JEB logo

Journal of Environmental Biology

pISSN: 0254-8704 ; eISSN: 2394-0379 ; CODEN: JEBIDP
About Journal
    Home
    Obituary: Dr. R. C. Dalela
    Editorial Board
    Reviewer Panel
    Publication Policies
    Guidelines for Editors
    Guidelines for Reviewers
    Abstracting and Indexing
    Subscription and Payments
    Contact Journal
    About Triveni Enterprises
 
Read Journal
    Current Issue
    Journal Archives
 
For Authors
    Guidelines for Authors
    Terms and Conditions
    Author Resources
    Fees and Payments
    Track Paper Status
 

Google Search the Journal web-site:


    Abstract - Issue Jul 2024, 45 (4)                                     Back


nstantaneous and historical temperature effects on a-pinene

Sensor, IoT-based post-harvest shelf life determination of tomato (Lycopersicon esculentum) through machine learning predictive analysis for intelligent transport

 

J. Shankaraswamy1* and T.S.L. Radhika2     

1Department of Fruit Science, College of Horticulture, Mojerla, Sri Konda Laxman,Wanaparthy-509 382, India

2Department of Mathematics, BITS Pilani, Hyderabad Campus, Hyderabad-500 078, India

Received: 15 April 2024                   Revised: 22 May 2024                   Accepted: 04 June 2024

*Corresponding Author Email : shankara.swamy@gmail.com                      *ORCiD: https://orcid.org/0000-0002-5623-6384

 

 

 

Abstract

 

Aim: The current research explores the potential of machine learning predictive models in optimizing the storage conditions of tomatoes. This is achieved through Internet of Things (IoT) technology, sensors, cameras, and microprocessors integrated into refrigerators along the supply chain.

Methodology: Controlling temperature and humidity inside the refrigerated container was accomplished by implementing the Arduino microcontroller and supplementary hardware components, including the ESP32 module relay, an advancement over the ESP8266 microcontroller. The Arduino Integrated Development Environment (IDE) was used as software platform for this experimentation. Various parameters, including humidity, oxygen, carbon-di-oxide, and shelf life, were recorded at different temperatures and on different days. Subsequently, the collected data was analyzed employing machine-learning models to determine the most effective prediction model for these variables.

Results: From the results it has been revealed that apolynomial of degree 4 is the best-fit regressor model for the data on humidity. Polynomials of degrees 2, 2, and 3 are the best models for the target variables oxygen, carbon-di-oxide, and shelf life.

Interpretation: During analysis, This result suggests that different polynomial degrees are optimal for modeling different variables in the dataset. Polynomials of degrees 2, 2, and 3 are the best ML models for the target variables oxygen, carbon-di-oxide, and shelf life, respectively,to enhance the effectiveness of our predictive models.

Key words: Io T sensors, ML models, Quantile loss, Supply chain, Tomato

 

 

 

Copyright © 2024 Triveni Enterprises. All rights reserved. No part of the Journal can be reproduced in any form without prior permission. Responsibility regarding the authenticity of the data, and the acceptability of the conclusions enforced or derived, rest completely with the author(s).