Difference between revisions of "Transfer function"
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[[File:KellerDoyaT.png|300px|thumb|Transfer functions of laser amplifiers with simple kinetics for the short pulses ([[Keller function]]) and for the continuous-wave operation ([[Doya function]])]] |
[[File:KellerDoyaT.png|300px|thumb|Transfer functions of laser amplifiers with simple kinetics for the short pulses ([[Keller function]]) and for the continuous-wave operation ([[Doya function]])]] |
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− | '''Transfer function''' |
+ | '''Transfer function''' \(h\) is expression of the state of the system in terms of its state at the precedent step of evolution. |
In the signal processing systems, the transfer function determines the output signal in terms of the input one. |
In the signal processing systems, the transfer function determines the output signal in terms of the input one. |
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Line 38: | Line 38: | ||
In [[mathematics]], the transfer function is generic name for a given function that appears in the [[transfer equation]] and in the [[Abel equation]]. |
In [[mathematics]], the transfer function is generic name for a given function that appears in the [[transfer equation]] and in the [[Abel equation]]. |
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− | If |
+ | If \(h\) is declared as [[transfer function]], then, the [[superfunction]] \(F\) is solution of the [[transfer equation]] |
− | : |
+ | : \((1) ~ ~ ~ ~ ~ F(z\!+\!1)=h(F(z))\) |
− | and the [[Abel function]] |
+ | and the [[Abel function]] \(G\) is solution of the [[Abel equation]] |
− | : |
+ | : \((2) ~ ~ ~ ~ ~ G(h(z))=G(z)+1\) |
==Transfer function and the Abel function== |
==Transfer function and the Abel function== |
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− | It is convenient to consider such [[Abel function]] |
+ | It is convenient to consider such [[Abel function]] \(G\) that is inverse function of the [[superfunction]] \(F~\); \(~H(G(z))=z\) |
Then, the [[Transfer function]] can be expressed as follows: |
Then, the [[Transfer function]] can be expressed as follows: |
||
− | : |
+ | : \((3) ~ ~ ~ ~ ~ h(z)=F(1+G(z))\) |
− | Such an expression can be used to define the |
+ | Such an expression can be used to define the \(c\)th iterate of the transfer function |
− | : |
+ | : \((4) ~ ~ ~ ~ ~ h^c(z)=F(c+G(z))\) |
− | for various |
+ | for various \(c\). In particular, for integer values of \(c\), |
− | + | \(h^{-1}\) is inverse function of \(h\), while |
|
− | + | \(h^{0}\) is [[identify function]], |
|
− | + | \(h^{1}\!=\!h~\); \(~h^{2}(z)\!=\!h(h(z))~\) and so on. |
|
− | Once the superfunction |
+ | Once the superfunction \(F\) and the Abelfunction \(G=F^{-1}\) are specified, |
− | the definition (4) of the |
+ | the definition (4) of the \(c\)th iteration of the transfer function can be used also for fractional, irrational and even for complex values of \(c\). |
==Table of superfunctions and Abel functions== |
==Table of superfunctions and Abel functions== |
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− | In principle any holomorphic function can be declared as a [[superfunction]] |
+ | In principle any holomorphic function can be declared as a [[superfunction]] \(F\), and the inverse function \(G=F^{-1}\) can be declared as the [[Abel function]]. Then function \(h\) by equation (3) is corresponding [[transfer function]]. This gives simple way to construct the table of [[superfunction]]s and [[Abel function]]s. |
===Constant as transfer function=== |
===Constant as transfer function=== |
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− | Consider |
+ | Consider \(F(z)=C=\)const as superfunction. The inverse function \(G\) cannot be defined at any complex domain, but the transfer function that is always constant can be considered as the transfer function; \(h(z)=C\). |
This is example of a [[transfer function]] identical to its [[superfunction]]. |
This is example of a [[transfer function]] identical to its [[superfunction]]. |
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===Unity increment as the transfer function=== |
===Unity increment as the transfer function=== |
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− | Consider the addition of a constant |
+ | Consider the addition of a constant \(b\); let \(F(z)=b+z\) be superfunction. Then, the Abel function is \(G(z)=z-b\). |
The corresponding transfer function |
The corresponding transfer function |
||
− | : |
+ | : \((5) ~ ~ ~ ~ ~ h(x)= b+ (1+(z-b))=z+1 = +\!+(z)\) |
is just unity increment. |
is just unity increment. |
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− | In particular, expression (5) is valid at |
+ | In particular, expression (5) is valid at \(b=1\); this is another example when |
the [[transfer function]] identical to its [[superfunction]]. |
the [[transfer function]] identical to its [[superfunction]]. |
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===Addition as transfer function=== |
===Addition as transfer function=== |
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− | Consider the multilication by a constant |
+ | Consider the multilication by a constant \(b\); let \(F(z)=b z\) be superfunction. Then, at \(b\!\ne\! 0\), the Abel function is \(G(z)=z/b\). |
The corresponding transfer function |
The corresponding transfer function |
||
− | : |
+ | : \((6) ~ ~ ~ ~ ~ h(x)= b*(1+z/b)=z+b\) |
− | In such a way, the addition of constant |
+ | In such a way, the addition of constant \(b\) is [[superfunction]] with respect to the [[unity increment]] and [[transfer function]] with respect to multiplicaiton by a constant \(b\). |
=== multiplication as transfer function=== |
=== multiplication as transfer function=== |
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− | Consider the [[exponentiation]], let |
+ | Consider the [[exponentiation]], let \(F(z)=\exp_b(z)\) be superfunction. Then, at \(b\!\ne\! 0\), \(b\!\ne\! 1\), the Abel function is \(G(z)=\log_b(z)\). |
The corresponding transfer function |
The corresponding transfer function |
||
− | : |
+ | : \((7) ~ ~ ~ ~ ~ h(x)= \exp_b(1+\log_b(z))= b z\) |
− | In such a way, the multiplication by constant |
+ | In such a way, the multiplication by constant \(b\) is [[superfunction]] with respect to the [[addition of constant]] \(b\) and [[transfer function]] with respect to exponentiation to base \(b\). |
===Exponentiation as transfer function=== |
===Exponentiation as transfer function=== |
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− | Consider the [[tetration]], let |
+ | Consider the [[tetration]], let \(F(z)=\mathrm{tet}_b(z)\). Then, at least for \(b\!>\!1\), the Abel function is arctetration, \(G(z)=\mathrm{ate}_b(z)\). |
The corresponding transfer function |
The corresponding transfer function |
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− | : |
+ | : \((8) ~ ~ ~ ~ ~ h(x)= \mathrm{tet}_b(1+\mathrm{ate}_b(z))=b^z\) |
So, the exponentiation is superfunction with respect to to multipliction and [[transfer function]] with respect to [[tetration]] |
So, the exponentiation is superfunction with respect to to multipliction and [[transfer function]] with respect to [[tetration]] |
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===Another superfunction for a linear function=== |
===Another superfunction for a linear function=== |
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− | Consider the linear superfunction, let |
+ | Consider the linear superfunction, let \(F(z)=a\!+\!b z\). Then, for \(b\!\ne\! 0\), the [[Abel function]] \(G(z)=z/b\! -\! a\). Then, the corresponding tansfer function |
− | : |
+ | : \((9) ~ ~ ~ ~ ~ h(x)= a+ b \times (z/b-a) = z+ (1\!-\!b) a\) |
which looks preffy similar to equation (6); it is the simple case when the different superfunctions correspond to the same transfer function. |
which looks preffy similar to equation (6); it is the simple case when the different superfunctions correspond to the same transfer function. |
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===Linear fraction as superfunction=== |
===Linear fraction as superfunction=== |
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Consider |
Consider |
||
− | : |
+ | : \((10) \displaystyle ~ ~ ~ ~ ~ F(z)=\frac{a+b z}{p+q z}~ ~, ~ ~\) where \(a,b,p,q\) are constants (for example, some complex numbers). |
Then |
Then |
||
− | : |
+ | : \((11) \displaystyle ~ ~ ~ ~ ~ G(z)=F^{-1}(z)=\frac{a- p z}{-b+q z}\) |
and the corresponding transfer function |
and the corresponding transfer function |
||
− | : |
+ | : \((12) \displaystyle ~ ~ ~ ~ ~ f(z)=F(1+G(z))=\frac{b^2+(bp-bq-aq)z}{bp+bq-qa - q^2 z}\) |
is also the linear fraction function. |
is also the linear fraction function. |
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Denoting |
Denoting |
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− | : |
+ | : \((13) \displaystyle ~ ~ ~ ~ ~ A=-b^2\) |
− | : |
+ | : \((14) \displaystyle ~ ~ ~ ~ ~ B=-bp+bq+aq\) |
− | : |
+ | : \((15) \displaystyle ~ ~ ~ ~ ~ P=-bp-bq+qa\) |
− | : |
+ | : \((16) \displaystyle ~ ~ ~ ~ ~ Q=q^2\) |
the transfer function can be written in the simple form |
the transfer function can be written in the simple form |
||
− | : |
+ | : \((17) \displaystyle ~ ~ ~ ~ ~ f(z)=\frac{A+Bz}{P+Qz}\) |
− | The corresponding [[superfunction]] |
+ | The corresponding [[superfunction]] \(F\) and the [[Abel function]] \(G\) are expressed with (10) and (11). |
− | Consider the case, that |
+ | Consider the case, that \(A\), \(B\), \(P\), \(Q\) are given. They determine the transfer function \(f\). |
− | Then, if the solution |
+ | Then, if the solution \(a\), \(b\), \(p\), \(q\) of equations (13),(14),(15),(16) exists, then, \(F\) by (10) and \(G\) by (11) are corresponding [[superfunction]] and the [[Abel function]]. |
<!-- |
<!-- |
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− | If the |
+ | If the \(A\), \(B\), \(P\) and \(Q\) are given, then superfunction can be expressed with (10), and the possible solutions for the coefficients can be expressed as follows: |
− | : |
+ | : \((18) \displaystyle ~ ~ ~ ~ ~ b=\sqrt{A}+\) |
− | : |
+ | : \((19) \displaystyle ~ ~ ~ ~ ~ q=-\sqrt{Q}+\) |
− | : |
+ | : \((20) \displaystyle ~ ~ ~ ~ ~ b=\frac{P-B-2\sqrt{A}\sqrt{Q}+\) |
!--> |
!--> |
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==More complicated transfer functions== |
==More complicated transfer functions== |
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− | In principle any pair of biholomorphic |
+ | In principle any pair of biholomorphic \(F\) and \(G=F^{-1}\) with wide enough range of holomorphism can be declared as superfunction and Abel function; then \(f(z)=F(1+G(z))\) appears as the corresponding transfer function. In such a way, the table of superfunctions |
<ref name="factorial"> |
<ref name="factorial"> |
||
http://www.springerlink.com/content/qt31671237421111/fulltext.pdf?page=1 |
http://www.springerlink.com/content/qt31671237421111/fulltext.pdf?page=1 |
Latest revision as of 06:33, 20 July 2020
Transfer function \(h\) is expression of the state of the system in terms of its state at the precedent step of evolution.
In the signal processing systems, the transfer function determines the output signal in terms of the input one.
In the linear optics, the transfer can be expressed as linear operator, that describes the transform of light inside some system.
In TORI, the term usually refers to the Transfer equation, the Abel equation; the transfer function is assumed to be given function that appear in these equations. The solutions of these equations are called superfunctions and Abel functions. For a given transfer function, the additional restrictions should be applied to make the superfunction and the Abel function unique [1][2][3][4][5][6].
Transfer equation and Abel equation
In mathematics, the transfer function is generic name for a given function that appears in the transfer equation and in the Abel equation.
If \(h\) is declared as transfer function, then, the superfunction \(F\) is solution of the transfer equation
- \((1) ~ ~ ~ ~ ~ F(z\!+\!1)=h(F(z))\)
and the Abel function \(G\) is solution of the Abel equation
- \((2) ~ ~ ~ ~ ~ G(h(z))=G(z)+1\)
Transfer function and the Abel function
It is convenient to consider such Abel function \(G\) that is inverse function of the superfunction \(F~\); \(~H(G(z))=z\) Then, the Transfer function can be expressed as follows:
- \((3) ~ ~ ~ ~ ~ h(z)=F(1+G(z))\)
Such an expression can be used to define the \(c\)th iterate of the transfer function
- \((4) ~ ~ ~ ~ ~ h^c(z)=F(c+G(z))\)
for various \(c\). In particular, for integer values of \(c\), \(h^{-1}\) is inverse function of \(h\), while \(h^{0}\) is identify function, \(h^{1}\!=\!h~\); \(~h^{2}(z)\!=\!h(h(z))~\) and so on.
Once the superfunction \(F\) and the Abelfunction \(G=F^{-1}\) are specified, the definition (4) of the \(c\)th iteration of the transfer function can be used also for fractional, irrational and even for complex values of \(c\).
Table of superfunctions and Abel functions
In principle any holomorphic function can be declared as a superfunction \(F\), and the inverse function \(G=F^{-1}\) can be declared as the Abel function. Then function \(h\) by equation (3) is corresponding transfer function. This gives simple way to construct the table of superfunctions and Abel functions.
Constant as transfer function
Consider \(F(z)=C=\)const as superfunction. The inverse function \(G\) cannot be defined at any complex domain, but the transfer function that is always constant can be considered as the transfer function; \(h(z)=C\).
This is example of a transfer function identical to its superfunction.
Unity increment as the transfer function
Consider the addition of a constant \(b\); let \(F(z)=b+z\) be superfunction. Then, the Abel function is \(G(z)=z-b\). The corresponding transfer function
- \((5) ~ ~ ~ ~ ~ h(x)= b+ (1+(z-b))=z+1 = +\!+(z)\)
is just unity increment.
In particular, expression (5) is valid at \(b=1\); this is another example when the transfer function identical to its superfunction.
Addition as transfer function
Consider the multilication by a constant \(b\); let \(F(z)=b z\) be superfunction. Then, at \(b\!\ne\! 0\), the Abel function is \(G(z)=z/b\).
The corresponding transfer function
- \((6) ~ ~ ~ ~ ~ h(x)= b*(1+z/b)=z+b\)
In such a way, the addition of constant \(b\) is superfunction with respect to the unity increment and transfer function with respect to multiplicaiton by a constant \(b\).
multiplication as transfer function
Consider the exponentiation, let \(F(z)=\exp_b(z)\) be superfunction. Then, at \(b\!\ne\! 0\), \(b\!\ne\! 1\), the Abel function is \(G(z)=\log_b(z)\). The corresponding transfer function
- \((7) ~ ~ ~ ~ ~ h(x)= \exp_b(1+\log_b(z))= b z\)
In such a way, the multiplication by constant \(b\) is superfunction with respect to the addition of constant \(b\) and transfer function with respect to exponentiation to base \(b\).
Exponentiation as transfer function
Consider the tetration, let \(F(z)=\mathrm{tet}_b(z)\). Then, at least for \(b\!>\!1\), the Abel function is arctetration, \(G(z)=\mathrm{ate}_b(z)\).
The corresponding transfer function
- \((8) ~ ~ ~ ~ ~ h(x)= \mathrm{tet}_b(1+\mathrm{ate}_b(z))=b^z\)
So, the exponentiation is superfunction with respect to to multipliction and transfer function with respect to tetration
In the similar way, tetration is superfunction with respect to exponential and transfer function with respect to pentation, and so on for other the ackermann functions.
Another superfunction for a linear function
Consider the linear superfunction, let \(F(z)=a\!+\!b z\). Then, for \(b\!\ne\! 0\), the Abel function \(G(z)=z/b\! -\! a\). Then, the corresponding tansfer function
- \((9) ~ ~ ~ ~ ~ h(x)= a+ b \times (z/b-a) = z+ (1\!-\!b) a\)
which looks preffy similar to equation (6); it is the simple case when the different superfunctions correspond to the same transfer function.
Linear fraction as superfunction
Consider
- \((10) \displaystyle ~ ~ ~ ~ ~ F(z)=\frac{a+b z}{p+q z}~ ~, ~ ~\) where \(a,b,p,q\) are constants (for example, some complex numbers).
Then
- \((11) \displaystyle ~ ~ ~ ~ ~ G(z)=F^{-1}(z)=\frac{a- p z}{-b+q z}\)
and the corresponding transfer function
- \((12) \displaystyle ~ ~ ~ ~ ~ f(z)=F(1+G(z))=\frac{b^2+(bp-bq-aq)z}{bp+bq-qa - q^2 z}\)
is also the linear fraction function.
Denoting
- \((13) \displaystyle ~ ~ ~ ~ ~ A=-b^2\)
- \((14) \displaystyle ~ ~ ~ ~ ~ B=-bp+bq+aq\)
- \((15) \displaystyle ~ ~ ~ ~ ~ P=-bp-bq+qa\)
- \((16) \displaystyle ~ ~ ~ ~ ~ Q=q^2\)
the transfer function can be written in the simple form
- \((17) \displaystyle ~ ~ ~ ~ ~ f(z)=\frac{A+Bz}{P+Qz}\)
The corresponding superfunction \(F\) and the Abel function \(G\) are expressed with (10) and (11).
Consider the case, that \(A\), \(B\), \(P\), \(Q\) are given. They determine the transfer function \(f\). Then, if the solution \(a\), \(b\), \(p\), \(q\) of equations (13),(14),(15),(16) exists, then, \(F\) by (10) and \(G\) by (11) are corresponding superfunction and the Abel function.
More complicated transfer functions
In principle any pair of biholomorphic \(F\) and \(G=F^{-1}\) with wide enough range of holomorphism can be declared as superfunction and Abel function; then \(f(z)=F(1+G(z))\) appears as the corresponding transfer function. In such a way, the table of superfunctions [4] can be constructed.
In general the transfer function can be defined on the the set of vectors or set of functions. In this case, the transfer function is called also functional. (Such a name may assyme that the Functional is considered as something superior to just a function of single variable). Such a case my be important for the signal processing [7].
The transfer function determines the transformation of a function (that is interpreted as a signal), as it passes through some filter. In principle, the signal may pass through the filter several times (or to pass through the set of identical filters). If the filter is interpreted as a piece of a system with translational symmetry, then the superfunction may express the evolution of the signal inside the filter. For the multidimensional transfer function, the definition of the Abel function cannot be applied as is; it should be generalizad.
References
- ↑
http://www.ams.org/mcom/2009-78-267/S0025-5718-09-02188-7/home.html
http://www.ils.uec.ac.jp/~dima/PAPERS/2009analuxpRepri.pdf
http://mizugadro.mydns.jp/PAPERS/2009analuxpRepri.pdf D.Kouznetsov. Analytic solution of F(z+1)=exp(F(z)) in complex z-plane. Mathematics of Computation, v.78 (2009), 1647-1670. - ↑
http://www.ams.org/journals/mcom/2010-79-271/S0025-5718-10-02342-2/home.html
http://www.ils.uec.ac.jp/~dima/PAPERS/2010sqrt2.pdf
http://mizugadro.mydns.jp/PAPERS/2010sqrt2.pdf D.Kouznetsov, H.Trappmann. Portrait of the four regular super-exponentials to base sqrt(2). Mathematics of Computation, 2010, v.79, p.1727-1756. - ↑
http://www.ams.org/journals/mcom/2012-81-280/S0025-5718-2012-02590-7/home.html
http://mizugadro.mydns.jp/PAPERS/2011e1e.pdf H.Trappmann, D.Kouznetsov. Computation of the Two Regular Super-Exponentials to base exp(1/e). Mathematics of Computation, v.81 (2012), p. 2207-2227. - ↑ 4.0 4.1
http://www.springerlink.com/content/qt31671237421111/fulltext.pdf?page=1 , Preview
http://www.ils.uec.ac.jp/~dima/PAPERS/2010superfae.pdf reprint, English version
http://mizugadro.mydns.jp/PAPERS/2010superfar.pdf reprint, Russian version
D.Kouznetsov, H.Trappmann. Superfunctions and square root of factorial. Moscow University Physics Bulletin, 2010, v.65, No.1, p.6-12. Cite error: Invalid<ref>
tag; name "factorial" defined multiple times with different content - ↑
http://www.springerlink.com/content/u7327836m2850246/
http://www.ils.uec.ac.jp/~dima/PAPERS/2011uniabel.pdf
http://mizugadro.mydns.jp/PAPERS/2011uniabel.pdf H.Trappmann, D.Kouznetsov. Uniqueness of Analytic Abel Functions in Absence of a Real Fixed Point. Aequationes Mathematicae, v.81, p.65-76 (2011) - ↑ http://www.proofwiki.org/wiki/Definition:Superfunction
- ↑ http://en.wikipedia.org/wiki/Transfer_function