Difference between revisions of "Rational function"
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− | + | A rational function is a function $ w = R ( z) $, | |
+ | where $ R ( z) $ | ||
+ | is rational expression in $ z $, | ||
+ | i.e. an expression obtained from an independent variable $ z $ | ||
+ | and some finite set of numbers (real or complex) by means of a finite number of arithmetical operations. A rational function can be written (non-uniquely) in the form | ||
− | + | $$ | |
+ | R ( z) = | ||
+ | \frac{P ( z) }{Q ( z) } | ||
+ | , | ||
+ | $$ | ||
− | + | where $ P $, | |
+ | $ Q $ | ||
+ | are polynomials, $ Q ( z) \not\equiv 0 $. | ||
+ | The coefficients of these polynomials are called the coefficients of the rational function. The function $ P / Q $ | ||
+ | is called irreducible when $ P $ | ||
+ | and $ Q $ | ||
+ | have no common zeros (that is, $ P $ | ||
+ | and $ Q $ | ||
+ | are relatively prime polynomials). Every rational function can be written as an irreducible fraction $ R ( z) = P ( z) / Q ( z) $; | ||
+ | if $ P $ | ||
+ | has degree $ m $ | ||
+ | and $ Q $ | ||
+ | has degree $ n $, | ||
+ | then the degree of $ R ( z) $ | ||
+ | is either taken to be the pair $ ( m , n ) $ | ||
+ | or the number | ||
− | + | $$ | |
+ | N = \max \{ m , n \} . | ||
+ | $$ | ||
− | + | A rational function of degree $ ( m , n ) $ | |
+ | with $ n = 0 $, | ||
+ | that is, a [[Polynomial|polynomial]], is also called an entire rational function. Otherwise it is called a fractional-rational function. The degree of the rational function $ R ( z) \equiv 0 $ | ||
+ | is not defined. When $ m < n $, | ||
+ | the fraction $ P / Q $ | ||
+ | is called proper, and it is called improper otherwise. An improper fraction can be uniquely written as | ||
− | + | $$ | |
+ | |||
+ | \frac{P}{Q} | ||
+ | = P _ {1} + | ||
+ | \frac{P _ {2} }{Q} | ||
+ | , | ||
+ | $$ | ||
+ | |||
+ | where $ P _ {1} $ | ||
+ | is a polynomial, called the integral part of the fraction $ P / Q $, | ||
+ | and $ P _ {2} / Q $ | ||
+ | is a proper fraction. A proper fraction, $ R ( z) = P ( z) / Q ( z) $, | ||
+ | in irreducible form, where | ||
+ | |||
+ | $$ | ||
+ | Q ( z) = b _ {0} ( z - b _ {1} ) ^ {n _ {1} } \dots | ||
+ | ( z - b _ {l} ) ^ {n _ {l} } , | ||
+ | $$ | ||
admits a unique expansion as a sum of simple partial fractions | admits a unique expansion as a sum of simple partial fractions | ||
− | + | $$ \tag{1 } | |
+ | R ( z) = \sum _ { i= } 1 ^ { l } | ||
+ | |||
+ | \frac{c _ {i _ {1} } }{z - b _ {i} } | ||
+ | + \dots | ||
+ | + | ||
+ | \frac{c _ {i _ { n _ i } } }{( z - b _ {i} ) ^ {n _ {i} } } | ||
+ | . | ||
+ | $$ | ||
− | If | + | If $ P ( x) / Q ( x) $ |
+ | is a proper rational function with real coefficients and | ||
− | + | $$ | |
+ | Q ( x) = | ||
+ | $$ | ||
− | + | $$ | |
+ | = \ | ||
+ | b _ {0} ( x - b _ {1} ) ^ {l _ {1} } \dots ( x - b _ {r} ) ^ {l _ {r} } ( x ^ {2} + p _ {1} x + q _ {1} ) ^ {t _ {1} } \dots | ||
+ | ( x ^ {2} + p _ {s} x + q _ {s} ) ^ {t _ {s} } , | ||
+ | $$ | ||
− | where | + | where $ b _ {0} \dots b _ {r} , p _ {1} , q _ {1} \dots p _ {s} , q _ {s} $ |
+ | are real numbers such that $ p _ {j} ^ {2} - 4 q _ {j} < 0 $ | ||
+ | for $ j = 1 \dots s $, | ||
+ | then $ P ( x) / Q ( x) $ | ||
+ | can be uniquely written in the form | ||
− | + | $$ \tag{2 } | |
− | + | \frac{P ( x) }{Q ( x) } | |
+ | = \ | ||
+ | \sum _ { i= } 1 ^ { r } | ||
+ | \left [ | ||
− | + | \frac{c _ {i _ {1} } }{x - b _ {i} } | |
+ | + \dots | ||
+ | + | ||
+ | \frac{c _ {i _ { l _ i } } }{( x - b _ {i} ) ^ {l _ {i} } } | ||
− | + | \right ] + | |
+ | $$ | ||
− | + | $$ | |
+ | + | ||
+ | \sum _ { j= } 1 ^ { s } \left [ | ||
+ | \frac{D _ {j _ {1} } x + E _ {j _ {1} } }{x ^ {2} + p _ {j} x + q _ {j} } | ||
+ | + \dots + | ||
− | + | \frac{D _ {j _ { t _ j } } x + E _ {j _ { t _ j } } }{( x ^ {2} + p _ {j} x + q _ {j} ) ^ {t _ {j} } } | |
+ | \right ] , | ||
+ | $$ | ||
− | + | where all the coefficients are real. These coefficients, like the $ c _ {ij} $ | |
+ | in (1), can be found by the method of indefinite coefficients (cf. [[Undetermined coefficients, method of|Undetermined coefficients, method of]]). | ||
− | and | + | A rational function of degree $ ( m , n ) $ |
+ | in irreducible form is defined and analytic in the extended complex plane (that is, the plane together with the point $ z = \infty $), | ||
+ | except at a finite number of singular points, poles: the zeros of its denominator and, when $ m > n $, | ||
+ | also the point $ \infty $. | ||
+ | Note that if $ m > n $, | ||
+ | the sum of the multiplicities of the poles of $ R $ | ||
+ | is equal to its degree $ N $. | ||
+ | Conversely, if $ R $ | ||
+ | is an analytic function whose only singular points in the extended complex plane are finitely many poles, then $ R $ | ||
+ | is a rational function. | ||
− | + | The application of arithmetical operations (with the exception of division by $ R ( z) \equiv 0 $) | |
+ | to rational functions again gives a rational function, so that the set of all rational functions forms a field. In general, the rational functions with coefficients in a field form a field. If $ R _ {1} ( z) $, | ||
+ | $ R _ {2} ( z) $ | ||
+ | are rational functions, then $ R _ {1} ( R _ {2} ( z) ) $ | ||
+ | is also a rational function. The derivative of order $ p $ | ||
+ | of a rational function of degree $ N $ | ||
+ | is a rational function of degree at most $ ( p + 1 ) N $. | ||
+ | An indefinite integral (or primitive) of a rational function is the sum of a rational function and expressions of the form $ c _ {r} \mathop{\rm log} ( z - b _ {r} ) $. | ||
+ | If a rational function $ R ( x) $ | ||
+ | is real for all real $ x $, | ||
+ | then the indefinite integral $ \int R ( x) d x $ | ||
+ | can be written as the sum of a rational function $ R _ {0} ( x) $ | ||
+ | with real coefficients, expressions of the form | ||
− | + | $$ | |
+ | c _ {i _ {1} } \mathop{\rm log} | x - b _ {i} | ,\ \ | ||
+ | M _ {j} \mathop{\rm log} ( x ^ {2} + p _ {j} x + q _ {j} ) , | ||
+ | $$ | ||
− | + | $$ | |
+ | N _ {j} \mathop{\rm arctan} | ||
+ | \frac{2 x + p _ {j} }{\sqrt {4 q _ {j} - p _ {j} ^ {2} } } | ||
+ | ,\ i = 1 \dots r ; \ j = 1 \dots s , | ||
+ | $$ | ||
+ | |||
+ | and an arbitrary constant $ C $( | ||
+ | where $ c _ {i _ {1} } $, | ||
+ | $ b _ {i} $, | ||
+ | $ p _ {j} $, | ||
+ | $ q _ {j} $ | ||
+ | are the same as in (2), and $ M _ {j} $, | ||
+ | $ N _ {j} $ | ||
+ | are real numbers). The function $ R _ {0} ( x) $ | ||
+ | can be found by the [[Ostrogradski method|Ostrogradski method]], which avoids the need to expand $ R ( x) $ | ||
+ | into partial fractions (2). | ||
+ | |||
+ | For ease of computation, rational functions can be used to approximate a given function. Attention has also been paid to rational functions $ R = P / Q $ | ||
+ | in several real or complex variables, where $ P $ | ||
+ | and $ Q $ | ||
+ | are polynomials in these variables with $ Q \not\equiv 0 $, | ||
+ | and to abstract rational functions | ||
+ | |||
+ | $$ | ||
+ | R = \ | ||
+ | |||
+ | \frac{A _ {1} \Phi _ {1} + \dots + A _ {m} \Phi _ {m} }{B _ {1} \Phi _ {1} + \dots + B _ {n} \Phi _ {n} } | ||
+ | , | ||
+ | $$ | ||
+ | |||
+ | where $ \Phi _ {1} , \Phi _ {2} \dots $ | ||
+ | are linearly independent functions on some compact space $ X $, | ||
+ | and $ A _ {1} \dots A _ {m} , B _ {1} \dots B _ {n} $ | ||
+ | are numbers. See also [[Fractional-linear function|Fractional-linear function]]; [[Zhukovskii function|Zhukovskii function]]. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> I.I. [I.I. Privalov] Priwalow, "Einführung in die Funktionentheorie" , '''1–3''' , Teubner (1958–1959) (Translated from Russian) {{MR|0342680}} {{MR|0264037}} {{MR|0264036}} {{MR|0264038}} {{MR|0123686}} {{MR|0123685}} {{MR|0098843}} {{ZBL|0177.33401}} {{ZBL|0141.26003}} {{ZBL|0141.26002}} {{ZBL|0082.28802}} </TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> A.G. Kurosh, "Higher algebra" , MIR (1972) (Translated from Russian) {{MR|0945393}} {{MR|0926059}} {{MR|0778202}} {{MR|0759341}} {{MR|0628003}} {{MR|0384363}} {{ZBL|0237.13001}} </TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> I.I. [I.I. Privalov] Priwalow, "Einführung in die Funktionentheorie" , '''1–3''' , Teubner (1958–1959) (Translated from Russian) {{MR|0342680}} {{MR|0264037}} {{MR|0264036}} {{MR|0264038}} {{MR|0123686}} {{MR|0123685}} {{MR|0098843}} {{ZBL|0177.33401}} {{ZBL|0141.26003}} {{ZBL|0141.26002}} {{ZBL|0082.28802}} </TD></TR><TR><TD valign="top">[2]</TD> <TD valign="top"> A.G. Kurosh, "Higher algebra" , MIR (1972) (Translated from Russian) {{MR|0945393}} {{MR|0926059}} {{MR|0778202}} {{MR|0759341}} {{MR|0628003}} {{MR|0384363}} {{ZBL|0237.13001}} </TD></TR></table> | ||
− | |||
− | |||
====Comments==== | ====Comments==== | ||
Line 60: | Line 203: | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> J.B. Conway, "Functions of one complex variable" , Springer (1973) {{MR|0447532}} {{ZBL|0277.30001}} </TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> S. Lang, "Algebra" , Addison-Wesley (1984) {{MR|0783636}} {{ZBL|0712.00001}} </TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> J.B. Conway, "Functions of one complex variable" , Springer (1973) {{MR|0447532}} {{ZBL|0277.30001}} </TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> S. Lang, "Algebra" , Addison-Wesley (1984) {{MR|0783636}} {{ZBL|0712.00001}} </TD></TR></table> | ||
− | Rational functions on an algebraic variety are a generalization of the classical concept of a rational function (see section 1)). A rational function on an irreducible [[Algebraic variety|algebraic variety]] | + | Rational functions on an algebraic variety are a generalization of the classical concept of a rational function (see section 1)). A rational function on an irreducible [[Algebraic variety|algebraic variety]] $ X $ |
+ | is an equivalence class of pairs $ ( U , f ) $, | ||
+ | where $ U $ | ||
+ | is a non-empty open subset of $ X $ | ||
+ | and $ f $ | ||
+ | is a [[Regular function|regular function]] on $ U $. | ||
+ | Two pairs $ ( U , f ) $ | ||
+ | and $ ( V , g ) $ | ||
+ | are said to be equivalent if $ f = g $ | ||
+ | on $ U \cap V $. | ||
+ | The rational functions on $ X $ | ||
+ | form a field, denoted by $ k ( X) $. | ||
− | In the case when | + | In the case when $ X = \mathop{\rm spec} R $ |
+ | is an irreducible [[Affine variety|affine variety]], the field of rational functions on $ X $ | ||
+ | coincides with the field of fractions of the ring $ R $. | ||
+ | The transcendence degree of $ k ( X) $ | ||
+ | over $ k $ | ||
+ | is called the dimension of the variety $ X $. | ||
====References==== | ====References==== |
Revision as of 08:09, 6 June 2020
A rational function is a function $ w = R ( z) $,
where $ R ( z) $
is rational expression in $ z $,
i.e. an expression obtained from an independent variable $ z $
and some finite set of numbers (real or complex) by means of a finite number of arithmetical operations. A rational function can be written (non-uniquely) in the form
$$ R ( z) = \frac{P ( z) }{Q ( z) } , $$
where $ P $, $ Q $ are polynomials, $ Q ( z) \not\equiv 0 $. The coefficients of these polynomials are called the coefficients of the rational function. The function $ P / Q $ is called irreducible when $ P $ and $ Q $ have no common zeros (that is, $ P $ and $ Q $ are relatively prime polynomials). Every rational function can be written as an irreducible fraction $ R ( z) = P ( z) / Q ( z) $; if $ P $ has degree $ m $ and $ Q $ has degree $ n $, then the degree of $ R ( z) $ is either taken to be the pair $ ( m , n ) $ or the number
$$ N = \max \{ m , n \} . $$
A rational function of degree $ ( m , n ) $ with $ n = 0 $, that is, a polynomial, is also called an entire rational function. Otherwise it is called a fractional-rational function. The degree of the rational function $ R ( z) \equiv 0 $ is not defined. When $ m < n $, the fraction $ P / Q $ is called proper, and it is called improper otherwise. An improper fraction can be uniquely written as
$$ \frac{P}{Q} = P _ {1} + \frac{P _ {2} }{Q} , $$
where $ P _ {1} $ is a polynomial, called the integral part of the fraction $ P / Q $, and $ P _ {2} / Q $ is a proper fraction. A proper fraction, $ R ( z) = P ( z) / Q ( z) $, in irreducible form, where
$$ Q ( z) = b _ {0} ( z - b _ {1} ) ^ {n _ {1} } \dots ( z - b _ {l} ) ^ {n _ {l} } , $$
admits a unique expansion as a sum of simple partial fractions
$$ \tag{1 } R ( z) = \sum _ { i= } 1 ^ { l } \frac{c _ {i _ {1} } }{z - b _ {i} } + \dots + \frac{c _ {i _ { n _ i } } }{( z - b _ {i} ) ^ {n _ {i} } } . $$
If $ P ( x) / Q ( x) $ is a proper rational function with real coefficients and
$$ Q ( x) = $$
$$ = \ b _ {0} ( x - b _ {1} ) ^ {l _ {1} } \dots ( x - b _ {r} ) ^ {l _ {r} } ( x ^ {2} + p _ {1} x + q _ {1} ) ^ {t _ {1} } \dots ( x ^ {2} + p _ {s} x + q _ {s} ) ^ {t _ {s} } , $$
where $ b _ {0} \dots b _ {r} , p _ {1} , q _ {1} \dots p _ {s} , q _ {s} $ are real numbers such that $ p _ {j} ^ {2} - 4 q _ {j} < 0 $ for $ j = 1 \dots s $, then $ P ( x) / Q ( x) $ can be uniquely written in the form
$$ \tag{2 } \frac{P ( x) }{Q ( x) } = \ \sum _ { i= } 1 ^ { r } \left [ \frac{c _ {i _ {1} } }{x - b _ {i} } + \dots + \frac{c _ {i _ { l _ i } } }{( x - b _ {i} ) ^ {l _ {i} } } \right ] + $$
$$ + \sum _ { j= } 1 ^ { s } \left [ \frac{D _ {j _ {1} } x + E _ {j _ {1} } }{x ^ {2} + p _ {j} x + q _ {j} } + \dots + \frac{D _ {j _ { t _ j } } x + E _ {j _ { t _ j } } }{( x ^ {2} + p _ {j} x + q _ {j} ) ^ {t _ {j} } } \right ] , $$
where all the coefficients are real. These coefficients, like the $ c _ {ij} $ in (1), can be found by the method of indefinite coefficients (cf. Undetermined coefficients, method of).
A rational function of degree $ ( m , n ) $ in irreducible form is defined and analytic in the extended complex plane (that is, the plane together with the point $ z = \infty $), except at a finite number of singular points, poles: the zeros of its denominator and, when $ m > n $, also the point $ \infty $. Note that if $ m > n $, the sum of the multiplicities of the poles of $ R $ is equal to its degree $ N $. Conversely, if $ R $ is an analytic function whose only singular points in the extended complex plane are finitely many poles, then $ R $ is a rational function.
The application of arithmetical operations (with the exception of division by $ R ( z) \equiv 0 $) to rational functions again gives a rational function, so that the set of all rational functions forms a field. In general, the rational functions with coefficients in a field form a field. If $ R _ {1} ( z) $, $ R _ {2} ( z) $ are rational functions, then $ R _ {1} ( R _ {2} ( z) ) $ is also a rational function. The derivative of order $ p $ of a rational function of degree $ N $ is a rational function of degree at most $ ( p + 1 ) N $. An indefinite integral (or primitive) of a rational function is the sum of a rational function and expressions of the form $ c _ {r} \mathop{\rm log} ( z - b _ {r} ) $. If a rational function $ R ( x) $ is real for all real $ x $, then the indefinite integral $ \int R ( x) d x $ can be written as the sum of a rational function $ R _ {0} ( x) $ with real coefficients, expressions of the form
$$ c _ {i _ {1} } \mathop{\rm log} | x - b _ {i} | ,\ \ M _ {j} \mathop{\rm log} ( x ^ {2} + p _ {j} x + q _ {j} ) , $$
$$ N _ {j} \mathop{\rm arctan} \frac{2 x + p _ {j} }{\sqrt {4 q _ {j} - p _ {j} ^ {2} } } ,\ i = 1 \dots r ; \ j = 1 \dots s , $$
and an arbitrary constant $ C $( where $ c _ {i _ {1} } $, $ b _ {i} $, $ p _ {j} $, $ q _ {j} $ are the same as in (2), and $ M _ {j} $, $ N _ {j} $ are real numbers). The function $ R _ {0} ( x) $ can be found by the Ostrogradski method, which avoids the need to expand $ R ( x) $ into partial fractions (2).
For ease of computation, rational functions can be used to approximate a given function. Attention has also been paid to rational functions $ R = P / Q $ in several real or complex variables, where $ P $ and $ Q $ are polynomials in these variables with $ Q \not\equiv 0 $, and to abstract rational functions
$$ R = \ \frac{A _ {1} \Phi _ {1} + \dots + A _ {m} \Phi _ {m} }{B _ {1} \Phi _ {1} + \dots + B _ {n} \Phi _ {n} } , $$
where $ \Phi _ {1} , \Phi _ {2} \dots $ are linearly independent functions on some compact space $ X $, and $ A _ {1} \dots A _ {m} , B _ {1} \dots B _ {n} $ are numbers. See also Fractional-linear function; Zhukovskii function.
References
[1] | I.I. [I.I. Privalov] Priwalow, "Einführung in die Funktionentheorie" , 1–3 , Teubner (1958–1959) (Translated from Russian) MR0342680 MR0264037 MR0264036 MR0264038 MR0123686 MR0123685 MR0098843 Zbl 0177.33401 Zbl 0141.26003 Zbl 0141.26002 Zbl 0082.28802 |
[2] | A.G. Kurosh, "Higher algebra" , MIR (1972) (Translated from Russian) MR0945393 MR0926059 MR0778202 MR0759341 MR0628003 MR0384363 Zbl 0237.13001 |
Comments
For approximation results see Padé approximation.
References
[a1] | J.B. Conway, "Functions of one complex variable" , Springer (1973) MR0447532 Zbl 0277.30001 |
[a2] | S. Lang, "Algebra" , Addison-Wesley (1984) MR0783636 Zbl 0712.00001 |
Rational functions on an algebraic variety are a generalization of the classical concept of a rational function (see section 1)). A rational function on an irreducible algebraic variety $ X $ is an equivalence class of pairs $ ( U , f ) $, where $ U $ is a non-empty open subset of $ X $ and $ f $ is a regular function on $ U $. Two pairs $ ( U , f ) $ and $ ( V , g ) $ are said to be equivalent if $ f = g $ on $ U \cap V $. The rational functions on $ X $ form a field, denoted by $ k ( X) $.
In the case when $ X = \mathop{\rm spec} R $ is an irreducible affine variety, the field of rational functions on $ X $ coincides with the field of fractions of the ring $ R $. The transcendence degree of $ k ( X) $ over $ k $ is called the dimension of the variety $ X $.
References
[1] | I.R. Shafarevich, "Basic algebraic geometry" , Springer (1977) (Translated from Russian) MR0447223 Zbl 0362.14001 |
Vik.S. Kulikov
Rational function. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Rational_function&oldid=23949