interdisciplinary education

Reverse Engineering Pedagogy To Bridge Diverse Learning Background In Classrooms

cdtlsd Poster , , , ,

Da Yang TAN* and Yoke Leng LOO 

NUS College

*dytan@nus.edu.sg

Tan, D. Y., & Loo, Y. L. (2024). Reverse engineering pedagogy to bridge diverse learning backgrounds in classrooms [Poster presentation]. In Higher Education Conference in Singapore (HECS) 2024, 3 December, National University of Singapore. https://blog.nus.edu.sg/hecs/hecs2024-dytan-ylloo/

SUB-THEME

Others 

KEYWORDS

Reverse engineering, interdisciplinary education, honours education, programming 

CATEGORY

Poster Presentation

BACKGROUND

With the push for interdisciplinary education within the higher education settings, many of such programmes are designed to help students gain a wider perspective and develop a diverse skill set essential for addressing the complex challenges of the modern world (World Economic Forum, 2023). This means that students from wide-ranging backgrounds now learn together within the same classroom settings. While the exchange of perspectives from students’ different backgrounds add tremendous value to the classroom learning experience, the varying learning abilities and starting points of students bring new challenges to the instructors, especially in subjects that seek to impart technical knowledge, such as quantitative reasoning. The same learning experience now must seek to accommodate a spectrum of students: students with prior knowledge and who are likely to find the learning objective trivial; while students who have little background will struggle to play catchup when faced with new technical knowledge that they need to pick up within the short duration of the course.  

 

To mitigate the challenge of diverse learning backgrounds, reverse engineering pedagogy (REP) (Tan, Cheah, & Lee, 2021) as a teaching method has been piloted in an earlier run of the authors’ sections of GEA1000N: Quantitative Reasoning with Data (Tan & Loo, 2024). Within the course, one of the learning objectives is for students to be familiar with R programming to handle large datasets (see Figure 1 for a sample of such activity). Students with limited prior programming knowledge may struggle to reconcile the theory with the programming tasks, while those with programming experience may find the tasks underwhelming. Below, we highlight some of the considerations in designing such activities: 

Figure 1. Sample of reverse engineering learning activity implemented in the class.

DESIGN AND USER CONSIDERATIONS 

Resources

The design of the activities needs to consider the resources allocated to the class, such as contact time within the classroom. For the REP activities, they were all designed to be completed within 30 minutes of the class, so that there will be sufficient time to complete other activities within the class.

Curriculum Structure

The activities need to situate itself well within the curriculum of the course, so that both instructors and students will not find the activity out of place during the learning process. This requires a careful consideration of the suitable timing to contact the learning activities. For the REP activities, they were introduced at the midpoint of the course in Week 5 and 7, since a theoretical minimum such as basic syntax, data structure, logical operators and loops would still be needed to be introduced earlier in the course to help students successfully navigate the RE activities; on the other hand, introducing the activities at midpoint will allow students to expose themselves R programming and subsequently use them in the later part of the course, especially in other in-class activities and projects. The RE activities also situates itself within the original activities that the teaching team have designed 

Instructors

The role of the instructor should not be overlooked as a key user of the activities, especially in the team-teaching context of the course. Given that the designer of the learning activities and the instructors delivering the materials may not be the same person, the learning activities should be intuitive and clear for the instructors for the buy-in.  

Students

Students are the primary stakeholders of the learning activities and their appreciation towards the learning activities would therefore be important. To reconcile the challenges of varying learning background, the RE activities are deliberately conducted in small groups during the class, so that the less experienced students could learn from experienced students, while the experienced students could gain new perspectives from the questions or gaps in understanding from the less experienced students. 

CONCLUDING REMARKS 

In this work, the use of reverse engineering in the teaching of R programming is introduced. Earlier preliminary results have hinted at the potential of REP learning activities as potential strategy for classes with varying learning background. By highlighting the possible design considerations in the development of materials, it is hoped the approach would be useful for generalisation of such reverse engineering approaches to other courses of similar students’ background in technical subjects. 

REFERENCES

Tan, D. Y., & Loo, Y. L. (2024). Reverse Engineering Pedagogy To Promote Confidence and Motivation in Programming Among Honors College Students. 2024 IEEE Global Engineering Education Conference (EDUCON) (pp. 1 – 3). Kos Island, Greece: IEEE. 

Tan, D. Y., Cheah, C. W., & Lee, C. H. (2021). Reverse Engineering Pedagogy as an Educational Tool to Promote Symbiosis between Design and Physics. IEEE International Conference on Engineering, Technology and Education (IEEE TALE). Wuhan, China. doi:10.1109/TALE52509.2021.9678692 

World Economic Forum. (2023). The Future of Jobs Report 2023. Geneva: World Economic Forum.

Engaging Communities in Sustainability

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Eunice S. Q. NG 

Ridge View Residential College (RVRC)

E.Ng@nus.edu.sg 

Ng, E. S. Q. (2024). Engaging communities in sustainability [Paper presentation]. In Higher Education Conference in Singapore (HECS) 2024, 3 December, National University of Singapore.  https://blog.nus.edu.sg/hecs/hecs2024-esqng/ ‎

SUB-THEME

Opportunities from Engaging Communities 

KEYWORDS

Interdisciplinary education, sustainability education, environmental stewardship, service learning, experiential learning 

CATEGORY

Paper Presentation

 

EXTENDED ABSTRACT

Sustainability challenges are complex global issues without straightforward solutions, which often invoke feelings of being overwhelmed and powerless within learners (Hickman, 2020; Pickering & Dale, 2024). Scholars and practitioners have recommended for sustainability educators to be aware of learners’ emotional and mental states, and recommended strategies for coping with these ecological emotions (Pihkala, 2020). Such strategies include fostering a sense of personal meaning in sustainability action, providing authentic learning experiences, and engaging in collective pro-environmental action (Olsen et al., 2024). By engaging communities in sustainability, learners can contribute meaningfully to sustainability while witnessing the impact of community participation on sustainability (Restrepo-Mieth et al., 2023). 

 

Offered at Ridge View Residential College (RVRC) in fulfilment of NUS General Education’s Communities and Engagement (CE) pillar, the course RVN2000 “Engaging Communities in Sustainability” explores the role of communities in addressing resource consumption and waste production challenges through field trips and classroom seminars. Field trips were designed to educate about Singapore’s three priority waste streams (Ministry of Sustainability and the Environment, 2020) (see Table 1). As part of an assignment, students were also tasked to interview community members on a sustainability issue to understand their views and motivations towards sustainability.

Table 1 
Course Field Trips

 

These out-of-classroom activities offered students authentic learning experiences, allowing them to go beyond individual pro-environmental action to participate in collective action instead. Being part of a community invoked feelings of empowerment in sustainability, with one student reflecting that “the example of FRC demonstrated how we can initiate changes in our community by ourselves, rather than waiting for others e.g. government to step in”. 

Figure 1. Students rescued 5 tonnes of “ugly food” during a food rescue with FRC.

 

Figure 2. Students sorted through waste collected at NUS University Town’s Resource Sorting Station. 

 

Figure 3. Students observed how e-waste was sorted at ALBA’s E-waste facility in Tuas.

While field trips provided tangible examples of community participation in action, they appeared discrete and disconnected since each community had a different purpose. Hence, a key stage in the course was to actively frame students’ community engagement experiences within a broader framework of community participation. This highlighted the complementarity and contributions of various forms of community participation at the ecosystem level (Sandri, 2021). 

 

Students leveraged Rut et al. (2021)’s Ecologies of Participation framework (see Figure 4) to analyse different community participation approaches’ contributions and limitations vis-à-vis their field trip experiences. In doing so, students found deeper meaning in their out-of-classroom experiences, as evidenced in a student’s reflection that “the most memorable connection I have learnt is the power of the community. Seeing examples from case studies such as Koh Pitak as well as seeing FRC operate first-hand, I have learnt that with high social capital, a strong motivation and goal, we can achieve a lot in terms of pushing for sustainable initiatives”.

Figure 4. Ecologies of community participation in sustainability (Adapted from Rut et al. (2021)

 

By emphasising community participation beyond individual community units, students recognised the significance of having diverse, multiple forms of community participation within the broader ecosystem. Coupled with their personal experiences in engaging with communities in sustainability, students recognised their own role in addressing sustainability challenges and were empowered to be change agents for sustainability. 

 

REFERENCES

Hickman, C. (2020). We need to (find a way to) talk about … Eco-anxiety. Journal of Social Work Practice, 34(4), 411-424. https://doi.org/10.1080/02650533.2020.1844166 

Ministry of Sustainability and the Environment. (2020, 30 July). The Resource Sustainability Act. Retrieved July 12 from https://www.mse.gov.sg/resource-room/category/2020-07-30-resource-sustainability-act/ 

Olsen, E. K., Lawson, D. F., McClain, L. R., & Plummer, J. D. (2024). Heads, hearts, and hands: A systematic review of empirical studies about eco/climate anxiety and environmental education. Environmental Education Research, 1-28.  https://doi.org/10.1080/13504622.2024.2315572 

Pickering, G. J., & Dale, G. (2024). The role of perceived powerlessness and other barriers to climate action. Canadian Geographies, 1-14. https://doi.org/10.1111/cag.12938 

Pihkala, P. (2020). Eco-Anxiety and Environmental Education. Sustainability, 12(23), 10149. https://doi.org/10.3390/su122310149 

Restrepo-Mieth, A., Perry, J., Garnick, J., & Weisberg, M. (2023). Community-based participatory climate action. Global Sustainability, 6, 1-16. https://doi.org/10.1017/sus.2023.12 

Rut, M., Davies, A. R., & Ng, H. (2021). Participating in food waste transitions: exploring surplus food redistribution in Singapore through the ecologies of participation framework. Journal of Environmental Policy & Planning, 23(1), 34-47. https://doi.org/10.1080/1523908x.2020.1792859 

Sandri, O. (2021). Providing a ‘point of entry’: Approaches to framing sustainability in curriculum design in Higher Education. Australian Journal of Environmental Education, 37(1), 56-68. https://doi.org/10.1017/aee.2020.19 

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