Well-posedness of Stochastic Port-Hamiltonian Systems on Infinite-dimensional Spaces

Fran\c{c}ois Lamoline; Joseph J. Winkin

arxiv: 1907.04158 · v1 · pith:NL7J5S6Wnew · submitted 2019-07-09 · 🧮 math.OC

Well-posedness of Stochastic Port-Hamiltonian Systems on Infinite-dimensional Spaces

Fran\c{c}ois Lamoline , Joseph J. Winkin This is my paper

Pith reviewed 2026-05-25 00:28 UTC · model grok-4.3

classification 🧮 math.OC

keywords stochastic port-Hamiltonian systemsinfinite-dimensional systemswell-posednessItô stochastic differential equationsWeiss-Salamon conceptvibrating stringGaussian white noisemild solutions

0 comments

The pith

Stochastic port-Hamiltonian systems on infinite-dimensional spaces are well-posed under a generalized Weiss-Salamon definition.

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper introduces stochastic port-Hamiltonian systems on infinite-dimensional spaces as an extension of their finite-dimensional counterparts, now governed by Itô stochastic differential equations. It generalizes the Weiss-Salamon well-posedness concept from deterministic infinite-dimensional systems to the stochastic setting. Under this extended definition the systems are shown to be well-posed, establishing existence and uniqueness of solutions. The result is illustrated with a vibrating string driven by Hilbert-space-valued Gaussian white noise. A sympathetic reader would care because the framework supplies a rigorous foundation for analyzing stochastic distributed-parameter systems that arise in control and engineering.

Core claim

Stochastic port-Hamiltonian systems on infinite-dimensional spaces governed by Itô stochastic differential equations are well-posed in the sense of a stochastic generalization of the Weiss-Salamon concept, which guarantees the existence and uniqueness of mild solutions.

What carries the argument

The stochastic generalization of the Weiss-Salamon well-posedness concept, which extends the deterministic operator-theoretic definition to Itô equations on Hilbert spaces and ensures existence and uniqueness of solutions.

If this is right

Existence and uniqueness of mild solutions hold for the introduced class of stochastic port-Hamiltonian systems.
The vibrating-string example with Hilbert-space-valued Gaussian white noise is well-posed under the same definition.
The theory supplies a direct extension from the finite-dimensional stochastic port-Hamiltonian case to the infinite-dimensional case.
Well-posedness is established without requiring additional regularity assumptions beyond those implicit in the generalized definition.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The same generalized definition may serve as a template for proving well-posedness of other classes of stochastic infinite-dimensional systems that are not port-Hamiltonian.
Control-theoretic results that rely on well-posedness, such as stabilizability or optimal control, could be lifted from the deterministic infinite-dimensional setting to this stochastic version.
Numerical approximation schemes for the vibrating-string example could be justified by appealing to the established well-posedness.

Load-bearing premise

That the proposed generalization of the Weiss-Salamon well-posedness notion remains a valid and sufficient criterion for existence and uniqueness once the setting becomes stochastic and infinite-dimensional.

What would settle it

An explicit stochastic port-Hamiltonian system on an infinite-dimensional space that satisfies the authors' generalized definition yet fails to possess a unique mild solution, or conversely possesses a unique solution while violating the definition.

read the original abstract

Stochastic port-Hamiltonian systems on infinite-dimensional spaces governed by It\^o stochastic differential equations (SDEs) are introduced and some properties of this new class of systems are studied. They are an extension of stochastic port-Hamiltonian systems defined on a finite-dimensional state space. The concept of well-posedness in the sense of Weiss and Salamon is generalized to the stochastic context. Under this extended definition, stochastic port-Hamiltonian systems are shown to be well-posed. The theory is illustrated on an example of a vibrating string subject to a Hilbert space-valued Gaussian white noise process.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

They introduce stochastic port-Hamiltonian systems in infinite dimensions and prove a generalized well-posedness result, but the contribution stays within a narrow extension of existing deterministic theory.

read the letter

The paper defines stochastic port-Hamiltonian systems on infinite-dimensional spaces using Itô SDEs and generalizes the Weiss-Salamon well-posedness concept to this setting. It then shows that these systems are well-posed under the new definition, with an illustration on a vibrating string driven by Hilbert space-valued Gaussian white noise. What stands out is the move from finite to infinite dimensions in the stochastic case. The deterministic port-Hamiltonian theory on infinite spaces is already there, so this adds the noise component and adjusts the well-posedness notion accordingly. The example helps show how the abstract setup applies to a concrete PDE. On the positive side, the abstract indicates a clean statement of the result without obvious circularity or invented entities. It builds directly on prior work. The soft spots are around the details of the generalization. The weakest assumption seems to be that the stochastic version of Weiss-Salamon well-posedness is the appropriate one and sufficient for existence and uniqueness. Without seeing the full proof, it's unclear if new technical conditions on the noise or the port operators are needed or if the extension is mostly formal. The vibrating string is cited as an illustration, but if it doesn't involve heavy computation or verification of the conditions, it doesn't add much evidential weight. This paper is for specialists in mathematical control theory, particularly those dealing with infinite-dimensional systems and stochastic perturbations. A reader already familiar with port-Hamiltonian modeling would see how the framework extends, but it won't interest people outside that subfield much. It deserves peer review because it introduces a defined new class and a positive well-posedness result. Referees can verify the proof and assess if the generalization holds up.

Referee Report

0 major / 2 minor

Summary. The manuscript introduces stochastic port-Hamiltonian systems on infinite-dimensional spaces, formulated via Itô stochastic differential equations as an extension of the finite-dimensional case. It generalizes the Weiss-Salamon notion of well-posedness to the stochastic infinite-dimensional setting and claims to establish well-posedness of these systems under the extended definition. The theory is illustrated by an example of a vibrating string driven by Hilbert space-valued Gaussian white noise.

Significance. If the generalization of well-posedness and the accompanying existence/uniqueness result hold, the work would supply a systematic framework for stochastic infinite-dimensional port-Hamiltonian systems, extending deterministic theory in a manner that preserves structural properties such as energy balance. The vibrating-string example, even at an illustrative level, indicates concrete applicability to distributed-parameter models with additive noise.

minor comments (2)

[Abstract] The abstract states that well-posedness 'follows under this extended definition' but does not indicate the precise regularity assumptions placed on the noise operator or the port variables; adding one sentence summarizing these conditions would improve readability.
[Example section] The vibrating-string example is described only at the level of existence; a brief statement of the concrete state space, Hamiltonian, and noise operator (e.g., in §4 or the example section) would allow readers to verify that the general hypotheses are satisfied.

Simulated Author's Rebuttal

0 responses · 0 unresolved

We thank the referee for their positive assessment of the manuscript, the accurate summary of its contributions, and the recommendation for minor revision. No major comments were provided in the report.

Circularity Check

0 steps flagged

No significant circularity identified

full rationale

The paper introduces stochastic port-Hamiltonian systems as an extension of the finite-dimensional case and generalizes the external Weiss-Salamon well-posedness concept to the stochastic infinite-dimensional setting before proving well-posedness under the new definition. This constitutes a standard definitional extension followed by a proof, with the vibrating-string example serving only as illustration. No load-bearing step reduces by construction to a fitted input, self-citation chain, or self-definitional loop; the derivation remains independent of its own outputs and relies on prior external theory.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Only abstract available; ledger is therefore minimal and provisional. The work appears to rest on standard assumptions from deterministic port-Hamiltonian theory and stochastic analysis on Hilbert spaces.

axioms (1)

domain assumption The Weiss-Salamon notion of well-posedness can be meaningfully extended to the stochastic setting.
This extension is invoked to prove well-posedness of the new systems.

pith-pipeline@v0.9.0 · 5628 in / 1133 out tokens · 20040 ms · 2026-05-25T00:28:08.553831+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

25 extracted references · 25 canonical work pages

[1]

P.L. Chow. Stochastic Partial Diﬀerential Equations, Second Edition. Advances in Applied Mathematics. Taylor & Francis, 2014

work page 2014
[2]

R.F. Curtain. Stochastic evolution equations with gene ral white noise disturbance. Journal of Mathe- matical Analysis and Applications , 60(3):570 – 595, 1977

work page 1977
[3]

Curtain and A.J

R.F. Curtain and A.J. Pritchard. Inﬁnite Dimensional Linear Systems Theory . Lecture notes in control and information sciences. Springer-Verlag, 1978

work page 1978
[4]

Curtain and H.J

R.F. Curtain and H.J. Zwart. An Introduction to Inﬁnite-Dimensional Linear Systems Theory . Springer edition, 1995

work page 1995
[5]

Da Prato and J

G. Da Prato and J. Zabczyk. Stochastic Equations in Inﬁnite Dimensions . Encyclopedia of Mathematics and its Applications. Cambridge University Press, 2008

work page 2008
[6]

Guo and Z.-X

B.-Z. Guo and Z.-X. Zhang. On the well-posedness and regu larity of the wave equation with variable coeﬃcients. ESAIM: Control, Optimisation and Calculus of Variations , 2007

work page 2007
[7]

Guo and Z.-X

B.-Z. Guo and Z.-X. Zhang. Well-posedness of systems of l inear elasticity with dirichlet boundary control and observation. SIAM J. Control and Optimization , 2009

work page 2009
[8]

Hausenblas and J

E. Hausenblas and J. Seidler. A note on maximal inequalit y for stochastic convolutions. Czechoslovak Mathematical Journal , 51(4):785–790, 2001

work page 2001
[9]

Jacob and H.J

B. Jacob and H.J. Zwart. Linear Port-Hamiltonian Systems on Inﬁnite-dimensional Spa ces. Springer edition, 2012

work page 2012
[10]

Lamoline and J.J Winkin

F. Lamoline and J.J Winkin. Nice port-Hamiltonian syst ems are Riesz-spectral systems. Preprints of the 20th World Congress, The International Federation of Autom atic Control, pages 695–699, July 9-14

work page
[11]

Lamoline and J.J

F. Lamoline and J.J. Winkin. On stochastic port-Hamilt onian systems with boundary control and observation. In Proceedings of the 56th IEEE Conference on Decision and Contr ol, pages 2492–2497, 2017

work page 2017
[12]

Le Gorrec, H.J

Y. Le Gorrec, H.J. Zwart, and B. Maschke. Dirac structur es and boundary control systems associated with skew-symmetric diﬀerential operators. SIAM J. Control and Optimization , 44(5):1864–1892, 2005

work page 2005
[13]

Q. Lü. Stochastic Well-Posed Systems and Well-Posedne ss of Some Stochastic Partial Diﬀerential Equations with Boundary Control and Observation. SIAM J. Control and Optimization , 53(6):3457– 3482, 2015

work page 2015
[14]

Maschke and A.J

B. Maschke and A.J. van der Schaft. Port-controlled Ham iltonian systems: modelling origins and system theoretic properties. Proceedings 2nd IF AC Symposium on Nonlinear Control Systems , pages 282–288, June 1992

work page 1992
[15]

D. Salamon. Realization theory in Hilbert space. Math. Systems Theory , 1989

work page 1989
[16]

Satoh and K

S. Satoh and K. Fujimoto. Passivity Based Control of Sto chastic Port-Hamiltonian Systems. IEEE Transactions on Automatic Control , 58(5):1139–1153, May 2013

work page 2013
[17]

O. Staﬀans. Well-Posed Linear Systems . Cambridge University Press, 2005. 21

work page 2005
[18]

Sz.-Nagy

B. Sz.-Nagy. Sur les contractions de l’espace de Hilber t. Acta Sci. Math. Szeged , 15:87–92, 1953

work page 1953
[19]

C. Tretter. Spectral problems for systems of diﬀerenti al equations y′ + A0y = λA1y with polynomial boundary conditions. Mathematische Nachrichten , 214(1):129–172, 2000

work page 2000
[20]

Tucsnak and G

M. Tucsnak and G. Weiss. Observation and Control for Operator Semigroups . Birkhäuser Advanced Texts Basler Lehrbücher. Birkhäuser Basel, 2009

work page 2009
[21]

Tucsnak and G

M. Tucsnak and G. Weiss. Well-posed systems–the LTI cas e and beyond. Automatica, 50(7):1757–1779, 2014

work page 2014
[22]

van der Schaft and B.M

A.J. van der Schaft and B.M. Maschke. Hamiltonian formu lation of distributed-parameter systems with boundary energy ﬂow. Journal of Geometry and Physics , 42:166 – 194, 2002

work page 2002
[23]

Villegas

J.A. Villegas. A Port-Hamiltonian Approach to distributed parameter system s. PhD thesis, University of Twente, 2007

work page 2007
[24]

Weiss, O.J

G. Weiss, O.J. Staﬀans, and M. Tucsnak. Well-posed line ar systems a survey with emphasis on conser- vative systems. Int. J. Appl. Math. Comput. Sci. , 11(1):7–33, 2001

work page 2001
[25]

Zwart, Y

H.J. Zwart, Y. Le Gorrec, B. Maschke, and J.A. Villegas. Well-posedness and regularity of hyperbolic boundary control systems on a one-dimensional spatial doma in. ESAIM: Control, Optimisation and Calculus of Variations , 16:1077–1093, 2010. 22

work page 2010

[1] [1]

P.L. Chow. Stochastic Partial Diﬀerential Equations, Second Edition. Advances in Applied Mathematics. Taylor & Francis, 2014

work page 2014

[2] [2]

R.F. Curtain. Stochastic evolution equations with gene ral white noise disturbance. Journal of Mathe- matical Analysis and Applications , 60(3):570 – 595, 1977

work page 1977

[3] [3]

Curtain and A.J

R.F. Curtain and A.J. Pritchard. Inﬁnite Dimensional Linear Systems Theory . Lecture notes in control and information sciences. Springer-Verlag, 1978

work page 1978

[4] [4]

Curtain and H.J

R.F. Curtain and H.J. Zwart. An Introduction to Inﬁnite-Dimensional Linear Systems Theory . Springer edition, 1995

work page 1995

[5] [5]

Da Prato and J

G. Da Prato and J. Zabczyk. Stochastic Equations in Inﬁnite Dimensions . Encyclopedia of Mathematics and its Applications. Cambridge University Press, 2008

work page 2008

[6] [6]

Guo and Z.-X

B.-Z. Guo and Z.-X. Zhang. On the well-posedness and regu larity of the wave equation with variable coeﬃcients. ESAIM: Control, Optimisation and Calculus of Variations , 2007

work page 2007

[7] [7]

Guo and Z.-X

B.-Z. Guo and Z.-X. Zhang. Well-posedness of systems of l inear elasticity with dirichlet boundary control and observation. SIAM J. Control and Optimization , 2009

work page 2009

[8] [8]

Hausenblas and J

E. Hausenblas and J. Seidler. A note on maximal inequalit y for stochastic convolutions. Czechoslovak Mathematical Journal , 51(4):785–790, 2001

work page 2001

[9] [9]

Jacob and H.J

B. Jacob and H.J. Zwart. Linear Port-Hamiltonian Systems on Inﬁnite-dimensional Spa ces. Springer edition, 2012

work page 2012

[10] [10]

Lamoline and J.J Winkin

F. Lamoline and J.J Winkin. Nice port-Hamiltonian syst ems are Riesz-spectral systems. Preprints of the 20th World Congress, The International Federation of Autom atic Control, pages 695–699, July 9-14

work page

[11] [11]

Lamoline and J.J

F. Lamoline and J.J. Winkin. On stochastic port-Hamilt onian systems with boundary control and observation. In Proceedings of the 56th IEEE Conference on Decision and Contr ol, pages 2492–2497, 2017

work page 2017

[12] [12]

Le Gorrec, H.J

Y. Le Gorrec, H.J. Zwart, and B. Maschke. Dirac structur es and boundary control systems associated with skew-symmetric diﬀerential operators. SIAM J. Control and Optimization , 44(5):1864–1892, 2005

work page 2005

[13] [13]

Q. Lü. Stochastic Well-Posed Systems and Well-Posedne ss of Some Stochastic Partial Diﬀerential Equations with Boundary Control and Observation. SIAM J. Control and Optimization , 53(6):3457– 3482, 2015

work page 2015

[14] [14]

Maschke and A.J

B. Maschke and A.J. van der Schaft. Port-controlled Ham iltonian systems: modelling origins and system theoretic properties. Proceedings 2nd IF AC Symposium on Nonlinear Control Systems , pages 282–288, June 1992

work page 1992

[15] [15]

D. Salamon. Realization theory in Hilbert space. Math. Systems Theory , 1989

work page 1989

[16] [16]

Satoh and K

S. Satoh and K. Fujimoto. Passivity Based Control of Sto chastic Port-Hamiltonian Systems. IEEE Transactions on Automatic Control , 58(5):1139–1153, May 2013

work page 2013

[17] [17]

O. Staﬀans. Well-Posed Linear Systems . Cambridge University Press, 2005. 21

work page 2005

[18] [18]

Sz.-Nagy

B. Sz.-Nagy. Sur les contractions de l’espace de Hilber t. Acta Sci. Math. Szeged , 15:87–92, 1953

work page 1953

[19] [19]

C. Tretter. Spectral problems for systems of diﬀerenti al equations y′ + A0y = λA1y with polynomial boundary conditions. Mathematische Nachrichten , 214(1):129–172, 2000

work page 2000

[20] [20]

Tucsnak and G

M. Tucsnak and G. Weiss. Observation and Control for Operator Semigroups . Birkhäuser Advanced Texts Basler Lehrbücher. Birkhäuser Basel, 2009

work page 2009

[21] [21]

Tucsnak and G

M. Tucsnak and G. Weiss. Well-posed systems–the LTI cas e and beyond. Automatica, 50(7):1757–1779, 2014

work page 2014

[22] [22]

van der Schaft and B.M

A.J. van der Schaft and B.M. Maschke. Hamiltonian formu lation of distributed-parameter systems with boundary energy ﬂow. Journal of Geometry and Physics , 42:166 – 194, 2002

work page 2002

[23] [23]

Villegas

J.A. Villegas. A Port-Hamiltonian Approach to distributed parameter system s. PhD thesis, University of Twente, 2007

work page 2007

[24] [24]

Weiss, O.J

G. Weiss, O.J. Staﬀans, and M. Tucsnak. Well-posed line ar systems a survey with emphasis on conser- vative systems. Int. J. Appl. Math. Comput. Sci. , 11(1):7–33, 2001

work page 2001

[25] [25]

Zwart, Y

H.J. Zwart, Y. Le Gorrec, B. Maschke, and J.A. Villegas. Well-posedness and regularity of hyperbolic boundary control systems on a one-dimensional spatial doma in. ESAIM: Control, Optimisation and Calculus of Variations , 16:1077–1093, 2010. 22

work page 2010