Your search keyword '"Ernesto Hernandez"' showing total 2 results

1. Event-Based, Intermittent, Discrete Adaptive Control for Speed Regulation of Artificial Legs

Author

Salvador Echeveste, Ernesto Hernandez-Hinojosa, and Pranav A. Bhounsule

Subjects

event-based control, adaptive control, intermittent control, discrete control, pendulum swing, artificial legs, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

For artificial legs that are used in legged robots, exoskeletons, and prostheses, it suffices to achieve velocity regulation at a few key instants of swing rather than tight trajectory tracking. Here, we advertise an event-based, intermittent, discrete controller to enable set-point regulation for problems that are traditionally posed as trajectory following. We measure the system state at prior-chosen instants known as events (e.g., vertically downward position), and we turn on the controller intermittently based on the regulation errors at the set point. The controller is truly discrete, as these measurements and controls occur at the time scale of the system to be controlled. To enable set-point regulation in the presence of uncertainty, we use the errors to tune the model parameters. We demonstrate the method in the velocity control of an artificial leg, a simple pendulum, with up to 50% mass uncertainty. Starting with a 100% regulation error, we achieve velocity regulation of up to 10% in about five swings with only one measurement per swing.

Published

2021

2. Event-Based, Intermittent, Discrete Adaptive Control for Speed Regulation of Artificial Legs

Author

Ernesto Hernandez-Hinojosa, Pranav A. Bhounsule, and Salvador Echeveste

Subjects

TK1001-1841, Control and Optimization, Adaptive control, event-based control, artificial legs, Computer science, Intermittent control, intermittent control, discrete control, Swing, adaptive control, Exoskeleton, Production of electric energy or power. Powerplants. Central stations, Control and Systems Engineering, Control theory, Position (vector), TA401-492, Trajectory, Robot, Materials of engineering and construction. Mechanics of materials, pendulum swing

Abstract

For artificial legs that are used in legged robots, exoskeletons, and prostheses, it suffices to achieve velocity regulation at a few key instants of swing rather than tight trajectory tracking. Here, we advertise an event-based, intermittent, discrete controller to enable set-point regulation for problems that are traditionally posed as trajectory following. We measure the system state at prior-chosen instants known as events (e.g., vertically downward position), and we turn on the controller intermittently based on the regulation errors at the set point. The controller is truly discrete, as these measurements and controls occur at the time scale of the system to be controlled. To enable set-point regulation in the presence of uncertainty, we use the errors to tune the model parameters. We demonstrate the method in the velocity control of an artificial leg, a simple pendulum, with up to 50% mass uncertainty. Starting with a 100% regulation error, we achieve velocity regulation of up to 10% in about five swings with only one measurement per swing.

Published

2021