Incremental Motor Skill Learning and Generalization from Human Dynamic Reactions based on Dynamic Movement Primitives and Fuzzy Logic System

AbstractIn this paper, composite dynamic movement primitives (DMPs) based on radial basis function neural networks (RBFNNs) are investigated for robots’ skill learning from human demonstrations. The composite DMPs could encode the position and orientation manipulation skills simultaneously for human-to-robot skills transfer. As the robot manipulator is expected to perform tasks in unstructured and uncertain environments, it requires the manipulator to own the adaptive ability to adjust its behaviours to new situations and environments. Since the DMPs can adapt to uncertainties and perturbation, and spatial and temporal scaling, it has been successfully employed for various tasks, such as trajectory planning and obstacle avoidance. However, the existing skill model mainly focuses on position or orientation modelling separately; it is a common constraint in terms of position and orientation simultaneously in practice. Besides, the generalisation of the skill learning model based on DMPs is still hard to deal with dynamic tasks, e.g., reaching a moving target and obstacle avoidance. In this paper, we proposed a composite DMPs-based framework representing position and orientation simultaneously for robot skill acquisition and the neural networks technique is used to train the skill model. The effectiveness of the proposed approach is validated by simulation and experiments.

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Dynamic movement primitives based cloud robotic skill learning for point and non-point obstacle avoidance

Assembly Automation ◽

10.1108/aa-11-2020-0168 ◽

2021 ◽

Vol ahead-of-print (ahead-of-print) ◽

Author(s):

Zhenyu Lu ◽

Ning Wang

Keyword(s):

Obstacle Avoidance ◽

Skill Learning ◽

Unknown Parameters ◽

Content Type ◽

Learning Framework ◽

Movement Primitives ◽

Dynamic Movement ◽

Forcing Function ◽

Universal Space ◽

Dynamic Movement Primitives

Purpose Dynamic movement primitives (DMPs) is a general robotic skill learning from demonstration method, but it is usually used for single robotic manipulation. For cloud-based robotic skill learning, the authors consider trajectories/skills changed by the environment, rebuild the DMPs model and propose a new DMPs-based skill learning framework removing the influence of the changing environment. Design/methodology/approach The authors proposed methods for two obstacle avoidance scenes: point obstacle and non-point obstacle. For the case with point obstacles, an accelerating term is added to the original DMPs function. The unknown parameters in this term are estimated by interactive identification and fitting step of the forcing function. Then a pure skill despising the influence of obstacles is achieved. Using identified parameters, the skill can be applied to new tasks with obstacles. For the non-point obstacle case, a space matching method is proposed by building a matching function from the universal space without obstacle to the space condensed by obstacles. Then the original trajectory will change along with transformation of the space to get a general trajectory for the new environment. Findings The proposed two methods are certified by two experiments, one of which is taken based on Omni joystick to record operator’s manipulation motions. Results show that the learned skills allow robots to execute tasks such as autonomous assembling in a new environment. Originality/value This is a new innovation for DMPs-based cloud robotic skill learning from multi-scene tasks and generalizing new skills following the changes of the environment.

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The Effect of Aimed Movements in Sequenced Motor Skill Learning Motor Skill Acquisition Using Aiming and the SRTT

PsycEXTRA Dataset ◽

10.1037/e626972012-119 ◽

2008 ◽

Author(s):

Michelle V. Thompson ◽

Janet L. Utschig ◽

Mikaela K. Vaughan ◽

Marc V. Richard ◽

Benjamin A. Clegg

Keyword(s):

Skill Acquisition ◽

Motor Skill ◽

Skill Learning ◽

Motor Skill Learning ◽

Motor Skill Acquisition

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A New Hardware Architecture for Fuzzy Logic System Acceleration

Iraqi Journal for Electrical And Electronic Engineering ◽

10.33762/eeej.2016.118377 ◽

2016 ◽

Vol 12 (2) ◽

pp. 188-197

Author(s):

A yahoo.com ◽

Aumalhuda Gani Abood aumalhuda ◽

A comp ◽

Dr. Mohammed A. Jodha ◽

Dr. Majid A. Alwan

Keyword(s):

Fuzzy Logic ◽

Fuzzy Logic System ◽

Hardware Architecture ◽

Logic System

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Bimanual Motor Skill Learning Through Robotics in Stroke Survivors and Healthy Individuals

Case Medical Research ◽

10.31525/ct1-nct03974750 ◽

2019 ◽

Author(s):

Keyword(s):

Motor Skill ◽

Skill Learning ◽

Stroke Survivors ◽

Motor Skill Learning ◽

Healthy Individuals

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Penerapan Logika Samar dalam Peramalan Data Runtun Waktu

Jurnal ULTIMATICS ◽

10.31937/ti.v3i2.299 ◽

2011 ◽

Vol 3 (2) ◽

pp. 11-15

Author(s):

Seng Hansun

Keyword(s):

Time Series ◽

Fuzzy Logic ◽

Time Series Analysis ◽

Fuzzy Sets ◽

Fuzzy System ◽

Time Series Data ◽

Fuzzy Logic System ◽

Series Data ◽

Series Analysis ◽

Logic System

Recently, there are so many soft computing methods been used in time series analysis. One of these methods is fuzzy logic system. In this paper, we will try to implement fuzzy logic system to predict a non-stationary time series data. The data we use here is Mackey-Glass chaotic time series. We also use MATLAB software to predict the time series data, which have been divided into four groups of input-output pairs. These groups then will be used as the input variables of the fuzzy logic system. There are two scenarios been used in this paper, first is by using seven fuzzy sets, and second is by using fifteen fuzzy sets. The result shows that the fuzzy system with fifteen fuzzy sets give a better forecasting result than the fuzzy system with seven fuzzy sets. Index Terms—forecasting, fuzzy logic, Mackey-Glass chaotic, MATLAB, time series analysis

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