This paper presents a run-time solver for the inverse kinematics of a robotic arm implemented on a heterogeneous Multi-Processor System-on-Chip (MPSoC). The solver has been formulated as an optimization problem,… Click to show full abstract
This paper presents a run-time solver for the inverse kinematics of a robotic arm implemented on a heterogeneous Multi-Processor System-on-Chip (MPSoC). The solver has been formulated as an optimization problem, in which two levels of algorithmic parallelism are proposed: i) the Nelder-Mead derivative-free method used as the optimization engine is modified to allow the evaluation of the cost function in multiple vertices simultaneously, ii) the trajectory is divided into non-overlapping segments, in which all the points are solved concurrently. Algorithmic parallelism is supported by a variable number of parallel instances of a custom hardware accelerator, which speeds up the computation of the forward kinematics equations of the robot required during the resolution of the inverse kinematics. This adaptable scheme provides run-time scalability in terms of trajectory accuracy, logic resources, dependability, and execution time. New design methodologies are used to unify the modeling of the software and hardware partitions of the controller while transparently providing adaptability. They are based on the dataflow Model of Computation (MoC), supported by the PREESM prototyping tool. This tool has been extended to support the use of dynamically reconfigurable hardware accelerators implemented using the ARTICo3 framework. The proposal has been validated with a python-based robotic arm simulator. Experimental results show how the proposed parallelism, combined with hardware acceleration, enables the run-time resolution of the trajectory with adaptable performance using a Xilinx Zynq UltraScale+ MPSoC device.
               
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