Fuchsian theory explained

The Fuchsian theory of linear differential equations, which is named after Lazarus Immanuel Fuchs, provides a characterization of various types of singularities and the relations among them.

At any ordinary point of a homogeneous linear differential equation of order

there exists a fundamental system of

linearly independent power series solutions. A non-ordinary point is called a singularity. At a singularity the maximal number of linearly independent power series solutions may be less than the order of the differential equation.

Generalized series solutions

The generalized series at

\xi\inC

is defined by

	infty
(z-\xi)
	k=0

	k,
c
	k(z-\xi)

with\alpha,c_k\inCandc_{0 ≠ 0,}

which is known as Frobenius series, due to the connection with the Frobenius series method. Frobenius series solutions are formal solutions of differential equations. The formal derivative of

z^\alpha

, with

\alpha\inC

, is defined such that

(z^{\alpha)'=\alpha}z^\alpha-1

. Let

denote a Frobenius series relative to

\xi

, then

{d^nf\overdz^n}=(z-\xi)^\alpha-n

	infty
\sum
	k=0

(\alpha+k)^\underline{n

} c_k(z-\xi)^k,

where $\alpha^:=\prod_^(\alpha-i) = \alpha(\alpha-1)\cdots(\alpha-n+1)$ denotes the falling factorial notation.

Indicial equation

Let $f:=(z-\xi)^\sum_^c_k(z-\xi)^k$ be a Frobenius series relative to

\xi\inC

. Let

Lf=f⁽ⁿ⁾+

	(n-1)
q
	1f

+ … +q_nf

be a linear differential operator of order

with one valued coefficient functions

q_1,...,q_n

. Let all coefficients

q_1,...,q_n

be expandable as Laurent series with finite principle part at

\xi

. Then there exists a smallest

N\inN

such that

	Nq
(z-\xi)
	i

is a power series for all

i\in\{1,...,n\}

. Hence,

is a Frobenius series of the form

Lf=(z-\xi)^\alpha-n-N\psi(z)

, with a certain power series

\psi(z)

(z-\xi)

. The indicial polynomial is defined by

P_\xi:=\psi(0)

which is a polynomial in

\alpha

, i.e.,

P_\xi

equals the coefficient of

with lowest degree in

(z-\xi)

. For each formal Frobenius series solution

Lf=0

\alpha

must be a root of the indicial polynomial at

\xi

, i. e.,

\alpha

needs to solve the indicial equation

P_\xi(\alpha)=0

.^[1]

\xi

is an ordinary point, the resulting indicial equation is given by

\alpha^\underline{n

}=0. If

\xi

is a regular singularity, then

\deg(P_\xi(\alpha))=n

and if

\xi

is an irregular singularity,

\deg(P_\xi(\alpha))<n

holds.^[2] This is illustrated by the later examples. The indicial equation relative to

\xi=infty

is defined by the indicial equation of

\widetilde{L}f

, where

\widetilde{L}

denotes the differential operator

transformed by

z=x^-1

which is a linear differential operator in

, at

x=0

.^[3]

Example: Regular singularity

The differential operator of order

Lf:=f''+

	1	f'+
	z

	1
	z²

, has a regular singularity at

z=0

. Consider a Frobenius series solution relative to

f:=

	\alpha(c
z
	0

+c_1z+c₂z²+ … )

with

c_{0 ≠ 0}

\begin{align} Lf&=z^\alpha-2(\alpha(\alpha-1)c₀+ … )+

	1
	z

z^\alpha-1(\alphac₀+ … )+

	1
	z²

z^\alpha(c₀+ … )\\[5pt] &=z^\alpha-2c_{0(\alpha(\alpha-1)}+\alpha+1)+ … . \end{align}

This implies that the degree of the indicial polynomial relative to

is equal to the order of the differential equation,

\deg(P_0(\alpha))=\deg(\alpha²+1)=2

Example: Irregular singularity

The differential operator of order

Lf:=f''+	1
	z²

f'+f

, has an irregular singularity at

z=0

. Let

be a Frobenius series solution relative to

\begin{align} Lf&=z^\alpha-2(\alpha(\alpha-1)c₀+ … )+

	1
	z²

z^\alpha-1(\alphac₀+ … )+z^\alpha(c₀+ … )\\[5pt] &=z^\alpha-3c₀\alpha+z^\alpha-2(c_{0\alpha(\alpha-1)}+c₁₎+ … . \end{align}

Certainly, at least one coefficient of the lower derivatives pushes the exponent of

down. Inevitably, the coefficient of a lower derivative is of smallest exponent. The degree of the indicial polynomial relative to

is less than the order of the differential equation,

\deg(P_0(\alpha))=\deg(\alpha)=1<2

Formal fundamental systems

We have given a homogeneous linear differential equation

Lf=0

of order

with coefficients that are expandable as Laurent series with finite principle part. The goal is to obtain a fundamental set of formal Frobenius series solutions relative to any point

\xi\inC

. This can be done by the Frobenius series method, which says: The starting exponents are given by the solutions of the indicial equation and the coefficients describe a polynomial recursion. W.l.o.g., assume

\xi=0

Fundamental system at ordinary point

is an ordinary point, a fundamental system is formed by the

linearly independent formal Frobenius series solutions

\psi_1,z\psi_2,...,z^n-1\psi_n

, where

\psi_i\in\mathbb z

denotes a formal power series in

with

\psi(0) ≠ 0

, for

i\in\{1,...,n\}

. Due to the reason that the starting exponents are integers, the Frobenius series are power series.

Fundamental system at regular singularity

is a regular singularity, one has to pay attention to roots of the indicial polynomial that differ by integers. In this case the recursive calculation of the Frobenius series' coefficients stops for some roots and the Frobenius series method does not give an

-dimensional solution space. The following can be shown independent of the distance between roots of the indicial polynomial: Let

\alpha\inC

be a

\mu

-fold root of the indicial polynomial relative to

. Then the part of the fundamental system corresponding to

\alpha

is given by the

\mu

linearly independent formal solutions

\begin{align} &z^\alpha\psi₀\\ &z^\alpha\psi₁+

	\alphalog(z)\psi
z
	0\\ &

z^\alpha\psi₂+

	\alphalog(z)\psi
2z
	1

+z^\alphalog

	2(z)\psi

	0\\ &

\vdots\\ &z^\alpha\psi_\mu-1+ … +\binom{\mu-1}{k}z^\alpha

	k(z)\psi
log
	\mu-k

+ … +z^\alphalog^\mu-1(z)\psi_{0
\end{align}}

where $\psi_i\in\mathbb z$ denotes a formal power series in

with

\psi(0) ≠ 0

, for

i\in\{0,...,\mu-1\}

. One obtains a fundamental set of

linearly independent formal solutions, because the indicial polynomial relative to a regular singularity is of degree

.^[4]

General result

One can show that a linear differential equation of order

always has

linearly independent solutions of the form

\exp(u(z^-1/s)) ⋅

	1/s
z
	0(z

)+ … +log^k(z)

	1/s
\psi
	k(z

)+ … +log^w(z)

	1/s
\psi
	w(z

))

where

s\inN\setminus\{0\},u(z)\inC[z]

and

u(0)=0,\alpha\inC,w\inN

, and the formal power series

\psi_{0(z),...,\psi}_w\inC[[z]]

.^[5]

is an irregular singularity if and only if there is a solution with

u ≠ 0

. Hence, a differential equation is of Fuchsian type if and only if for all

\xi\inC\cup\{infty\}

there exists a fundamental system of Frobenius series solutions with

u=0

\xi

References

Book: Ince, Edward Lindsay. Ordinary Differential Equations. Dover Publications. 1956. 9780486158211. New York, USA.
Book: Poole, Edgar Girard Croker. Clarendon Press. Introduction to the theory of linear differential equations. New York. 1936.
Book: Ordinary Differential Equations. Tenenbaum. Pollard. Morris. Harry. Dover Publications. 1963. 9780486649405. New York, USA. Lecture 40.
Book: Horn, Jakob. Gewöhnliche Differentialgleichungen beliebiger Ordnung. G. J. Göschensche Verlagshandlung. 1905. Leipzig, Germany.
Book: Schlesinger, Ludwig Lindsay. Handbuch der Theorie der linearen Differentialgleichungen (2. Band, 1. Teil). B. G.Teubner. 1897. Leipzig, Germany. 241 ff.

Notes and References

Book: Ordinary Differential Equations. Tenenbaum. Morris. Pollard. Harry. Dover Publications. 1963. 9780486649405. New York, USA. Lesson 40.
Book: Ince, Edward Lindsay. Ordinary Differential Equations. limited. Dover Publications. 1956. 9780486158211. New York, USA. 160.
Book: Ince, Edward Lindsay. Ordinary Differential Equations. limited. Dover Publications. 1956. 9780486158211. New York, USA. 370.
Book: Ince, Edward Lindsay. Ordinary Differential Equations. Dover Publications. 1956. 9780486158211. New York, USA. Section 16.3.
Book: The Concrete Tetrahedron. Kauers. Manuel. Paule. Peter. Springer-Verlag. 2011. 9783709104453. Vienna, Austria. Theorem 7.3.