Decentralized Heading Control With Rate Constraints Using Pulse-Coupled Oscillators

Abstract: Decentralized heading control is crucial for robotic network operations such as surveillance, exploration, and cooperative construction. However, few results consider decentralized heading control when the speed of heading adjustment is restricted. In this paper, we propose a simple hybrid-dynamical model based on pulse-coupled oscillators for decentralized heading control in mobile robots while accounting for the constraint on the rate of heading change. The pulse-coupled oscillator model is effective in coor… Show more

“…For example, biological systems such as cardiac pacemakers and neuron networks can be effectively modeled by PCOs ( 61 ). In addition, the proposed method are well positioned to synchronize clocks in wireless sensor networks ( 41 , 42 , 53 ) and coordinate motions in robot networks ( 32 , 34 ). Furthermore, to the best of our knowledge, this paper is the first to use a distributed reinforcement learning approach to optimize synchronization under noncontinuous pulse-based interactions, which is different from continuous-time smooth interactions in the Kuramoto model ( 62 ).…”

Optimal synchronization in pulse-coupled oscillator networks using reinforcement learning

“…For example, biological systems such as cardiac pacemakers and neuron networks can be effectively modeled by PCOs ( 61 ). In addition, the proposed method are well positioned to synchronize clocks in wireless sensor networks ( 41 , 42 , 53 ) and coordinate motions in robot networks ( 32 , 34 ). Furthermore, to the best of our knowledge, this paper is the first to use a distributed reinforcement learning approach to optimize synchronization under noncontinuous pulse-based interactions, which is different from continuous-time smooth interactions in the Kuramoto model ( 62 ).…”

Optimal synchronization in pulse-coupled oscillator networks using reinforcement learning