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Robust Formation Control for PWM-Controlled Mobile Autonomous Multiagent Systems

Abstract

This article investigates the robust formation problem of a class of nonholonomic mobile robots that are controlled by pulsewidth-modulation (PWM) signals and subject to switching topologies and measurement disturbances. However, the existing literature does not fully account for the impact of hybrid PWM control inputs and second-order dynamics. As a result, traditional continuous linear control schemes require significant modification before application. To address this problem, a new class of distributed robust PWM controllers is proposed, ensuring that each PWM-controlled agent asymptotically converges to the desired position and velocity. In addition, an invariant set-like method is presented that restricts the states of each subsystem to a chosen closed set by analyzing the dynamic relationship between the interactions, as long as the information exchange topology satisfies a mild restriction. Finally, it is demonstrated that by analyzing the dynamic relationship between the interactions of different agents, the closed-loop system converges in the sense of input-to-state stability (ISS). A numerical example is provided to validate the theoretical results.

article Article

date_range 2024

language English

link Link of the paper

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Xu Jingwei

Wang Zhanxiu

Jin Zhenghong

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Featured Keywords

Pulse width modulation

Topology

Switches

Control systems

Multi-agent systems

Measurement uncertainty

Numerical stability

Distributed control

multiagent systems

pulsewidth modulation (PWM)

robust formation

switching topology

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Effect of corrosion on flexural strength of reinforced concrete beams with polypropylene fibers

Abstract

An experimental study was performed to investigate the effects of polypropylene fibers on uncorroded and corroded reinforced concrete beams. Three different volume fractions of polypropylene fibers having 0, 0.5, and 1.5%, were tested at four corrosion levels of 0% and approximately 5, 7, and 9%. A full scale of an accelerated corrosion pool was used for the accelerated corrosion process. Reinforced concrete beams were used for an under monotonic bending test. The contribution of the actual corrosion levels of transverse and longitudinal reinforcement bars to the total corrosion levels were obtained from reinforcement bars fully extracted from concrete. Flexural strength, bond-slip, and moment-curvature relationships were examined for uncorroded and corroded reinforced concrete beams. A new model was developed to predict the flexural strength of corroded reinforced concrete beams. The proposed model for predicting the residual flexural strength of corroded beams was compared with test data published in previous studies. Furthermore, a novel model is presented for improved predictions between the actual and theoretically estimated corrosion mass losses, based on Faraday’s law, with the aid of fully extracted reinforcement bars. The model used to predict the flexural strength of corroded reinforced concrete beams with large sizes demonstrated good agreement with current and previously published literature data. In the case of corroded beams comprising differing amounts of polypropylene fibers, the performance of the corroded beams was limited by a fiber volume fraction of 1.5% at low corrosion levels.

article Article

date_range 2018

language English

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