Embedded system for front differential drive of rotational and translational vehicle position control

Angie J. Valencia Castañeda; Mauricio F. Mauledoux; Óscar F. Avilés; Paola A. Niño Suarez; Edgar A. Portilla Flores

doi:10.15866/ireaco.v10i4.11802

Embedded system for front differential drive of rotational and translational vehicle position control

Angie J. Valencia Castañeda, Mauricio F. Mauledoux, Óscar F. Avilés, Paola A. Niño Suarez, Edgar A. Portilla Flores

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Resumen

Hardware in the loop is presented as a valid solution both to design and simulate mechanical models using “close loop control” techniques. Through the application of controller algorithms, the mechanical model is defined either as a physical mechanism or as an embedded device, allowing to get a suitable control structure to implement in real life. Hence, the following work will show the design of a PID and a Root Locus Compensator controllers for a differential transmission in a four-wheeled vehicle, using Hardware in the loop (HIL) techniques and an STM development boards. Subsequently, a simulation is carried out to get a comparison between the data produced by HIL and those obtained by computational tests, allowing to acquire the system behaviour at different sample time.

Idioma original	Inglés
Páginas (desde-hasta)	325-331
Número de páginas	7
Publicación	International Review of Automatic Control
Volumen	10
N.º	4
DOI	https://doi.org/10.15866/ireaco.v10i4.11802
Estado	Publicada - 2017
Publicado de forma externa	Sí

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AU - Valencia Castañeda, Angie J.

AU - Mauledoux, Mauricio F.

AU - Avilés, Óscar F.

AU - Niño Suarez, Paola A.

AU - Portilla Flores, Edgar A.

PY - 2017

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N2 - Hardware in the loop is presented as a valid solution both to design and simulate mechanical models using “close loop control” techniques. Through the application of controller algorithms, the mechanical model is defined either as a physical mechanism or as an embedded device, allowing to get a suitable control structure to implement in real life. Hence, the following work will show the design of a PID and a Root Locus Compensator controllers for a differential transmission in a four-wheeled vehicle, using Hardware in the loop (HIL) techniques and an STM development boards. Subsequently, a simulation is carried out to get a comparison between the data produced by HIL and those obtained by computational tests, allowing to acquire the system behaviour at different sample time.

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DO - 10.15866/ireaco.v10i4.11802

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Embedded system for front differential drive of rotational and translational vehicle position control

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