Elliptic rational functions

Elliptic rational functions

In mathematics the elliptic rational functions are a sequence of rational functions with real coefficients. Elliptic rational functions are extensively used in the design of elliptic electronic filters. (These functions are sometimes called Chebyshev rational functions, not to be confused with certain other functions of the same name).

Rational elliptic functions are identified by a positive integer order "n" and include a parameter xi ge 1 called the selectivity factor. A rational elliptic function of degree "n" in "x" with selectivity factor ξ is generally defined as:

:R_n(xi,x)equiv mathrm{cd}left(nfrac{K(1/L_n)}{K(1/xi)},mathrm{cd}^{-1}(x,1/xi),1/L_n ight)

* cd() is the Jacobi elliptic cosine function.
* K() is a complete elliptic integral of the first kind.
* L_n(xi)=R_n(xi,xi) is the discrimination factor, equal to the minimum value of the magnitude of R_n(xi,x) for |x|gexi.

For many cases, in particular for orders of the form n=2^a3^b where "a" and "b" are integers, the elliptic rational functions can be expressed using algebraic functions alone. Elliptic rational functions are closely related to the Chebyshev polynomials: Just as the circular trigonometric functions are special cases of the Jacobi elliptic functions, so the Chebyshev polynomials are special cases of the elliptic rational functions.

Expression as a ratio of polynomials

For even orders, the elliptic rational functions may be expressed as a ratio of two polynomials, both of order "n".

:R_n(xi,x)=r_0,frac{prod_{i=1}^n (x-x_i)}{prod_{i=1}^n (x-x_{pi})} (for n even)

where x_i are the zeroes and x_{pi} are the poles, and r_0 is a normalizing constant chosen such that R_n(xi,1)=1. The above form would be true for odd orders as well except that for odd orders, there will be a pole at x=∞ and a zero at x=0 so that the above form must be modified to read:

:R_n(xi,x)=r_0,x,frac{prod_{i=1}^{n-1} (x-x_i)}{prod_{i=1}^{n-1} (x-x_{pi})} (for n odd)

Properties

The canonical properties

* R_n^2(xi,x)le 1 for |x|le 1,
* R_n^2(xi,x)= 1 at |x|= 1,
* R_n^2(xi,-x)=R_n^2(xi,x)
* R_n^2(xi,x)>1 for x>1,
* The slope at x=1 is as large as possible
* The slope at x=1 is larger than the corresponding slope of the Chebyshev polynomial of the same order.

The only rational function satisfying the above properties is the elliptic rational function. ref_harvard|Lutovac|Lutovac 2001 § 13.2|. The following properties are derived:

Normalization

The elliptic rational function is normalized to unity at x=1:

:R_n(xi,1)=1,

Nesting property

The nesting property is written:

:R_m(R_n(xi,xi),R_n(xi,x))=R_{mcdot n}(xi,x),

This is a very important property:

* If R_n is known for all prime "n", then nesting property gives R_n for all "n". In particular, since R_2 and R_3 can be expressed in closed form without explicit use of the Jacobi elliptic functions, then all R_n for "n" of the form n=2^a3^b can be so expressed.
* It follows that if the zeroes of R_n for prime "n" are known, the zeros of all R_n can be found. Using the inversion relationship (see below), the poles can also be found.
* The nesting property implies the nesting property of the discrimination factor:

::L_{mcdot n}(xi)=L_m(L_n(xi))

Limiting values

The elliptic rational functions are related to the Chebyshev polynomials of the first kind T_n(x) by:

:lim_{xi= ightarrow,infty}R_n(xi,x)=T_n(x),

ymmetry

:R_n(xi,-x)=R_n(xi,x), for n even:R_n(xi,-x)=-R_n(xi,x), for n odd

Equiripple

R_n(xi,x) has equal ripple of pm 1 in the interval -1le xle 1. By the inversion relationship (see below), it follows that 1/R_n(xi,x) has equiripple in -1/xi le xle 1/xi of pm 1/L_n(xi).

Inversion relationship

The following inversion relationship holds:

:R_n(xi,xi/x)=frac{R_n(xi,xi)}{R_n(xi,x)},

This implies that poles and zeroes come in pairs such that

:x_{pi}x_{zi}=xi,

Odd order functions will have a zero at "x=0" and a corresponding pole at infinity.

Poles and Zeroes

The zeroes of the elliptic rational function of order "n" will be written x_{ni}(xi) or x_{ni} when xi is implicitly known. The zeroes of the elliptic rational function will be the zeroes of the polynomial in the numerator of the function.

The following derivation of the zeroes of the elliptic rational function is analogous to that of determining the zeroes of the Chebyshev polynomials. ref_harvard|Lutovac|Lutovac 2001 § 12.6| Using the fact that for any "z"

:mathrm{cd}left((2m-1)Kleft(1/z ight),frac{1}{z} ight)=0,

the defining equation for the elliptic rational functions implies that

:n frac{K(1/L_n)}{K(1/xi)}mathrm{cd}^{-1}(x_m,1/xi)=(2m-1)K(1/L_n)

so that the zeroes are given by

:x_m=mathrm{cd}left(K(1/xi),frac{2m-1}{n},frac{1}{xi} ight)

Using the inversion relationship, the poles may then be calculated.

From the nesting property, if the zeroes of R_m and R_n can be algebraically expressed (i.e. without the need for calculating the Jacobi ellipse functions) then the zeroes of R_{mcdot n} can be algebraically expressed. In particular, the zeroes of elliptic rational functions of order 2^i3^j may be algebraically expressed. ref_harvard|Lutovac|Lutovac 2001 § 12.9, 13.9| For example, we can find the zeroes of R_8(xi,x) as follows: Define

:X_nequiv R_n(xi,x)qquad L_nequiv R_n(xi,xi)qquad t_nequiv sqrt{1-1/L_n^2}

Then, from the nesting property and knowing that

:R_2(xi,x)=frac{(t+1)x^2-1}{(t-1)x^2+1}

where tequiv sqrt{1-1/xi^2} we have:

:L_2=frac{1+t}{1-t},qquad L_4=frac{1+t_2}{1-t_2},qquad L_8=frac{1+t_4}{1-t_4}

:X_2=frac{(t+1)x^2 -1}{(t-1)x^2 +1},qquad X_4=frac{(t_2+1)X_2^2-1}{(t_2-1)X_2^2+1},qquad X_8=frac{(t_4+1)X_4^2-1}{(t_4-1)X_4^2+1}

These last three equations may be inverted:

:x =frac{1}{pmsqrt{1+t ,left(frac{1-X_2}{1+X_2} ight),qquadX_2=frac{1}{pmsqrt{1+t_2,left(frac{1-X_4}{1+X_4} ight),qquadX_4=frac{1}{pmsqrt{1+t_4,left(frac{1-X_8}{1+X_8} ight),qquad

To calculate the zeroes of R_8(xi,x) we set X_8=0 in the third equation, calculate the two values of X_4, then use these values of X_4 in the second equation to calculate four values of X_2 and finally, use these values in the first equation to calculate the eight zeroes of R_8(xi,x). (The t_n are calculated by a similar recursion.) Again, using the inversion relationship, these zeroes can be used to calculate the poles.

Particular values

We may write the first few elliptic rational functions as:

:R_1(xi,x)=x,:R_2(xi,x)=frac{(t+1)x^2-1}{(t-1)x^2+1}::: where:::t equiv sqrt{1-frac{1}{xi^2:R_3(xi,x)=x,frac{(1-x_p^2)(x^2-x_z^2)}{(1-x_z^2)(x^2-x_p^2)}::: where:::Gequivsqrt{4xi^2+(4xi^2(xi^2!-!1))^{2/3:::x_p^2equivfrac{2xi^2sqrt{G{sqrt{8xi^2(xi^2!+!1)+12Gxi^2-G^3}-sqrt{G^3:::x_z^2=xi^2/x_p^2:R_4(xi,x)=R_2(R_2(xi,xi),R_2(xi,x))=frac{(1+t)(1+sqrt{t})^2x^4-2(1+t)(1+sqrt{t})x^2+1}{(1+t)(1-sqrt{t})^2x^4-2(1+t)(1-sqrt{t})x^2+1}:R_6(xi,x)=R_3(R_2(xi,xi),R_2(xi,x)), etc.

See ref_harvard|Lutovac|Lutovac 2001 § 13| for further explicit expressions of order "n=5" and n=2^i,3^j.

The corresponding discrimination factors are:

:L_1(xi)=xi,:L_2(xi)=frac{1+t}{1-t}=left(xi+sqrt{xi^2-1} ight)^2:L_3(xi)=xi^3left(frac{1-x_p^2}{xi^2-x_p^2} ight)^2:L_4(xi)=left(sqrt{xi}+(xi^2-1)^{1/4} ight)^4left(xi+sqrt{xi^2-1} ight)^2:L_6(xi)=L_3(L_2(xi)), etc.

The corresponding zeroes are x_{nj} where "n" is the order and "j" is the number of the zero. There will be a total of "n" zeroes for each order.

:x_{11}=0,

:x_{21}=xisqrt{1-t},:x_{22}=-x_{21},

:x_{31}=x_z,:x_{32}=0,:x_{33}=-x_{31},

:x_{41}=xisqrt{left(1-sqrt{t} ight)left(1+t-sqrt{t(t+1)} ight)},:x_{42}=xisqrt{left(1-sqrt{t} ight)left(1+t+sqrt{t(t+1)} ight)},:x_{43}=-x_{42},:x_{44}=-x_{41},

From the inversion relationship, the corresponding poles x_{p,ni} may be found by x_{p,ni}=xi/(x_{ni})

References

* [http://mathworld.wolfram.com/EllipticRationalFunction.html MathWorld]

*note_label|Daniels|Daniels 1974|cite book |last=Daniels |first=Richard W. |authorlink= |coauthors= |title=Approximation Methods for Electronic Filter Design |year=1974 |publisher=McGraw-Hill |location=New York |id=ISBN 0-07-015308-6

*cite book |last=Lutovac |first=Miroslav D. |coauthors= Tosic, Dejan V., Evans, Brian L. |title=Filter Design for Signal Processing using MATLAB© and Mathematica© |year=2001 |publisher=Prentice Hall |location=New Jersey, USA |language=English |id=ISBN 0-201-36130-2


Wikimedia Foundation. 2010.

Игры ⚽ Нужно сделать НИР?

Look at other dictionaries:

  • Chebyshev rational functions — This article is not about the Chebyshev rational functions used in the design of elliptic filters. For those functions, see Elliptic rational functions. Plot of the Chebyshev rational functions for n=0,1,2,3 and 4 for x between 0.01 and 100. In… …   Wikipedia

  • Elliptic filter — An elliptic filter (also known as a Cauer filter, named after Wilhelm Cauer) is an electronic filter with equalized ripple (equiripple) behavior in both the passband and the stopband. The amount of ripple in each band is independently adjustable …   Wikipedia

  • Rational elliptische Funktionen — Darstellung der rational elliptischen Funktionen zwischen x= 1 und x=1 für die Ordnungen 1,2,3 und 4 mit dem Selektivfaktor ξ=1,1. Die Rational elliptische Funktionen stellen in der Mathematik eine Reihe von rationalen Funktionen mit reellen… …   Deutsch Wikipedia

  • Elliptic integral — In integral calculus, elliptic integrals originally arose in connection with the problem of giving the arc length of an ellipse. They were first studied by Giulio Fagnano and Leonhard Euler. Modern mathematics defines an elliptic integral as any… …   Wikipedia

  • Elliptic hypergeometric series — In mathematics, an elliptic hypergeometric series is a series Σcn such that the ratio cn/cn−1 is an elliptic function of n, analogous to generalized hypergeometric series where the ratio is a rational function of n, and basic hypergeometric… …   Wikipedia

  • Elliptic curve — In mathematics, an elliptic curve is a smooth, projective algebraic curve of genus one, on which there is a specified point O . An elliptic curve is in fact an abelian variety mdash; that is, it has a multiplication defined algebraically with… …   Wikipedia

  • elliptic integral — noun : the integral as to x of a function rational in x and the square root of a polynomial of third or fourth degree in x * * * Math. a certain kind of definite integral that is not expressible by means of elementary functions. [1880 85] …   Useful english dictionary

  • Weierstrass's elliptic functions — In mathematics, Weierstrass s elliptic functions are elliptic functions that take a particularly simple form; they are named for Karl Weierstrass. This class of functions are also referred to as p functions and generally written using the symbol… …   Wikipedia

  • Lenstra elliptic curve factorization — The Lenstra elliptic curve factorization or the elliptic curve factorization method (ECM) is a fast, sub exponential running time algorithm for integer factorization which employs elliptic curves. Technically, the ECM is classified as a… …   Wikipedia

  • List of mathematical functions — In mathematics, several functions or groups of functions are important enough to deserve their own names. This is a listing of pointers to those articles which explain these functions in more detail. There is a large theory of special functions… …   Wikipedia

Share the article and excerpts

Direct link
Do a right-click on the link above
and select “Copy Link”