ABSTRACT
All first-year students at the J. B. Speed School of Engineering (SSoE) at the University of Louisville (UofL) are required to complete a two-course sequence. The purpose of the two-course sequence is to introduce incoming students to the fundamentals and profession of engineering. The first course in the sequence is titled Engineering Methods, Tools, & Practice I (ENGR 110) and primarily focuses on introduction to and practice with fundamental engineering skills. The second course Engineering Methods, Tools, & Practice II (ENGR 111) is a makerspace-based course primarily focused on application and integration of the fundamentals learned in ENGR 110. ENGR 111 includes a variety of fundamental skills in its instruction, one of which is programming. Therefore, all disciplines of SSoE engineering students are exposed to the basics and applications of programming through this course sequence. Programming instruction in ENGR 111 is designed to include relevant software development skills that students might encounter in the engineering profession. The students have learned initial programming skills in their ENGR 110 course through the Python programming language. In ENGR 111, students practice programming skills learned in ENGR 110 on two different platforms: Arduino Microcontrollers (Arduino) and Programmable Logic Controllers (PLCs). In normal face-to-face semesters, students are put into teams of 3 to 4 and given modules to develop and practice these skills (two for Arduino, two for PLCs). Due to the COVID-19 pandemic, ENGR 111 was augmented into a synchronous remote course to avoid close proximity and shared tools in the makerspace. Arduino programming instruction was performed using Tinkercad (tinkercad.com), a website that allows for Arduino programming and circuitry simulations. PLC instruction was performed utilizing a free online PLC simulator website, “PLCfiddle” [1]. At the end of each semester, students take a survey on their perceptions of the course. Included in this survey are questions pertaining to programming instruction. These questions assess student confidence in programming and platform preference. Results of these questions from Spring 2019 (a makerspace iteration) and Spring 2021 (a remote iteration) are compared in this paper. © American Society for Engineering Education, 2022.
ABSTRACT
This paper is focused on a course redesign transitioning from a hardware-based course into a course taught remotely. The J. B. Speed School of Engineering (SSoE) at the University of Louisville (UofL) has a two-course sequence that all first-year SSoE students are required to complete. This two-course sequence is designed to introduce incoming students to the profession and fundamentals of engineering. The first course is titled Engineering Methods, Tools, & Practice I (ENGR 110), and primarily focuses on introduction to and practice with fundamental engineering skills. The second course, Engineering Methods, Tools, & Practice II (ENGR 111) is typically a makerspace-based course primarily focused on application and integration of the fundamentals learned in ENGR 110. Included amongst numerous skills institutionally identified as “fundamental” were programming and basic circuitry. Therefore, all disciplines of SSoE engineering students are exposed to the basics of circuitry and programming through ENGR 111 pedagogy. Due to the COVID-19 pandemic, this makerspace course is to be taught remotely in the spring semester of 2021. The instructional team felt that there were too many shared tools and teams were too close together to safely continue the course in a makerspace environment. This remote teaching has posed the instructional team some unique challenges due to the hands-on nature of the ENGR 111 course. Students are typically in face-to-face teams of 3 or 4 students and each group is given an Arduino, breadboard, and circuit components. The given assignments start out with basic circuity and Arduino programming, followed by utilizing an Arduino to communicate with created circuits. The assignments are designed to help the first-year students gain comfort in circuitry and programming. The instructional team has decided to use Tinkercad, which is a free online collection of software tools provided by Autodesk. Many people are only aware of Tinkercad as a 3D modeling programming, however in 2017 Autodesk merged its “123D Circuits” into Tinkercad [1] [2]. This makes Tinkercad an ideal platform to use for circuitry and Arduino programming. The paper will further describe the design of the assignments, instructional team expectations from the students, the environment in which the students are using Tinkercad, as well as looking at expected course outcomes using the platform. This topic is a work in progress as data for evidence-based analyses will not be fully procured until after publication. © American Society for Engineering Education, 2021