This expression
res[i] = c1*(s[i] + s[i-1])/2 + c2*res[i-1] + c3*res[i-2]
says that res
is the output of a linear filter (or ARMA process) with input s
. Several libraries have functions for computing this. Here's how you can use the scipy function scipy.signal.lfilter
.
From inspection of the recurrence relation, we get the coefficients of the numerator (b
) and denominator (a
) of the filter's transfer function:
b = c1 * np.array([0.5, 0.5])
a = np.array([1, -c2, -c3])
We'll also need an appropriate initial condition for lfilter
to handle res[:2] == [0, k]
. For this, we use scipy.signal.lfiltic
:
zi = lfiltic(b, a, [k, 0], x=s[1::-1])
In the simplest case, one would call lfilter
like this:
y = lfilter(b, a, s)
With an initial condition zi
, we use:
y, zo = lfilter(b, a, s, zi=zi)
However, to exactly match the calculation provided in the question, we need the output y
to start with [0, k]
. So we'll allocate an array y
, initialize the first two elements with [0, k]
, and assign the output of lfilter
to y[2:]
:
y = np.empty_like(s)
y[:2] = [0, k]
y[2:], zo = lfilter(b, a, s[2:], zi=zi)
Here's a complete script with the original loop and with lfilter
:
import numpy as np
from scipy.signal import lfilter, lfiltic
c1 = 0.125
c2 = 0.5
c3 = 0.25
np.random.seed(123)
s = np.random.rand(8)
k = 3.0
# Original version (edited lightly)
res = np.zeros_like(s)
res[1] = k # k is a constant
for i in range(2, len(s)):
res[i] = c1*(s[i] + s[i-1])/2 + c2*res[i-1] + c3*res[i-2]
# Using scipy.signal.lfilter
# Coefficients of the filter's transfer function.
b = c1 * np.array([0.5, 0.5])
a = np.array([1, -c2, -c3])
# Create the initial condition of the filter such that
# y[:2] == [0, k]
zi = lfiltic(b, a, [k, 0], x=s[1::-1])
y = np.empty_like(s)
y[:2] = [0, k]
y[2:], zo = lfilter(b, a, s[2:], zi=zi)
np.set_printoptions(precision=5)
print "res:", res
print "y: ", y
The output is:
res: [ 0. 3. 1.53206 1.56467 1.24477 1.08496 0.94142 0.84605]
y: [ 0. 3. 1.53206 1.56467 1.24477 1.08496 0.94142 0.84605]
lfilter
accepts an axis
argument, so you can filter an array of signals with a single call. lfiltic
does not have an axis
argument, so setting up the initial conditions requires a loop. The following script shows an example.
import numpy as np
from scipy.signal import lfilter, lfiltic
import matplotlib.pyplot as plt
# Parameters
c1 = 0.2
c2 = 1.1
c3 = -0.5
k = 1
# Create an array of signals for the demonstration.
np.random.seed(123)
nsamples = 50
nsignals = 4
s = np.random.randn(nsamples, nsignals)
# Coefficients of the filter's transfer function.
b = c1 * np.array([0.5, 0.5])
a = np.array([1, -c2, -c3])
# Create the initial condition of the filter for each signal
# such that
# y[:2] == [0, k]
# We need a loop here, because lfiltic is not vectorized.
zi = np.empty((2, nsignals))
for i in range(nsignals):
zi[:, i] = lfiltic(b, a, [k, 0], x=s[1::-1, i])
# Create the filtered signals.
y = np.empty_like(s)
y[:2, :] = np.array([0, k]).reshape(-1, 1)
y[2:, :], zo = lfilter(b, a, s[2:], zi=zi, axis=0)
# Plot the filtered signals.
plt.plot(y, linewidth=2, alpha=0.6)
ptp = y.ptp()
plt.ylim(y.min() - 0.05*ptp, y.max() + 0.05*ptp)
plt.grid(True)
plt.show()
Plot: