Abstract
Multirobot cooperation enhancing the efficiency of numerous applications such as maintenance, rescue, inspection in cluttered unknown environments is the interesting topic recently. However, designing a formation strategy for multiple robots which enables the agents to follow the predefined master robot during navigation actions without a prebuilt map is challenging due to the uncertainties of self-localization and motion control. In this paper, we present a multirobot system to form the symmetrical patterns effectively within the unknown environment deployed randomly. To enable self-localization during group formatting, we propose the sensor fusion system leveraging sensor fusion from the ultrawideband-based positioning system, Inertial Measurement Unit orientation system, and wheel encoder to estimate robot locations precisely. Moreover, we propose a global path planning algorithm considering the kinematic of the robot’s action inside the workspace as a metric space. Experiments are conducted on a set of robots called Falcon with a conventional four-wheel skid steering schematic as a case study to validate our proposed path planning technique. The outcome of our trials shows that the proposed approach produces exact robot locations after sensor fusion with the feasible formation tracking of multiple robots system on the simulated and real-world experiments.
Highlights
Multirobot cooperation as the swarm system is one of the most discussed topics in the field of Robotics
The current paper utilizes a swarm of robots to address the problem of robot formation in unknown environments by low cost sensor fusion for robot self-localization and global path planning
A Marvelmind UWB with stationary and mobile versions are shown in Figure 1 in which the beacons on top of the robots are connected to Raspberry Pi through a USB cable, which will enable the positioning of swarm robots in the 2D map
Summary
The authors in the paper [5] proposed a decentralized control algorithm that enables the swarm robots to search for a given target. Another group of authors in [26] mimicked biological neural systems to perform task assignments to swarm robots This approach can handle dynamic path planning in 3D environments that are prone to uncertainty. The authors in the [29] presented an implementation of the previously mentioned Robotic Darwinian Particle Swarm Optimization (RDPSO) algorithm for a search and rescue application They reiterated that this approach helps solve the local minimum problem by adopting a Darwinian approach suitable for search and rescue applications. The current paper utilizes a swarm of robots to address the problem of robot formation in unknown environments by low cost sensor fusion for robot self-localization and global path planning.
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