The clamp function is clamp(x, min, max) = min if x < min, max if x > max, else x
I need a function that behaves like the clamp function, but is smooth (i.e. has a continuous derivative).
The clamp function is clamp(x, min, max) = min if x < min, max if x > max, else x
I need a function that behaves like the clamp function, but is smooth (i.e. has a continuous derivative).
What you are looking for is something like the Smoothstep function, which has a free parameter N
, giving the "smoothness", i.e. how many derivatives should be continuous. It is defined as such:
This is used in several libraries and can be implemented in numpy as
import numpy as np
from scipy.special import comb
def smoothstep(x, x_min=0, x_max=1, N=1):
x = np.clip((x - x_min) / (x_max - x_min), 0, 1)
result = 0
for n in range(0, N + 1):
result += comb(N + n, n) * comb(2 * N + 1, N - n) * (-x) ** n
result *= x ** (N + 1)
return result
It reduces to the regular clamp function given N=0
(0 times differentiable), and gives increasing smoothness as you increase N. You can visualize it like this:
import matplotlib.pyplot as plt
x = np.linspace(-0.5, 1.5, 1000)
for N in range(0, 5):
y = smoothstep(x, N=N)
plt.plot(x, y, label=str(N))
plt.legend()
which gives this result:
Normal clamp:
np.clip(x, mi, mx)
Smoothclamp (guaranteed to agree with normal clamp for x < min and x > max):
def smoothclamp(x, mi, mx): return mi + (mx-mi)*(lambda t: np.where(t < 0 , 0, np.where( t <= 1 , 3*t**2-2*t**3, 1 ) ) )( (x-mi)/(mx-mi) )
Sigmoid (Approximates clamp, never smaller than min, never larger than max)
def sigmoid(x,mi, mx): return mi + (mx-mi)*(lambda t: (1+200**(-t+0.5))**(-1) )( (x-mi)/(mx-mi) )
For some purposes Sigmoid will be better than Smoothclamp because Sigmoid is an invertible function - no information is lost.
For other purposes, you may need to be certain that f(x) = xmax for all x > xmax - in that case Smoothclamp is better. Also, as mentioned in another answer, there is a whole family of Smoothclamp functions, though the one given here is adequate for my purposes (no special properties other than a smooth derivative needed)
Plot them:
import numpy as np
import matplotlib.pyplot as plt
fig, ax = plt.subplots(1, 1)
x = np.linspace(-4,7,1000)
ax.plot(x, np.clip(x, -1, 4),'k-', lw=2, alpha=0.8, label='clamp')
ax.plot(x, smoothclamp(x, -1, 4),'g-', lw=3, alpha=0.5, label='smoothclamp')
ax.plot(x, sigmoid(x, -1, 4),'b-', lw=3, alpha=0.5, label='sigmoid')
plt.legend(loc='upper left')
plt.show()
Also of potential use is the arithmetic mean of these two:
def clampoid(x, mi, mx): return mi + (mx-mi)*(lambda t: 0.5*(1+200**(-t+0.5))**(-1) + 0.5*np.where(t < 0 , 0, np.where( t <= 1 , 3*t**2-2*t**3, 1 ) ) )( (x-mi)/(mx-mi) )
import numpy as np; a = np.random.rand(10**6); %timeit max(a); %timeit np.max(a);
- on my PC the vectorized Numpy function took 127 times less time ;-)
Jul 18, 2017 at 13:20
As an option, if you want to make sure that there is a correspondence with the clamp function, you can convolve the normal clamp function with a smooth bell-like function such as Lorentzian or Gaussian.
This will guarantee the correspondence between the normal clamp function and its smoothed version. The smoothness itself will be defined by the underlying smooth function you choose to use in the convolution.