,sD)
update_inner_pinA(se,sRm, phi)
update_inner_pinB(se,sRm, phi)
update_inner_pinC(se,sRm, phi)
inner_pin_update(sn,sN,srd,sRd,phi)
drive_pin_update(sRm)
update_inner_circleA(se,sn,sN,srd,sRd, phi)
update_inner_circleB(se,sn,sN,srd,sRd, phi)
update_inner_circleC(se,sn,sN,srd,sRd, phi)
update_ehypocycloidA(se,sN,sD,sd, phi)
update_ehypocycloidB(se,sN,sD,sd, phi)
update_ehypocycloidC(se,sN,sD,sd, phi)
fig.canvas.draw_idle()
ani = animation.FuncAnimation(fig, animate,frames=sli_fm.val*(sli_N.val-1), interval=150)
dpi=100
plt.show()