Combining Evolutionary and Adaptive Control Strategies for Quadruped Robotic Locomotion

The cerebellum, which is responsible for motor control and learning, has been suggested to act as a Smith predictor for compensation of time-delays by means of internal forward models. However, insights about how forward model predictions are integrated in the Smith predictor have not yet been unveiled. To fill this gap, a novel bio-inspired modular control architecture that merges a recurrent cerebellar-like loop for adaptive control and a Smith predictor controller is proposed. The goal is to provide accurate anticipatory corrections to the generation of the motor commands in spite of sensory delays and to validate the robustness of the proposed control method to input and physical dynamic changes. The outcome of the proposed architecture with other two control schemes that do not include the Smith control strategy or the cerebellar-like corrections are compared. The results obtained on four sets of experiments confirm that the cerebellum-like circuit provides more effective corrections when only the Smith strategy is adopted and that minor tuning in the parameters, fast adaptation and reproducible configuration are enabled.

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“…55,56 Finally, we argue that the performance could be improved by using advanced techniques for optimization of control parameters. 57,58…”

Section: Discussionmentioning

confidence: 99%

A Cerebellum-Inspired Learning Approach for Adaptive and Anticipatory Control

Tolu

Capolei

Vannucci

et al. 2019

Int. J. Neur. Syst.

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“…There are also six-legged robots called hexapods. In [41], various control architectures are applied in the four-legged robot to monitor robot behavior. These procedures are base on bio-inspired structures help in carrying heavy loads for their dynamic stability and heavy equipment carrying capacity through the rough surface [41].…”

Section: ) Four-legged Robot (Quadruped Robots)mentioning

confidence: 99%

Critical Design and Control Issues of Indoor Autonomous Mobile Robots: A Review

et al. 2021

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Robots that can move autonomously and can make intelligent decisions by perceiving their environments and surrounding objects are known as autonomous mobile robots. Such robots have rapidly moved from laboratories to automated industries to fill a variety of roles in our lives, homes, offices, hospitals, industries, and even on the streets. The interest in mobile robots is growing rapidly, prompting an enormous amount of research over the last 30 years, on critical factors of mobile robots such as locomotion, perception, localization, mapping, ego-motion tracking, and dynamic navigation. This article surveys these essential factors of autonomous mobile robots in terms of mathematical modeling, control issues, and challenging factors. Brief discussions are provided on the fundamentals of these technologies, popular algorithms in comprehensive mode, future challenges, and promising directions to guide the construction of an autonomous mobile robot with high accuracy and effectiveness. Since it is difficult to find complete coverage of those topics in a single location, this article provides a guideline for researchers entering the field or for innovators in the mobile robotics sector. The paper also examines open challenges in indoor mobile robots and identifies potential futures for autonomous mobile robots.

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“…For each joint i ∈ {a; k}, the desired torque is expressed as τ i des = τ i FB +τ i pred , where the feedback torque component τ i FB is computed by a proportional-derivative (PD) controller and the predictive torque component τ i pred relies on iterative learning of a dynamical internal model. This control architecture -and in particular its prediction module -is inspired from [26], [27].…”

Section: Control Architecturementioning

confidence: 99%

“…This dynamical model is incrementally learned by LWPR, an algorithm that has been successfully used in different simulation studies, e.g. [26], [27]. In our approach, each prosthesis joint i ∈ {a; k} has its own LWPR module, computing τ i pred from the set of sensory inputs x.…”

Section: B Predictive Contribution: Dynamical Internal Modelmentioning

confidence: 99%