Aplicación de internet de las cosas (IoT) para entornos de invernadero optimizados

Chrysanthos   Maraveas; Thomas  Bartzanas

doi:10.54502/msuceva.v2n2a11

Autores/as

Chrysanthos Maraveas Farm Structures Lab, Department of Natural Resources Management and Agricultural Engineering Agricultural University of Athens https://orcid.org/0000-0003-2140-615X
Thomas Bartzanas Laboratorio de Estructuras Agrícolas, Departamento de Recursos Naturales e Ingeniería Agrícola, Universidad Agrícola de Atenas, 11855 Atenas, Grecia. https://orcid.org/0000-0002-5962-9909

DOI:

https://doi.org/10.54502/msuceva.v2n2a11

Palabras clave:

Agricultura, agricultura inteligente, Internet de las Cosas, invernaderos, tecnología

Resumen

Esta revisión presenta la investigación más avanzada sobre sistemas IoT para entornos de invernadero optimizados. Los datos fueron analizados usando métodos descriptivos y estadísticos para inferir relaciones entre Internet de las cosas (IoT), tecnologías emergentes, agricultura de precisión, agricultura 4.0 y mejoras en la agricultura comercial. La discusión se sitúa en el contexto más amplio de IoT en la mitigación de los efectos adversos del cambio climático y el calentamiento global en la agricultura a través de la optimización de parámetros críticos como la temperatura y la humedad, la adquisición inteligente de datos, el control basado en reglas y la resolución de las barreras para la adopción comercial de sistemas IoT en la agricultura. Los recientes eventos meteorológicos severos e inesperados han contribuido a los bajos rendimientos y pérdidas agrícolas; este es un desafío que se puede resolver a través de la agricultura de precisión mediada por tecnología. Los avances tecnológicos han contribuido con el tiempo al desarrollo de sensores para la prevención de heladas, el control remoto de cultivos, la prevención de riesgos de incendio, el control preciso de nutrientes en cultivos de invernadero sin suelo, la autonomía energética mediante el uso de energía solar y la alimentación, el sombreado y la iluminación inteligentes. control para mejorar los rendimientos y reducir los costos operativos. Sin embargo, abundan los desafíos particulares, incluida la adopción limitada de tecnologías inteligentes en la agricultura comercial, el precio y la precisión de los sensores. Las barreras y los desafíos deberían ayudar a guiar futuros proyectos de investigación y desarrollo y aplicaciones comerciales.

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Biografía del autor/a

Chrysanthos Maraveas , Farm Structures Lab, Department of Natural Resources Management and Agricultural Engineering Agricultural University of Athens

El Dr. Maraveas obtuvo su PhD en Ingeniería Civil de la Universidad de Manchester, Reino Unido, en 2015; MSc. en Ingeniería del Imperial College de Londres, Reino Unido, de la Universidad de Swansea, Reino Unido, y de la Universidad Demócrito de Tracia, Grecia. Fue investigador posdoctoral en la Universidad de Lieja y la Universidad de Patras. Cuenta con una experiencia de más de 20 años como consultor de ingeniería estructural y director técnico de infraestructuras. Es miembro de la Institución de Ingenieros Civiles del Reino Unido e ingeniero del colegiado en Grecia y el Reino Unido. Es profesor asistente en el Departamento de Recursos Naturales e Ingeniería Agrícola de la Universidad Agrícola de Atenas.

Thomas Bartzanas, Laboratorio de Estructuras Agrícolas, Departamento de Recursos Naturales e Ingeniería Agrícola, Universidad Agrícola de Atenas, 11855 Atenas, Grecia.

Profesor Asociado y Director del Laboratorio de Estructuras Agrícolas en la Universidad Agrícola de Atenas (AUA) en Grecia e Investigador colaborador en el Instituto de Bioeconomía y Agrotecnología (IBO) del Centro de Investigación y Tecnología-Hellas (CERTH). Su área de investigación se centra en sistemas agrícolas de ambiente controlado (cultivos y ganadería), análisis y modelado de sistemas en agricultura y evaluación de impacto ambiental de sistemas agrícolas utilizando el enfoque del ciclo de vida. Actúa actualmente como presidente en la acción COST de LivAge que se ocupa de las emisiones para edificios de ganado y vicepresidente y representante de organizaciones académicas/de investigación en la plataforma tecnológica Food for Life en Grecia coordinada por la Federación de industrias alimentarias griegas (SEVT).

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