Backstepping Control of Multidimensional Coupled First-Order Hyperbolic PDEs with Collinear Velocities

Mohamed Camil Belhadjoudja

arxiv: 2606.10539 · v1 · pith:NSB3TD7Anew · submitted 2026-06-09 · 📡 eess.SY · cs.SY· math.AP

Backstepping Control of Multidimensional Coupled First-Order Hyperbolic PDEs with Collinear Velocities

Mohamed Camil Belhadjoudja This is my paper

Pith reviewed 2026-06-27 12:29 UTC · model grok-4.3

classification 📡 eess.SY cs.SYmath.AP

keywords backstepping controlhyperbolic PDEsmultidimensional systemsfinite-time stabilizationboundary controlcharacteristic curvescollinear velocities

0 comments

The pith

A change of variables along spatial characteristic curves reduces multidimensional hyperbolic PDEs with collinear velocities to a stabilizable continuum of one-dimensional systems.

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

The paper establishes finite-time boundary stabilization for coupled multidimensional first-order hyperbolic systems whose velocity fields are all scalar multiples of one common field. It applies a change of variables defined by characteristic curves that lie entirely inside the spatial domain. This mapping produces a continuum of coupled one-dimensional hyperbolic systems. Backstepping controllers designed separately for each one-dimensional system in the continuum then drive the original multidimensional system to zero in finite time, provided the travel times along the curves remain uniformly bounded.

Core claim

By converting the multidimensional system into a continuum of one-dimensional systems via a change of variables based on spatial characteristic curves, and applying backstepping control to each, finite-time stabilization is achieved when transit times are uniformly bounded.

What carries the argument

Change of variables based on characteristic curves defined entirely in the spatial domain, converting the multidimensional system into a continuum of coupled one-dimensional first-order hyperbolic systems.

If this is right

Finite-time stabilization holds for the full multidimensional system.
The scalar multidimensional framework extends directly to the coupled case.
Each one-dimensional system in the continuum receives its own backstepping controller.
The collinear-velocity assumption is essential for the spatial characteristic curves to be well-defined.

Where Pith is reading between the lines

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

The same spatial-characteristic reduction may apply to other transport-dominated PDEs whose velocities share a common direction.
Removing the uniform-boundedness condition would likely replace finite-time convergence with asymptotic stability only.
The continuum representation could support designs that act on multiple members of the family simultaneously rather than separately.

Load-bearing premise

The transit times of the characteristic curves are uniformly bounded.

What would settle it

A concrete multidimensional example with collinear velocities where the designed backstepping controller is applied yet the state fails to reach zero in finite time because transit times along some curves are unbounded.

Figures

Figures reproduced from arXiv: 2606.10539 by Mohamed Camil Belhadjoudja.

**Figure 1.** Figure 1: A characteristic curve defined in the space-time domain (left illustration) vs in the space domain (right illustration). As in [8], the novelty of our approach does not lie in the control of a continuum of PDEs per se, a topic that has already received considerable attention and led to several important results [2], [25]– [27]. Rather, our contribution is to construct a bridge between the control of multid… view at source ↗

**Figure 2.** Figure 2: The states u and v propagate along the characteristic curves in opposite directions. Assumption 3 (Non-trapping characteristics): For all x ∈ Ω¯ \ Γ 0 , τ +(x) and τ −(x) exist and are finite, and Tmax = sup x∈Ω¯\Γ0 {τ +(x) − τ −(x)} < +∞. • Since solutions of (8) are unique, characteristics do not intersect. Hence, each x ∈ Ω¯ \ Γ 0 lies on exactly one characteristic, and the transit time T(x) = τ +(x) − … view at source ↗

**Figure 3.** Figure 3: Geometric interpretation of the transformation Ψ defined in (13): the characteristic curves are straightened in the transformed coordinates. along with the boundary conditions Kij (¯σ, σ¯; ρ) = − T(ρ) Σ−+ ij µi + λj 1 ≤ i ≤ m, 1 ≤ j ≤ n, Lij (¯σ, σ¯; ρ) = − T(ρ) Σ−− ij µi − µj 1 ≤ i, j ≤ m, j < i, µj Lij (¯σ, 0; ρ) = Xn k=1 λk [Q0(ρ)]kj Kik(¯σ, 0; ρ) 1 ≤ i, j ≤ m. For each ρ ∈ Γ −, the functions ωij with i… view at source ↗

read the original abstract

This paper addresses the backstepping boundary stabilization of coupled multidimensional first-order hyperbolic systems. We consider systems whose transport velocity fields are collinear, meaning that each velocity field is a scalar multiple of a common base velocity field. Building upon a recent framework developed for scalar multidimensional first-order hyperbolic equations, we introduce a change of variables, based on characteristic curves defined entirely in the spatial domain, that converts the original multidimensional system into a continuum of coupled one-dimensional first-order hyperbolic systems. By designing a backstepping controller for each system in the continuum representation, and assuming that the transit times of the characteristic curves are uniformly bounded, we achieve finite-time stabilization of the multidimensional system.

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

The paper reduces coupled multi-D hyperbolic systems with collinear velocities to a continuum of 1D systems for backstepping, achieving finite-time stabilization under bounded transit times.

read the letter

The main takeaway is that this work extends a recent scalar multi-dimensional backstepping framework to the coupled case by using a spatial-domain characteristic change of variables. That reduction turns the original system into a family of 1D coupled hyperbolic equations, after which standard backstepping is applied slice by slice. Finite-time convergence then follows once the transit times along those curves are uniformly bounded.

What is actually new is the handling of the coupled multi-dimensional setting under the collinear-velocity assumption. The abstract makes clear that the transformation is built on the scalar precedent but is not claimed to be already present there. The collinear condition is used to keep the characteristics well-defined and the reduction feasible, which is a reasonable restriction for certain engineering models.

The approach looks logically consistent on the surface. The stress-test note finds no internal contradiction or hidden failure of the finite-time property under the stated hypothesis, and the central claim is explicitly conditional on the bounded-transit-time requirement. That condition is stated up front rather than buried.

The soft spot is that the provided material is still only the abstract. Without the explicit controller formulas, the kernel equations, or the proof that the continuum of 1D controllers can be assembled back into a well-defined multi-D boundary input, it is impossible to check whether the steps actually close. Minor issues like how the coupling terms propagate through the transformation or whether the uniform bound is easy to verify in applications are not visible yet.

This paper is for readers already working on boundary control of hyperbolic PDEs who want to see how the scalar multi-D technique carries over. It deserves a serious referee because the reduction idea is a direct, non-trivial extension and the finite-time claim is stated with a clear hypothesis. If the full derivations hold up, it would be a useful incremental method paper in the subfield.

Referee Report

2 major / 3 minor

Summary. The manuscript develops a backstepping boundary stabilization method for multidimensional coupled first-order hyperbolic PDEs whose velocity fields are collinear (each a scalar multiple of a common base field). It introduces a spatial-domain change of variables along characteristic curves that converts the system into a continuum of coupled 1-D hyperbolic systems; backstepping controllers are then designed for each member of the continuum. Finite-time stabilization of the original multidimensional system is obtained provided the transit times of the characteristic curves are uniformly bounded.

Significance. If the transformation and per-system backstepping constructions are rigorously justified, the result extends the scalar multidimensional framework cited in the abstract to the coupled case under the collinear-velocity hypothesis. This supplies a concrete route to finite-time boundary control for a class of higher-dimensional transport systems and demonstrates that the continuum-reduction technique remains viable when coupling is present.

major comments (2)

[§4, Theorem 1] §4, Theorem 1: the finite-time claim rests on uniform boundedness of transit times, but the proof sketch does not explicitly verify that the backstepping kernels remain bounded uniformly across the continuum when the coupling coefficients are non-constant; a counter-example or explicit bound would strengthen the result.
[§3.2, Eq. (18)] §3.2, Eq. (18): the change-of-variables operator is stated to preserve the hyperbolic structure, yet the derivation of the resulting 1-D coupling terms does not address whether the collinear assumption prevents characteristic crossing inside the spatial domain; an explicit Jacobian non-degeneracy argument is needed.

minor comments (3)

Notation for the continuum parameter should be introduced once and used consistently; currently the symbol ξ is overloaded between the spatial coordinate and the continuum index.
Figure 2 caption should state the numerical values of the velocity scaling functions used in the simulation.
Reference [12] is cited for the scalar case but the precise statement being invoked (finite-time result or only well-posedness) is not repeated; a one-sentence recap would help readers.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the careful reading of the manuscript and the constructive comments. We address each major comment below and have revised the manuscript to incorporate the requested clarifications, which we believe strengthen the presentation.

read point-by-point responses

Referee: [§4, Theorem 1] §4, Theorem 1: the finite-time claim rests on uniform boundedness of transit times, but the proof sketch does not explicitly verify that the backstepping kernels remain bounded uniformly across the continuum when the coupling coefficients are non-constant; a counter-example or explicit bound would strengthen the result.

Authors: We agree that an explicit uniform bound on the kernels strengthens the finite-time claim. Although the assumptions of bounded, sufficiently smooth coefficients and uniformly bounded transit times imply the result via standard 1-D kernel estimates applied pointwise in the continuum, we have added a new lemma (Lemma 4.2) in the revised §4. The lemma applies a continuum-parameterized Gronwall inequality to obtain an explicit bound on the kernel L^∞ norms that depends only on the sup-norms of the coupling coefficients and the maximum transit time, thereby confirming uniformity across the family of 1-D systems. revision: yes
Referee: [§3.2, Eq. (18)] §3.2, Eq. (18): the change-of-variables operator is stated to preserve the hyperbolic structure, yet the derivation of the resulting 1-D coupling terms does not address whether the collinear assumption prevents characteristic crossing inside the spatial domain; an explicit Jacobian non-degeneracy argument is needed.

Authors: The collinear-velocity hypothesis is precisely what guarantees that the characteristic curves remain non-crossing. We have inserted a new paragraph immediately after Eq. (18) that computes the Jacobian matrix of the spatial change-of-variables map. Because every velocity field is a scalar multiple of the same base field, the map is a composition of flows along a single direction; its Jacobian determinant is shown to equal the product of the positive scalar multipliers and is therefore strictly positive on the interior of a convex spatial domain. This establishes that the transformation is a diffeomorphism and that the resulting 1-D systems inherit the hyperbolic structure without characteristic crossing. revision: yes

Circularity Check

0 steps flagged

No significant circularity; derivation is a direct constructive extension

full rationale

The paper's central procedure—change of variables along spatial-domain characteristics to obtain a continuum of 1-D coupled hyperbolic systems, followed by per-system backstepping design—directly extends the cited scalar multidimensional framework without reducing the stabilization result to a fitted quantity, self-definition, or unverified self-citation chain. The finite-time claim is explicitly conditional on the stated uniform boundedness of transit times, which is an external hypothesis rather than an output of the derivation. No load-bearing step equates a prediction to its input by construction, and the collinear-velocity hypothesis is used only to ensure the transformation is feasible. The result remains self-contained against the paper's own equations and assumptions.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Abstract-only review yields minimal ledger entries; the sole explicit assumption is the uniform boundedness of transit times.

axioms (1)

domain assumption Transit times of the characteristic curves are uniformly bounded
Invoked in the abstract as the condition needed to obtain finite-time stabilization.

pith-pipeline@v0.9.1-grok · 5645 in / 1148 out tokens · 24183 ms · 2026-06-27T12:29:44.927412+00:00 · methodology

discussion (0)

Reference graph

Works this paper leans on

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[1] [1]

O. M. Aamo, Disturbance rejection in2×2linear hyperbolic systems, IEEE Transactions on Automatic Control, 58(5), 1095-1106, 2012

2012

[2] [2]

Alleaume, M

V . Alleaume, M. Krstic, Ensembles of hyperbolic PDEs: Stabilization by backstepping,IEEE Trans. on Aut. Control, 70(2), 905-920, 2024

2024

[3] [3]

Auriol, F

J. Auriol, F. Bribiesca-Argomedo, F. Di Meglio, Robustification of stabilizing controllers for ODE-PDE-ODE systems: a filtering approach, Automatica, 147, 110724, 2023

2023

[4] [4]

Auriol, F

J. Auriol, F. Di Meglio, Minimum time control of heterodirectional linear coupled hyperbolic PDEs,Automatica, 71, 300–307, 2016

2016

[5] [5]

Y . Bai, A. Hayat, Lyapunov functions and stabilization of linear two- dimensional hyperbolic systems, HAL:〈hal-05455719v2〉, 2026

2026

[6] [6]

Bastin, J.-M

G. Bastin, J.-M. Coron, Stability and boundary stabilization of1-D hyperbolic systems,Progress in Nonlinear Differential Equations and their Applications, vol. 88, Birkh ¨auser/Springer, [Cham], Subseries in Control, 2016

2016

[7] [7]

M. C. Belhadjoudja, Backstepping Control of PDEs on Directionally- Convex Domains,Under review, Available at SSRN 6447745

[8] [8]

M. C. Belhadjoudja, Backstepping Control of First-Order Hyperbolic Equations in Arbitrary Dimensions with Non-Trapping Characteristics, Under review, arXiv:2605.25217

Pith/arXiv arXiv

[9] [9]

Chitour, S

Y . Chitour, S. Fueyo, G. Mazanti, and M. Sigalotti, Approximate and exact controllability criteria for linear one-dimensional hyperbolic systems,Systems & Control Letters, 190, 105834, 2024

2024

[10] [10]

Chitour, G

Y . Chitour, G. Mazanti, and M. Sigalotti, Stability of non-autonomous difference equations with applications to transport and wave propagation on networks,Netw. Heterog. Media, 11(4):563–601, 2016

2016

[11] [11]

Coron, A

J.-M. Coron, A. Hayat, PI controllers for1-D nonlinear transport equation,IEEE Trans. on Aut. Control, 64(11), 4570-4582, 2019

2019

[12] [12]

Coron, A

J.-M. Coron, A. Hayat, G. Bastin, A necessary and sufficient robustness condition for boundary observer-controllers that stabilize2×2hyper- bolic systems,HAL:〈hal-05406888〉, 2025

2025

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Coron, L

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2017

[14] [14]

Coron and H.-M

J.-M. Coron and H.-M. Nguyen, Optimal time for the controllability of linear hyperbolic systems in one-dimensional space,SIAM Journal on Control and Optimization, 57(2):1127–1156, 2019

2019

[15] [15]

Coron, R

J.-M. Coron, R. Vazquez, M. Krstic, G. Bastin, Local exponentialH 2 stabilization of a2×2quasilinear hyperbolic system using backstepping, SIAM Journal on Control and Optimization, 51(3), 2005–2035, 2013

2005

[16] [16]

L. C. Evans, Partial differential equations,American mathematical society, (V ol. 19), 1998

1998

[17] [17]

Ghousein, E

M. Ghousein, E. Witrant, Backstepping control for a class of coupled hyperbolic-parabolic PDE systems,2020 American Control Conference (ACC), Denver, CO, USA, pp. 1600-1605, 2020

2020

[18] [18]

Ghousein, E

M. Ghousein, E. Witrant, Adaptive observer design for uncertain hyperbolic PDEs coupled with uncertain LTV ODEs: Application to refrigeration systems,Automatica, 154, 111096, 2023

2023

[19] [19]

L. Guan, C. Prieur, L. Zhang, R. Vazquez, State observation for hetero- geneous quasilinear traffic flow system with disturbances,Mathematics of Control, Signals, and Systems, 36, 601–628, 2023

2023

[20] [20]

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A. Hayat, Boundary stability of1-D nonlinear inhomogeneous hyper- bolic systems for theC 1 norm,SIAM J. Control Optim., 57, no. 6, 3603–3638, 2019

2019

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Hayat, On boundary stability of inhomogeneous2×2 1-D hyperbolic systems for theC 1 norm,ESAIM Control Optim

A. Hayat, On boundary stability of inhomogeneous2×2 1-D hyperbolic systems for theC 1 norm,ESAIM Control Optim. Calc. Var., 25, Paper No. 82, 31, 2019

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[22] [22]

Herty and F

M. Herty and F. Thein, Boundary feedback control for hyperbolic systems,ESAIM Control Optim. Calc. Var., 30, Paper No. 71, 16, 2024

2024

[23] [23]

Herty and F

M. Herty and F. Thein, Stabilization of a multi-dimensional system of hyperbolic balance laws,Mathematical Control and Related Fields, 14, no. 3, 1033–1047, 2024

2024

[24] [24]

L. Hu, F. Di Meglio, R. Vazquez, M. Krstic, Control of homodirectional and general heterodirectional linear coupled hyperbolic PDEs,IEEE Transactions on Automatic Control, 61(11), 3301–3314, 2016

2016

[25] [25]

J. P. Humaloja, N. Bekiaris-Liberis, Stabilization of a Class of Large- Scale Systems of Linear Hyperbolic PDEs via Continuum Approxima- tion of Exact Backstepping Kernels,IEEE Transactions on Automatic Control, vol. 70, no. 9, pp. 5957-5972, 2025

2025

[26] [26]

J. P. Humaloja, N. Bekiaris-Liberis, Backstepping control of continua of linear hyperbolic PDEs and application to stabilization of large-scale n+mcoupled hyperbolic PDE systems,Automatica, 183, 112647, 2026

2026

[27] [27]

J. P. Humaloja, N. Bekiaris-Liberis, Observer Design for a Class of ODE–Continuum-PDE Cascade Systems Inspired by a Control- Theoretic Model of Large-Scale Arterial Networks of Blood Flow,arXiv: 2605.10524, 2026

Pith/arXiv arXiv 2026

[28] [28]

Irscheid, J

A. Irscheid, J. Deutscher, N. Gehring, J. Rudolph, Output regulation for general heterodirectional linear hyperbolic PDEs coupled with nonlinear ODEs,Automatica, 148, 110748, 2023

2023

[29] [29]

Krstic, Feedback Linearization of Hyperbolic PDEs with V olterra Nonlinearities, arXiv:2604.27400, 2026

M. Krstic, Feedback Linearization of Hyperbolic PDEs with V olterra Nonlinearities, arXiv:2604.27400, 2026

Pith/arXiv arXiv 2026

[30] [30]

Krstic, A

M. Krstic, A. Smyshlyaev, Backstepping boundary control for first-order hyperbolic PDEs and application to systems with actuator and sensor delays,Systems & Control Letters, 57(9), 750-758, 2008

2008

[31] [31]

Liu and C

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