Your search keyword '"Van Tran, Quoc"' showing total 19 results

1. Fixed-time Localization of Local Coordinate Frames: Interpretation and Applications to Formation Control Problems

Author

Van Tran, Quoc

Published

2023

2. Matrix-Scaled Consensus

Author

Trinh, Minh Hoang, Van Vu, Dung, Van Tran, Quoc, and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control, Electrical Engineering and Systems Science - Systems and Control

Abstract

This paper proposes matrix-scaled consensus algorithm, which generalizes the scaled consensus algorithm in \cite{Roy2015scaled}. In (scalar) scaled consensus algorithms, the agents' states do not converge to a common value, but to different points along a straight line in the state space, which depends on the scaling factors and the initial states of the agents. In the matrix-scaled consensus algorithm, a positive/negative definite matrix weight is assigned to each agent. Each agent updates its state based on the product of the sum of relative matrix scaled states and the sign of the matrix weight. Under the proposed algorithm, each agent asymptotically converges to a final point differing with a common consensus point by the inverse of its own scaling matrix. Thus, the final states of the agents are not restricted to a straight line but are extended to an open subspace of the state-space. Convergence analysis of matrix-scaled consensus for single and double-integrator agents are studied in detail. Simulation results are given to support the analysis., Comment: Accepted to the IEEE Conference on Decision and Control (CDC), 2022

Published

2022

3. Further analysis on structure and spectral properties of symmetric graphs

Author

Van Tran, Quoc and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

Graph is an abstract representation commonly used to model networked systems and structure. In problems across various fields, including computer vision and pattern recognition, and neuroscience, graphs are often brought into comparison (a process is called \textit{graph matching}) or checked for symmetry. Friendliness property of the associated adjacency matrices, specified by their spectral properties, is important in deriving a convex relaxation of the (intractable) discrete graph matching problem. In this work, we study unfriendliness properties of symmetric graphs by studying its relation to the underlying graph structure. It is revealed that a symmetric graph has two or more subgraphs of the same topology, and are adjacent to the same set of vertices. We then show that if adjacency matrices of symmetric graphs have distinct eigenvalues then there exist eigenvectors orthogonal to the vector of all ones, making them unfriendly. Relation of graph symmetry to uncontrollability of multi-agent systems under agreement dynamics with one controlled node is revisited. Examples of both synthetic and real-world graphs are also given for illustrations., Comment: 7 pages, manuscript accepted at the 2022 European Control Conference

Published

2022

4. Bearing-constrained Formation Tracking Control of Nonholonomic Agents without Inter-agent Communication

Author

Van Tran, Quoc and Kim, Jinwhan

Subjects

Mathematics - Optimization and Control

Abstract

This letter presents two bearing-constrained formation tracking control protocols for multiple nonholonomic agents based respectively on the bearing vectors and displacements between the agents. The desired formation pattern of the system is specified by the desired inter-agent bearing vectors. In the proposed control schemes, there are two or more leaders moving with the same constant velocity; the other follower agents do not have the information of the leaders' velocity nor communicate variables with their neighbors. Under both the proposed control laws, the system achieves the moving target formation asymptotically. Simulation results are provided to support the theoretical development., Comment: 8 pages, Manuscript submitted to the IEEE Control Systems Letters (L-CSS)

Published

2022

5. Direction-only Orientation Alignment of Leader-Follower Networks

Author

Van Tran, Quoc, Ahn, Hyo-Sung, and Kim, Jinwhan

Subjects

Mathematics - Optimization and Control

Abstract

When a team of agents, such as unmanned aerial/underwater vehicles, are operating in $3$-dimensional space, their coordinated action in pursuit of a cooperative task generally requires all agents to either share a common coordinate system or know the orientations of their coordinate axes with regard to the global coordinate frame. Given the coordinate axes that are initially unaligned, this work proposes an orientation alignment scheme for multiple agents with a type of leader-following graph typologies using only inter-agent directional vectors, and the direction measurements to one or more landmarks of the first two agents. The directional vectors are expressed in the agents' body-fixed coordinate frames and the proposed alignment protocol works exclusively with the directional vectors without the need of a global coordinate frame common to all agents or the construction of the agents' orientation matrices. Under the proposed alignment scheme, the orientations of the agents converge almost globally and asymptotically to the orientation of the leader agent. Finally, numerical simulations are also given to illustrate the effectiveness of the proposed method., Comment: Preprint accepted by the 2022 American Control Conference

Published

2022

6. Free-Will Arbitrary Time Consensus Protocols with Diffusive Coupling

Author

Van Tran, Quoc, Trinh, Minh Hoang, Nguyen, Nam Hoai, and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

In this technical note, we first clarify a technical issue in the convergence proof of a free-will arbitrary time (FwAT) consensus law proposed recently in Pal et al. IEEE Trans. Cybern. (2020)[1], making the results questionable. We then propose free-will arbitrary time consensus protocols for multi-agent systems with first- and second-order dynamics, respectively, and with (possibly switching) connected interaction graphs. Under the proposed consensus laws, we show that an average consensus is achieved in a free-will arbitrary prespecified time. Further, the proposed consensus laws are distributed in the sense that information is only communicated locally between neighboring agents; unlike the average consensus in [1] that uses a deformed Laplacian., Comment: 7 pages

Published

2021

7. Discrete-Time Matrix-Weighted Consensus

Author

Van Tran, Quoc, Trinh, Minh Hoang, and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

This article investigates discrete-time matrix-weighted consensus of multi-agent networks over undirected and connected graphs. We first present consensus protocols for the agents in common networks of symmetric matrix weights with possibly different update rates and switching network topologies. A special type of matrix-weighted consensus with non-symmetric matrix-weights that can render several consensus control scenarios such as ones with scaled/rotated updates and affine motion constraints is also considered. We employ Lyapunov stability theory for discrete-time systems and occasionally utilize Lipschitz continuity of the gradient of the Lyapunov function to show the convergence to a consensus of the agents in the system. Finally, simulation results are provided to illustrate the theoretical results., Comment: 10 pages. IEEE Transactions on Control of Network Systems, 2021

Published

2020

8. Distributed Computation of Graph Matching in Multi-Agent Networks

Author

Van Tran, Quoc, Sun, Zhiyong, Anderson, Brian D. O., and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

This work considers the distributed computation of the one-to-one vertex correspondences between two undirected and connected graphs, which is called \textit{graph matching}, over multi-agent networks. Given two \textit{isomorphic} and \textit{asymmetric} graphs, there is a unique permutation matrix that maps the vertices in one graph to the vertices in the other. Based on a convex relaxation of graph matching in Aflalo et al. (2015), we propose a distributed computation of graph matching as a distributed convex optimization problem subject to equality constraints and a global set constraint, using a network of multiple agents whose interaction graph is connected. Each agent in the network only knows one column of each of the adjacency matrices of the two graphs, and all agents collaboratively learn the graph matching by exchanging information with their neighbors. The proposed algorithm employs a projected primal-dual gradient method to handle equality constraints and a set constraint. Under the proposed algorithm, the agents' estimates of the permutation matrix converge to the optimal permutation globally and exponentially fast. Finally, simulation results are given to illustrate the effectiveness of the method., Comment: 10 pages, 2 figures, an extended version of a paper submitted to CDC20

Published

2020

9. Pose Localization of Leader-Follower Networks with Direction Measurements

Author

Van Tran, Quoc, Anderson, Brian D. O., and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

A distributed pose localization framework based on direction measurements is proposed for a type of \textit{leader-follower} multi-agent systems in $\mathbb{R}^3$. The novelty of the proposed localization method lies in the elimination of the need for using distance measurements and relative orientation measurements for the network pose localization problem. In particular, a network localization scheme is developed based directly on the measured direction constraints between an agent and its neighboring agents in the network. The proposed position and orientation localization algorithms are implemented through differential equations which simultaneously compute poses of all followers by using locally measured directional vectors and angular velocities, and actual pose knowledge of some leader agents, allowing some tracking of time-varying orientations. Further, we establish an almost global asymptotic convergence of the estimated positions and orientations of the agents to the actual poses in the stationary case., Comment: 13 pages, 6 figures

Published

2019

10. Multi-agent Localization of A Common Reference Coordinate Frame: An Extrinsic Approach

Author

Van Tran, Quoc and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

This paper studies the problem of multi-agent cooperative localization of a common reference coordinate frame in $\mathbb{R}^3$. Each agent in a system maintains a body-fixed coordinate frame and its actual \textit{frame transformation} (translation and rotation) from the global coordinate system is unknown. The mobile agents aim to determine their \textit{trajectories of rigid-body motions} (or the frame transformations, i.e., rotations and translations) with respect to the global coordinate frame up to a common frame transformation by using local measurements and information exchanged with neighbors. We present two frame localization schemes which compute the rigid-body motions of the agents with asymptotic stability and finite-time stability properties, respectively. Under both localization laws, the estimates of the frame transformations of the agents converge to the actual frame transformations almost globally and up to an unknown constant transformation bias. Finally, simulation results are provided., Comment: 9 pages, 4 figures, Extended version of a paper accepted at Ifac NecSys 2019

Published

2019

11. Topological Controllability of Undirected Networks of Diffusively-Coupled Agents

Author

Ahn, Hyo-Sung, Moore, Kevin L., Kwon, Seong-Ho, Van Tran, Quoc, Kim, Byeong-Yeon, and Oh, Kwang-Kyo

Subjects

Computer Science - Systems and Control

Abstract

This paper presents conditions for establishing topological controllability in undirected networks of diffusively coupled agents. Specifically, controllability is considered based on the signs of the edges (negative, positive or zero). Our approach differs from well-known structural controllability conditions for linear systems or consensus networks, where controllability conditions are based on edge connectivity (i.e., zero or nonzero edges). Our results first provide a process for merging controllable graphs into a larger controllable graph. Then, based on this process, we provide a graph decomposition process for evaluating the topological controllability of a given network.

Published

2019

12. Cooperative opinion dynamics on multiple interdependent topics: Modeling and analysis

Author

Ahn, Hyo-Sung, Van Tran, Quoc, Trinh, Minh Hoang, Moore, Kevin L., Ye, Mengbin, and Liu, Ji

Subjects

Electrical Engineering and Systems Science - Systems and Control

Abstract

To model the interdependent couplings of multiple topics, we develop a set of rules for opinion updates of a group of agents. The rules are used to design or assign values to the elements of interdependent weighting matrices. The cooperative and anti-cooperative couplings are modeled in both the inverse-proportional and proportional feedbacks. The behaviors of cooperative opinion dynamics are analyzed using a null space property of state-dependent matrix-weighted Laplacian matrices and a Lyapunov candidate. Various consensus properties of state-dependent matrix-weighted Laplacian matrices are predicted according to the intra-agent network topology and inter-dependency topical coupling topologies.

Published

2018

13. Pointing consensus for rooted out-branching graphs

Author

Trinh, Minh Hoang, Zelazo, Daniel, Van Tran, Quoc, and Ahn, Hyo-Sung

Subjects

Mathematics - Optimization and Control

Abstract

Given a network of multiple agents, the pointing consensus problem asks all agents to point toward a common target. This paper proposes a simple method to solve the pointing consensus problem in the plane. In our formulation, each agent does not know its own position, but has information about its own heading vector expressed in a common coordinate frame and some desired relative angles to the neighbors. By exchanging the heading vectors via a communication network described by a rooted out-branching graph and controlling the angle between the heading vectors, we show that all agents' heading vectors asymptotically point towards the same target for almost all initial conditions. Simulations are provided to validate the effectiveness of the proposed method., Comment: 6 pages, 6 figures, accepted to the American Control Conference 2018, Milwaukee, WI

Published

2018

14. Robust Path Tracking and Obstacle Avoidance using Tube-based Model Predictive Control for Surface Vehicles

Author

Lee, Changyu, Van Tran, Quoc, and Kim, Jinwhan

Published

2022

15. Distance-Based Formation Tracking of Single- and Double-Integrator Agents

Author

Vu, Hieu Minh, Trinh, Minh Hoang, Van Tran, Quoc, and Ahn, Hyo-Sung

Abstract

This article studies the distance-based formation tracking problem of a group of agents with a leader–follower topology. It is assumed that the desired formation is minimally infinitesimally rigid and the agents in the formation are classified as leaders and followers. The leaders are moving in the space and their positions determine a time-varying target formation, which may differ from the desired formation by a translation and a rotation. The followers, which can sense the local displacements with regard to their neighboring agents, track the moving target formation by controlling several interagent distance constraints. In case the followers are modeled by single integrators and the leaders are moving with bounded uniformly continuous velocities, we propose formation tracking control laws for followers with and without information on the exact upper bound of the leaders' velocities. Furthermore, another formation tracking law is proposed for double-integrator followers when the leaders are moving with the same constant velocity. In all cases, we provide sufficient conditions on the bound of the initial conditions so that the time-varying target formation is asymptotically achieved. Simulation results are then given to support the mathematical analysis.

Published

2024

16. Distributed Optimization for Graph Matching

Author

Van Tran, Quoc, Sun, Zhiyong, D. O. Anderson, Brian, and Ahn, Hyo-Sung

Abstract

Graph matching, or the determination of the vertex correspondences between a pair of graphs, is a crucial task in various problems in different science and engineering disciplines. This article aims to propose a distributed optimization approach for graph matching (GM) between two isomorphic graphs over multiagent networks. For this, we first show that for a class of asymmetric graphs, GM of two isomorphic graphs is equivalent to a convex relaxation where the set of permutation matrices is replaced by the set of pseudostochastic matrices. Then, we formulate GM as a distributed convex optimization problem with equality constraints and a set constraint, over a network of multiple agents. For arbitrary labelings of the vertices, each agent only has information about just one vertex and its neighborhood, and can exchange information with its neighbors. A projected primal-dual gradient method is developed to solve the constrained optimization problem, and globally exponential convergence of the agents’ states to the optimal permutation is achieved. Finally, we illustrate the effectiveness of the algorithm through simulation examples.

Published

2023

17. Distributed Optimization for Graph Matching

Author

Van Tran, Quoc, primary, Sun, Zhiyong, additional, Anderson, Brian D. O., additional, and Ahn, Hyo-Sung, additional

Published

2022

18. Minimal and Redundant Bearing Rigidity: Conditions and Applications

Author

Trinh, Minh Hoang, primary, Van Tran, Quoc, additional, and Ahn, Hyo-Sung, additional

Published

2020

19. Distributed Orientation Localization of Multi-agent Systems in 3-dimensional Space with Direction-only Measurements

Author

van Tran, Quoc, Ahn, Hyo-Sung, Anderson, Brian, van Tran, Quoc, Ahn, Hyo-Sung, and Anderson, Brian

Abstract

When a group of agents such as unmanned aerial vehicles are operating in 3-dimensional space, their coordinated action in pursuit of some group objective generally requires all agents to share a common coordinate frame or orientations of the coordinate axes of agents up to an unknown coordinate rotation common to all agents, which are simply referred to as having common coordinate axis orientations. Given coordinate axes that are initially unaligned, this paper considers the process of using direction measurements between agent pairs (obtained in their own coordinate frames) to achieve orientation localization, i.e. determination of common coordinate axis orientations, the calculations all being distributed. The process builds on the initial determination of relative orientations of agent pairs in a common coordinate basis. Distributed differential equations then allow determination of a common set of coordinate axis orientations, uniquely up to a common rotation transformation, which can itself be determined if and only if one or more agents have access to global coordinates.

Published

2018