The quadruped robot locomotion based on force control

Achieving versatile robot locomotion requires motor skills that can adapt to previously unseen situations. We propose a multi-expert learning architecture (MELA) that learns to generate adaptive skills from a group of representative expert skills. During training, MELA is first initialized by a distinct set of pretrained experts, each in a separate deep neural network (DNN). Then, by learning the combination of these DNNs using a gating neural network (GNN), MELA can acquire more specialized experts and transitional skills across various locomotion modes. During runtime, MELA constantly blends multiple DNNs and dynamically synthesizes a new DNN to produce adaptive behaviors in response to changing situations. This approach leverages the advantages of trained expert skills and the fast online synthesis of adaptive policies to generate responsive motor skills during the changing tasks. Using one unified MELA framework, we demonstrated successful multiskill locomotion on a real quadruped robot that performed coherent trotting, steering, and fall recovery autonomously and showed the merit of multi-expert learning generating behaviors that can adapt to unseen scenarios.

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Position/Force Control for a Single Leg of a Quadruped Robot in an Operation Space

International Journal of Advanced Robotic Systems ◽

10.5772/54823 ◽

2013 ◽

Vol 10 (2) ◽

pp. 137 ◽

Cited By ~ 8

Author(s):

Taihui Zhang ◽

Qing Wei ◽

Hongxu Ma

Keyword(s):

Force Control ◽

Quadruped Robot

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Quadruped Robot Locomotion in Unknown Terrain Using Deep Reinforcement Learning

2020 3rd International Conference on Unmanned Systems (ICUS) ◽

10.1109/icus50048.2020.9274920 ◽

2020 ◽

Author(s):

Muleilan Pei ◽

Dongping Wu ◽

Changhong Wang

Keyword(s):

Reinforcement Learning ◽

Quadruped Robot ◽

Robot Locomotion

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Performance Comparisons of Bio-micro Genetic Algorithms on Robot Locomotion

10.20944/preprints202003.0079.v1 ◽

2020 ◽

Author(s):

Francisco A. Chávez-Estrada ◽

Jacobo Sandoval-Gutierrez ◽

Juan C. Herrera-Lozada ◽

Mauricio Olguín-Carbajal ◽

Daniel L. Martínez-Vázquez ◽

...

Keyword(s):

Genetic Algorithm ◽

Embedded System ◽

Processing Time ◽

Quadruped Robot ◽

Robot Locomotion ◽

Real Performance ◽

The Individual ◽

Computational Resources ◽

And Control ◽

Better Than

This paper presents a novel micro-segmented genetic algorithm (μsGA) to identify the best solution for the locomotion of a quadruped robot designed on a rectangular ABS plastic platform. We compare our algorithm with three similar algorithms found in the specialized literature: a standard genetic algorithm (GA), a micro-genetic algorithm (μGA), and a micro artificial immune system (μAIS). The quadruped robot prototype guarantees the same conditions for each test. The platform was developed using 3D printing for the structure and can accommodate the mechanisms, sensors, servomechanisms as actuators. It also has an internal battery and a multicore embedded system (mES) to process and control the robot locomotion. This research proposes a μsGA that segments the individual into specific bytes. μGA techniques are applied to each segment to reduce the processing time; the same benefits as the GA are obtained, while the use of a computer and the high computational resources characteristic of the GA are avoided. This is the reason why some research in robot locomotion is limited to simulation. The results show that the performance of μsGA is better than the three other algorithms (GA, μGA and AIS). The processing time was reduced using a mES architecture that enables parallel processing, meaning that the requirements for resources and memory were reduced. This research solves the problem of continuous locomotion of a quadruped robot, and gives a feasible solution with real performance parameters using a μsGA bio-micro algorithm and a mES architecture.

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