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"""modelsimp_array_test.py - test model reduction functions

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

"""

import numpy as np

import pytest

from control import StateSpace, forced_response, tf, rss, c2d

from control.exception import ControlMIMONotImplemented

from control.tests.conftest import slycotonly, matarrayin

from control.modelsimp import balred, hsvd, markov, modred

class TestModelsimp:

"""Test model reduction functions"""

@slycotonly

def testHSVD(self, matarrayout, matarrayin):

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

B = matarrayin([[5.], [7.]])

C = matarrayin([[6., 8.]])

D = matarrayin([[9.]])

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

hsv = hsvd(sys)

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

np.testing.assert_array_almost_equal(hsv, hsvtrue)

# test for correct return type: ALWAYS return ndarray, even when

# use_numpy_matrix(True) was used

assert isinstance(hsv, np.ndarray)

assert not isinstance(hsv, np.matrix)

def testMarkovSignature(self, matarrayout, matarrayin):

U = matarrayin([[1., 1., 1., 1., 1.]])

Y = U

m = 3

H = markov(Y, U, m, transpose=False)

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

np.testing.assert_array_almost_equal(H, Htrue)

# Make sure that transposed data also works

H = markov(np.transpose(Y), np.transpose(U), m, transpose=True)

np.testing.assert_array_almost_equal(H, np.transpose(Htrue))

# Generate Markov parameters without any arguments

H = markov(Y, U, m)

np.testing.assert_array_almost_equal(H, Htrue)

# Test example from docstring

T = np.linspace(0, 10, 100)

U = np.ones((1, 100))

T, Y = forced_response(tf([1], [1, 0.5], True), T, U)

H = markov(Y, U, 3, transpose=False)

# Test example from issue #395

inp = np.array([1, 2])

outp = np.array([2, 4])

mrk = markov(outp, inp, 1, transpose=False)

# Make sure MIMO generates an error

U = np.ones((2, 100)) # 2 inputs (Y unchanged, with 1 output)

with pytest.raises(ControlMIMONotImplemented):

markov(Y, U, m)

# Make sure markov() returns the right answer

@pytest.mark.parametrize("k, m, n",

[(2, 2, 2),

(2, 5, 5),

(5, 2, 2),

(5, 5, 5),

(5, 10, 10)])

def testMarkovResults(self, k, m, n):

#

# Test over a range of parameters

#

# k = order of the system

# m = number of Markov parameters

# n = size of the data vector

#

# Values *should* match exactly for n = m, otherewise you get a

# close match but errors due to the assumption that C A^k B =

# 0 for k > m-2 (see modelsimp.py).

#

# Generate stable continuous time system

Hc = rss(k, 1, 1)

# Choose sampling time based on fastest time constant / 10

w, _ = np.linalg.eig(Hc.A)

Ts = np.min(-np.real(w)) / 10.

# Convert to a discrete time system via sampling

Hd = c2d(Hc, Ts, 'zoh')

# Compute the Markov parameters from state space

Mtrue = np.hstack([Hd.D] + [

Hd.C @ np.linalg.matrix_power(Hd.A, i) @ Hd.B

for i in range(m-1)])

# Generate input/output data

T = np.array(range(n)) * Ts

U = np.cos(T) + np.sin(T/np.pi)

_, Y = forced_response(Hd, T, U, squeeze=True)

Mcomp = markov(Y, U, m)

# Compare to results from markov()

# experimentally determined probability to get non matching results

# with rtot=1e-6 and atol=1e-8 due to numerical errors

# for k=5, m=n=10: 0.015 %

np.testing.assert_allclose(Mtrue, Mcomp, rtol=1e-6, atol=1e-8)

def testModredMatchDC(self, matarrayin):

#balanced realization computed in matlab for the transfer function:

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

A = matarrayin(

[[-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 = matarrayin([[-0.9057], [-0.4068], [-0.3263], [-0.3474]])

C = matarrayin([[-0.9057, -0.4068, 0.3263, -0.3474]])

D = matarrayin([[0.]])

sys = StateSpace(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, matarrayin):

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

A = matarrayin(

[[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 = matarrayin([[1.0, 1.0], [2.0, 2.0], [3.0, 3.0], [4.0, 4.0]])

C = matarrayin([[1.0, 2.0, 3.0, 4.0], [1.0, 2.0, 3.0, 4.0]])

D = matarrayin([[0.0, 0.0], [0.0, 0.0]])

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

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

def testModredTruncate(self, matarrayin):

#balanced realization computed in matlab for the transfer function:

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

A = matarrayin(

[[-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 = matarrayin([[-0.9057], [-0.4068], [-0.3263], [-0.3474]])

C = matarrayin([[-0.9057, -0.4068, 0.3263, -0.3474]])

D = matarrayin([[0.]])

sys = StateSpace(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)

@slycotonly

def testBalredTruncate(self, matarrayin):

# controlable canonical realization computed in matlab for the transfer

# function:

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

A = matarrayin(

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

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

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

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

B = matarrayin([[2.], [0.], [0.], [0.]])

C = matarrayin([[0.5, 0.6875, 0.7031, 0.5]])

D = matarrayin([[0.]])

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

orders = 2

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

Ar, Br, Cr, Dr = rsys.A, rsys.B, rsys.C, rsys.D

# Result from MATLAB

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.]])

# Look for possible changes in state in slycot

T1 = np.array([[1, 0], [0, -1]])

T2 = np.array([[-1, 0], [0, 1]])

T3 = np.array([[0, 1], [1, 0]])

for T in (T1, T2, T3):

if np.allclose(T @ Ar @ T, Artrue, atol=1e-2, rtol=1e-2):

# Apply a similarity transformation

Ar, Br, Cr = T @ Ar @ T, T @ Br, Cr @ T

break

# Make sure we got the correct answer

np.testing.assert_array_almost_equal(Ar, Artrue, decimal=2)

np.testing.assert_array_almost_equal(Br, Brtrue, decimal=4)

np.testing.assert_array_almost_equal(Cr, Crtrue, decimal=4)

np.testing.assert_array_almost_equal(Dr, Drtrue, decimal=4)

@slycotonly

def testBalredMatchDC(self, matarrayin):

# controlable canonical realization computed in matlab for the transfer

# function:

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

A = matarrayin(

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

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

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

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

B = matarrayin([[2.], [0.], [0.], [0.]])

C = matarrayin([[0.5, 0.6875, 0.7031, 0.5]])

D = matarrayin([[0.]])

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

orders = 2

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

Ar, Br, Cr, Dr = rsys.A, rsys.B, rsys.C, rsys.D

# Result from MATLAB

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]])

# Look for possible changes in state in slycot

T1 = np.array([[1, 0], [0, -1]])

T2 = np.array([[-1, 0], [0, 1]])

T3 = np.array([[0, 1], [1, 0]])

for T in (T1, T2, T3):

if np.allclose(T @ Ar @ T, Artrue, atol=1e-2, rtol=1e-2):

# Apply a similarity transformation

Ar, Br, Cr = T @ Ar @ T, T @ Br, Cr @ T

break

# Make sure we got the correct answer

np.testing.assert_array_almost_equal(Ar, Artrue, decimal=2)

np.testing.assert_array_almost_equal(Br, Brtrue, decimal=4)

np.testing.assert_array_almost_equal(Cr, Crtrue, decimal=4)

np.testing.assert_array_almost_equal(Dr, Drtrue, decimal=4)