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#!/usr/bin/env python

#

# modelsimp_test.py - test model reduction functions

# RMM, 30 Mar 2011 (based on TestModelSimp from v0.4a)

import unittest

import numpy as np

import warnings

import control

from control.modelsimp import *

from control.matlab import *

from control.exception import slycot_check

class TestModelsimp(unittest.TestCase):

def setUp(self):

# Use array instead of matrix (and save old value to restore at end)

control.use_numpy_matrix(False)

@unittest.skipIf(not slycot_check(), "slycot not installed")

def testHSVD(self):

A = np.array([[1., -2.], [3., -4.]])

B = np.array([[5.], [7.]])

C = np.array([[6., 8.]])

D = np.array([[9.]])

sys = ss(A,B,C,D)

hsv = hsvd(sys)

hsvtrue = np.array([24.42686, 0.5731395]) # from MATLAB

np.testing.assert_array_almost_equal(hsv, hsvtrue)

# Make sure default type values are correct

self.assertTrue(isinstance(hsv, np.ndarray))

self.assertFalse(isinstance(hsv, np.matrix))

# Check that using numpy.matrix does *not* affect answer

with warnings.catch_warnings(record=True) as w:

control.use_numpy_matrix(True)

self.assertTrue(issubclass(w[-1].category, UserWarning))

# Redefine the system (using np.matrix for storage)

sys = ss(A, B, C, D)

# Compute the Hankel singular value decomposition

hsv = hsvd(sys)

# Make sure that return type is correct

self.assertTrue(isinstance(hsv, np.ndarray))

self.assertFalse(isinstance(hsv, np.matrix))

# Go back to using the normal np.array representation

control.use_numpy_matrix(False)

def testMarkov(self):

U = np.array([[1.], [1.], [1.], [1.], [1.]])

Y = U

M = 3

H = markov(Y,U,M)

Htrue = np.array([[1.], [0.], [0.]])

np.testing.assert_array_almost_equal( H, Htrue )

def testModredMatchDC(self):

#balanced realization computed in matlab for the transfer function:

# num = [1 11 45 32], den = [1 15 60 200 60]

A = np.array(

[[-1.958, -1.194, 1.824, -1.464],

[-1.194, -0.8344, 2.563, -1.351],

[-1.824, -2.563, -1.124, 2.704],

[-1.464, -1.351, -2.704, -11.08]])

B = np.array([[-0.9057], [-0.4068], [-0.3263], [-0.3474]])

C = np.array([[-0.9057, -0.4068, 0.3263, -0.3474]])

D = np.array([[0.]])

sys = ss(A,B,C,D)

rsys = modred(sys,[2, 3],'matchdc')

Artrue = np.array([[-4.431, -4.552], [-4.552, -5.361]])

Brtrue = np.array([[-1.362], [-1.031]])

Crtrue = np.array([[-1.362, -1.031]])

Drtrue = np.array([[-0.08384]])

np.testing.assert_array_almost_equal(rsys.A, Artrue,decimal=3)

np.testing.assert_array_almost_equal(rsys.B, Brtrue,decimal=3)

np.testing.assert_array_almost_equal(rsys.C, Crtrue,decimal=3)

np.testing.assert_array_almost_equal(rsys.D, Drtrue,decimal=2)

def testModredUnstable(self):

# Check if an error is thrown when an unstable system is given

A = np.array(

[[4.5418, 3.3999, 5.0342, 4.3808],

[0.3890, 0.3599, 0.4195, 0.1760],

[-4.2117, -3.2395, -4.6760, -4.2180],

[0.0052, 0.0429, 0.0155, 0.2743]])

B = np.array([[1.0, 1.0], [2.0, 2.0], [3.0, 3.0], [4.0, 4.0]])

C = np.array([[1.0, 2.0, 3.0, 4.0], [1.0, 2.0, 3.0, 4.0]])

D = np.array([[0.0, 0.0], [0.0, 0.0]])

sys = ss(A,B,C,D)

np.testing.assert_raises(ValueError, modred, sys, [2, 3])

def testModredTruncate(self):

#balanced realization computed in matlab for the transfer function:

# num = [1 11 45 32], den = [1 15 60 200 60]

A = np.array(

[[-1.958, -1.194, 1.824, -1.464],

[-1.194, -0.8344, 2.563, -1.351],

[-1.824, -2.563, -1.124, 2.704],

[-1.464, -1.351, -2.704, -11.08]])

B = np.array([[-0.9057], [-0.4068], [-0.3263], [-0.3474]])

C = np.array([[-0.9057, -0.4068, 0.3263, -0.3474]])

D = np.array([[0.]])

sys = ss(A,B,C,D)

rsys = modred(sys,[2, 3],'truncate')

Artrue = np.array([[-1.958, -1.194], [-1.194, -0.8344]])

Brtrue = np.array([[-0.9057], [-0.4068]])

Crtrue = np.array([[-0.9057, -0.4068]])

Drtrue = np.array([[0.]])

np.testing.assert_array_almost_equal(rsys.A, Artrue)

np.testing.assert_array_almost_equal(rsys.B, Brtrue)

np.testing.assert_array_almost_equal(rsys.C, Crtrue)

np.testing.assert_array_almost_equal(rsys.D, Drtrue)

@unittest.skipIf(not slycot_check(), "slycot not installed")

def testBalredTruncate(self):

#controlable canonical realization computed in matlab for the transfer function:

# num = [1 11 45 32], den = [1 15 60 200 60]

A = np.array(

[[-15., -7.5, -6.25, -1.875],

[8., 0., 0., 0.],

[0., 4., 0., 0.],

[0., 0., 1., 0.]])

B = np.array([[2.], [0.], [0.], [0.]])

C = np.array([[0.5, 0.6875, 0.7031, 0.5]])

D = np.array([[0.]])

sys = ss(A,B,C,D)

orders = 2

rsys = balred(sys,orders,method='truncate')

Artrue = np.array([[-1.958, -1.194], [-1.194, -0.8344]])

Brtrue = np.array([[0.9057], [0.4068]])

Crtrue = np.array([[0.9057, 0.4068]])

Drtrue = np.array([[0.]])

np.testing.assert_array_almost_equal(rsys.A, Artrue,decimal=2)

np.testing.assert_array_almost_equal(rsys.B, Brtrue,decimal=4)

np.testing.assert_array_almost_equal(rsys.C, Crtrue,decimal=4)

np.testing.assert_array_almost_equal(rsys.D, Drtrue,decimal=4)

@unittest.skipIf(not slycot_check(), "slycot not installed")

def testBalredMatchDC(self):

#controlable canonical realization computed in matlab for the transfer function:

# num = [1 11 45 32], den = [1 15 60 200 60]

A = np.array(

[[-15., -7.5, -6.25, -1.875],

[8., 0., 0., 0.],

[0., 4., 0., 0.],

[0., 0., 1., 0.]])

B = np.array([[2.], [0.], [0.], [0.]])

C = np.array([[0.5, 0.6875, 0.7031, 0.5]])

D = np.array([[0.]])

sys = ss(A,B,C,D)

orders = 2

rsys = balred(sys,orders,method='matchdc')

Artrue = np.array(

[[-4.43094773, -4.55232904],

[-4.55232904, -5.36195206]])

Brtrue = np.array([[1.36235673], [1.03114388]])

Crtrue = np.array([[1.36235673, 1.03114388]])

Drtrue = np.array([[-0.08383902]])

np.testing.assert_array_almost_equal(rsys.A, Artrue,decimal=2)

np.testing.assert_array_almost_equal(rsys.B, Brtrue,decimal=4)

np.testing.assert_array_almost_equal(rsys.C, Crtrue,decimal=4)

np.testing.assert_array_almost_equal(rsys.D, Drtrue,decimal=4)

def tearDown(self):

# Reset configuration variables to their original settings

control.config.reset_defaults()

if __name__ == '__main__':

unittest.main()