Abstract
For the last four decades, the development of robotic hands has been the focus of several works. However, a small part of those approaches consider the exploitation of parallelism of FPGA-based (Field Programmable Gate Arrays) systems or discuss how using bioinspired optimization algorithms could improve the mechanical and controller components. This work considers developing a bioinspired robotic hand that achieves motion and force control with a logic hardware architecture implemented in FPGA intended to be replicated and executed with suitable parallelism, fitting a single device. The developed robotic hand prototype has five fingers and seven DoF (Degrees of Freedom). Using bioinspired optimization, such as PSO (Particle Swarm Optimization), both the rigid finger mechanism and the impedance controller were optimized and incorporated the results in several practical grasping experiments. The validation of this work is done with the Cutkosky grasping taxonomy and some grasping experiments with interference. The tests proved the proficiency of this works for a wide range of power and some precision grasp. The reader can see the experiments in the attached videos.
Highlights
Over the past four decades, there have been significant contributions in the field of computer science, artificial intelligence, robotics, and other related fields
There is much effort towards building biomimetic robotic hands, which have contributed to a better understanding of implementing a human hand into a dexterous gripper/manipulation robot, widening its applications through improved sensors and mechanisms [15]
This work’s primary goal is developing a bioinspired robotic hand that achieves motion and force control based on the previously developed logic hardware architecture validated for a single finger [19]
Summary
Over the past four decades, there have been significant contributions in the field of computer science, artificial intelligence, robotics, and other related fields. This work’s primary goal is developing a bioinspired robotic hand that achieves motion and force control based on the previously developed logic hardware architecture validated for a single finger [19] In this sense, this work explores a suitable manner to parallelize the impedance controllers for a complete 7-DoF robotic hand, fitting a single FPGA device. This work’s contributions are the following: (a) A novel experimental setup process for implementing a bioinspired robotic hand with an embedded controller using reconfigurable hardware FPGA/SoC (System on a Chip) This approach’s main advantage is its capacity to control several DoF in parallel using a single chip that’s relatively cheap and energy-efficient, different from other works that need to use a grid of micro-controllers or big processors.
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