Semigroups associated with differential-algebraic equations
Sascha Trostorff

TL;DR
This paper investigates conditions under which differential-algebraic equations in infinite-dimensional spaces can be associated with $C_{0}$-semigroups, focusing on initial value spaces and operator pencils with polynomially bounded resolvents.
Contribution
It characterizes the existence of $C_{0}$-semigroups for infinite-dimensional differential-algebraic equations and identifies the appropriate initial value spaces.
Findings
Identifies conditions for associating $C_{0}$-semigroups with such equations.
Characterizes the initial value space for these equations.
Analyzes operator pencils with polynomially bounded resolvents.
Abstract
We consider differential-algebraic equations in infinite dimensional state spaces and study, under which conditions we can associate a -semigroup with such equations. We determine the right space of initial values and characterise the existence of a -semigroup in the case of operator pencils with polynomially bounded resolvents.
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Semigroups associated with differential-algebraic equations
Sascha Trostorff Mathematisches Seminar, CAU Kiel, Germany, email: [email protected]
**Abstract. **We consider differential-algebraic equations in infinite dimensional state spaces, and study under which conditions we can associate a -semigroup with such equations. We determine the right space of initial values and characterise the existence of a -semigroup in the case of operator pencils with polynomially bounded resolvents.
**Keywords: differential-algebraic equations, -semigroups, Wong sequence, operator pencil, polynomially bounded resolvent **
**2010 MSC: 46N20, 34A09, 35M31 **
1 Introduction
In the case of matrices the study of differential-algebraic equations (DAEs), i.e. equations of the form
[TABLE]
for matrices , is a very active field in mathematics (see e.g. [7, 8, 9, 10] and the references therein). The main difference to classical differential equations is that the matrix is allowed to have a nontrivial kernel. Thus, one cannot expect to solve the equation for each right hand side and each initial value . In case of matrices one can use normal forms (see e.g. [2, 12, Theorem 2.7]) to determine the ‘right’ space of initial values, so-called consistent initial values. However, this approach cannot be used in case of operators on infinite dimensional spaces. Another approach uses so-called Wong sequences associated with matrices and (see e.g. [3]) and this turns out to be applicable also in the operator case.
In contrast to the finite dimensional case, the case of infinite dimensions is not that well studied. It is the aim of this article, to generalise some of the results in the finite dimensional case to infinite dimensions. For simplicity, we restrict ourselves to homogeneous problems. More precisely, we consider equations of the form
[TABLE]
where for some Banach spaces and is a densely defined closed linear operator. We will define the notion of mild and classical solutions for such equations and determine the ‘right’ space of initial conditions for which a mild solution could be obtained.
For doing so, we start with the definition of Wong sequences associated with in Section 3 which turns out to yield the right spaces for initial conditions. In Section 4 we consider the space of consistent initial values and provide some necessary conditions for the existence of a -semigroup associated with the above problem under the assumption that the space of consistent initial values is closed and the mild solutions are unique (Hypotheses A). In Section 5 we consider operators such that is boundedly invertible on a right half plane and the inverse is polynomially bounded on that half plane. In this case it is possible to determine the space of consistent initial values in terms of the Wong sequence and we can characterise the conditions for the existence of a -semigroup yielding the mild solutions of (1) at least in the case of Hilbert spaces. One tool needed in the proof are the Fourier-Laplace transform and the Theorem of Paley-Wiener, which will be recalled in Section 2.
As indicated above, the study of DAEs in infinite dimensions is not such an active field of study as for the finite dimensional case. We mention [22] where in Hilbert spaces the case of selfadjoint operators is treated using positive definiteness of the operator pencil. Similar approaches in Hilbert spaces were used in [16] for more general equations. However, in both references the initial condition was formulated as We also mention the book [6], where such equations are studied with the focus on maximal regularity. Another approach for dealing with such degenerated equations uses the framework of set-valued (or multi-valued) operators, see [5, 11]. Furthermore we refer to [18, 19], where sequences of projectors are used to decouple the system. Moreover, there exist several references in the Russian literature, where the equations are called Sobolev type equations (see e.g. [23] an the references therein). Finally, we mention the articles [24, 25], which are closely related to the present work, but did not consider the case of operator pencils with polynomially bounded resolvents. In case of bounded operators and , equations of the form (1) were studied by the author in [28, 27], where the concept of Wong sequences associated with was already used.
We assume that the reader is familiar with functional analysis and in particular with the theory of -semigroups and refer to the monographs [14, 4, 29]. Throughout, if not announced differently, and are Banach spaces.
2 Preliminaries
We collect some basic knowledge on the so-called Fourier-Laplace transformation and weak derivatives in exponentially weighted -spaces, which is needed in Section 5. We remark that these concepts were successfully used to study a broad class of partial differential equations (see e.g. [15, 16, 17] and the references therein).
Definition**.**
Let and a Hilbert space. Define
[TABLE]
with the usual identification of functions which are equal almost everywhere. Moreover, we define the Sobolev space
[TABLE]
where the derivative is meant in the distributional sense. Finally, we define as the unitary extension of the mapping
[TABLE]
We call the *Fourier-Laplace transform. *Here, denotes the space of -valued continuous functions with compact support.
Remark 2.1*.*
It is a direct consequence of Plancherels theorem, that becomes unitary.
The connection of and the space is explained in the next proposition.
Proposition 2.2** (see e.g. [26, Proposition 1.1.4]).**
Let for some Then if and only if In this case we have
[TABLE]
Moreover, we have the following variant of the classical Sobolev embedding theorem.
Proposition 2.3** **(Sobolev-embedding theorem, see [16, Lemma 3.1.59]
or [26, Proposition 1.1.8]).
Let for some Then, has a continuous representer with
Finally, we need the Theorem of Paley-Wiener allowing to characterise those -functions supported on the positive real axis in terms of their Fourier-Laplace transform.
Theorem 2.4** (Paley-Wiener, [13] or [20, 19.2 Theorem]).**
Let We define the Hardy space
[TABLE]
Let Then if and only if
[TABLE]
3 Wong sequence
Throughout, let and densely defined closed linear.
Definition**.**
For we define the spaces recursively by
[TABLE]
This sequence of subspaces is called the Wong sequence associated with .
Remark 3.1*.*
We have
[TABLE]
Indeed, for this follows from and hence, the assertion follows by induction.
Definition**.**
We define
[TABLE]
the resolvent set associated with .
We start with some useful facts on the Wong sequence. The following result was already given in [27] in case of a bounded operator .
Lemma 3.2**.**
Let Then
[TABLE]
and
[TABLE]
for each . Moreover, for we find elements such that
[TABLE]
Proof.
For we compute
[TABLE]
We prove the second and third claim by induction. Let and Then with
[TABLE]
and thus, Moreover
[TABLE]
showing the equality with . Assume now that both assertions hold for and let . Then for some and we infer
[TABLE]
by induction hypothesis. Hence, Moreover, by assumption we find and such that
[TABLE]
Thus, we obtain the desired formula with for . ∎
Lemma 3.3**.**
Assume Then for each we have that
[TABLE]
Proof.
We prove the claim by induction. For let such that for some Hence, we find a sequence in with and since * *is bounded, we derive For set
[TABLE]
By Lemma 3.2 we have that and
[TABLE]
hence
Assume now that the assertion holds for some and let . Then clearly and hence, we find a sequence in with For we infer
[TABLE]
and by Lemma 3.2 we have Moreover, we find a sequence in with As above, we set
[TABLE]
and obtain a sequence in converging to . Hence ∎
4 Necessary conditions for -semigroups
In this section we focus on the differential-algebraic problem
[TABLE]
where again and is a linear closed densely defined operator and . We begin with the notion of a classical solution and a mild solution of the above problem.
Definition**.**
Let be continuous.
- (a)
is called a *classical solution *of (2), if is continuously differentiable on , for each and (2) holds. 2. (b)
is called a mild solution of (2), if and for all we have and
[TABLE]
Obviously, a classical solution of (2) is also a mild solution of (2). The main question is now to determine a natural space, where one should seek for (mild) solutions. In particular, we have to find the initial values. We define the space of such values by
[TABLE]
Clearly, is a subspace of .
Proposition 4.1**.**
Let and be a mild solution of (2) with initial value . Then for each . In particular,
Proof.
Let Obviously, we have that Assume now that we know for all . We then have
[TABLE]
and thus,
[TABLE]
by Lemma 3.3. Hence,
[TABLE]
We state the following hypothesis, which we assume to be valid throughout the whole section.
Hypotheses A**.**
The space is closed and for each the mild solution of (2) is unique.
As in the case of Cauchy problems, we can show that we can associate a -semigroup with (2). The proof follows the lines of [1, Theorem 3.1.12].
Proposition 4.2**.**
Denote for the unique mild solution of (2) by Then the mappings
[TABLE]
for define a -semigroup on . In particular, for each .
Proof.
Consider the mapping
[TABLE]
We equip with the topology induced by the seminorms
[TABLE]
for which becomes a Fréchet space. Then is linear and closed. Indeed, if is a sequence in such that and as for some and we derive for each since uniformly on Moreover,
[TABLE]
for each and hence, with
[TABLE]
Finally, since we infer that and hence, is closed. By the closed graph theorem (see e.g. [21, III, Theorem 2.3]), we derive that is continuous. In particular, for each the operator
[TABLE]
is bounded and linear. Moreover, as for each We are left to show that and that satisfies the semigroup law. For doing so, let and We define the function by Then clearly, is continuous with and
[TABLE]
for each with
[TABLE]
Hence, is a mild solution of (2) with initial value and thus, . This proves and
[TABLE]
We want to inspect the generator of a bit closer.
Proposition 4.3**.**
Let denote the generator of the -semigroup . Then we have
Proof.
Let . Consequently, and thus,
[TABLE]
for each . Since as we infer that for each and
[TABLE]
i.e. is a classical solution of (2). Choosing we infer and ∎
5 Pencils with polynomially bounded resolvent
Let and densely defined closed and linear. Throughout this section we assume the following.
Hypotheses B**.**
There exist and such that:
- (a)
, 2. (b)
Definition**.**
We call the minimal such that there exists with
[TABLE]
the *index of , *denoted by
Proposition 5.1**.**
Consider the Wong sequence associated with Then
[TABLE]
for all
Proof.
Since we clearly have it suffices to prove for So, let for some By Lemma 3.2 there exist such that
[TABLE]
We define for . Then by Lemma 3.2 and by what we have above
[TABLE]
Since we have that as and hence, as which shows the claim. ∎
Our next goal is to determine the space . For doing so, we restrict ourselves to Hilbert spaces .
Proposition 5.2**.**
Assume Hypotheses A and let be a Hilbert space. Then
Proof.
By Proposition 4.3 and Proposition 5.1 we have that . We now prove that which would yield the assertion. Let and We define
[TABLE]
and show that For doing so, we use Lemma 3.2 to find , , such that
[TABLE]
Then we have
[TABLE]
for some constant and hence, since obviously is holomorphic. Setting
[TABLE]
we thus have by the Theorem of Paley-Wiener, Theorem 2.4. Moreover,
[TABLE]
and thus, which yields
[TABLE]
i.e. which shows that is continuous on by the Sobolev embedding theorem, Proposition 2.3. We now prove that is indeed a mild solution. Since is continuous on we infer that
[TABLE]
and thus attains the initial value . Moreover,
[TABLE]
for almost every Hence, almost everywhere and
[TABLE]
for almost every By integrating over an interval , we derive
[TABLE]
and hence, is a mild solution of (2). Thus, and so, ∎
For sake of readability, we introduce the following notion.
Definition**.**
We define the space
[TABLE]
Remark 5.3*.*
Note that by Lemma 3.3 and Proposition 5.1.
Lemma 5.4**.**
Assume that is injective. Then
[TABLE]
is well-defined and closed.
Proof.
Note that and thus, is well-defined. Let by a sequence in such that and in for some We then have
[TABLE]
and hence, with This shows, and , thus is closed. ∎
Proposition 5.5**.**
Assume Hypotheses A and let be a Hilbert space. Denote by the generator of . Then is injective and , where is the operator defined in Lemma 5.4.
Proof.
By Proposition 4.3 we have Hence, for (see Proposition 5.2) and we obtain
[TABLE]
and hence,
[TABLE]
Thus, if for some , we infer that and thus, Hence, is injective and thus, is well defined. Moreover, we observe that for and we have
[TABLE]
and thus, with which in turn implies . ∎
The converse statement also holds true, even in the case of a Banach space .
Proposition 5.6**.**
Let be injective and generate a -semigroup on , where is the operator defined in Lemma 5.4. Then Hypotheses A holds.
Proof.
Denote by the semigroup generated by By Proposition 4.1 and Proposition 5.1 we know that We first prove equality here. For doing so, we need to show that is a mild solution of (2) for We have
[TABLE]
Since , we know that
[TABLE]
and that
[TABLE]
and thus, is a mild solution of (2), which in turn implies So, we indeed have and hence, is closed. It remains to prove the uniqueness of mild solutions for initial values in . So, let be a mild solution for some By Proposition 4.1 we know that for each . Hence,
[TABLE]
which shows Hence,
[TABLE]
i.e. is a mild solution of the Cauchy problem associated with . Hence, which shows the claim. ∎
We summarise our findings of this section in the following theorem.
Theorem 5.7**.**
We consider the following two statements.
- (a)
Hypotheses A holds, 2. (b)
* is injective and generates a -semigroup on , where is the operator defined in Lemma 5.4.*
Then (b) (a) and if is a Hilbert space, then (b) (a).
The crucial condition for Hypotheses A to hold is the injectivity of It is noteworthy that is always injective. Indeed, if for some we can use Lemma 3.2 to find such that
[TABLE]
Thus, we have as and hence, However, it is not true in general,that the injectivity carries over to the closure as the following example shows.
Example 5.8**.**
Consider the Hilbert space and define the operator
[TABLE]
where
[TABLE]
It is well-known that this operator is skew-selfadjoint. We set
[TABLE]
where denotes the multiplication operator with the function on Clearly, is linear and bounded and is closed linear and densely defined. Moreover, for and we obtain
[TABLE]
where we have used the skew-selfadjointness of in the first equality. Hence, we have
[TABLE]
which proves the injectivity of and the continuity of its inverse. Since the same argumentation works for the adjoint , it follows that with
[TABLE]
Hence, satisfies Hypotheses B on for each with Moreover, we have
[TABLE]
if and only if and
[TABLE]
for some The latter is equivalent to and
[TABLE]
Thus, we have
[TABLE]
In particular, we obtain that
[TABLE]
belongs to . But this function satisfies and hence, is not injective on
Remark 5.9*.*
In the case and the injectivity of carries over to Indeed, we observe that the operators
[TABLE]
for large enough are uniformly bounded. Moreover, for we have
[TABLE]
and hence, the latter converges carries over to In particular, if for some we infer and thus, * *is indeed injective on So far, the author is not able to prove or disprove that the injectivity also holds for if and are bounded.
Acknowledgement
We thank Felix Schwenninger for pointing our attention to the concept of Wong sequences in matrix calculus. Moreover, we thank Florian Pannasch for the observation in Remark 5.9 and the anonymous referee for drawing our attention to the subject of Sobolev type equations in the Russian literature.
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