Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer

Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer

The production of food crops in controlled environment agriculture (CEA) can help mitigate food insecurity that may result from increasingly frequent and severe weather events in agricultural areas. Lighting is an absolute requirement for crop growth in CEA, and is undergoing rapid advances with the...

Full description

Bibliographic Details
Main Authors: Matthew R. Urschel, Tessa Pocock
Format: Article
Language:English
Published: MDPI AG 2018-10-01
Series:Agronomy
Subjects:
chlorophyll fluorescence
controlled environment agriculture
crop growth
crop modeling
relative growth rates
remote sensing
light emitting diodes
Online Access:http://www.mdpi.com/2073-4395/8/10/227
id doaj-5dcab43547ac42ac9ea74dd23ad56458
record_format Article
spelling doaj-5dcab43547ac42ac9ea74dd23ad564582021-04-02T04:17:12ZengMDPI AGAgronomy2073-43952018-10-0181022710.3390/agronomy8100227agronomy8100227Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a FluorometerMatthew R. Urschel0Tessa Pocock1Center for Lighting Enabled Systems and Applications (LESA), Rensselaer Polytechnic Institute (RPI), Troy, NY 12180, USACenter for Lighting Enabled Systems and Applications (LESA), Rensselaer Polytechnic Institute (RPI), Troy, NY 12180, USAThe production of food crops in controlled environment agriculture (CEA) can help mitigate food insecurity that may result from increasingly frequent and severe weather events in agricultural areas. Lighting is an absolute requirement for crop growth in CEA, and is undergoing rapid advances with the advent of tunable, light emitting diode (LED) systems. The integration of these systems into existing CEA environmental control architectures is in its infancy and would benefit from a non-invasive, rapid, real-time, remote sensor that could track crop growth under different lighting regimes. A newly-developed remote chlorophyll a fluorescence (ChlF) sensing device is described herein that provides direct, remote, real-time physiological data collection for integration into tunable LED lighting control systems, thereby enabling better control of crop growth and energy efficiency. Data collected by this device can be used to accurately model growth of red lettuce plants. In addition to monitoring growth, this system can predict relative growth rates (RGR), net assimilation rates (NAR), plant area (PA), and leaf area ratio (LAR).http://www.mdpi.com/2073-4395/8/10/227chlorophyll fluorescencecontrolled environment agriculturecrop growthcrop modelingrelative growth ratesremote sensinglight emitting diodes
collection DOAJ
language English
format Article
sources DOAJ
author Matthew R. Urschel
Tessa Pocock
spellingShingle Matthew R. Urschel
Tessa Pocock
Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer
Agronomy
chlorophyll fluorescence
controlled environment agriculture
crop growth
crop modeling
relative growth rates
remote sensing
light emitting diodes
author_facet Matthew R. Urschel
Tessa Pocock
author_sort Matthew R. Urschel
title Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer
title_short Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer
title_full Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer
title_fullStr Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer
title_full_unstemmed Remote Detection of Growth Dynamics in Red Lettuce Using a Novel Chlorophyll a Fluorometer
title_sort remote detection of growth dynamics in red lettuce using a novel chlorophyll a fluorometer
publisher MDPI AG
series Agronomy
issn 2073-4395
publishDate 2018-10-01
description The production of food crops in controlled environment agriculture (CEA) can help mitigate food insecurity that may result from increasingly frequent and severe weather events in agricultural areas. Lighting is an absolute requirement for crop growth in CEA, and is undergoing rapid advances with the advent of tunable, light emitting diode (LED) systems. The integration of these systems into existing CEA environmental control architectures is in its infancy and would benefit from a non-invasive, rapid, real-time, remote sensor that could track crop growth under different lighting regimes. A newly-developed remote chlorophyll a fluorescence (ChlF) sensing device is described herein that provides direct, remote, real-time physiological data collection for integration into tunable LED lighting control systems, thereby enabling better control of crop growth and energy efficiency. Data collected by this device can be used to accurately model growth of red lettuce plants. In addition to monitoring growth, this system can predict relative growth rates (RGR), net assimilation rates (NAR), plant area (PA), and leaf area ratio (LAR).
topic chlorophyll fluorescence
controlled environment agriculture
crop growth
crop modeling
relative growth rates
remote sensing
light emitting diodes
url http://www.mdpi.com/2073-4395/8/10/227
work_keys_str_mv AT matthewrurschel remotedetectionofgrowthdynamicsinredlettuceusinganovelchlorophyllafluorometer
AT tessapocock remotedetectionofgrowthdynamicsinredlettuceusinganovelchlorophyllafluorometer
_version_ 1724173364723974144

Similar Items