Version 1
: Received: 20 July 2016 / Approved: 21 July 2016 / Online: 21 July 2016 (09:44:16 CEST)
How to cite:
Faouzi, D.; Bibi-Triki, N. Modeling, Simulation and Optimization of agricultural greenhouse microclimate by the application of artificial intelligence and / or fuzzy logic. Preprints2016, 2016070064. https://doi.org/10.20944/preprints201607.0064.v1
Faouzi, D.; Bibi-Triki, N. Modeling, Simulation and Optimization of agricultural greenhouse microclimate by the application of artificial intelligence and / or fuzzy logic. Preprints 2016, 2016070064. https://doi.org/10.20944/preprints201607.0064.v1
Faouzi, D.; Bibi-Triki, N. Modeling, Simulation and Optimization of agricultural greenhouse microclimate by the application of artificial intelligence and / or fuzzy logic. Preprints2016, 2016070064. https://doi.org/10.20944/preprints201607.0064.v1
APA Style
Faouzi, D., & Bibi-Triki, N. (2016). Modeling, Simulation and Optimization of agricultural greenhouse microclimate by the application of artificial intelligence and / or fuzzy logic. Preprints. https://doi.org/10.20944/preprints201607.0064.v1
Chicago/Turabian Style
Faouzi, D. and Nacereddine Bibi-Triki. 2016 "Modeling, Simulation and Optimization of agricultural greenhouse microclimate by the application of artificial intelligence and / or fuzzy logic" Preprints. https://doi.org/10.20944/preprints201607.0064.v1
Abstract
Agricultural greenhouse is largely answered in the agricultural sphere, despite the shortcomings it has, including overheating during the day and night cooling which sometimes results in the thermal inversion mainly due to its low inertia. The glasshouse dressed chapel is relatively more efficient than the conventional tunnel greenhouse. Its proliferation on the ground is more or less timid because of its relatively high cost[14-22]. Agricultural greenhouse aims to create a favorable microclimate to the requirements of growth and development of culture, from the surrounding weather conditions, produce according to the cropping calendars fruits, vegetables and flower species out of season and widely available along the year. It is defined by its structural and functional architecture, the quality thermal, mechanical and optical of its wall, with its sealing level and the technical and technological accompanying[12-13]. The greenhouse is a very confined environment, where multiple components are exchanged between key stakeholders and them factors are light, temperature and relative humidity[8]. This state of thermal evolution is the level sealing of the cover of its physical characteristics to be transparent to solar, absorbent and reflective of infrared radiation emitted by the enclosure where the solar radiation trapping effect otherwise called "greenhouse effect" and its technical and technological means of air that accompany. The socio-economic analysis of populations in the world leaves appear especially the last two decades of rapid and profound transformations These changes are accompanied by changes in eating habits, mainly characterized by rising consumption spread along the year[14]. To effectively meet this demand, greenhouse-systems have evolved, particularly towards greater control of production conditions (climate, irrigation, ventilation techniques, CO2 supply, etc ...). Technological progress has allowed the development of greenhouses so that they become increasingly sophisticated and of an industrial nature (heating, air conditioning, control, computer, regulation, etc ...). New climate driving techniques have emerged, including the use of control devices from the classic to the use of artificial intelligence[10-11] such as neural networks and / or fuzzy logic, etc... As a result, the greenhouse growers prefer these new technologies while optimizing the investment in the field to effectively meet the supply and demand of these fresh products cheaply and widely available throughout the year.
Keywords
Greenhouse , microclimate , Modelling , fuzzy controller , Optimization , Solar Energy , Energy saving , Climate Model ,Greenhouse effect , Temperature
Subject
Computer Science and Mathematics, Artificial Intelligence and Machine Learning
Copyright:
This is an open access article distributed under the Creative Commons Attribution License which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
The commenter has declared there is no conflict of interests.
Hope you are doing well.
I have couple of questions that I wish if you can make it clearer for me.
1) For the cooling pad model , the humidity equation was written as:
H,pad = H,out +n,pad (H.wb -H ,out) , so my question is what is H,wb and how do you calculate it ?
2)In the mass transfer GH, the equation for the humidity balance was written as :
dH,in / dt = - n * V,p (H,in - H,sat)
what do you mean by n , V,p and H, sat (how do you calculate it ?)