As with the binder example activating this page will connect to
the public my binder service at https://mybinder.org service.
Although, here we launch from a different repo and create an ipywidgets based
plot using ipympl
In addition, ipympl in turn requires font-awesome fonts to be
loaded on the page. Other ipywidgets based libraries and custom widgets may
also require additional fonts, css or libraries to be side loaded.
A simple widgets example.
# borrowed from https://jupyterlite.readthedocs.io/en/latest/_static/lab/index.html
from ipywidgets import interact, IntSlider
from IPython.display import Markdown, display
slider = IntSlider()
@interact(cookies=slider)
def cookies(cookies=slider.value, calories=(0, 150)):
total_calories = calories * cookies
if cookies:
display(
Markdown(
f"If each cookie contains _{calories} calories_, \
_{cookies} cookies_ contain **{total_calories} calories**!"
)
)
else:
display(Markdown(f"No cookies!"))
if total_calories > 2000:
display(Markdown(f"> Maybe that's too many cookies..."))
import numpy as np
import matplotlib.pyplot as plt
%matplotlib inline
from ipywidgets import interact, interactive
from IPython.display import clear_output, display, HTML
import numpy as np
from scipy import integrate
from matplotlib import pyplot as plt
from mpl_toolkits.mplot3d import Axes3D
from matplotlib.colors import cnames
from matplotlib import animation
def solve_lorenz(
N=10, angle=0.0, max_time=4.0,
sigma=10.0, beta=8./3, rho=28.0):
fig = plt.figure()
ax = fig.add_axes([0, 0, 1, 1], projection='3d')
ax.axis('off')
# prepare the axes limits
ax.set_xlim((-25, 25))
ax.set_ylim((-35, 35))
ax.set_zlim((5, 55))
def lorenz_deriv(x_y_z, t0, sigma=sigma, beta=beta, rho=rho):
"""Compute the time-derivative of a Lorenz system."""
x, y, z = x_y_z
return [sigma * (y - x), x * (rho - z) - y, x * y - beta * z]
# Choose random starting points, uniformly distributed from -15 to 15
np.random.seed(1)
x0 = -15 + 30 * np.random.random((N, 3))
# Solve for the trajectories
t = np.linspace(0, max_time, int(250*max_time))
x_t = np.asarray([integrate.odeint(lorenz_deriv, x0i, t)
for x0i in x0])
# choose a different color for each trajectory
colors = plt.cm.viridis(np.linspace(0, 1, N))
for i in range(N):
x, y, z = x_t[i,:,:].T
lines = ax.plot(x, y, z, '-', c=colors[i])
plt.setp(lines, linewidth=2)
ax.view_init(30, angle)
plt.show()
return t, x_t
w = interactive(solve_lorenz, angle=(0.,360.), max_time=(0.1, 4.0),
N=(0,50), sigma=(0.0,50.0), rho=(0.0,50.0))
display(w)