Portland, Oregon
June 23, 2024
June 23, 2024
June 26, 2024
ELOS Technical Session 5 - Remote, Virtual, and Digital Realities
Experimentation and Laboratory-Oriented Studies Division (DELOS)
11
10.18260/1-2--47384
https://peer.asee.org/47384
104
David Hicks is an Associate Professor in the Electrical Engineering and Computer Science Department at Texas A&M University-Kingsville. Before joining TAMU-K he served as Associate Professor and Department Head at Aalborg University in Esbjerg, Denmark. He has also held positions in research labs in the U.S. as well as Europe, and spent time as a researcher in the software industry.
Dr. Lifford McLauchlan is an Associate Professor in the Electrical Engineering and Computer Science Department at Texas A&M University - Kingsville, and has also worked for Raytheon, Microvision, AT&T Bell Labs, and as an ONR Distinguished Summer Faculty at SPAWAR San Diego, CA. He has over 55 publications covering areas such as adaptive and intelligent controls, robotics, an ocean wave energy converter, green technology, education, wireless sensor networks and image processing. He is a co-inventor on 3 US patents related to control systems. Dr. McLauchlan is a member of ASEE and was the 2012-2014 Chair of the Ocean and Marine Engineering Division. He is also a member of IEEE (senior member), SPIE, Eta Kappa Nu, ACES and Tau Beta Pi, and has served on the IEEE Corpus Christi Section Board in various capacities such as Chair, Vice Chair, Secretary and Membership Development Officer. Dr. McLauchlan has received the Dean’s Distinguished Service Award twice and the Dean’s Outstanding Teaching Award once for the College of Engineering at Texas A&M University-Kingsville.
Dr. Mehrubeoglu received her B.S. degree in Electrical Engineering from The University of Texas at Austin. She earned an M.S. degree in Bioengineering and Ph.D. degree in Electrical Engineering from Texas A&M University. She is currently an associate prof
Hemanth Kumar Reddy is pursuing master’s in computer science as well as working on campus as a Graduate Research Assistant in the Electrical Engineering and Computer Science Department at Texas A&M University-Kingsville. Before that he did his Bachelor's in Electronics and Communication Engineering at KL University-Andhra Pradesh, India. He is actively working on developing IOT applications and doing research on U3810A IOT Educational Kit.
Internet of Things (IoT) based systems have proven to be effective solutions in a wide variety of application areas. The availability of low-cost versions of the hardware elements that form the basis of these systems, including processor boards, sensors, and communication devices, combined with expanding software support, such as cloud based IoT resources, ensure the popularity of IoT approaches will continue to expand further. Consequently, the inclusion of IoT concepts and technologies is becoming an increasingly important part of many engineering degree programs (e.g., computer engineering, electrical engineering, computer science, and mechanical engineering). An ongoing project at Texas A&M University-Kingsville has focused on expanding the coverage of IoT concepts and technology that is included in engineering degree programs. A particular emphasis of the project has been on the support of remote engaged student learning. To ensure students are given not only theoretical coverage of IoT concepts, but also receive practical, hands-on experience, a toolkit approach has been utilized. Remotely learning students, who do not have easy access to a classroom laboratory setting, are provided with an IoT toolkit they can utilize throughout the semester so they will be able to perform IoT exercises and assignments in order to fully engage with the material being covered. The initial IoT toolkit utilized for the project was a very basic one that included a single board computer, sensors, actuators, LEDs, a breadboard, and jumper wires. More recently a more advanced toolkit has been assembled based on a commercially available IoT learning platform. A series of exercises have been developed to accommodate the learning toolkits and facilitate remotely learning students. As reported previously, a set of five introductory level exercises were originally developed and provided for students utilizing the basic IoT toolkit to assist them in becoming familiar with its components and basic IoT concepts. The introductory exercises were later adapted into a form that is appropriate for the advanced IoT toolkit. This paper reports on an additional set of exercises that have been developed more recently to teach more advanced IoT concepts to students utilizing the expanded features and capabilities of the advanced IoT toolkit. While the examples and solutions developed for the first two sets of basic exercises were written in the C language, the support materials created for the more advanced exercises utilize the Python language in order to accommodate a wider variety of student backgrounds.
Hicks, D., & McLauchlan, L., & Mehrubeoglu, M., & Bhimavarapu, H. K. R. (2024, June), Expanding Support for Engaged Remote Student Learning of Internet of Things Concepts and Technology Paper presented at 2024 ASEE Annual Conference & Exposition, Portland, Oregon. 10.18260/1-2--47384
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