Transfer Function
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- For "transfer function" as used in computer graphics, see lookup table.
Explanation
The transfer function is commonly used in the analysis of single-input single-output analog electronic circuits, for instance. It is mainly used in signal processing, communication theory, and control theory. The term is often used exclusively to refer to linear, time-invariant systems (LTI), as covered in this article, but most real systems have non-linear input/output characteristics. However many systems, when operated within nominal parameters (not "over-driven") have behavior that is close enough to linear that LTI system theory is an acceptable representation of the input/output behavior.
In its simplest form for continuous-time input signal x(t) and output y(t), the transfer function is the linear mapping of the Laplace transform of the input, X(s), to the output Y(s)):
- [ Y(s) = H(s) \, X(s) ]
- [ H(s) = \frac ]
In discrete-time systems, the function is similarly written as [H(z) = \frac] (see Z transform).
Signal processing
Let [ x(t) \ ] be the input to a general linear time-invariant system, and [ y(t) \ ] be the output, and the Laplace transform of [ x(t) \ ] and [ y(t) \ ] be
- [ X(s) = \mathcal\left \ \equiv \int_^ x(t) e^\, dt ]
- [ Y(s) = \mathcal\left \ \equiv \int_^ y(t) e^\, dt ].
- : [ Y(s) = H(s) X(s) \, ]
- : [ H(s) = \frac ] .
- [ x(t) = Xe^ = |X|e^ ]
- where [ X = |X|e^ ]
- [ y(t) = Ye^ = |Y|e^ ]
- and [ Y = |Y|e^ ].
- [G(\omega) = \frac
>
>
= |H(j \omega)| \ ] and phase shift: - [\phi(\omega) = \arg(Y) - \arg(X) = \arg( H(j \omega))].
- [\tau_(\omega) = -\begin\frac\end].
- [\tau_(\omega) = -\begin\frac\end].
Control engineering
In control engineering and control theory the transfer function is derived using the Laplace transform.
The transfer function was the primary tool used in classical control engineering. However, it has proven to be unwieldy for the analysis of multiple-input multiple-output (MIMO) systems, and has been largely supplanted by state space representations for such systems. In spite of this, a transfer matrix can be always obtained for any linear system, in order to analyze its dynamics and other properties: each element of a transfer matrix is a transfer function relating a particular input variable to an output variable.
Optics
In optics the modulation transfer function describes the ability of an optical system to transfer contrast.
For example, if a series of alternating white and black bars is drawn at a specific spatial frequency, when these bars are observed, the image will be somewhat degraded. The white bars may appear somewhat darker and the black bars will be somewhat lighter.
By definition, the modulation transfer function at a given spatial frequency is defined as follows:
- [ \mathrm(f) = \frac)} )}]
- [ M = \frac - L_\mathrm )} + L_\mathrm)} ]
See also
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