Promoting Greenness with IoT-Based Plant Growth System

2018 ◽  
pp. 235-253 ◽  
Author(s):  
S. M. Kamruzzaman ◽  
M. I. Pavel ◽  
M. A. Hoque ◽  
S. R. Sabuj
Keyword(s):  
Plant Growth ◽  
Growth System

Research on the Intelligent Plant Growth System Temperature Acquisition Based on the Data Fusion

2013 ◽  
Vol 846-847 ◽  
pp. 906-909
Author(s):  
Gao Li Chen ◽  
Li Guo Tian ◽  
Meng Li ◽  
Zhi Qi Liu
Keyword(s):  
Plant Growth ◽  
Data Fusion ◽  
Sensor Data ◽  
Fusion Method ◽  
Relevant Research ◽  
Multi Sensor Data Fusion ◽  
Temperature Detection ◽  
Growth System ◽  
System Temperature ◽  
Sensor Measurement

The growth of plants needs certain temperature conditions, carried out relevant research for intelligent plant growth systems of temperature acquisition. For plant growth cabinet temperature is by the influence of many factors, and multi-sensor measurement error caused by temperature detecting, using the distribution display method of temperature detection divorced value removing method and the Bayesian estimation of multi-sensor data fusion method. The experiment results show that the algorithm is reasonable and reliable, improving the accuracy of the temperature acquisition, and effectively eliminate the error caused by the failure sensor.

scholarly journals Plant Pillow Preparation for the Veggie Plant Growth System on the International Space Station

2020 ◽  
Vol 5 (1) ◽  
pp. 24-34 ◽  
Author(s):  
Gioia D. Massa ◽  
Gerard Newsham ◽  
Mary E. Hummerick ◽  
Robert C. Morrow ◽  
Raymond M. Wheeler
Keyword(s):  
Plant Growth ◽  
International Space Station ◽  
Space Station ◽  
Preparation Methods ◽  
International Space ◽  
Surface Sterilization ◽  
Growth System ◽  
Validation Tests ◽  
Growth Methods ◽  
Controlled Released

AbstractThe first Veggie plant growth chamber was installed on the International Space Station in 2014. Crop plants can be grown in Veggie using plant pillows, small rooting packets that contain substrate, fertilizer, and germination wicks along with attached seeds. The pillows were designed to interface with the Veggie root mat reservoir watering system to provide a capillary water column to growing plants. In preparation for flight, methods of arcillite substrate washing, autoclaving, and drying were established to reduce dust and to provide a dry sterile substrate. A controlled released fertilizer mixed into arcillite substrate provides nutrition for plant growth. Methods of seed surface sterilization were tested for both germination and microbial contamination, and the optimum methods were determined for candidate flight crops. Plant pillows were prepared for flight by cutting and inserting germination wicks, filling with the substrate/fertilizer mix, and sewing closed. Following pillow filling, seeds were attached to the wicks, and the pillows were packaged for flight. Pillow preparation methods have been successfully tested in the VEG-01 hardware validation tests on the International Space Station with ‘Outredgeous’ lettuce and ‘Profusion’ zinnia, and in the VEG-03 test, using ‘Outredgeous’ lettuce and ‘Tokyo bekana’ Chinese cabbage.

scholarly journals Development of a Man–Plant Interface for Greenhouse Environmental Computers Using Generic Databases and Virtual Plants

HortScience ◽  
1996 ◽  
Vol 31 (4) ◽  
pp. 607e-607
Author(s):  
Niels Ehler ◽  
Mark A. Rose ◽  
Jesper Mazanti Hansen
Keyword(s):  
User Interface ◽  
Plant Growth ◽  
Tissue Temperature ◽  
Interactive Software ◽  
Dynamic Interactions ◽  
Physiological Processes ◽  
Growth System ◽  
Climate Controls ◽  
Dynamic Relationships ◽  
And Control

Currently, greenhouse environmental computers are programmed to monitor and control the macroclimate instead of directly controlling plant growth and development, which are features of more interest to growers. Our objective was to develop a generic system to represent and control the dynamic plant processes that regulate plant growth in the greenhouse. Before plant growth can be directly controlled, the dynamic interactions between the microclimate around plants and plant physiological processes must be further understood. Future computerized control systems must be able to display an intuitive, interactive software program that helps the user understand and make use of the dynamic relationships between climate controls, climate processes, and plant processes. A conceptual framework was designed for a user interface with a biological orientation. This software consists of five different elements: the information provider, the information monitor, the information browser, the growth system controller, and the system visualizer. A demonstrator application illustrating this concept was developed and connected in real time to a standard greenhouse environmental computer. Crop tissue temperature is calculated and used instead of conventional irradiance limits to control shading screens to optimize the amount of radiation absorbed by the crop. The application is based on a set of generic automatically created paradox databases. A graphical user interface on the screen displays virtual plants that are used for visualizing, understanding, and controlling the different processes governing the crop tissue temperature.

scholarly journals Litterbox—A gnotobiotic Zeolite-Clay System to Investigate Arabidopsis–Microbe Interactions

2020 ◽  
Vol 8 (4) ◽  
pp. 464
Author(s):  
Moritz Miebach ◽  
Rudolf O. Schlechter ◽  
John Clemens ◽  
Paula E. Jameson ◽  
Mitja N.P. Remus-Emsermann
Keyword(s):  
Plant Growth ◽  
Bacterial Load ◽  
Transcriptional Responses ◽  
Controlled System ◽  
Growth System ◽  
Microbe Interactions ◽  
Clay System ◽  
Underlying Mechanisms ◽  
Positive Effect ◽  
Systemic Responses

Plants are colonised by millions of microorganisms representing thousands of species with varying effects on plant growth and health. The microbial communities found on plants are compositionally consistent and their overall positive effect on the plant is well known. However, the effects of individual microbiota members on plant hosts and vice versa, as well as the underlying mechanisms, remain largely unknown. Here, we describe “Litterbox”, a highly controlled system to investigate plant–microbe interactions. Plants were grown gnotobiotically, otherwise sterile, on zeolite-clay, a soil replacement that retains enough moisture to avoid subsequent watering. Litterbox-grown plants resemble greenhouse-grown plants more closely than agar-grown plants and exhibit lower leaf epiphyte densities (106 cfu/g), reflecting natural conditions. A polydimethylsiloxane (PDMS) sheet was used to cover the zeolite, significantly lowering the bacterial load in the zeolite and rhizosphere. This reduced the likelihood of potential systemic responses in leaves induced by microbial rhizosphere colonisation. We present results of example experiments studying the transcriptional responses of leaves to defined microbiota members and the spatial distribution of bacteria on leaves. We anticipate that this versatile and affordable plant growth system will promote microbiota research and help in elucidating plant-microbe interactions and their underlying mechanisms.

Tree Physiology Optimization in Benchmark Function and Traveling Salesman Problem

2017 ◽  
Vol 28 (5) ◽  
pp. 849-871 ◽  
Author(s):  
A. Hanif Halim ◽  
I. Ismail
Keyword(s):  
Plant Growth ◽  
Traveling Salesman Problem ◽  
Nearest Neighbor ◽  
Optimization Problems ◽  
Traveling Salesman ◽  
Optimization Approach ◽  
Metaheuristic Algorithm ◽  
Tree Physiology ◽  
Growth System ◽  
The Traveling Salesman Problem

Abstract Nature has the ability of sustainability and improvisation for better survival. This unique characteristic reflects a pattern of optimization that inspires the computational intelligence toward different scopes of optimization: a nondeterministic optimization approach or a nature-inspired metaheuristic algorithm. To date, there are many metaheuristic algorithms introduced with good promising results and also becoming a powerful method for solving numerous optimization problems. In this paper, a new metaheuristic algorithm inspired from a plant growth system is proposed, which is defined as tree physiology optimization (TPO). A plant growth consists of two main counterparts: plant shoots and roots. Shoots extend to find better sunlight for the photosynthesis process that converts light and water supplied from the roots into energy for plant growth; at the same time, roots elongate in the opposite way in search for water and nutrients for shoot survival. The collaboration from both systems ensures plant sustainability. This idea is transformed into an optimization algorithm: shoots with defined branches find the potential solution with the help of roots variable. The shoots-branches extension enhances the search diversity and the root system amplifying the search via evaluated fitness. To demonstrate its effectiveness, two different classes of problem are evaluated: (1) a continuous benchmark test function compared to particle swarm optimization (PSO) and genetic algorithm (GA) and (2) an NP-hard problem with the traveling salesman problem (TSP) compared to GA and nearest-neighbor (NN) algorithm. The simulation results show that TPO outperforms PSO and GA in all problem characteristics (flat surface and steep-drop with a combination of many local minima and plateau). In the TSP, TPO has a comparable result to GA.

scholarly journals Design and Development of Intelligent Plant Growth System that Enables Growth Under Extreme Environmental Conditions

2016 ◽  
Vol 44 (11) ◽  
pp. 735
Author(s):  
Fumiteru AKAMATSU ◽  
Jun HAYASHI ◽  
Hiroyuki TAKEISHI ◽  
Atsushi OKAZAWA ◽  
Yoshiaki KIMURA ◽  
...  
Keyword(s):  
Plant Growth ◽  
Environmental Conditions ◽  
Design And Development ◽  
Growth System

scholarly journals 951 PB 446 RESPONSE OF TOMATOES GROWN IN AN AEROPONIC GROWTH CHAMBER

HortScience ◽  
1994 ◽  
Vol 29 (5) ◽  
pp. 570b-570
Author(s):  
Michael D. Berg ◽  
Preston K. Andrews
Keyword(s):  
High Pressure ◽  
Plant Growth ◽  
Light Period ◽  
Leaf Primordia ◽  
Growth Chamber ◽  
Growing Period ◽  
Sodium Lamp ◽  
Growth System ◽  
High Pressure Sodium Lamp ◽  
Plastochron Index

An aeroponic growth chamber is a system for growing plants in air with water and nutrients supplied by intermittent mist. This type of plant growth system is especially useful for experiments where root accessibility is desired. Tomatoes (Lycopersicon esculentum L. `Bonnie Best') were used to test the performance of an aeroponic growth chamber. A nutrient solution mist was applied through spray nozzles suspended below roots of supported seedlings. Mist application was regulated by electric timers, so that mist was applied for 50 sec. every 5 min. during the 16-hr light period, which was supplemented with a high-pressure sodium lamp. Root and stem lengths, leaf number and leaf lengths were measured weekly. Plastochron index (PI) was used to measure rate of leaf initiation. PI increased linearly, indicating uniform initiation of leaf primordia and absence of environmental stresses. Stem and root lengths increased consistently throughout the growing period. Each plant was harvested, separated into leaves, shoots and roots, oven dried, and dry weights measured.

Developing a Physical-Chemical Model for a Plant Growth System

1969 ◽  
Vol 12 (5) ◽  
pp. 0698-0702 ◽  
Author(s):  
L. H. Chen ◽  
B. K. Huang ◽  
and W. E. Splinter
Keyword(s):  
Plant Growth ◽  
Chemical Model ◽  
Physical Chemical ◽  
Growth System
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