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	"""
	ltisys -- a collection of functions to convert linear time invariant systems
	from one representation to another.
	"""
	import numpy
	import numpy as np
	from numpy import (r_, eye, atleast_2d, poly, dot,
	asarray, prod, zeros, array, outer)
	from scipy import linalg

	from ._filter_design import tf2zpk, zpk2tf, normalize


	__all__ = ['tf2ss', 'abcd_normalize', 'ss2tf', 'zpk2ss', 'ss2zpk',
	'cont2discrete']


	def tf2ss(num, den):
	r"""Transfer function to state-space representation.

	Parameters
	----------
	num, den : array_like
	Sequences representing the coefficients of the numerator and
	denominator polynomials, in order of descending degree. The
	denominator needs to be at least as long as the numerator.

	Returns
	-------
	A, B, C, D : ndarray
	State space representation of the system, in controller canonical
	form.

	Examples
	--------
	Convert the transfer function:

	.. math:: H(s) = \frac{s^2 + 3s + 3}{s^2 + 2s + 1}

	>>> num = [1, 3, 3]
	>>> den = [1, 2, 1]

	to the state-space representation:

	.. math::

	\dot{\textbf{x}}(t) =
	\begin{bmatrix} -2 & -1 \\ 1 & 0 \end{bmatrix} \textbf{x}(t) +
	\begin{bmatrix} 1 \\ 0 \end{bmatrix} \textbf{u}(t) \\

	\textbf{y}(t) = \begin{bmatrix} 1 & 2 \end{bmatrix} \textbf{x}(t) +
	\begin{bmatrix} 1 \end{bmatrix} \textbf{u}(t)

	>>> from scipy.signal import tf2ss
	>>> A, B, C, D = tf2ss(num, den)
	>>> A
	array([[-2., -1.],
	[ 1., 0.]])
	>>> B
	array([[ 1.],
	[ 0.]])
	>>> C
	array([[ 1., 2.]])
	>>> D
	array([[ 1.]])
	"""
	# Controller canonical state-space representation.
	# if M+1 = len(num) and K+1 = len(den) then we must have M <= K
	# states are found by asserting that X(s) = U(s) / D(s)
	# then Y(s) = N(s) * X(s)
	#
	# A, B, C, and D follow quite naturally.
	#
	num, den = normalize(num, den) # Strips zeros, checks arrays
	nn = len(num.shape)
	if nn == 1:
	num = asarray([num], num.dtype)
	M = num.shape[1]
	K = len(den)
	if M > K:
	msg = "Improper transfer function. `num` is longer than `den`."
	raise ValueError(msg)
	if M == 0 or K == 0: # Null system
	return (array([], float), array([], float), array([], float),
	array([], float))

	# pad numerator to have same number of columns has denominator
	num = np.hstack((np.zeros((num.shape[0], K - M), dtype=num.dtype), num))

	if num.shape[-1] > 0:
	D = atleast_2d(num[:, 0])

	else:
	# We don't assign it an empty array because this system
	# is not 'null'. It just doesn't have a non-zero D
	# matrix. Thus, it should have a non-zero shape so that
	# it can be operated on by functions like 'ss2tf'
	D = array([[0]], float)

	if K == 1:
	D = D.reshape(num.shape)

	return (zeros((1, 1)), zeros((1, D.shape[1])),
	zeros((D.shape[0], 1)), D)

	frow = -array([den[1:]])
	A = r_[frow, eye(K - 2, K - 1)]
	B = eye(K - 1, 1)
	C = num[:, 1:] - outer(num[:, 0], den[1:])
	D = D.reshape((C.shape[0], B.shape[1]))

	return A, B, C, D


	def _none_to_empty_2d(arg):
	if arg is None:
	return zeros((0, 0))
	else:
	return arg


	def _atleast_2d_or_none(arg):
	if arg is not None:
	return atleast_2d(arg)


	def _shape_or_none(M):
	if M is not None:
	return M.shape
	else:
	return (None,) * 2


	def _choice_not_none(*args):
	for arg in args:
	if arg is not None:
	return arg


	def _restore(M, shape):
	if M.shape == (0, 0):
	return zeros(shape)
	else:
	if M.shape != shape:
	raise ValueError("The input arrays have incompatible shapes.")
	return M


	def abcd_normalize(A=None, B=None, C=None, D=None):
	"""Check state-space matrices and ensure they are 2-D.

	If enough information on the system is provided, that is, enough
	properly-shaped arrays are passed to the function, the missing ones
	are built from this information, ensuring the correct number of
	rows and columns. Otherwise a ValueError is raised.

	Parameters
	----------
	A, B, C, D : array_like, optional
	State-space matrices. All of them are None (missing) by default.
	See `ss2tf` for format.

	Returns
	-------
	A, B, C, D : array
	Properly shaped state-space matrices.

	Raises
	------
	ValueError
	If not enough information on the system was provided.

	"""
	A, B, C, D = map(_atleast_2d_or_none, (A, B, C, D))

	MA, NA = _shape_or_none(A)
	MB, NB = _shape_or_none(B)
	MC, NC = _shape_or_none(C)
	MD, ND = _shape_or_none(D)

	p = _choice_not_none(MA, MB, NC)
	q = _choice_not_none(NB, ND)
	r = _choice_not_none(MC, MD)
	if p is None or q is None or r is None:
	raise ValueError("Not enough information on the system.")

	A, B, C, D = map(_none_to_empty_2d, (A, B, C, D))
	A = _restore(A, (p, p))
	B = _restore(B, (p, q))
	C = _restore(C, (r, p))
	D = _restore(D, (r, q))

	return A, B, C, D


	def ss2tf(A, B, C, D, input=0):
	r"""State-space to transfer function.

	A, B, C, D defines a linear state-space system with `p` inputs,
	`q` outputs, and `n` state variables.

	Parameters
	----------
	A : array_like
	State (or system) matrix of shape ``(n, n)``
	B : array_like
	Input matrix of shape ``(n, p)``
	C : array_like
	Output matrix of shape ``(q, n)``
	D : array_like
	Feedthrough (or feedforward) matrix of shape ``(q, p)``
	input : int, optional
	For multiple-input systems, the index of the input to use.

	Returns
	-------
	num : 2-D ndarray
	Numerator(s) of the resulting transfer function(s). `num` has one row
	for each of the system's outputs. Each row is a sequence representation
	of the numerator polynomial.
	den : 1-D ndarray
	Denominator of the resulting transfer function(s). `den` is a sequence
	representation of the denominator polynomial.

	Examples
	--------
	Convert the state-space representation:

	.. math::

	\dot{\textbf{x}}(t) =
	\begin{bmatrix} -2 & -1 \\ 1 & 0 \end{bmatrix} \textbf{x}(t) +
	\begin{bmatrix} 1 \\ 0 \end{bmatrix} \textbf{u}(t) \\

	\textbf{y}(t) = \begin{bmatrix} 1 & 2 \end{bmatrix} \textbf{x}(t) +
	\begin{bmatrix} 1 \end{bmatrix} \textbf{u}(t)

	>>> A = [[-2, -1], [1, 0]]
	>>> B = [[1], [0]] # 2-D column vector
	>>> C = [[1, 2]] # 2-D row vector
	>>> D = 1

	to the transfer function:

	.. math:: H(s) = \frac{s^2 + 3s + 3}{s^2 + 2s + 1}

	>>> from scipy.signal import ss2tf
	>>> ss2tf(A, B, C, D)
	(array([[1., 3., 3.]]), array([ 1., 2., 1.]))
	"""
	# transfer function is C (sI - A)**(-1) B + D

	# Check consistency and make them all rank-2 arrays
	A, B, C, D = abcd_normalize(A, B, C, D)

	nout, nin = D.shape
	if input >= nin:
	raise ValueError("System does not have the input specified.")

	# make SIMO from possibly MIMO system.
	B = B[:, input:input + 1]
	D = D[:, input:input + 1]

	try:
	den = poly(A)
	except ValueError:
	den = 1

	if (prod(B.shape, axis=0) == 0) and (prod(C.shape, axis=0) == 0):
	num = numpy.ravel(D)
	if (prod(D.shape, axis=0) == 0) and (prod(A.shape, axis=0) == 0):
	den = []
	return num, den

	num_states = A.shape[0]
	type_test = A[:, 0] + B[:, 0] + C[0, :] + D + 0.0
	num = numpy.empty((nout, num_states + 1), type_test.dtype)
	for k in range(nout):
	Ck = atleast_2d(C[k, :])
	num[k] = poly(A - dot(B, Ck)) + (D[k] - 1) * den

	return num, den


	def zpk2ss(z, p, k):
	"""Zero-pole-gain representation to state-space representation

	Parameters
	----------
	z, p : sequence
	Zeros and poles.
	k : float
	System gain.

	Returns
	-------
	A, B, C, D : ndarray
	State space representation of the system, in controller canonical
	form.

	"""
	return tf2ss(*zpk2tf(z, p, k))


	def ss2zpk(A, B, C, D, input=0):
	"""State-space representation to zero-pole-gain representation.

	A, B, C, D defines a linear state-space system with `p` inputs,
	`q` outputs, and `n` state variables.

	Parameters
	----------
	A : array_like
	State (or system) matrix of shape ``(n, n)``
	B : array_like
	Input matrix of shape ``(n, p)``
	C : array_like
	Output matrix of shape ``(q, n)``
	D : array_like
	Feedthrough (or feedforward) matrix of shape ``(q, p)``
	input : int, optional
	For multiple-input systems, the index of the input to use.

	Returns
	-------
	z, p : sequence
	Zeros and poles.
	k : float
	System gain.

	"""
	return tf2zpk(*ss2tf(A, B, C, D, input=input))


	def cont2discrete(system, dt, method="zoh", alpha=None):
	"""
	Transform a continuous to a discrete state-space system.

	Parameters
	----------
	system : a tuple describing the system or an instance of `lti`
	The following gives the number of elements in the tuple and
	the interpretation:

	* 1: (instance of `lti`)
	* 2: (num, den)
	* 3: (zeros, poles, gain)
	* 4: (A, B, C, D)

	dt : float
	The discretization time step.
	method : str, optional
	Which method to use:

	* gbt: generalized bilinear transformation
	* bilinear: Tustin's approximation ("gbt" with alpha=0.5)
	* euler: Euler (or forward differencing) method ("gbt" with alpha=0)
	* backward_diff: Backwards differencing ("gbt" with alpha=1.0)
	* zoh: zero-order hold (default)
	* foh: first-order hold (versionadded: 1.3.0)
	* impulse: equivalent impulse response (versionadded: 1.3.0)

	alpha : float within [0, 1], optional
	The generalized bilinear transformation weighting parameter, which
	should only be specified with method="gbt", and is ignored otherwise

	Returns
	-------
	sysd : tuple containing the discrete system
	Based on the input type, the output will be of the form

	* (num, den, dt) for transfer function input
	* (zeros, poles, gain, dt) for zeros-poles-gain input
	* (A, B, C, D, dt) for state-space system input

	Notes
	-----
	By default, the routine uses a Zero-Order Hold (zoh) method to perform
	the transformation. Alternatively, a generalized bilinear transformation
	may be used, which includes the common Tustin's bilinear approximation,
	an Euler's method technique, or a backwards differencing technique.

	The Zero-Order Hold (zoh) method is based on [1]_, the generalized bilinear
	approximation is based on [2]_ and [3]_, the First-Order Hold (foh) method
	is based on [4]_.

	References
	----------
	.. [1] https://en.wikipedia.org/wiki/Discretization#Discretization_of_linear_state_space_models

	.. [2] http://techteach.no/publications/discretetime_signals_systems/discrete.pdf

	.. [3] G. Zhang, X. Chen, and T. Chen, Digital redesign via the generalized
	bilinear transformation, Int. J. Control, vol. 82, no. 4, pp. 741-754,
	2009.
	(https://www.mypolyuweb.hk/~magzhang/Research/ZCC09_IJC.pdf)

	.. [4] G. F. Franklin, J. D. Powell, and M. L. Workman, Digital control
	of dynamic systems, 3rd ed. Menlo Park, Calif: Addison-Wesley,
	pp. 204-206, 1998.

	Examples
	--------
	We can transform a continuous state-space system to a discrete one:

	>>> import numpy as np
	>>> import matplotlib.pyplot as plt
	>>> from scipy.signal import cont2discrete, lti, dlti, dstep

	Define a continuous state-space system.

	>>> A = np.array([[0, 1],[-10., -3]])
	>>> B = np.array([[0],[10.]])
	>>> C = np.array([[1., 0]])
	>>> D = np.array([[0.]])
	>>> l_system = lti(A, B, C, D)
	>>> t, x = l_system.step(T=np.linspace(0, 5, 100))
	>>> fig, ax = plt.subplots()
	>>> ax.plot(t, x, label='Continuous', linewidth=3)

	Transform it to a discrete state-space system using several methods.

	>>> dt = 0.1
	>>> for method in ['zoh', 'bilinear', 'euler', 'backward_diff', 'foh', 'impulse']:
	... d_system = cont2discrete((A, B, C, D), dt, method=method)
	... s, x_d = dstep(d_system)
	... ax.step(s, np.squeeze(x_d), label=method, where='post')
	>>> ax.axis([t[0], t[-1], x[0], 1.4])
	>>> ax.legend(loc='best')
	>>> fig.tight_layout()
	>>> plt.show()

	"""
	if len(system) == 1:
	return system.to_discrete()
	if len(system) == 2:
	sysd = cont2discrete(tf2ss(system[0], system[1]), dt, method=method,
	alpha=alpha)
	return ss2tf(sysd[0], sysd[1], sysd[2], sysd[3]) + (dt,)
	elif len(system) == 3:
	sysd = cont2discrete(zpk2ss(system[0], system[1], system[2]), dt,
	method=method, alpha=alpha)
	return ss2zpk(sysd[0], sysd[1], sysd[2], sysd[3]) + (dt,)
	elif len(system) == 4:
	a, b, c, d = system
	else:
	raise ValueError("First argument must either be a tuple of 2 (tf), "
	"3 (zpk), or 4 (ss) arrays.")

	if method == 'gbt':
	if alpha is None:
	raise ValueError("Alpha parameter must be specified for the "
	"generalized bilinear transform (gbt) method")
	elif alpha < 0 or alpha > 1:
	raise ValueError("Alpha parameter must be within the interval "
	"[0,1] for the gbt method")

	if method == 'gbt':
	# This parameter is used repeatedly - compute once here
	ima = np.eye(a.shape[0]) - alphadta
	ad = linalg.solve(ima, np.eye(a.shape[0]) + (1.0-alpha)dta)
	bd = linalg.solve(ima, dt*b)

	# Similarly solve for the output equation matrices
	cd = linalg.solve(ima.transpose(), c.transpose())
	cd = cd.transpose()
	dd = d + alpha*np.dot(c, bd)

	elif method == 'bilinear' or method == 'tustin':
	return cont2discrete(system, dt, method="gbt", alpha=0.5)

	elif method == 'euler' or method == 'forward_diff':
	return cont2discrete(system, dt, method="gbt", alpha=0.0)

	elif method == 'backward_diff':
	return cont2discrete(system, dt, method="gbt", alpha=1.0)

	elif method == 'zoh':
	# Build an exponential matrix
	em_upper = np.hstack((a, b))

	# Need to stack zeros under the a and b matrices
	em_lower = np.hstack((np.zeros((b.shape[1], a.shape[0])),
	np.zeros((b.shape[1], b.shape[1]))))

	em = np.vstack((em_upper, em_lower))
	ms = linalg.expm(dt * em)

	# Dispose of the lower rows
	ms = ms[:a.shape[0], :]

	ad = ms[:, 0:a.shape[1]]
	bd = ms[:, a.shape[1]:]

	cd = c
	dd = d

	elif method == 'foh':
	# Size parameters for convenience
	n = a.shape[0]
	m = b.shape[1]

	# Build an exponential matrix similar to 'zoh' method
	em_upper = linalg.block_diag(np.block([a, b]) * dt, np.eye(m))
	em_lower = zeros((m, n + 2 * m))
	em = np.block([[em_upper], [em_lower]])

	ms = linalg.expm(em)

	# Get the three blocks from upper rows
	ms11 = ms[:n, 0:n]
	ms12 = ms[:n, n:n + m]
	ms13 = ms[:n, n + m:]

	ad = ms11
	bd = ms12 - ms13 + ms11 @ ms13
	cd = c
	dd = d + c @ ms13

	elif method == 'impulse':
	if not np.allclose(d, 0):
	raise ValueError("Impulse method is only applicable"
	"to strictly proper systems")

	ad = linalg.expm(a * dt)
	bd = ad @ b * dt
	cd = c
	dd = c @ b * dt

	else:
	raise ValueError("Unknown transformation method '%s'" % method)

	return ad, bd, cd, dd, dt