Remote Humidity and Temperature Real-Time Monitoring System for the Study of the After-Ripening Process in Seeds

Thiruparan Balachandran; Saleh M. Sbenaty; Jeffrey Walck

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Conference: 2013 ASEE Annual Conference & Exposition
Location: Atlanta, Georgia
Publication Date: June 23, 2013
Start Date: June 23, 2013
End Date: June 26, 2013
ISSN: 2153-5965
Conference Session: Instrumentation Technical Session
Tagged Division: Instrumentation
Page Count: 11
Page Numbers: 23.1035.1 - 23.1035.11
DOI: 10.18260/1-2--22420
Permanent URL: https://peer.asee.org/22420
Download Count: 603

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Thiruparan Balachandran Middle Tennessee State University

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Thiruparn is graduate student at Middle Tennessee State University and pressuring MS degree in Engineering Technology concentration .He has his BS degree in Engineering Physics. He is interested in Embedded system .he has published several conference papers. He can be researched by email at: bt2t@mtmail.mtsu.edu

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Saleh M. Sbenaty Middle Tennessee State University

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Saleh M. Sbenaty is currently a professor of engineering technology at Middle Tennessee State University. He received the B.S. degree in E.E. from Damascus University and the M.S. and Ph.D. degrees in E.E. from Tennessee Technological University. He is actively engaged in curriculum development for technological education. He has authored and co-authored several industry-based case studies. He is also conducting research in the area of mass spectrometry, power electronics, lasers, instrumentation, digital forensics, and microcontroller applications.

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Jeffrey Walck Middle Tennessee State University

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Jeffrey Walck is a Professor of Biology at Middle Tennessee State University. His research interests focus on the ecology of seed germination and on the conservation biology of the cedar glade ecosystem. He has been an Invited Visiting Scientist to Australia, Japan, South Korea, Taiwan, and China.

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Abstract

REMOTE HUMIDITY AND TEMPERATURE REAL-TIME MONITORING SYSTEM FOR THE STUDY OF THE AFTER-RIPENING PROCESS IN SEEDSThe current paper discusses the design, prototyping, and testing of a remote monitoring systemthat is used to study seed germination under various controlled conditions. The research willhelp biologists in determining the optimal conditions for after-ripening in seeds, which arenecessary for successful seed storage and germination. Seed biology is an important branch ofplant science. Many seed germination experiments are carried out under controlledenvironmental conditions and seed scientists have experienced difficulties to maintain andmonitor relative humidity inside closed containers. The common practice is the use of super-saturated solutions of different chemicals to provide relative humidity measurements. However,these super-saturated solutions are not accurate and require continuous (manual) checking by theresearcher. The current paper will discuss the development of a remote monitoring system thatcan be used to accurately monitor and measure the relative humidity and temperature of theclosed containers used for after-ripening. What makes this task especially challenging is that theclosed containers are housed in an incubator that maintains a desired temperature. The incubatoris not permeable to Wi-Fi signals required for the proper communication with the monitoringsystem.The system under discussion allows the monitoring the relative humidity and temperature of five(can be expandable to more than five) different closed containers remotely and in real time. Thesystem functions as a server that is connected to Internet using Wi-Fi technology. When a clientrequests for data, the system will read the sensor values and pass them wirelessly to the client(s).A client can see these data on a web browser and will be able to study and plot the data. A timeand date stamp is provided with each measurement. Application-specific software is created toimplement data logging and facilitate data transfer into Microsoft Excel for further analysis.The system uses multiple sensors, a microcontroller, and a Wi-Fi module. SHT 75 fromSensirion is used to sense the relative humidity and temperature. This sensor is factory calibrated.Its RH response time is 8 sec, power consumption is 80 μW, and has an operating range from -40to +125 °C and from 0 to 100% RH for temperature and relative humidity, respectively. Theprocessor used is an Ardunio microcontroller that has an AVR 8-bit 2 microcontroller on it. Thisdevice is connected to Internet using Microchip MRF24WB0MA Wi-Fi module using IEEE Std.802.11b/g/n wireless networks protocol. Figure 1 illustrates the basic block diagram of thesystem. The full paper will provide complete details of the system and results. The research isbeing performed through collaborative efforts between the Engineering Technology and BiologyDepartments at _______ . SHT 75 1 SHT 75 2 Wi-Fi Microcontroller Shield Board MUX SHT 75 3 SHT 75 5 Figure 1 Block diagram of the system

Citation
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Balachandran, T., & Sbenaty, S. M., & Walck, J. (2013, June), Remote Humidity and Temperature Real-Time Monitoring System for the Study of the After-Ripening Process in Seeds Paper presented at 2013 ASEE Annual Conference & Exposition, Atlanta, Georgia. 10.18260/1-2--22420

TY - CPAPER
AB - REMOTE HUMIDITY AND TEMPERATURE REAL-TIME MONITORING SYSTEM FOR THE STUDY OF THE AFTER-RIPENING PROCESS IN SEEDSThe current paper discusses the design, prototyping, and testing of a remote monitoring systemthat is used to study seed germination under various controlled conditions. The research willhelp biologists in determining the optimal conditions for after-ripening in seeds, which arenecessary for successful seed storage and germination. Seed biology is an important branch ofplant science. Many seed germination experiments are carried out under controlledenvironmental conditions and seed scientists have experienced difficulties to maintain andmonitor relative humidity inside closed containers. The common practice is the use of super-saturated solutions of different chemicals to provide relative humidity measurements. However,these super-saturated solutions are not accurate and require continuous (manual) checking by theresearcher. The current paper will discuss the development of a remote monitoring system thatcan be used to accurately monitor and measure the relative humidity and temperature of theclosed containers used for after-ripening. What makes this task especially challenging is that theclosed containers are housed in an incubator that maintains a desired temperature. The incubatoris not permeable to Wi-Fi signals required for the proper communication with the monitoringsystem.The system under discussion allows the monitoring the relative humidity and temperature of five(can be expandable to more than five) different closed containers remotely and in real time. Thesystem functions as a server that is connected to Internet using Wi-Fi technology. When a clientrequests for data, the system will read the sensor values and pass them wirelessly to the client(s).A client can see these data on a web browser and will be able to study and plot the data. A timeand date stamp is provided with each measurement. Application-specific software is created toimplement data logging and facilitate data transfer into Microsoft Excel for further analysis.The system uses multiple sensors, a microcontroller, and a Wi-Fi module. SHT 75 fromSensirion is used to sense the relative humidity and temperature. This sensor is factory calibrated.Its RH response time is 8 sec, power consumption is 80 μW, and has an operating range from -40to +125 °C and from 0 to 100% RH for temperature and relative humidity, respectively. Theprocessor used is an Ardunio microcontroller that has an AVR 8-bit 2 microcontroller on it. Thisdevice is connected to Internet using Microchip MRF24WB0MA Wi-Fi module using IEEE Std.802.11b/g/n wireless networks protocol. Figure 1 illustrates the basic block diagram of thesystem. The full paper will provide complete details of the system and results. The research isbeing performed through collaborative efforts between the Engineering Technology and BiologyDepartments at _______ . SHT 75 1 SHT 75 2 Wi-Fi Microcontroller Shield Board MUX SHT 75 3 SHT 75 5 Figure 1 Block diagram of the system
AU - Thiruparan Balachandran
AU - Saleh M. Sbenaty
AU - Jeffrey Walck
CY - Atlanta, Georgia
DA - 2013/06/23
PB - ASEE Conferences
TI - Remote Humidity and Temperature Real-Time Monitoring System for the Study of the After-Ripening Process in Seeds
UR - https://peer.asee.org/22420
DO - 10.18260/1-2--22420
ER -