Incomplete gamma function
Encyclopedia
In mathematics
, the gamma function
is defined by a definite integral
. The incomplete gamma function is defined as an integral function of the same integrand
. There are two varieties of the incomplete gamma function: the upper incomplete gamma function is for the case that the lower limit of integration is variable (i.e. where the "upper" limit is fixed), and the lower incomplete gamma function can vary the upper limit of integration.
The upper incomplete gamma function is defined as:
The lower incomplete gamma function is defined as:
By integration by parts
we find the recurrence relations
and conversely
Since the ordinary gamma function is defined as
we have
s, with respect both to x and s, defined for almost all combinations of complex x and s.. Complex analysis shows how properties of the real incomplete gamma functions extend to their holomorphic counterparts.
Repeated application of the recurrence relation for the lower incomplete gamma function leads to the power series expansion: http://dlmf.nist.gov/8.8.E7
Given the rapid growth in absolute value of
when k → ∞, and the fact that the reciprocal of
is an entire function
, the coefficients in the rightmost sum are well-defined, and locally the sum converges uniformly for all complex s and x. By a theorem of Weierstraß, the limiting function, sometimes denoted as
,
http://dlmf.nist.gov/8.7.E1
is entire
with respect to both z (for fixed s) and s (for fixed z) http://dlmf.nist.gov/8.2.ii, and, thus, holomorphic on ℂ×ℂ by Hartog's theoremhttp://www.math.umn.edu/~garrett/m/complex/hartogs.pdf. Hence, the following decomposition
http://dlmf.nist.gov/8.2.E6,
extends the real lower incomplete gamma function as a holomorphic
function, both jointly and separately in z and s. It follows from the properties of
and the 
-function
, that the first two factors capture the singularities
of
(z = 0 and s a non-positive integer), whereas the last factor contributes to its zeros.
In particular, the factor
causes 
to be multi-valued for s not an integer. This complication is often overcome by cutting the image
of
, for fixed s, (usually) along the negative real axis into separate, single-valued branches
, and then restricting oneself to the principal branch
corresponding to that of
. Values from other branches can be derived by multiplication by 
http://dlmf.nist.gov/8.2.E8, k an integer. (For another view on these phenomena see Riemann surfaces
).
The decomposition above further shows, that
behaves near z = 0 asymptotically like:
For positive real x, y and s,
, when (x, y) → (0, s). This seems to justify setting 
for real s > 0. However, matters are somewhat different in the complex realm. Only if (a) the real part of s is positive, and (b) values from just a finite set of branches of 
are taken, then 
is guaranteed to converge to zero as (u, v) → (0, s), and so does 
. A single branch
of
naturally fulfills (b), so 
for s with positive real part is a continuous limit
there. Also note that such a continuation is by no means an analytic one
.
All algebraic relations and differential equations observed by the real
hold for its holomorphic counterpart as well. This is a consequence of the identity theorem http://planetmath.org/encyclopedia/RigidityTheoremForAnalyticFunctions.html, stating that equations between holomorphic functions valid on a real interval, hold everywhere. In particular, the recurrence relation http://dlmf.nist.gov/8.8.E1 and 
http://dlmf.nist.gov/8.8.E12 are preserved on corresponding branches.
The last relation tells us, that, for fixed s,
is a primitive or antiderivative of the holomorphic function 
. Consequently http://planetmath.org/encyclopedia/ComplexAntiderivative.html, for any complex u, v ≠ 0,
holds, as long as the path of integration
does not wind around the singular branch point 0. If the path is entirely contained in the interior of a single branch of the integrand, and the real part of s is positive, then the limit
→ 0 for u → 0 applies, finally arriving at the complex integral definition of 
http://dlmf.nist.gov/8.2.E1
Any path of integration containing 0 only at its beginning, and never crossing or touching the negative real line, is valid here, for example, the straight line connecting 0 and z. If z is a negative real, some technical adjustments are required to guarantee the result is from the correct branch.
is:
extension, with respect to z or s, is given by
http://dlmf.nist.gov/8.2.E3
at points (s, z), where the right hand side exists. Since
is multi-valued, the same holds for 
, but a restriction to principal values only yields the single-valued principal branch of 
.
When s is a non-positive integer in the above equation, neither part of the difference is defined, and a limiting process
, here developed for s → 0, fills in the missing values. Complex analysis
guarantees holomorphicity, because
proves to be bounded
in a neighbourhood
of that limit for a fixed zhttp://planetmath.org/encyclopedia/RiemannsRemovableSingularityTheorem.html.
To determine the limit, the power series of
at z = 0 turns out useful. When replacing 
by its power series in the integral definition of 
, one obtains (assume x,s positive reals for now):
or
. http://dlmf.nist.gov/8.7.E1
which, as a series representation of the entire
function, converges for all complex x (and all complex s not a non-positive integer).
With its restriction to real values lifted, the series allows the expansion:
When s → 0:
,
(
is the Euler-Mascheroni constant
here), hence,
is the limiting function to the upper incomplete gamma function as s → 0, also known as
.
By way of the recurrence relation, values of
for positive integers n can be derived from this result, so the upper incomplete gamma function proves to exist and be holomorphic, with respect both to z and s, for all s and z ≠ 0.
is:
Here, Ei is the exponential integral
, erf is the error function
, and erfc is the complementary error function, erfc(x) = 1 − erf(x).
where M is Kummer's confluent hypergeometric function
.
where
has an infinite radius of convergence.
Again with confluent hypergeometric functions and employing Kummer's identity,
For the actual computation of numerical values, Gauss's continued fraction provides a useful expansion:
This continued fraction converges for all complex z, provided only that s is not a negative integer.
The upper gamma function has the continued fraction
and
holds true:
is the cumulative distribution function
for Gamma random variables with shape parameter
and scale parameter
1.
When
is an integer, 
is the cumulative distribution function for Poisson random variables: If 
is a 
random variable then
This formula can be derived by repeated integration by parts.
with respect to x is well known. It is simply given by the integrand of its integral definition:
The derivative with respect to its first argument
is given by
and the second derivative by
where the function
is a special case of the Meijer G-function
This particular special case has internal closure properties of its own because it can be used to express all successive derivatives. In general,
where
All such derivatives can be generated in succession from:
and
This function
can be computed from its series representation valid for 
,
with the understanding that s is not a negative integer or zero. In such a case, one must use a limit. Results for
can be obtained by analytic continuation
. Some special cases of this function can be simplified. For example,
, 
, where 
is the Exponential integral
. These derivatives and the function
provide exact solutions to a number of integrals by repeated differentiation of the integral definition of the upper incomplete gamma function.
For example,
This formula can be further inflated or generalized to a huge class of Laplace transforms and Mellin transform
s. When combined with a computer algebra system
, the exploitation of special functions provides a powerful method for solving definite integrals, in particular those encountered by practical engineering applications (see Symbolic integration
for more details).
:
The lower and the upper incomplete Gamma function are connected via the Fourier transform
:
This follows, for example, by suitable specialization of .
Mathematics
Mathematics is the study of quantity, space, structure, and change. Mathematicians seek out patterns and formulate new conjectures. Mathematicians resolve the truth or falsity of conjectures by mathematical proofs, which are arguments sufficient to convince other mathematicians of their validity...
, the gamma function
Gamma function
In mathematics, the gamma function is an extension of the factorial function, with its argument shifted down by 1, to real and complex numbers...
is defined by a definite integral
Integral
Integration is an important concept in mathematics and, together with its inverse, differentiation, is one of the two main operations in calculus...
. The incomplete gamma function is defined as an integral function of the same integrand
Integral
Integration is an important concept in mathematics and, together with its inverse, differentiation, is one of the two main operations in calculus...
. There are two varieties of the incomplete gamma function: the upper incomplete gamma function is for the case that the lower limit of integration is variable (i.e. where the "upper" limit is fixed), and the lower incomplete gamma function can vary the upper limit of integration.
The upper incomplete gamma function is defined as:
The lower incomplete gamma function is defined as:
Properties
In both cases s is a complex parameter, such that the real part of s is positive.By integration by parts
Integration by parts
In calculus, and more generally in mathematical analysis, integration by parts is a rule that transforms the integral of products of functions into other integrals...
we find the recurrence relations
and conversely
Since the ordinary gamma function is defined as
we have
Continuation to complex values
The lower incomplete gamma and the upper incomplete gamma function, as defined above for real positive s and x, can be developed into holomorphic functionHolomorphic function
In mathematics, holomorphic functions are the central objects of study in complex analysis. A holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighborhood of every point in its domain...
s, with respect both to x and s, defined for almost all combinations of complex x and s.. Complex analysis shows how properties of the real incomplete gamma functions extend to their holomorphic counterparts.
Holomorphic Extension
Repeated application of the recurrence relation for the lower incomplete gamma function leads to the power series expansion: http://dlmf.nist.gov/8.8.E7
Given the rapid growth in absolute value of
Gamma function
In mathematics, the gamma function is an extension of the factorial function, with its argument shifted down by 1, to real and complex numbers...
when k → ∞, and the fact that the reciprocal of
is an entire functionEntire function
In complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic over the whole complex plane...
, the coefficients in the rightmost sum are well-defined, and locally the sum converges uniformly for all complex s and x. By a theorem of Weierstraß, the limiting function, sometimes denoted as
, http://dlmf.nist.gov/8.7.E1is entire
Entire function
In complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic over the whole complex plane...
with respect to both z (for fixed s) and s (for fixed z) http://dlmf.nist.gov/8.2.ii, and, thus, holomorphic on ℂ×ℂ by Hartog's theoremhttp://www.math.umn.edu/~garrett/m/complex/hartogs.pdf. Hence, the following decomposition
http://dlmf.nist.gov/8.2.E6,extends the real lower incomplete gamma function as a holomorphic
Holomorphic function
In mathematics, holomorphic functions are the central objects of study in complex analysis. A holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighborhood of every point in its domain...
function, both jointly and separately in z and s. It follows from the properties of
and the -functionGamma function
In mathematics, the gamma function is an extension of the factorial function, with its argument shifted down by 1, to real and complex numbers...
, that the first two factors capture the singularities
Mathematical singularity
In mathematics, a singularity is in general a point at which a given mathematical object is not defined, or a point of an exceptional set where it fails to be well-behaved in some particular way, such as differentiability...
of
(z = 0 and s a non-positive integer), whereas the last factor contributes to its zeros.Branches
In particular, the factor
causes to be multi-valued for s not an integer. This complication is often overcome by cutting the imageImage (mathematics)
In mathematics, an image is the subset of a function's codomain which is the output of the function on a subset of its domain. Precisely, evaluating the function at each element of a subset X of the domain produces a set called the image of X under or through the function...
of
, for fixed s, (usually) along the negative real axis into separate, single-valued branchesBranch point
In the mathematical field of complex analysis, a branch point of a multi-valued function is a point such that the function is discontinuous when going around an arbitrarily small circuit around this point...
, and then restricting oneself to the principal branch
Principal branch
In mathematics, a principal branch is a function which selects one branch, or "slice", of a multi-valued function. Most often, this applies to functions defined on the complex plane: see branch cut....
corresponding to that of
. Values from other branches can be derived by multiplication by http://dlmf.nist.gov/8.2.E8, k an integer. (For another view on these phenomena see Riemann surfacesRiemann surface
In mathematics, particularly in complex analysis, a Riemann surface, first studied by and named after Bernhard Riemann, is a one-dimensional complex manifold. Riemann surfaces can be thought of as "deformed versions" of the complex plane: locally near every point they look like patches of the...
).
Behavior near Branch Point
The decomposition above further shows, that
behaves near z = 0 asymptotically like:For positive real x, y and s,
, when (x, y) → (0, s). This seems to justify setting for real s > 0. However, matters are somewhat different in the complex realm. Only if (a) the real part of s is positive, and (b) values from just a finite set of branches of are taken, then is guaranteed to converge to zero as (u, v) → (0, s), and so does . A single branchBranch point
In the mathematical field of complex analysis, a branch point of a multi-valued function is a point such that the function is discontinuous when going around an arbitrarily small circuit around this point...
of
naturally fulfills (b), so for s with positive real part is a continuous limitContinuous function
In mathematics, a continuous function is a function for which, intuitively, "small" changes in the input result in "small" changes in the output. Otherwise, a function is said to be "discontinuous". A continuous function with a continuous inverse function is called "bicontinuous".Continuity of...
there. Also note that such a continuation is by no means an analytic one
Analytic continuation
In complex analysis, a branch of mathematics, analytic continuation is a technique to extend the domain of a given analytic function. Analytic continuation often succeeds in defining further values of a function, for example in a new region where an infinite series representation in terms of which...
.
Algebraic Relations
All algebraic relations and differential equations observed by the real
hold for its holomorphic counterpart as well. This is a consequence of the identity theorem http://planetmath.org/encyclopedia/RigidityTheoremForAnalyticFunctions.html, stating that equations between holomorphic functions valid on a real interval, hold everywhere. In particular, the recurrence relation http://dlmf.nist.gov/8.8.E1 and http://dlmf.nist.gov/8.8.E12 are preserved on corresponding branches.Integral Representation
The last relation tells us, that, for fixed s,
is a primitive or antiderivative of the holomorphic function . Consequently http://planetmath.org/encyclopedia/ComplexAntiderivative.html, for any complex u, v ≠ 0,holds, as long as the path of integration
Line integral
In mathematics, a line integral is an integral where the function to be integrated is evaluated along a curve.The function to be integrated may be a scalar field or a vector field...
does not wind around the singular branch point 0. If the path is entirely contained in the interior of a single branch of the integrand, and the real part of s is positive, then the limit
→ 0 for u → 0 applies, finally arriving at the complex integral definition of http://dlmf.nist.gov/8.2.E1Any path of integration containing 0 only at its beginning, and never crossing or touching the negative real line, is valid here, for example, the straight line connecting 0 and z. If z is a negative real, some technical adjustments are required to guarantee the result is from the correct branch.
Overview
is:- entireEntire functionIn complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic over the whole complex plane...
in z for fixed, positive integral s; - multi-valued holomorphicHolomorphic functionIn mathematics, holomorphic functions are the central objects of study in complex analysis. A holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighborhood of every point in its domain...
in z for fixed s not an integer, with a branch pointBranch pointIn the mathematical field of complex analysis, a branch point of a multi-valued function is a point such that the function is discontinuous when going around an arbitrarily small circuit around this point...
at z = 0; - on each branch meromorphic in s for fixed z ≠ 0, with simple poles at non-positive integers s.
Upper Incomplete Gamma Function
As for the upper incomplete gamma function, a holomorphicHolomorphic function
In mathematics, holomorphic functions are the central objects of study in complex analysis. A holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighborhood of every point in its domain...
extension, with respect to z or s, is given by
http://dlmf.nist.gov/8.2.E3at points (s, z), where the right hand side exists. Since
is multi-valued, the same holds for , but a restriction to principal values only yields the single-valued principal branch of .When s is a non-positive integer in the above equation, neither part of the difference is defined, and a limiting process
Limit of a function
In mathematics, the limit of a function is a fundamental concept in calculus and analysis concerning the behavior of that function near a particular input....
, here developed for s → 0, fills in the missing values. Complex analysis
Complex analysis
Complex analysis, traditionally known as the theory of functions of a complex variable, is the branch of mathematical analysis that investigates functions of complex numbers. It is useful in many branches of mathematics, including number theory and applied mathematics; as well as in physics,...
guarantees holomorphicity, because
proves to be boundedBounded function
In mathematics, a function f defined on some set X with real or complex values is called bounded, if the set of its values is bounded. In other words, there exists a real number M...
in a neighbourhood
Neighbourhood (mathematics)
In topology and related areas of mathematics, a neighbourhood is one of the basic concepts in a topological space. Intuitively speaking, a neighbourhood of a point is a set containing the point where you can move that point some amount without leaving the set.This concept is closely related to the...
of that limit for a fixed zhttp://planetmath.org/encyclopedia/RiemannsRemovableSingularityTheorem.html.
To determine the limit, the power series of
at z = 0 turns out useful. When replacing by its power series in the integral definition of , one obtains (assume x,s positive reals for now):or
. http://dlmf.nist.gov/8.7.E1which, as a series representation of the entire
function, converges for all complex x (and all complex s not a non-positive integer).With its restriction to real values lifted, the series allows the expansion:
When s → 0:
,(
is the Euler-Mascheroni constantEuler-Mascheroni constant
The Euler–Mascheroni constant is a mathematical constant recurring in analysis and number theory, usually denoted by the lowercase Greek letter ....
here), hence,
is the limiting function to the upper incomplete gamma function as s → 0, also known as
Exponential integral
In mathematics, the exponential integral is a special function defined on the complex plane given the symbol Ei.-Definitions:For real, nonzero values of x, the exponential integral Ei can be defined as...
.
By way of the recurrence relation, values of
for positive integers n can be derived from this result, so the upper incomplete gamma function proves to exist and be holomorphic, with respect both to z and s, for all s and z ≠ 0. is:- entireEntire functionIn complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic over the whole complex plane...
in z for fixed, positive integral s; - multi-valued holomorphicHolomorphic functionIn mathematics, holomorphic functions are the central objects of study in complex analysis. A holomorphic function is a complex-valued function of one or more complex variables that is complex differentiable in a neighborhood of every point in its domain...
in z for fixed s not an integer, with a branch pointBranch pointIn the mathematical field of complex analysis, a branch point of a multi-valued function is a point such that the function is discontinuous when going around an arbitrarily small circuit around this point...
at z = 0; - =
for s with positive real part and z = 0 (the limit when 
), but this is a continuous extension, not an analytic oneAnalytic continuationIn complex analysis, a branch of mathematics, analytic continuation is a technique to extend the domain of a given analytic function. Analytic continuation often succeeds in defining further values of a function, for example in a new region where an infinite series representation in terms of which...
(does not hold for real s<0!); - on each branch entireEntire functionIn complex analysis, an entire function, also called an integral function, is a complex-valued function that is holomorphic over the whole complex plane...
in s for fixed z ≠ 0.
Special values
-
if s is a positive integerIntegerThe integers are formed by the natural numbers together with the negatives of the non-zero natural numbers .They are known as Positive and Negative Integers respectively...
,
-
if s is a positive integerIntegerThe integers are formed by the natural numbers together with the negatives of the non-zero natural numbers .They are known as Positive and Negative Integers respectively...
,
-
for 
Here, Ei is the exponential integral
Exponential integral
In mathematics, the exponential integral is a special function defined on the complex plane given the symbol Ei.-Definitions:For real, nonzero values of x, the exponential integral Ei can be defined as...
, erf is the error function
Error function
In mathematics, the error function is a special function of sigmoid shape which occurs in probability, statistics and partial differential equations...
, and erfc is the complementary error function, erfc(x) = 1 − erf(x).
Asymptotic behavior
-
as 
-
as 
and 
-
as 
-
as 
-
as an asymptotic series where 
and 
.
Evaluation formulae
The lower gamma function has the straight forward expansionwhere M is Kummer's confluent hypergeometric function
Confluent hypergeometric function
In mathematics, a confluent hypergeometric function is a solution of a confluent hypergeometric equation, which is a degenerate form of a hypergeometric differential equation where two of the three regular singularities merge into an irregular singularity...
.
Connection with Kummer's confluent hypergeometric function
When the real part of z is positive,where
has an infinite radius of convergence.
Again with confluent hypergeometric functions and employing Kummer's identity,
For the actual computation of numerical values, Gauss's continued fraction provides a useful expansion:
This continued fraction converges for all complex z, provided only that s is not a negative integer.
The upper gamma function has the continued fraction
and
Multiplication theorem
The following multiplication theoremMultiplication theorem
In mathematics, the multiplication theorem is a certain type of identity obeyed by many special functions related to the gamma function. For the explicit case of the gamma function, the identity is a product of values; thus the name...
holds true:
Regularized Gamma functions and Poisson random variables
Two related functions are the regularized Gamma functions: is the cumulative distribution functionCumulative distribution function
In probability theory and statistics, the cumulative distribution function , or just distribution function, describes the probability that a real-valued random variable X with a given probability distribution will be found at a value less than or equal to x. Intuitively, it is the "area so far"...
for Gamma random variables with shape parameter
Shape parameter
In probability theory and statistics, a shape parameter is a kind of numerical parameter of a parametric family of probability distributions.- Definition :...
and scale parameterScale parameter
In probability theory and statistics, a scale parameter is a special kind of numerical parameter of a parametric family of probability distributions...
1.
When
is an integer, is the cumulative distribution function for Poisson random variables: If is a random variable thenThis formula can be derived by repeated integration by parts.
Derivatives
The derivative of the upper incomplete gamma function with respect to x is well known. It is simply given by the integrand of its integral definition:The derivative with respect to its first argument
is given byand the second derivative by
where the function
is a special case of the Meijer G-functionMeijer G-Function
In mathematics, the G-function was introduced by as a very general function intended to include most of the known special functions as particular cases. This was not the only attempt of its kind: the generalized hypergeometric function and the MacRobert E-function had the same aim, but Meijer's...
This particular special case has internal closure properties of its own because it can be used to express all successive derivatives. In general,
where
All such derivatives can be generated in succession from:
and
This function
can be computed from its series representation valid for ,with the understanding that s is not a negative integer or zero. In such a case, one must use a limit. Results for
can be obtained by analytic continuationAnalytic continuation
In complex analysis, a branch of mathematics, analytic continuation is a technique to extend the domain of a given analytic function. Analytic continuation often succeeds in defining further values of a function, for example in a new region where an infinite series representation in terms of which...
. Some special cases of this function can be simplified. For example,
, , where is the Exponential integralExponential integral
In mathematics, the exponential integral is a special function defined on the complex plane given the symbol Ei.-Definitions:For real, nonzero values of x, the exponential integral Ei can be defined as...
. These derivatives and the function
provide exact solutions to a number of integrals by repeated differentiation of the integral definition of the upper incomplete gamma function. For example,
This formula can be further inflated or generalized to a huge class of Laplace transforms and Mellin transform
Mellin transform
In mathematics, the Mellin transform is an integral transform that may be regarded as the multiplicative version of the two-sided Laplace transform...
s. When combined with a computer algebra system
Computer algebra system
A computer algebra system is a software program that facilitates symbolic mathematics. The core functionality of a CAS is manipulation of mathematical expressions in symbolic form.-Symbolic manipulations:...
, the exploitation of special functions provides a powerful method for solving definite integrals, in particular those encountered by practical engineering applications (see Symbolic integration
Symbolic integration
In calculus symbolic integration is the problem of finding a formula for the antiderivative, or indefinite integral, of a given function f, i.e...
for more details).
Indefinite and definite integrals
The following indefinite integrals are readily obtained using integration by partsIntegration by parts
In calculus, and more generally in mathematical analysis, integration by parts is a rule that transforms the integral of products of functions into other integrals...
:
The lower and the upper incomplete Gamma function are connected via the Fourier transform
Fourier transform
In mathematics, Fourier analysis is a subject area which grew from the study of Fourier series. The subject began with the study of the way general functions may be represented by sums of simpler trigonometric functions...
:
This follows, for example, by suitable specialization of .
Miscellaneous utilities
-
- Incomplete Gamma Function Calculator -
- Incomplete Gamma Function Calculator - Complemented -
- Incomplete Gamma Function Calculator - Lower Limit of Integration -
- Incomplete Gamma Function Calculator - Upper Limit of Integration - formulas and identities of the Incomplete Gamma Function functions.wolfram.com