scipy.signal.TransferFunction¶

class scipy.signal.TransferFunction(*system)[source]¶

Linear Time Invariant system class in transfer function form.

Represents the system as the transfer function \(H(s)=\sum_{i=0}^N b[N-i] s^i / \sum_{j=0}^M a[M-j] s^j\), where \(b\) are elements of the numerator num, \(a\) are elements of the denominator den, and N == len(b) - 1, M == len(a) - 1.

Parameters:

Parameters:	*system : arguments The `TransferFunction` class can be instantiated with 1 or 2 arguments. The following gives the number of input arguments and their interpretation: 1: `lti` system: (`StateSpace`, `TransferFunction` or `ZerosPolesGain`) 2: array_like: (numerator, denominator)

*system : arguments

The TransferFunction class can be instantiated with 1 or 2 arguments. The following gives the number of input arguments and their interpretation:

1: lti system: (StateSpace, TransferFunction or ZerosPolesGain)

2: array_like: (numerator, denominator)

Notes

Changing the value of properties that are not part of the TransferFunction system representation (such as the A, B, C, D state-space matrices) is very inefficient and may lead to numerical inaccuracies.

Examples

Construct the transfer function:

\[H(s) = \frac{s^2 + 3s + 3}{s^2 + 2s + 1}\]

>>> from scipy import signal
>>> num = [1, 3, 3]
>>> den = [1, 2, 1]
>>> signal.TransferFunction(num, den)
TransferFunction(
array([ 1.,  3.,  3.]),
array([ 1.,  2.,  1.])
)

Attributes

`A`	State matrix of the `StateSpace` system.
`B`	Input matrix of the `StateSpace` system.
`C`	Output matrix of the `StateSpace` system.
`D`	Feedthrough matrix of the `StateSpace` system.
`den`	Denominator of the `TransferFunction` system.
`gain`	Gain of the `ZerosPolesGain` system.
`num`	Numerator of the `TransferFunction` system.
`poles`	Poles of the `ZerosPolesGain` system.
`zeros`	Zeros of the `ZerosPolesGain` system.

Methods

`bode`([w, n])	Calculate Bode magnitude and phase data of a continuous-time system.
`freqresp`([w, n])	Calculate the frequency response of a continuous-time system.
`impulse`([X0, T, N])	Return the impulse response of a continuous-time system.
`output`(U, T[, X0])	Return the response of a continuous-time system to input U.
`step`([X0, T, N])	Return the step response of a continuous-time system.
`to_ss`()	Convert system representation to `StateSpace`.
`to_tf`()	Return a copy of the current `TransferFunction` system.
`to_zpk`()	Convert system representation to `ZerosPolesGain`.