Note
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Create a spectral modelΒΆ
This use case illustrates how the User can define his own density spectral function from parametric models. The library allows it thanks to the object UserDefinedSpectralModel defined from:
a frequency grid with step , stored in the object RegularGrid,
a collection of hermitian matrices stored in the object HermitianMatrixCollection, which are the images of each point of the frequency grid through the density spectral function.
The library builds a constant piecewise function on , where the intervals where the density spectral function is constant are centered on the points of the frequency grid, of length . Then, it is possible to evaluate the spectral density function for a given frequency thanks to the method [computeSpectralDensity]{}: if the frequency is not inside the interval , an exception is thrown. Otherwise, it returns the hermitian matrix of the subinterval of that contains the given frequency.
In the following script, we illustrate how to create a modified low pass model of dimension with exponential decrease defined by: where
Frequency value should be positive,
for , the spectral density function is constant: ,
for , the spectral density function is equal to .
The frequency grid is with Hz. The figure draws the spectral density.
import openturns as ot
import openturns.viewer as viewer
from matplotlib import pylab as plt
import math as m
ot.Log.Show(ot.Log.NONE)
Create the frequency grid:
fmin = 0.1
df = 0.5
N = int((10.0 - fmin) / df)
fgrid = ot.RegularGrid(fmin, df, N)
Define the spectral function:
def s(f):
if f <= 5.0:
return 1.0
else:
x = f - 5.0
return m.exp(-2.0 * x * x)
Create the collection of HermitianMatrix:
coll = ot.HermitianMatrixCollection()
for k in range(N):
frequency = fgrid.getValue(k)
matrix = ot.HermitianMatrix(1)
matrix[0, 0] = s(frequency)
coll.add(matrix)
Create the spectral model:
spectralModel = ot.UserDefinedSpectralModel(fgrid, coll)
# Get the spectral density function computed at first frequency values
firstFrequency = fgrid.getStart()
frequencyStep = fgrid.getStep()
firstHermitian = spectralModel(firstFrequency)
# Get the spectral function at frequency + 0.3 * frequencyStep
spectralModel(frequency + 0.3 * frequencyStep)
Draw the spectral density
# Create the curve of the spectral function
x = ot.Sample(N, 2)
for k in range(N):
frequency = fgrid.getValue(k)
x[k, 0] = frequency
value = spectralModel(frequency)
x[k, 1] = value[0, 0].real
# Create the graph
graph = ot.Graph(
"Spectral user-defined model", "Frequency", "Spectral density value", True
)
curve = ot.Curve(x, "UserSpectral")
graph.add(curve)
graph.setLegendPosition("topright")
view = viewer.View(graph)
plt.show()
Total running time of the script: ( 0 minutes 0.064 seconds)