More Like this

1. Utilization of Real-life Hands-on Pedagogy to Motivate Undergraduate Students in Grasping Transportation Related Concepts

   Olude, A. (June 2023, American Society for Engineering Education, 2023. https://peer.asee.org/44591)

   Real-life hands-on pedagogy adequately grounded in workable social learning theory is a precursor to motivating students to grasp transportation-related concepts. At a historically black university, an evidence-based, experiment-focused, hands-on method of instruction was adopted in the transportation discipline from the fall of 2020 until now. This paper outlines the development and implementation of hands-on pedagogy in the transportation systems discipline from fall 2020 to fall 2022. The Motivated Strategies for Learning Questionnaire (MSLQ) developed by Pintrich, Smith, García, and McKeachie in 1991 was used to measure key constructs associated with students' success, such as motivation, epistemic and perceptual curiosity, and self-efficacy. Signature assignments were developed to measure student success outcomes from adopting the pedagogy. The results of the MSLQ administered to 44 students impacted by the pedagogy reveal a significant increase in the students' key constructs associated with success. The pedagogy reveals better knowledge gain and classroom engagement than the traditional teaching approach. 

   more » « less
2. Performance-Based Learning: An Innovative Approach to Teaching Engineering Thermodynamics in a Hybrid Learning Environment

   Akinpelu, O. (June 2023, American Society for Engineering Education, 2023. https://strategy.asee.org/43883)

   A cost-effective, secure, and portable electronic instrumentation equipment is used in Experiment Centric Pedagogy (ECP), formerly known as Mobile Hands-On Studio Technology and Pedagogy, as a teaching method for STEM subjects both inside and outside of the classroom. Since the Spring of 2020, ECP has been integrated into two Industrial Engineering (IE) courses: Thermodynamics and Materials Engineering. This has been done in various ways, including through student use at home and in-class demonstrations and teaching labs. During the most recent academic session (Fall 2021–Spring 2022), the effects of practical home-based experimentation and lab activities on students' attitudes, interests, and performance were examined for the Engineering Thermodynamics course. The outcomes of a survey known as the Motivated Strategies for Learning Questionnaires (MLSQ), which was given to 51 students, demonstrated better improvements in the student's motivation, epistemic, and perceptual curiosity, three crucial characteristics linked to their success. Along with the MLSQ, the Classroom Observation Protocol for Undergraduate Students (COPUS) assesses active learning in Industrial Engineering courses, and quantitative and qualitative data on the significant components of student achievement were gathered. Results obtained show that using ECP has improved students' awareness of material properties and increased their interest in learning about the thermodynamics concept of heat transfer in connection to various solid materials. 

   more » « less
3. Hands-on Learning Pedagogy in Teaching Concepts Relevant in the Analysis, Design, and Maintenance of Transportation Infrastructure Systems

   https://doi.org/10.1177/03611981241242067  

   Owolabi, Oludare; Abedoh, Hannah; Abiodun, Pelumi; Ikiriko, Sotonye; Wemida, Ayodeji; Duru, Chukwuemeka; Nwachukwu, Nkiruka Jane; Bello, Mojeed; Emiola-Owolabi, Olushola; Efe, Steve; et al (May 2024, Transportation Research Record: Journal of the Transportation Research Board)

   Learning critical concepts that are centered on the analysis, design, and maintenance of transportation infrastructure systems poses a measure of difficulty for undergraduates in engineering. Therefore, hands-on learning pedagogy should be an excellent precursor to increase understanding of these concepts, since the pedagogy incorporates real-life experience in the delivery. This paper describes how a hands-on learning pedagogy called experiment-centric pedagogy (ECP) has been used to teach these concepts to undergraduate students at a historically Black university. The research questions are as follows: (1) How well can ECP improve students’ understanding of concepts essential to the analysis and design of transportation infrastructure systems? (2) How has the ECP facilitated the achievement of the learning objectives of these concepts? and (3) Does an ECP increase the engagement of undergraduate students in their transportation infrastructure engineering learning and lead to measurable lasting gains? To answer these research questions, ECP was implemented and assessed when used to teach the concepts of stress and strain utilized in the analysis of bridges and other transportation infrastructure, sound used in the development and design of noise barriers, moisture content in controlling compaction of highway infrastructure systems, and degradation of infrastructure systems exposed to various environmental settings. Assessment results from 92 undergraduates reveal an increase in students’ motivation and cognitive understanding of the relevant concepts, as well as learning gains and an improved success rate compared to the traditional method of teaching. 

   more » « less
4. Preliminary Experience and Impact of Experiment-focused Teaching Approach in a Computer Architecture Course in Computer Science

   Adeniran, O. (June 2023, American Society for Engineering Education, 2023. https://sftp.asee.org/43945)

   One of the key knowledge areas in Computer Science (CS) is Digital Logic and Computer Architecture where the learning outcome is an understanding of Boolean algebra, logic gates, registers, or arithmetic logic units, etc. and explaining how software and hardware are related to a computing system. Experimental Centric based Instructional Pedagogy (ECP) with portable laboratory instrumentation might provide real hands-on experience to obtain a practical understanding of those concepts at a lower cost compared with virtual hands-on laboratories that lack direct interaction with real apparatus or no integration of labs in the course. This work presents the initial adaptation of ECP to introduce the fundamentals of digital logic concepts in a Computer Architecture course in Spring 2022 for the first time in a CS department at a university teaching such courses without a lab and serving predominantly minority students. To establish a conducive and dynamic classroom environment by discovering course content through exploration, students majoring in CS were introduced to several logic gate types, worked with breadboards to connect circuits, and carried out operations to produce the necessary output using the commercial ADALM 1K Active Learning Module. To evaluate the impact of the ECP on students; performance in the class, three different evaluation methods were used, such as classroom observation, a signature assignment, and a Motivated Strategies for Learning Questionnaire (MSLQ) survey. The Classroom Observation Protocol for Undergraduate STEM (COPUS) findings indicated greater student engagement when ECP is used; the Signature assignment results indicated improved learning outcomes for students; and the MLSQ survey, which measures students; motivation, critical thinking, curiosity, collaboration, and metacognition, determined a positive impact of the ECP on the CS participants. 

   more » « less
5. Development and Implementation of Experiment Centric Active Learning Experiments/Activities in Transportation During the Pandemic and Beyond

   Owolabi, O.; Chavis, C.; Nwachukwu, N.; James-Okeke, P.; Ahangari, S.; Shourabi, N.; Freeman, M.; Bello, M.; Bista, K.; Gaulee, U.; et al (January 2022, Transportation Research Board 2022 Annual Meeting)

   The COVID-19 pandemic forced many colleges and universities to remain on a completely online or remote educational learning for more than a year; however, due to distraction, lack of motivation or engagement, and other internal/external pandemic contributing factors, learners could not pay attention 100% to the learning process. Additionally, given that transportation classes are very hands-on, students could not do the experiment from home due to limited resources available, thereby hampering all three phases of learner interactions. The limitation of the implementation of physical, hands-on laboratory exercises during the pandemic further exacerbated students’ actualization of the critical Accreditation Board for Engineering and Technology (ABET) outcomes in transportation: An ability to develop and conduct experiments or test hypotheses, analyze and interpret data and use scientific judgment to draw conclusions. Subsequently, this paper highlights the development and implementation of experiment centric pedagogy (ECP) home-based active learning experiments in three transportation courses: Introduction to Transportation Systems, Traffic Engineering, and Highway Engineering during the pandemic. Quantitative and qualitative student success key constructs data was collected in conjunction with the execution of classroom observation protocols that measure active learning in these transportation courses. The results reveal a significant difference between the pre, and post- tests of key constructs associated with student success, such as motivation, critical thinking, curiosity, collaboration, and metacognition. The results of the Classroom Observation Protocol for Undergraduate STEM (COPUS) show more active student engagement when ECP is implemented. 

   more » « less