Improving student-industry engagement through project oriented curriculum

Industry expects a creative and innovative academic practice that provides students with valuable practical knowledge focused on graduate ready skills for future careers. The learning environment in engineering is inadequate for students to become a skillful graduate. The practical role of engineering is gained through working on real world problems in an industry collaborative environment through projects. Industry academia collaboration seems to be actively increasing in the development of engineering education in various parts of the globe. The close relationship between industry and academia is a vital component of the engineering pedagogy to improve student engagement in industry through projects. By engaging students with industry, students will acquire global perspective about the core attributes expected in future engineering jobs. In today’s large-scale industrial market, companies tend to prefer graduates with design skills attained through the project approach. Thus, universities should open their doors and accept the challenges of interacting with students with industrial experiences and expectations. This paper is focused on improving student industry engagement through project/design oriented curriculum. Through quantitative and qualitative research, the paper shows the industry perspectives and students views on university and industry collaboration. The research results show that students and industry can possibly maintain their engagement by providing regular feedback, reviewing goals and objectives, improving communication, keeping focused, and sharing a similar vision.

Project-oriented design-based learning in engineering education

The School of Engineering at Deakin University (SOE-DU) is committed to provide authentic and unique learning experiences to students. Over the last five years, SOE-DU has undertaken a study to develop a unique teaching and learning model. The proposed model was based on the Project- Oriented Design Based Learning (PODBL) philosophy which is unique within Australia and in the world. Fundamentally, the framework balances project-driven pedagogy with a design-focused practice in response to industry needs. This paper focuses on the development of PODBL and articulating how it helps nurture creative and industry-ready professional engineers.

Reverse logistics in the construction industry

Reverse logistics in construction refers to the movement of products and materials from salvaged buildings to a new construction site. While there is a plethora of studies looking at various aspects of the reverse logistics chain, there is no systematic review of literature on this important subject as applied to the construction industry. Therefore, the objective of this study is to integrate the fragmented body of knowledge on reverse logistics in construction, with the aim of promoting the concept among industry stakeholders and the wider construction community. Through a qualitative meta-analysis, the study synthesises the findings of previous studies and presents some actions needed by industry stakeholders to promote this concept within the real-life context. First, the trend of research and terminology related with reverse logistics is introduced. Second, it unearths the main advantages and barriers of reverse logistics in construction while providing some suggestions to harness the advantages and mitigate these barriers. Finally, it provides a future research direction based on the review.

Residential schools in a first-year undergraduate engineering programme

BACKGROUND OR CONTEXT: For over 20 years, Deakin University has delivered an accredited undergraduate engineering course by means of distance education. Prior to 2004, off-campus students were not required to attend classes in person on campus. The course was designed so that the off campus students were able to undertake all study and assessment tasks remotely from the university campus. Offering accredited domestic undergraduate engineering courses via distance education has been seen as an important strategy for helping to provide graduate domestically educated engineers to meet Australia’s current and future needs. From 2000 the Australian accreditation management system for professional engineers, as managed by Engineers Australia, has increased its scrutiny of accredited domestic undergraduate engineering courses that were provided in distance-education mode. This led to a series of policies and recommendations for Australian universities that offer accredited engineering courses in distance-education mode: one of the recommendations was that off campus
enrolled engineering students should periodically attend some campus-based activities throughout the course. During the 2004 accreditation review of engineering courses at Deakin University, the
accreditation panel requested that mandatory campus-based activities be incorporated into the accredited undergraduate engineering course. Specifically the request was that Deakin mandate that all off-campus students enrolled in an accredited undergraduate engineering course provided by university attend in person a residential school at least once during every year of equivalent full-time study load. The accreditation panel suggested a program model for the residential school component of the course as developed by the University of Southern Queensland.
PURPOSE OR GOAL: This paper describes the development of the mandatory residential school component of accredited distance education undergraduate engineering courses at Deakin University with
a particular focus on how the residential school program is implemented at level 1 (first-year full-time equivalent level) of the courses.
APPROACH: To be compliant with accreditation requirements, since 2005 Deakin has conducted residential schools for off-campus students at its Geelong Waurn Ponds Campus. Initially the schools were conducted annually over two-weeks during the first semester, and have transitioned to the current mode where the residential school is conducted as a one week programme in each of the trimesters. During these schools, activities are organised around the respective engineering-course units undertaken by students during the trimester.
DISCUSSION: The minimum requirements for the on-campus components of distance-education-mode accredited engineering courses were developed by Engineers Australia in consultation with members of the Washington Accord (International Education Alliance) and at the time of development, generated considerable debate (Palmer, 2005, 2008). The intended purpose of residential schools was for off-campus enrolled students to have reasonable exposure to a typical “on-the-campus” student experience periodically throughout the course. Elements considered suitable and worthwhile for inclusion in residential school programs included:
• in person engagement with their academic lecturers,
• presentations and interaction with guest speakers from industry,
• industry-based site visits,
• engagement in sole and group-based learning and assessment activities on campus, and
• social interaction with other students.
RECOMMENDATIONS/IMPLICATIONS/CONCLUSION: We have found that advantages to the students who attends a residential school include completing real practical work without the need to assemble their own materials at home, and social engagement with staff and students. Off-campus students leave the residential school with a sense of belonging to a “community”, “one of many doing the same and not the only one”. They have the opportunity to share their often significant professional experience with the generally younger and less experienced on-campus student colleagues. Through this interaction between on-campus and off-campus students, the on-campus students benefit as much as the off-campus students. The disadvantages to the off-campus students is the requirement to travel to Geelong for an extended time, which costs the students both money and time away from work and family. From our experience, we recommend to other institutions starting residential schools of their own that they exploit the mandatory on-campus-presence requirement to enhance learning outcomes, well publicised timetables be available to students before trimester begins (certainly before census date), a standardised academic week during trimester be set for all residential schools, encourage student feedback on the program, and apply a practice of uniformity and consistency in how the programme is managed, especially mandated student attendance. Our residential schools for off-campus-mode students have been running for over 10 years. We have found that the educational and social advantages to the student outweigh the disadvantages.

Enzyme engineering (immobilization) for food applications

This chapter discusses technical details of enzyme immobilization and its application in the food industry. The chapter first presents the various immobilization technologies, including the pros and cons of each immobilization method and a description of the various classes of immobilization support materials that are food compatible. It then discusses two case studies using immobilized enzymes in the food industry, namely, lactose hydrolysis and milk protein degradation by immobilized enzymes. Recent advances in enzyme immobilization techniques, including the use of nanoparticles and fusion proteins, are presented followed by their implications for the food industry.

Does student engagement improve when 1:1 device technologies are used and adapted to cater for individual learning styles during online delivery of engineering courses?

BACKGROUND OR CONTEXT: A developing international engineering industry is dependent on competition and innovation, creating a market for highly skilled graduates from respected overseas and Australian Engineering universities. The delivery of engineering teaching and learning via blended faceto-face, problem based, research focused and online collaborative learning will continue to be the foundation of future engineering education, however, it will be those institutions who can reshape its learning spaces within a culture of innovation using 1:1 devices that will continue to attract the brightest minds. Investing in educational research that explores the preferred learning styles of learners and matching this to specifically designed 1:1 personalized web applications may be the ‘value add’ to improve student engagement. In this paper, a survey of Australian engineering education is presented and contrasted against a backdrop of internationally recognised educational pedagogy to demonstrate how engineering teaching and learning has changed over time. This paper draws on research and identifies a gap where a necessity to question the validity of 1:1 devices as the next step in the evolution of engineering education needs to be undertaken. How will teaching and learning look using 1:1 devices and will it drive student demand into engineering higher
education courses. Will this lead to improving professional standards within a dynamic engineering education context? How will current and future teaching and learning be influenced by constructivism using 1:1 device technologies? How will the engineering industry benefit from higher education investment in individualised engineering education
using 1:1 devices for teaching and learning?
PURPOSE OR GOAL: To review the current academic thinking around the topic of 1:1 devices within higher education engineering teaching and learning context in Australia. To identify any gaps in the current understandings and use of 1:1 devices within engineering courses in Australia. To generate discussion and better understanding about how the use of 1:1 devices may hinder and/or improve teaching and learning and student engagement.
APPROACH: A review covering the development of engineering education in Australia and a broader international review of engineering teaching methodology. To identify the extent of research into the use and effectiveness of online strategies within engineering education utilising 1:1 devices for teaching and learning. i.e. “Students must feel that they are part of a learning community and derive motivation to engage in the study material from the lecturer.’ (Lloyd et al., 2001) It is proposed to add to the current body of understandings and explore the effectiveness of a constructiveness teaching approach using course material specifically designed to cater for individual learning styles and delivered via the use of 1:1 devices in the classroom. It is anticipated the research will contrast current engineering teaching and learning practices and identify factors that will facilitate a greater understanding about student connectedness and engagement with the teaching and learning experience; where a constructiveness environment is supported with the use of 1:1 devices. Also, it is anticipated that the constructed learning environment will foster a culture of innovation and students will be empowered to take control of their own learning and be encouraged to contribute back to the discussion initiated by the lecture and/or course material with the aid of 1:1 device technologies. A gap has been identified in the academic literature that show there is a need to understand the relationship between engineering teaching, learning, students engagement and the use of 1:1 devices.
DISCUSSION: A review covering the development of engineering education in Australia and a broader international review of engineering teaching methodology. To identify the extent of research into the use and effectiveness of online strategies within engineering education utilising 1:1 devices for teaching and learning. i.e. “Students must feel that they are part of a learning community and derive motivation to engage in the study material from the lecturer.’ (Lloyd et al., 2001) It is proposed to add to the current body of understandings and explore the effectiveness of a constructiveness teaching approach using course material specifically designed to cater for individual learning styles and delivered via the use of 1:1 devices in the classroom.
ANTICIPATED OUTCOMES: It is anticipated the research will contrast current engineering teaching and learning practices and identify factors that will facilitate a greater understanding about student connectedness and engagement with the teaching and learning experience; where a constructiveness environment is supported with the use of 1:1 devices. Also, it is anticipated that the constructed learning environment will foster a culture of innovation and students will be empowered to take control of their own learning and be encouraged to contribute back to the discussion initiated by the lecture and/or course material with the aid of 1:1 device technologies. A gap has been identified in the academic literature that show there is a need to understand the relationship between engineering teaching, learning, students engagement and the use of 1:1 devices.
RECOMMENDATIONS/IMPLICATIONS/CONCLUSION: A gap exists in the current research about the effectiveness and use of 1:1 devices in engineering education; therefore, it is necessary to undertake further research in the area. It is proposed to hypothesize and conduct field research to identify any shortcomings and possible benefits for engineering educators and learners within a constructivist-teaching
context that explores the relationship between the use of personalized 1:1 devices for teaching and learning, adapting for individual learning styles, and identification and application of appropriate teaching and learning strategies within a constructiveness engineering course approach. Research is required to clarify the following research questions;
• What education teaching and learning strategies best facilitate the use of 1:1 devices for online teaching and learning?
• Does student engagement improve when 1:1 device technologies are used and adapted to cater for individual learning styles during online delivery of engineering courses?
• What are the factors within a university engineering faculty that may hinder and/or support the use of 1:1 devices for online teaching and learning?
• To what extent do 1:1 devices assist engineering educators and students to foster a culture of innovation? The study results will offer engineering educators and students an opportunity to reflect on
their current teaching and learning practice, and contextualise the use of 1:1 devices as a tool to improve student engagement. It is expected the learning benefits will outweigh the implementation costs and derive a unique learning experience that will empower engineering educators and students to inspire a culture of innovation.

Freshman residential schools for undergraduate on-campus and on-line engineering students

By means of evidence-based practice, this paper describes the residential-school component of an accredited online (distance education) undergraduate engineering program in Australia, with a particular focus on how the residential school program is implemented at freshman year. During these residential schools, activities were organised around the respective engineering courses undertaken by students during the semester. Elements considered suitable and worthwhile for inclusion in residential-school programs included: • In-person engagement with academic lecturers, • Practical and laboratory learning activities, • Presentations and interaction with guest speakers from industry, • Industry-based site visits, • Engagement in sole and group-based learning and assessment activities on campus, and • Social interaction with other students. After running pilot residential schools for two years, it was found that a workable format consisted in a two-week residential experience in the first semester, linked to two key freshman courses, Fundamentals of Technology Management, and Engineering Physics. On-campus and online students’ academic grades were compared for both courses over the years 2005 to 2012. We found that for physics lab, on-campus students’ grades tended to be higher than those for online students, and vice versa for technology management. We also conclude that when carefully designed, residential schools for online students do enhance learning for both online students and their on-campus counterparts.

Construction industry performance measurement with carbon reduction

The research developed non-parametric approaches for measuring construction industry performance in sustainable development. The research results support the improvement of value added and the reduction of carbon emissions, which have positive environmental and economic implications in the Australian construction industry.

Global virtual engineering teams (GVETs): a fertile ground for research in Australian construction projects context

Implementation of global virtual engineering teams (GVETs) commenced since at least two decades ago, but construction has been behind other industries in terms of harnessing this new paradigm. Nevertheless, GVETs are receiving increasing attention within the construction context due to numerous potential benefits they can bring about for the projects. On the other hand, the research about GVETs in Australia is still in its embryonic stages. Australian scholars noticeably have paid scant attention to GVETs in comparison to their colleagues in other developed countries. This paper assumes the process of implementation of a GVET as an isolated project. The study then highlights the well-known main areas of necessary knowledge for managing a GVET project within the construction context based on a project lifecycle approach. Recognizing the weaknesses of existing literature, the paper sets out an agenda for further research within Australian construction projects.