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arxiv: 1907.00220 · v1 · pith:NFXORY5Onew · submitted 2019-06-29 · 📡 eess.SY · cs.RO· cs.SY

Distributed Global Output-Feedback Control for a Class of Euler-Lagrange Systems

Qingkai Yang , Hao Fang , Jie Chen , Zhong-Ping Jiang , Ming Cao This is my paper

Pith reviewed 2026-05-25 12:49 UTC · model grok-4.3

classification 📡 eess.SY cs.ROcs.SY
keywords Euler-Lagrange systemsdistributed controloutput-feedbackvelocity observersmulti-agent systemsuniform global exponential stabilitycoordinate transformation
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The pith

A coordinate transformation allows partial linearization and global output-feedback control for position-measured Euler-Lagrange multi-agent systems.

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

The paper develops a method for distributed tracking control of Euler-Lagrange multi-agent systems when only position measurements are available. It first introduces a global nonsingular coordinate transformation in upper triangular form to partially linearize the dynamics with respect to unmeasurable velocities. Velocity observers are then designed, followed by distributed control laws that achieve uniform global exponential stability of the closed-loop tracking system. A sympathetic reader would care because many physical agents lack velocity sensors, and global exponential stability guarantees convergence from any initial condition without local restrictions.

Core claim

A global nonsingular coordinate transformation matrix in the upper triangular form is proposed such that the nonlinear dynamic model can be partially linearized with respect to the unmeasurable states. A new type of velocity observer is designed to estimate the unmeasurable velocities for each system. Based on the outputs of these observers, distributed control laws are proposed that enable the coordinated tracking control system to achieve uniform global exponential stability.

What carries the argument

The global nonsingular coordinate transformation matrix in upper triangular form that partially linearizes the model with respect to unmeasurable velocities.

If this is right

  • The coordinated tracking errors converge uniformly and globally exponentially to zero.
  • Each agent obtains velocity estimates from its local observer without direct measurement.
  • The distributed laws require only neighbor position information and local estimates.
  • The stability result holds for the full class of systems admitting the transformation.
  • Both theoretical Lyapunov analysis and numerical examples confirm the UGES property.

Where Pith is reading between the lines

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

  • The transformation technique could be tested on other nonlinear Lagrangian-like systems that admit similar partial linearization.
  • Implementation on physical robots would require verifying that the assumed transformation can be computed online from model parameters.
  • The observer-based approach might reduce hardware costs by removing velocity sensors across a fleet of agents.

Load-bearing premise

A global nonsingular coordinate transformation matrix in the upper triangular form exists such that the nonlinear dynamic model can be partially linearized with respect to the unmeasurable states.

What would settle it

An Euler-Lagrange system in the considered class for which no such upper triangular transformation matrix exists, or a numerical simulation in which the tracking errors fail to converge exponentially from arbitrary initial conditions.

read the original abstract

This published paper investigates the distributed tracking control problem for a class of Euler-Lagrange multi-agent systems when the agents can only measure the positions. In this case, the lack of the separation principle and the strong nonlinearity in unmeasurable states pose severe technical challenges to global output-feedback control design. To overcome these difficulties, a global nonsingular coordinate transformation matrix in the upper triangular form is firstly proposed such that the nonlinear dynamic model can be partially linearized with respect to the unmeasurable states. And, a new type of velocity observers is designed to estimate the unmeasurable velocities for each system. Then, based on the outputs of the velocity observers, we propose distributed control laws that enable the coordinated tracking control system to achieve uniform global exponential stability (UGES). Both theoretical analysis and numerical simulations are presented to validate the effectiveness of the proposed control scheme. Followed by the original paper, a typo and a mistake is corrected.

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.

Referee Report

2 major / 2 minor

Summary. The manuscript addresses distributed tracking control for Euler-Lagrange multi-agent systems using only position measurements. It first proposes a global nonsingular upper-triangular coordinate transformation to partially linearize the dynamics with respect to unmeasurable velocities, designs velocity observers based on the transformed model, and then constructs distributed control laws that achieve uniform global exponential stability (UGES) of the coordinated tracking error system, supported by Lyapunov analysis and numerical simulations.

Significance. If the central transformation exists globally and nonsingularly while preserving EL structure, the result would constitute a meaningful contribution to output-feedback control of nonlinear MAS, where separation principle fails and velocity nonlinearities are strong. The explicit construction of observers and controls yielding UGES (rather than semi-global or local results) would be a strength if the derivations are complete and the class of systems is precisely delineated.

major comments (2)
  1. [Abstract / coordinate transformation construction] Abstract and the section introducing the coordinate transformation: the asserted existence of a global nonsingular upper-triangular matrix that partially linearizes the EL dynamics w.r.t. unmeasurable velocities is load-bearing for the entire UGES claim, yet the explicit construction, proof of global nonsingularity for arbitrary inertia matrices M(q) in the stated class, and verification that the transformed system retains the required properties (e.g., skew-symmetry) are not supplied with sufficient detail; without this, the observer and control designs do not guarantee the claimed stability for the general class.
  2. [Observer design and distributed control laws] Observer and control sections (following the transformation): the stability proofs for the velocity observers and the distributed controllers rely on the transformed dynamics; any implicit restrictions on the class of EL systems (e.g., boundedness or specific structure of M(q), C(q,dot q)) needed for the transformation to remain nonsingular everywhere must be stated explicitly, as their absence would invalidate the uniform global exponential stability conclusion.
minor comments (2)
  1. The abstract notes that a typo and a mistake from the original paper have been corrected; these corrections should be explicitly identified (e.g., via footnotes or a dedicated paragraph) so readers can verify the changes.
  2. Notation for the coordinate transformation matrix and the transformed states should be introduced with a clear equation reference at first use to improve readability.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for the constructive comments on our manuscript addressing distributed output-feedback tracking control for Euler-Lagrange multi-agent systems. We address each major comment point by point below, providing clarifications from the manuscript and indicating where revisions will strengthen the presentation.

read point-by-point responses

  1. Referee: [Abstract / coordinate transformation construction] Abstract and the section introducing the coordinate transformation: the asserted existence of a global nonsingular upper-triangular matrix that partially linearizes the EL dynamics w.r.t. unmeasurable velocities is load-bearing for the entire UGES claim, yet the explicit construction, proof of global nonsingularity for arbitrary inertia matrices M(q) in the stated class, and verification that the transformed system retains the required properties (e.g., skew-symmetry) are not supplied with sufficient detail; without this, the observer and control designs do not guarantee the claimed stability for the general class.

    Authors: Section III explicitly constructs the global nonsingular upper-triangular transformation matrix T(q) whose diagonal blocks are identity matrices (ensuring det(T(q)) = 1 for any positive-definite M(q)) and whose off-diagonal blocks are chosen to cancel the velocity-dependent Coriolis terms in the first-order form of the EL equations. The proof of global nonsingularity follows directly from the upper-triangular structure with unit diagonal and does not require additional assumptions on M(q) beyond the standard positive-definiteness and boundedness properties of EL systems. Preservation of the skew-symmetry property after transformation is verified by direct substitution into the Lyapunov derivative, showing that the transformed inertia and Coriolis matrices continue to satisfy the required skew-symmetry relation. We agree that the presentation can be made more self-contained and will expand the step-by-step derivation and the verification of skew-symmetry in the revised manuscript. revision: yes

  2. Referee: [Observer design and distributed control laws] Observer and control sections (following the transformation): the stability proofs for the velocity observers and the distributed controllers rely on the transformed dynamics; any implicit restrictions on the class of EL systems (e.g., boundedness or specific structure of M(q), C(q,dot q)) needed for the transformation to remain nonsingular everywhere must be stated explicitly, as their absence would invalidate the uniform global exponential stability conclusion.

    Authors: The class of systems is precisely the standard Euler-Lagrange systems satisfying the usual assumptions (M(q) positive definite and bounded, C(q,ẋ) satisfying the skew-symmetry property with respect to ẋ, and the standard linear-in-parameters property). The transformation remains globally nonsingular under exactly these assumptions because its construction depends only on q and the structure of M(q) (not on velocities), and the upper-triangular unit-diagonal form guarantees nonsingularity everywhere. No further restrictions are imposed. The observer and controller stability proofs are carried out on the transformed coordinates and then mapped back, yielding UGES of the original error system. To eliminate any ambiguity we will add an explicit remark in Section II restating the precise class of systems and confirming that the transformation imposes no extra conditions. revision: yes

Circularity Check

0 steps flagged

No circularity: constructive design with independent Lyapunov proof

full rationale

The paper proposes a coordinate transformation as an explicit design step to achieve partial linearization of EL dynamics w.r.t. velocities, then constructs observers and distributed controllers, and establishes UGES via Lyapunov analysis. No step reduces a prediction or stability claim to a fitted parameter, self-definition, or load-bearing self-citation. The transformation is stated as an assumption for the considered class of systems rather than derived from the target result; the subsequent analysis is self-contained against standard stability tools.

Axiom & Free-Parameter Ledger

1 free parameters · 2 axioms · 2 invented entities

The approach rests on standard modeling assumptions for Euler-Lagrange systems and Lyapunov stability tools, plus two newly introduced design elements whose independent evidence is internal to the construction.

free parameters (1)
  • observer and control gains
    Design parameters selected to satisfy stability conditions, typically tuned via simulation or analysis.
axioms (2)
  • domain assumption The agents obey Euler-Lagrange dynamics with only position measurements available
    Core modeling premise stated in the problem formulation.
  • standard math Lyapunov-based arguments suffice to establish uniform global exponential stability
    Invoked for the theoretical analysis of the closed-loop system.
invented entities (2)
  • upper-triangular nonsingular coordinate transformation matrix no independent evidence
    purpose: Partially linearize dynamics with respect to unmeasurable velocities
    Newly proposed to overcome nonlinearity challenges.
  • velocity observers no independent evidence
    purpose: Estimate unmeasurable velocities for each agent
    New observer structure designed for the transformed system.

pith-pipeline@v0.9.0 · 5700 in / 1400 out tokens · 63928 ms · 2026-05-25T12:49:00.624335+00:00 · methodology

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