A survey on modeling and simulation practices for teaching power harmonics

On the basis of STEM, STEAM, and STREAMS, this paper presents a holistic multidisciplinary improved method for power engineering education of Generation Z students. The proposed STREAMS strategy is based on using the latest developments of technology for a mixed on-the-move and in-house university educational approach. A case study on STREAMS is used within power engineering education. To validate STREAMS, a pilot application and a survey are used. While 66% of the students in power engineering chose to attend on-the-move visits to complete classical teaching, the participation in field visits showed an improvement of the grades by about 20%, the increase of the number of students with comparative cognitive level, and a significant decrease of the fail percentage from 84.2% to 15.8%. The results show that the use of STREAMS in power engineering education allows a better understanding of both theoretical and practical issues, improves the overall attitude on studying the field, and develops critical thinking, thus leveraging the entering into the workforce. The authors consider that on-the-move STREAMS also proves to be a valuable improved teaching method, even under coronavirus disease 2019 pandemic restrictions.

Section: Introductionmentioning

confidence: 99%

Rethinking power engineering education for Generation Z

Opriş

Nistoran

Costinaş

et al. 2020

Modeling and simulation practices in engineering education

Magana

Jong

2018

Much can be learned from the vast work on the use of computer simulations for inquiry learning for the integration of modeling and simulation practices in engineering education. This special issue presents six manuscripts that take steps toward evidence‐based teaching and learning practices. These six studies present learning designs that align learning objectives, with evidence of the learning, and pedagogy. Here we highlight the main contributions from each paper individually, but also themes identified across all of them. These themes include (a) approaches for modeling‐and‐simulation‐centric course design; (b) teaching practices and pedagogies for modeling and simulation implementation; and (c) evidence of learning with and about modeling and simulation practices. We conclude our introduction by highlighting desirable characteristics of studies that report on the effectiveness of modeling and simulation in engineering education, and with that we provide some recommendations for improving the scholarship of teaching and learning in this field.

A Jupyter Notebook for teaching mathematical modeling with experiments

González‐Sierra,

Trujillo‐Franco,

Abundis‐Fong

2024

Mathematical modeling and numerical simulation have a considerable presence in the vast universe of engineering disciplines, given their usefulness in explaining, comprehending, and simulating phenomena and processes with which engineers are in contact in their daily creative and problem‐solving work. For this reason, engineering study programs have at least one course dedicated to dealing with the mathematical modeling of dynamic systems as an essential complement to subsequent courses such as automatic control, structural dynamics, and mechanical vibrations. Nowadays, many technological tools illustrate the applications of mathematical modeling interactively through experiments that offer an incomparable motivation to the students to corroborate with real‐world examples, the utility and veracity of the theory presented to them in the classroom and that in many occasions seems lacking utility and direct relation with the world in which they develop. Based on those mentioned above, this paper presents an example of applying the Laplace transform in modeling physical systems, using a second‐order circuit attached to an Arduino Due board in conjunction with the Jupyter Notebook environment. The numerical and experimental results can be obtained through three optional kernels: Python, Octave, or MATLAB®. For educational purposes, the resulting computer application was presented to undergraduate students of Mechatronics Engineering as an illustrative complement to two courses entitled Signals and Systems Analysis, part of the second semester, and Mathematical Modeling, part of the fifth semester.