Abstract
Purpose
Few resources exist to incorporate principles of modular approach to course design. This research aimed to help instructors by presenting principles for practical and empirically informed modular course design in engineering education.
Design/methodology/approach
In the first phase, a systematic literature review was completed to identify categories addressing a modular course design. Search and screening procedures resulted in 33 qualifying articles describing the development of a modular course. In the second phase, 6 expert interviews were conducted to elaborate on the identified categories.
Findings
Guided by the interview results and the ADDIE (Analyze, Design, Develop, Implement, and Evaluate) course design model, the categories were compiled into six design principles. To present the design principles in relation to the guiding principles of modular approach, an overarching conceptual model was developed.
Originality/value
Here, we present our innovation; a foundation for an evidence-based systematic approach to modular course design. Implications have value for supporting flexibility and autonomy in learning.
Keywords
Citation
Mesutoglu, C., Stollman, S. and Lopez Arteaga, I. (2024), "Principles and practices of modular course design in higher engineering education", International Journal of Information and Learning Technology, Vol. 41 No. 2, pp. 153-165. https://doi.org/10.1108/IJILT-05-2023-0061
Publisher
:Emerald Publishing Limited
Copyright © 2024, Canan Mesutoglu, Saskia Stollman and Ines Lopez Arteaga
License
Published by Emerald Publishing Limited. This article is published under the Creative Commons Attribution (CC BY 4.0) licence. Anyone may reproduce, distribute, translate and create derivative works of this article (for both commercial and non-commercial purposes), subject to full attribution to the original publication and authors. The full terms of this licence may be seen at http://creativecommons.org/licences/by/4.0/legalcode
Introduction
Higher education has been going through profound changes given the increased emphasis on information and communication technologies. The changing nature of the workforce suggests engaging students in learning environments that support flexibility of time and place for learning (Hernandez-de-Menendez and Morales-Menendez, 2019; Sarker et al., 2019). In line with these demands, recent vision statements for 21st century engineering education embrace interactive and online learning, responsiveness to different learning styles and teacher role as a facilitator (National Academy of Engineering, 2012). The adjustments in higher engineering education are evident in the growing applications of open-learning such as massive open online courses, flipped learning and modular instruction (Bradshaw et al., 2013; Sivapalan et al., 2016).
Modular instruction suggests a priority for frequent feedback, self-paced learning and individual interests and learning needs (Dejene, 2019; French, 2015; Goldschmid and Goldschmid, 1973).
Although higher engineering education literature include diverse examples of modular courses, methods of course design are inconclusive and not easily applicable for teachers (Cordray et al., 2008; Jahnke, 2023). There is thus a need for design principles systematically tailored to modular courses. Effective modular instruction partly lies in the support given to teachers (Botma et al., 2015; Sadiq and Zamir, 2014). The goal of this study was to assist instructors with evidence-based instructional design principles for modular courses in higher engineering education.
Conceptual framework
Modular approach in education
Modular approaches in higher education date back to the initiation of an elective course system in the late 1800s at Harvard University (Dochy et al., 1989). Since then, modules have been regarded as components of education and training programmes mostly in reference to credit-based curricula; dividing the curriculum into smaller components (French, 2015). In other words, modularization has been primarily associated with concepts such as semesterization, completion of degree programs, credit transfer and student mobility where courses themselves are treated as modules (e.g. Erasmus programs) (Dochy et al., 1989; French, 2015; Pollard et al., 2017).
From a different yet a complementary perspective, there have been efforts toward construction of a single course with modules in engineering education. Acknowledging the lack of an agreed-upon type of modular approach (Goldschmid and Goldschmid, 1973; Li and Pilz, 2017), this study adopted the conceptualization of modular courses by Boahin and Hofman (2014): “packaging of course content, either theory or practical, into shorter, logically self-contained units”. Key features of online course modules include self-pacing, availability at all times and places, flexibility and frequent practice and feedback (Dochy et al., 1989; Li and Pilz, 2017). Such attributes are rooted in multiple educational approaches such as programmed-instruction, learner-centered pedagogies, computer-assisted instruction and humanistic learning (Botma et al., 2015; Dewey, 1986; Malik, 2012).
Developing modular courses
Modules present a structure for the organization of course concepts and practices (Martínez, 2019). In a modular course, students can move through independent and self-contained modules at their own pace (Goldschmid and Goldschmid, 1973; Li and Pilz, 2017). Benefits of student autonomy in selection and completion of course modules include increased academic achievement, motivation and skills development (e.g. Boahin and Hofman, 2014; Cohen et al., 2019; Malik, 2012; Martínez, 2019).
The momentum toward modular courses brings forth teacher preparedness as a critical element. There is an identified need to support teachers in development and implementation of modules (Boahin and Hofman, 2014; Malik, 2012; Membrillo-Hernández et al., 2021; Schulz and Dahale, 1999). Addressing this need, Félix-Herrán et al. (2019) implemented a professional training program to support engineering instructors’ preparedness for module design and reported: “This new approach involves changes in the roles of educators … a transition from lecturing to facilitating. The professor must design learning modules that satisfy the proposed challenge and encourage students to discover in new scenarios”. It has also been proposed that module development should be carried out in the context of conceptual frameworks (Donnelly and Fitzmaurice, 2005). Although there are frameworks that can inspire modular course design in other domains such as health care (Botma et al., 2015), no course design model to help engineering instructors at a practical level could be located. Construction of design principles has significance for the long-term adoption of modular approach in engineering education.
Purpose of the study
Purposeful use of digital technologies can bring about self-paced learning experiences (Hernandez-de-Menendez and Morales-Menendez, 2019). Lack of design principles for modular courses led many studies of engineering education to identify and use components without a systematic consideration of the literature (e.g. Jahnke, 2023). When a well-defined scope is not present, teachers might design and deliver courses that fall short on supporting learning. In view of these constrains and the scholarly consensus regarding the necessity to support teachers, this study aimed to synthesize empirically grounded design principles for modular courses.
Method
This study adopted a convergent consensus-seeking process (Botma et al., 2015) made up of two phases to create design principles for modular courses in higher engineering education. Phase 1 included a systematic literature review to get a good overview of important principles in the instructional design of modular courses. In Phase 2, based on Phase 1 findings and expert views, the design principles were constructed.
Phase 1: systematic literature review
Systematic literature reviews are helpful in creating categorizations for an existing body of research (Collins and Fauser, 2005).
Data collection
Searches were conducted in Ebsco, Web of Science, Scopus and Proquest with the keywords: “engineering education,” “module(s),” “modular education,” “modular instruction,” “modular” and “course”. All searches were restricted to articles written in English, published in peer-reviewed journals between 2000 and 2021. Studies conducted before 2000 focused mostly on reforms such as credit transfer systems and semesterization depending on their definition of the concept to treat modules as courses. The researchers collaboratively used an Excel file as an analytical to detail each search attempt memo (Vanassche and Kelchtermans, 2015). The removal of duplicates led to 437 articles. To eliminate articles that did not fall into the scope of this review, two exclusion criteria were used. Accordingly.
40 studies that did not report a higher engineering education course and
235 studies that either reported modules as software or device (e.g. protein module, solar module) or discussed modular approach only in their conclusion were excluded.
Applying the exclusion criteria through screening the titles and the abstracts significantly decreased the number of articles to 162. Skimming full texts, 57 articles were selected for the review, that all accounted for three inclusion criteria:
explained modularization of a course,
detailed the structure and content of an online module e.g. learning outcomes, activities, assessment and/or pedagogical criteria and
detailed how modules were created.
Using purposive sampling (Fraenkel et al., 2012), 16 potentially relevant articles published in the journals: “Journal of Engineering Education” and “International Journal of Engineering Education,” and using snowballing (Mourão et al., 2020), another set of 7 articles were manually included in accordance with the inclusion and exclusion criteria.
After carefully reading all 73 full texts, again 40 articles were excluded. These articles were not entirely in line with the inclusion criterion, since they focused on creating a module to be used in multiple courses, rather than modularizing an existing course.
Data analysis
Analysis of the articles can be described as content analysis; study of written content to obtain detailed information in response to educational problems (Fraenkel et al., 2012). The first author read each of the 33 articles full text several times as she noted emerging categories and codes. Later in the process, the second author read a random sample of 10 articles, which she coded independently. Both authors discussed over the codes until agreement was reached, then a codebook was iteratively constructed. For each code, frequencies were calculated to find out the relative importance of certain concepts in modularization literature in higher engineering education (Fraenkel et al., 2012). Table 1 illustrates the codebook with frequencies, together with the corresponding articles’ references with the first author. Researchers’ online collaboration on Rayyan.ai and construction of an analytical memo contributed to the trustworthiness of the findings.
Phase 2: design principles
Phase 2 consisted of expert interviews to test usefulness and completeness of Phase 1 results. Expert interviews showed the importance of concepts that were not directly taken from the literature and they therefore were added to the design principles.
Data collection
The 6 experts were instructors and teacher supporters at our institution all experienced in modular instruction. Signed informed consent forms were collected from all experts. During the individual interviews conducted online by the first author, field notes were made. The experts were presented with Phase 1 results as they appear in Table 1 and were asked to provide recommendations considering the use of the design principles by course designers and teachers.
Data analysis
The first steps were reading the field notes right after the interviews, and several more times later to gain familiarity with the data. The field notes were then grouped under the relevant design principle. Next, the notes were checked for similarities and later transformed into a summary. This summary showed recommendations raised by at least three experts (Willis, 2015, p. 163).
Together with the codebook, the results provided the basis for construction of the design principles. The next step for Phase 2 was selecting the generic instructional design model, ADDIE, to structure and organize the results into logical design principles. ADDIE uses 5 steps to instructional design (Campbell and Schwier, 2014; Gagné et al., 2005):
analysis: analyze course content and learning outcomes in relation to modules,
design: explore how modules will help achieve the learning outcomes,
development: create content and materials for modules,
implementation: explore implementation in a course utilizing module-specific strategies and
evaluation: determine impacts of the newly designed modular course.
Guided by the ADDIE model and expert interviews, the codebook that emerged in Phase 1 was translated into a set of six design principles shown in Figure 1. During the systematic literature review, researchers’ online collaboration and construction of an analytical memo contributed to the trustworthiness of the findings. The researchers constantly debated and discussed during this process until agreement was reached. The design principles were shared with an audience of instructors and teacher supporters for member checking.
The final step for Phase 2 was to present the conceptual background of our design principles. Figure 2 shows the overarching model that was developed for this purpose.
Results
Phase 1: systematic literature review
Course coverage
Selected course content. 8 articles designed online modules according to selected course topics or course learning outcomes (LOs).
All course contents. In the majority, 24 of the articles, all content, all topics or LOs, of the regular course was covered by the modules.
Module components
Resources for theory. In 21 articles, modules included web links, articles, videos, presentations, lecture slides, book chapters, presentations, or audio-based slides drawing on course theory and topics.
Application. Exercises in the form of games, problem-solving, creating reports and other interactive activities appeared in the modules of 31 articles. The exercises aimed to help students transfer and apply theory. Anderson et al. (2005) explained that the module exercises: “interrupt passive learning, which occurs as students read static text or listen to lectures.”
A noticeable characteristic of all exercises was their real-world focus. Use of animations and simulations was another frequent attribute. In 2 articles, design problems framed the modules (Chatterjee et al., 2010; Williams et al., 2012). Course instructors’ timely feedback and corrective feedback through automated systems were also mentioned (n = 5).
Module goals. 17 articles defined separate module LOs or goals. Padmaperuma et al. (2006), for example, first identified the content of the modules and then, the course goals were transformed into module goals. Using tables, Martínez (2019) illustrated a systematic alignment of course competencies to subcompetencies developed for each module. Careful formulation of module goals is reported to facilitate student awareness on module components and assessment (n = 5).
Module category
Mandatory and sequenced. A majority of the articles reported that all students were expected to use the modules in a standard route communicated to them.
Elective modules. Six articles developed elective modules. Streif and Naples (2003), for example, presented the students with one mandatory module and for the rest, the students could decide which of the elective modules to use. In a later study Steif and Dollár (2009) students were expected to choose 1 or 2 modules per week, aligned with the weekly assignments, making up at least 9 out of 16 course modules. The articles persistently showed that students’ use of elective modules led to improved academic performance. Bernacki et al. (2020) and Syed et al. (2019) also put forth that, completion of a greater number of elective modules resulted in higher academic performance.
Self-pacing within module. A group of 21 articles reported on students’ control over the pace of their progression within the modules, choosing among the module components to interact with (e.g. Altuger-Genc et al., 2018; Henson et al., 2002) or freedom to skip parts (e.g. Pierre et al., 2009). As explained by Khader et al. (2017): “The material can be rearranged in different sequences for different learners to match with the learning abilities and preferences …” As indicated by Moradi et al. (2018), having control over one’s own progression within modules resulted in student empowerment. Hailey and Hailey (2019) also evidenced that learning outcomes associated with self-pacing in modules were greater.
Key strategies in module implementation
Although only a few articles specifically mentioned strategies that contributed to student engagement with modules, results could be revealed. Key strategies in module implementation emerged out of specific comments made in the articles, as well as how frequently they occurred, allowing us to use these in our design principles.
Consistent form. A consistent form for modules seems to be important, e.g. module number, title, module aims, prerequisites, outcomes and units for each module.
Alignment to in-class time. If there was face-to-face classroom time alongside the modules, this time was dedicated to lectures, teaching activities and feedback. Most (weekly) in-class time, intended to cover the theoretical course content. As indicated by Altuger-Genc et al. (2018), modules: “support the in-class learning as well as to provide students a hands-on and visual animation they can employ to understand the theory better.” All articles reported that the students were expected to use the modules before or after the face-to-face sessions.
Alignment to overarching project. In total, five articles described an overarching design project in their courses. The modules served as supportive tools to complete the project. As described by Baughman et al. (4): “students apply learning module content tools in completing design project work”.
Level of difficulty. Another strategy described in four articles was increasing the level of difficulty, complexity of application exercises and decreasing the amount of teacher guidance as the students progressed within a module or through different modules.
Other key strategies were: using a personalized intro to welcome students (n = 2), assigning extra course credit for module completion (n = 2) and marking module components to release module assessment (n = 1).
Evaluation
To investigate student learning, graded module tasks (n = 17) were in the form of traditional tests/quizzes, interactive exercises, or demonstration of solutions to problems. The courses with an overarching project required a module deliverable with the completion of separate modules, in addition to the final project outputs (e.g. Diefes-Dux et al., 2004).
The articles also reported on collecting data on module use and effectiveness in the form of questionnaires or interviews, 17 studies from students, 9 studies from teachers and 3 articles from stakeholders or experts included in the design and implementation of the course (Habib et al., 2019; Streif and Naples, 2003; Yalvac et al., 2007). Reflections focused on self-paced learning experiences, motivation and perceptions of learning.
Summary
Essential characteristics of modular approach are highlighted in the articles: time and location flexibility, self-paced learning and self-contained modules with multiple components. The results showed that modules can be designed with separate goals, theory, real-world focused practice activities and assessment tasks. Although only a few articles reported on elective modules, results concerning motivation and the learning gains are encouraging.
Phase 2: design principles
The summary of expert interviews evidenced two recommendations: (1) construction of a teacher guide to assist teachers in their design decisions and (2) examination of Phase 1 articles to locate further indications of feedback and online interaction. In the teacher guide, selected articles exemplify, for example, alignment of course LOs to modules, alignment of overarching projects to modules, examples of programming assignments, animations and simulations, courses with elective modules.
Considering further indications of feedback, Moradi et al. (2018) is revealed to use a diagnostic test to: “provide a pre-study opportunity for the student so he/she would have a better idea about the content”. Khader et al. (2017) and Heragu et al. (2003) gave module access to external experts, engineers and stakeholders with the goal of providing written feedback and sharing information. To continue, online interaction was offered in modules through synchronous and asynchronous communication; announcements, discussions forums. Henson et al. (2002), for example, explained: “questions about class material on the bulletin board where other students, instructor, graduate students and corporate sponsors can asynchronously respond”. Video-embedded questions (Moradi et al., 2018) was another indicator.
Summary
Phase 2 produced the design principles (see Figure 1) and the overarching conceptual model (see Figure 2). The conceptual model is built on a modular approach to course design, engineering education literature and the module definition used in this research. The model is structured on two axes. Because each teacher and classroom will necessitate different design decisions, the axes stress the idea of allowing for different modular course designs. As progressing through the course design principles, the axes will also trigger the teacher to constantly reflect on learner autonomy and whether the modules can stand on their own as self-contained modules.
Discussion
In line with practicality, our design principles are simple and inclusive (Yang et al., 2021) and we accompany them with a teacher guide to support the teachers in the design and implementation of the modules (Rota and Izquierdo, 2003).
We are aware the design principles are not necessarily directly applicable to each situation. In the adoption of the design principles, concerning elective modules and programming assignments for example, institutional context needs to be considered. Teachers may face certain limitations like specific equipment and resources (e.g. learning management system, access to programming tools), time constraints and large student numbers (Fan et al., 2021). The design principles should thus be considered as they are meant and that is part of a “constructive and iterative process” as each adoption of new approaches is (Tondeur et al., 2012, p. 141). To facilitate this process, institutional support can be presented in the form of a team directly working with the instructors to be withdrawn gradually (Adamson and Sloan, 2021). The instructors should be encouraged to constantly reflect on their design decisions as they iterate between our principles while at the same time using the teacher guide.
As demonstrated by the horizontal axes of our conceptual model, the design principles support a spectrum ranging from a standard route with “mandatory and sequenced modules” to a high learner autonomy level marked by “all elective modules”. The latter can be considered “a radical concept of modularization” with the complete flexibility to follow modules in a mix and match format (Li and Pilz, 2017). As this might not be feasible or necessary for some, our advice would be to start with a few elective modules and let students use modules of their own choice. The rest of the modules agreed upon as foundational by the instructors and an analysis of the students and the resources, can be presented as mandatory. This structure can facilitate students” emerging experiences in adhering to their interest and learning needs by using modules of their choice (Cohen et al., 2019).
Conclusion
To our knowledge, this study is the first attempt to construct empirically grounded design principles for modular courses for engineering education. Next steps include testing the design principles across different course contexts and making modifications based on data gathered from teachers implementing the principles and from students working with the modules. The design principles can benefit from technology-supported instructional design frameworks (e.g. Adamson and Sloan, 2021) and theories such as transactional distance (Stein et al., 2005). In the long run, the validated design principles and the teacher guide are expected to help engineering faculties implement modular courses.
Figures
Codebook for phase 1
| Categories | Codes and frequencies |
|---|---|
| 1. Course coverage | Modules for selected course topics or learning outcomes, 8 |
| Modules for all course content, 24 | |
| 2. Module components | Resources for theory, 21 |
| Application exercises, 31 | |
| Module goals, 17 | |
| 3. Module category | Mandatory and sequenced, 19 |
| Elective, 6 | |
| Self-pacing within module, 21 | |
| 4. Key strategies in module implementation | Consistent module form, 20 |
| Alignment to in-class time, 14 | |
| Alignment to overarching project, 5 | |
| Variety in complexity and guidance, 4 | |
| 5. Evaluation | Graded module tasks, 17 |
| Student reflections, 17 | |
| Teacher reflections, 9 |
Source(s): Created by authors
Please find enclosed our research article, authored by Dr Canan Mesutoglu, Dr Saskia Stollman and Prof. Dr Ines Lopez Arteaga. We confirm that this research article has not been published elsewhere and is not under consideration by another journal.
The authors have approved the manuscript and agreed with its submission to International Journal of Information and Learning Technology. The publication of this research can help the results reach teachers and researchers, with the recognition that the journal encourages research and practice efforts to improve engineering education.
Ethical statement: The authors confirm that this research article has not been published elsewhere and is not under consideration by another journal.
Data availability: Raw data were generated at Eindhoven University of Technology and kept in a folder provided by the same institution. Data can be shared upon request from the corresponding author; CM. Approval from the university ethics committee was obtained prior to data collection. All participants individually filled in informed consent forms.
Declaration of interest statement: The authors declare that they have no competing interests. The authors are willing to address any additional comments on the manuscript. The authors have worked collaboratively at all stages of the research and manuscript preparation.
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Further reading
* Baughman, J., Hassall, L. and Xu, X. (2019), “Comparison of student team dynamics between non-flipped and flipped versions of a large‐enrolment sophomore design engineering course”, Journal of Engineering Education, Vol. 108 No. 1, pp. 103-118, doi: 10.1002/jee.20251.
* Bhandari, A., Ong, S.K. and Steward, B.B. (2011), “Student learning in a multidisciplinary sustainable engineering course”, Journal of Professional Issues in Engineering Education and Practice, Vol. 137 No. 2, pp. 86-93, doi: 10.1061/(asce)ei.1943-5541.0000055.
* Chang, J.P. (2002), “A new undergraduate semiconductor manufacturing option in the chemical engineering curriculum”, International Journal of Engineering Education, Vol. 18, pp. 369-378.
* Cummings, M.L. (2006), “Conducting online course dialogue on the ethics of weapons design”, IEEE Technology and Society Magazine, Vol. 25 No. 1, pp. 31-37, doi: 10.1109/mtas.2006.1607722.
* Deliktas, B. (2011), “Computer technology for enhancing teaching and learning modules of engineering mechanics”, Computer Applications in Engineering Education, Vol. 19 No. 3, pp. 421-432, doi: 10.1002/cae.20321.
* Downey, G.L., Lucena, J.C., Moskal, B.M., Parkhurst, R., Bigley, T., Hays, C., Jesiek, B.K., Kelly, L., Miller, J., Ruff, S., Lehr, J.L. and Nichols‐Belo, A. (2006), “The globally competent engineer: working effectively with people who define problems differently”, Journal of Engineering Education, Vol. 95 No. 2, pp. 107-122, doi: 10.1002/j.2168-9830.2006.tb00883.x.
* Geller, J., Carpenter, S.K., Lamm, M.H., Rahman, S., Armstrong, P.I. and Coffman, C.R. (2017), “Pre-questions do not enhance the benefits of retrieval in a STEM classroom”, Cognitive Research: Principles and Implications, Vol. 2, pp. 1-13, doi: 10.1186/s41235-017-0078-z.
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Acknowledgements
This work was supported by the Innovation Fund of Eindhoven University of Technology, Netherlands.