Vitor Matos scite author profile

Vitor Matos

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5Publications

135Citation Statements Received

128Citation Statements Given

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Affiliations

University of Minho

Publications

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Gait transition and modulation in a quadruped robot: A brainstem-like modulation approach

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2011

Robotics and Autonomous Systems

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a b s t r a c tIn this article, we propose a bio-inspired architecture for a quadruped robot that is able to initiate/stop locomotion; generate different gaits, and to easily select and switch between the different gaits according to the speed and/or the behavioral context. This improves the robot stability and smoothness while locomoting.We apply nonlinear oscillators to model Central Pattern Generators (CPGs). These generate the rhythmic locomotor movements for a quadruped robot. The generated trajectories are modulated by a tonic signal, that encodes the required activity and/or modulation. This drive signal strength is mapped onto sets of CPG parameters. By increasing the drive signal, locomotion can be elicited and velocity increased while switching to the appropriate gaits. This drive signal can be specified according to sensory information or set a priori.The system is implemented in a simulated and real AIBO robot. Results demonstrate the adequacy of the architecture to generate and modulate the required coordinated trajectories according to a velocity increase; and to smoothly and easily switch among the different motor behaviors.

A brainstem-like modulation approach for gait transition in a quadruped robot

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2009

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Abstract-The ability to traverse a wide variety of terrains while walking is basically a requirement for performing useful tasks in our human centric world.In this article, we propose a bio-inspired robotic controller able to generate locomotion and to easily switch between different type of gaits. In order to improve the robot stability and response while locomoting, we adjust both the duty factor and the interlimb phase relationships, according to the velocities.We extend previous work, by applying nonlinear oscillators to generate the rhythmic locomotor movements for a quadruped robot, similarly to the biological counterparts. The generated trajectories are modulated by a drive signal, that modifies the oscillator frequency, amplitude and the coupling parameters among the oscillators, proportionally to the drive signal strength. By increasing the drive signal, locomotion can be elicited and velocity increased while switching to the appropriate gaits. This drive signal can be specified according to sensory information or set a priori.The implementation of the central pattern generator network and the activity modulation layer is shown in simulation and in an AIBO robot.

Central Pattern Generators with phase regulation for the control of humanoid locomotion

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2012

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CPG modulation for navigation and omnidirectional quadruped locomotion

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2012

Robotics and Autonomous Systems

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Multi-objective parameter CPG optimization for gait generation of a biped robot

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et al. 2013

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