Configuration of a Paraconsistent Artificial Neural Network for the Learning from Demonstration Method applied to a Robotic Arm

Authors

DOI:

https://doi.org/10.33448/rsd-v11i7.29720

Keywords:

Paraconsistent Annotated Logic; Learning from demonstration; Artificial Intelligence; Teaching; Paraconsistent artificial neural network.

Abstract

The Annotated Paraconsistent Logic - LPA is a non-classical logic, based on concepts that allow, under certain conditions, to accept the contradiction in its foundations, without invalidating the conclusions. Mathematical interpretations in its associated lattice make it possible to obtain equations and algorithm constructions, which form efficient paraconsistent analysis networks, in treating signals simulating learning. The algorithm used in this research is called Paraconsistent Artificial Neural Cell of Learning (CNAPap), and was created from equations based on LPA. With standardized signals repeatedly applied to its input, CNAPap is capable of gradually storing this information, increasing or decreasing its level of response at the output with asymptotic variation, controlled by a Learning Factor (FA). To run the tests, a set of five CNAPaps forming a learning Paraconsistent Artificial Neural Network (RNAPap), was implemented in an ATMEGA 328p microcontroller and several tests were carried out to validate its operation, acting on learning by demonstration (LfD) in a Robot Manipulator. Considering the fragile mechanical structure of the Robot Manipulator, and the sensor devices adapted to respond to the standards, the laboratory results obtained in the various tests presented were satisfactory, and the microprocessed system built responded efficiently, where the levels of correct answers corresponded to between 75 % to 90%, at all stages of the LfD method. The results of comparative studies showed that RNAPap has dynamic properties capable of acting both in the demonstration learning method and in the imitation method.

Author Biography

Cláudio Luís Magalhães Fernandes, Universidade Santa Cecília

Possui graduação em Engenharia Elétrica Modalidade Eletrônica com Ênfase em Computação pela Universidade Santa Cecilia (2006), Pós Graduação Lato Senso em Automação Industrial pela Faculdade SENAI de Tecnologia Mecatrônica (2010), Pós Graduação Lato Sensu em Docência na Educação Profissional, pelo SENAI CETIQT (2015), Mestrado Profissionalizante em Engenharia Mecânica pela Universidade Santa Cecília (2012) e cursando Doutorado em Engenharia Mecânica na Universidade Santa Cecília. Atualmente é Diretor Acadêmico do Ensino Superior das Faculdades SENAI do estado de São Paulo, Professor da Faculdade de Tecnologia São Vicente dos cursos Tecnólogo em Automação Industrial, Bacharelado em Sistemas de Informação, Engenharia Elétrica. Atua na Universidade Santa Cecília - UNISANTA como pesquisador de técnicas de Inteligência Artificial que fazem uso dos conceitos das Lógicas Não-Clássicas, com ênfase na LPA2V (Lógica Paraconsistente Anotada de dois Valores) e Lógica Fuzzy, aplicadas a sistemas Robóticos e no Controle de Processos Industriais.

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Published

21/05/2022

How to Cite

GOMES, P. M. .; FERNANDES, C. L. M. .; SILVA FILHO, J. I. da .; SILVEIRA, R. S. da .; SANTO, L. do E. .; MARIO, M. C. .; ROSA, V. da S. .; TORRES, G. L. . Configuration of a Paraconsistent Artificial Neural Network for the Learning from Demonstration Method applied to a Robotic Arm. Research, Society and Development, [S. l.], v. 11, n. 7, p. e20911729720, 2022. DOI: 10.33448/rsd-v11i7.29720. Disponível em: https://rsdjournal.org/index.php/rsd/article/view/29720. Acesso em: 2 dec. 2024.

Issue

Section

Engineerings