Showing total 9 results

1. A Common Framework for Complete and Incomplete Attitude Synchronization in Networks With Switching Topology.

Author

Pereira, Pedro O., Boskos, Dimitris, and Dimarogonas, Dimos V.

Subjects

*SWITCHING systems (Telecommunication), *SYNCHRONIZATION, *ANGULAR velocity, *TOPOLOGY, *ELECTRIC network topology

Abstract

In this paper, we study attitude synchronization for elements in the unit sphere in $\mathbb {R}^{\scriptscriptstyle {\scriptscriptstyle {3}}}$ and for elements in the three-dimensional (3-D) rotation group, for a network with switching topology. The agents’ angular velocities are assumed to be the control inputs, and a switching control law for each agent is devised that guarantees synchronization, provided that all elements are initially contained in a region, which we identify later in the paper. The control law is decentralized and it does not require a common orientation frame among all agents. We refer to synchronization of unit vectors in $\mathbb {R}^{\scriptscriptstyle {3}}$ as incomplete synchronization, and of 3-D rotation matrices as complete synchronization. Our main contribution lies in showing that these two problems can be analyzed under a common framework, where all agents’ dynamics are transformed into unit vectors dynamics on a sphere of appropriate dimension. [ABSTRACT FROM AUTHOR]

Published

2020

2. Event-Based Distributed Filtering Over Markovian Switching Topologies.

Author

Liu, Qinyuan, Wang, Zidong, He, Xiao, and Zhou, Donghua

Subjects

*NUMERICAL analysis, *WIRELESS sensor networks, *T cells, *ALGORITHMS, *DETECTORS

Abstract

In this paper, we consider the distributed filtering problem for continuous-time stochastic systems over sensor networks subject to Markovian switching topologies. Due to limited communication energy and bandwidth, an event-based communication scheme is proposed with the aim to decrease the transmission frequency. An individual triggering condition is put forward to regulate the communication rates for each component of the system state in order to better reflect the engineering requirements. The aim of this paper is to design a distributed filter over sensor networks with Markovian switching topologies such that the dynamics of the estimation error is exponentially mean-square bounded. It is shown that, with the proposed event-based distributed filtering algorithm, the exponential mean-square boundedness of the estimation errors is guaranteed if the sensor network is distributively detectable and the combined communication topology is strongly connected. A numerical example is presented to illustrate the usefulness of the developed algorithm. [ABSTRACT FROM AUTHOR]

Published

2019

3. Cooperative Control of Multiple Agents With Unknown High-Frequency Gain Signs Under Unbalanced and Switching Topologies.

Author

Wang, Qingling, Psillakis, Haris E., and Sun, Changyin

Subjects

*MULTIAGENT systems, *TOPOLOGY, *NONLINEAR systems, *GRAPH theory, *ALGORITHMS

Abstract

Existing results on cooperative control of multiagent systems with unknown control directions require that the underlying topology is either fixed with a strongly connected graph or switching between different strongly connected graphs. Furthermore, in most cases the graph is assumed to be balanced. This paper proposes a new class of nonlinear proportional-integral (PI) based algorithms to relax these requirements and allow for unbalanced and switching topologies having a jointly strongly connected basis. This is made possible for single-integrator (SI) and double-integrator (DI) agents with nonidentical unknown control directions by a suitable selection of the distributed nonlinear PI functions. Moreover, as a special case, the proposed algorithms are applied to strongly connected and fixed graphs. Finally, simulation examples are given to show the validity of our theoretical results. [ABSTRACT FROM AUTHOR]

Published

2019

4. Consensus of Nonidentical Euler–Lagrange Systems Under Switching Directed Graphs.

Author

Abdessameud, Abdelkader

Subjects

*ADAPTIVE control systems, *DISTRIBUTED algorithms, *EULER-Lagrange equations, *MULTIAGENT systems, *ELECTRIC switchgear, *TOPOLOGY

Abstract

This paper studies the consensus problem of nonidentical Euler–Lagrange systems with parametric uncertainties, under switching directed graphs. We present an adaptive distributed control algorithm that solves this problem in the leaderless scenario, under weak assumptions on the switching interconnection between agents. It is shown that the proposed consensus protocol achieves consensus without using neighbor's velocity information and accounts for the discontinuity of the input torque that results from the switching interaction between agents. Simulation results are given to illustrate the effectiveness of the proposed control schemes. [ABSTRACT FROM AUTHOR]

Published

2019

5. Event-Triggered Cooperative Output Regulation of Linear Multi-Agent Systems Under Jointly Connected Topologies.

Author

Hu, Wenfeng, Liu, Lu, and Feng, Gang

Subjects

*MULTIAGENT systems, *TOPOLOGY, *NUMERICAL analysis, *COMMUNICATION, *NONLINEAR systems

Abstract

This paper addresses the cooperative output regulation problem of linear multi-agent systems under switching communication topologies. A distributed event-triggered control scheme is proposed so that the cooperative output regulation problem is solved with only intermittent communication. The communication topology is not required to be connected at every time instant under the jointly connected assumption. With the proposed triggering mechanism, each agent only transmits the information to its neighbors at its own triggering times or the switching times. By introducing a fixed timer, Zeno behavior is strictly excluded for each agent. The effectiveness of the proposed control scheme is demonstrated by an example. [ABSTRACT FROM AUTHOR]

Published

2019

6. On Leader–Follower Consensus With Switching Topologies: An Analysis Inspired by Pigeon Hierarchies.

Author

Shao, Jinliang, Zheng, Wei Xing, Huang, Ting-Zhu, and Bishop, Adrian N.

Subjects

*DISCRETE-time systems, *TOPOLOGY, *MULTIAGENT systems, *HIERARCHICAL clustering (Cluster analysis), *SAMPLING errors

Abstract

Inspired by the interesting findings regarding the hierarchy and coordination of pigeons in Nagy et al.  [Nature, 2010], we revisit the discrete-time leader–follower consensus problem with switching topologies. The purpose of this paper is to investigate the impact of hierarchical topologies and followers’ self-loops on the convergence performance of leader–follower consensus, including the convergence rate and robustness to switching topologies. We first study the fixed topology case, and show that the followers converge to the leader's state in finite time if and only if each follower has no self-loops and the topology is hierarchical. However, we show via counterexample, that leader–follower consensus may not be achieved when some followers have no self-loops and the topology is switching; even if each interaction graph has a spanning tree rooted at the leader. With the aid of binary relation theory, we further develop a new approach to present a novel sufficient condition for leader–follower consensus with switching topologies and with some followers having no self-loops. We prove that when no followers have self-loops and the same hierarchical organization is kept under the switching topologies, then the fastest rate of convergence in leader–follower consensus can be achieved; even in the presence of complex dynamic topologies. This is consistent with the natural phenomena found in pigeons by Nagy et al. [ABSTRACT FROM AUTHOR]

Published

2018

7. A Graph Laplacian Approach to Coordinate-Free Formation Stabilization for Directed Networks.

Author

Lin, Zhiyun, Wang, Lili, Han, Zhimin, and Fu, Minyue

Subjects

*DIRECTED graphs, *STABILITY theory, *LAPLACIAN operator, *CONTROL theory (Engineering), *ANALYTIC geometry, *COMPUTER simulation

Abstract

This paper concentrates on coordinate-free formation control for directed networks, for which the dynamic motion of each agent is assumed to be governed only by a local control. We develop a graph Laplacian approach to solve the global and exponential formation stablization problem using merely relative position measurements between neighbors. First, to capture the sensing and control architectures that are needed to maintain the shape of a formation, a necessary and sufficient topological condition is proposed. Second, a Laplacian-based control law is developed for the stablization problem of a group of mobile agents to a desired formation shape under both fixed and switching topologies due to temporal node failures. Simulation results are provided to demonstrate that our Laplacian-based formation control strategy is inherently fault-tolerant and robust to node failures. [ABSTRACT FROM AUTHOR]

Published

2016

8. Connectivity and Set Tracking of Multi-Agent Systems Guided by Multiple Moving Leaders.

Author

Shi, Guodong, Hong, Yiguang, and Johansson, Karl Henrik

Subjects

*MULTIAGENT systems, *CONVEX sets, *POLYTOPES, *STOCHASTIC convergence, *ELECTRIC network topology, *ELECTRIC switchgear

Abstract

In this paper, we investigate distributed multi-agent tracking of a convex set specified by multiple moving leaders with unmeasurable velocities. Various jointly connected interaction topologies of the follower agents with uncertainties are considered in the study of set tracking. Based on the connectivity of the time-varying multi-agent system, necessary and sufficient conditions are obtained for set input-to-state stability and set integral input-to-state stability for a nonlinear neighbor-based coordination rule with switching directed topologies. Conditions for asymptotic set tracking are also proposed with respect to the polytope spanned by the leaders. [ABSTRACT FROM AUTHOR]

Published

2012

9. Passivity-Based Pose Synchronization in Three Dimensions.

Author

Hatanaka, Takeshi, Igarashi, Yuji, Fujita, Masayuki, and Spong, Mark W.

Subjects

*EUCLIDEAN algorithm, *PASSIVITY-based control, *SYNCHRONIZATION, *LAGRANGE equations, *VECTOR spaces

Abstract

This paper addresses passivity-based pose synchronization in the Special Euclidean group SE(3). We first develop a passivity-based distributed velocity input law to achieve pose synchronization. We next show that the pose synchronizes exponentially fast under an assumption on the initial states of the bodies, with an exponential convergence rate given by algebraic connectivity of interconnection graphs. We also prove pose synchronization in the presence of communication delays and topology switches. We moreover give further extensions of the present law, where desirable velocities and collision avoidance are taken into account. Finally, the effectiveness of the present inputs is demonstrated through numerical simulations and experiments on a planar (2D) test bed. [ABSTRACT FROM AUTHOR]

Published

2012