Resources for instructors of capstone courses in computing

Most computing programs now have some form of integrative or capstone course in which students undertake a significant project under supervision. There are many different models for such courses and conducting these courses is a complex task. This report is intended to assist instructors of capstone courses, particularly those new to the model of teaching and learning inherent in the capstone course.This paper discusses important issues that must be addressed when conducting capstone courses. These issues are addressed through a series of questions, with answers reflecting the way that different institutions have chosen to handle them, and commentary on the impact of these different choices. These questions include: Goals of the Course; Characteristics of Projects; Project Deliverables; Sponsors; Teams; Prerequisites and Preparation; Grading and Assessment; Administration and Supervision; and Reflection, Analysis and Review.Subsequently we present information about the companion Web site, intended as an active repository of best practice for instructors of capstone projects. The Web site will have examples of information about capstone courses and materials used by instructors. Readers are invited to contribute content to this site. The paper concludes with a bibliography of additional reference material and resources

Benefits of Industry Involvement in Multidisciplinary Capstone Design Courses

Opportunities for industry involvement in capstone design courses go beyond industry sponsorship of capstone design projects. Representatives from industry can serve as guest lecturers, curriculum advisors, and design project sponsors and team mentors. Since 2000, industry participation has been a core part of the capstone design course at Marquette University. Practicing engineers provide a relevant, practical real-world perspective of their topic, reinforcing its importance to professional engineering practice. Students and faculty benefit from the up-to-date treatment of the topic provided by guest speakers from industry who have expertise in the topic and are willing to share their experiences with students. Students benefit from industry sponsorship of senior design projects through the opportunity to work on realworld problems of importance to industry, exposure to industry and company-specific project management and product development processes, and familiarity with economic, legal, and regulatory design constraints. This paper provides a brief description of the Multidisciplinary Capstone Design course at Marquette University, examples of industry involvement in the course, and the observed benefits of industry involvement to students, the university, and industry participants. It presents examples of current practices used at other schools as well as helpful recommendations for managing industry participation in capstone design courses

The Benefits of Peer Review and a Multisemester Capstone Writing Series on Inquiry and Analysis Skills in an Undergraduate Thesis.

This study examines the relationship between the introduction of a four-course writing-intensive capstone series and improvement in inquiry and analysis skills of biology senior undergraduates. To measure the impact of the multicourse write-to-learn and peer-review pedagogy on student performance, we used a modified Valid Assessment of Learning in Undergraduate Education rubric for Inquiry and Analysis and Written Communication to score senior research theses from 2006 to 2008 (pretreatment) and 2009 to 2013 (intervention). A Fisher-Freeman-Halton test and a two-sample Student's t test were used to evaluate individual rubric dimensions and composite rubric scores, respectively, and a randomized complete block design analysis of variance was carried out on composite scores to examine the impact of the intervention across ethnicity, legacy (e.g., first-generation status), and research laboratory. The results show an increase in student performance in rubric scoring categories most closely associated with science literacy and critical-thinking skills, in addition to gains in students' writing abilities

Design process of web based portal: requirements of AUK Training and Development Institute : [presented May 18, 2010]

In order to improve the quality of registration and teaching at AUK Training and Development Institute, this project introduces a web educational portal, service-oriented portal in supporting students, instructors and administration in their daily business. Day by day, new service learning requirements related to key users’ work are being proposed. This capstone_masters_project proposed a service oriented software solution, where the key users could interface and deposit data based on their preferred requirements. There is a shortfall in software and computing facilities at the AUK Training and Development Institute for meeting increased demand for its training programs. This project assesses how to develop training programs necessary to improve registration and administrative procedures between students and administration while enhancing computing facilities capable of servicing increased student numbers. Using the qualitative tools such as surveys and interviewing techniques targeted to potential users, the project has provided a deeper analysis of effective implementation of the “MyTraining” web educational portal. The results from surveys were taken from three key users: students, administration and instructors. Their comments were synthesized into two main areas. They suggested that all features that are linked directly to the user’s work are important and necessary for the web portal. On the other hand, results from the interviews taken by two local companies and one international company, suggest that all technical features of the web educational portal shall be first evaluated by the business owner and then presented to the interested implementing parties

Enhancing project-related behavioral competence in education

The workforce has increasingly been demanding an educational model that produces students experienced in real project management (PM) practices. This includes producing technically competent students--one who can manage real-world project constraints of cost and schedule but also possess critical project related behavioral competence. Such soft skills are essential if a project is to run smoothly and eventually succeed. In this paper, we describe an educational framework grounded in outcomes based education to enhance project-related behavioral competence. Instructors can leverage this framework to augment their existing courses and develop the critical career skill sets of graduating students

Infusing Raspberry Pi in the Computer Science Curriculum for Enhanced Learning

With the advent of cloud computing, the Internet of Things (IoT), and mobile computing, CS faculty are continuously revamping the curriculum material to address such burgeoning set of technologies in practical and relatable ways. Raspberry Pi (RPi) devices represent an ideal hardware/software framework that embodies all these technologies through its simple architecture, small form factor (that minimizes the volume and footprint of a desktop computer), and ability to integrate various sensors that network together and connect to the Cloud. Therefore, one of the strategies of Computer Science Department, to enhance depth of learning concepts, has been to infuse Raspberry Pi (RPi) in computer science courses. RPi has been incorporated since 2016 in targeted courses, notably, Computer Organization & Assembly Language, Computer Architecture, Database Management Design & Implementation, Unix/Linux Programming, Internet Programming, and Senior Project. An inexpensive credit card sized computer, an RPi lends itself to allow depth of learning of concepts. From implementing firewalls, intrusion detection systems, scripting, client-server based computing, distributed computing, to interfacing with sensors and actuators, a student is guided to polish concepts taught in a class through RPi Project Based Learning (RPBL). Computer science curriculum already provides breadth of learning. The infusion of RPi in key courses provides depth in targeted concepts. There are peripheral desirable consequences as well, including a student learning prevalently used Linux environment even though a targeted course may have nothing directly to do with Linux. Furthermore, RPi provides an opportunity for students to realize that software programs can be interfaced with sensors and actuators to provide immersed experience in programming. From simply interfacing a switch and a Light Emitting Diode (LED) to getting data from sensors, buffering, and uploading to the cloud, a student already would have touched upon multiple disciplines in computer science. This paper provides a blueprint to infusing RPi in the targeted courses, and how each RPi based project provides depth to a targeted concept

Towards using online portfolios in computing courses

The direct experience we had with teaching a summer pre-college computing course in which we adopted an online portfolio approach has led us to consider the use of online portfolios in our regular computer science undergraduate courses. The technical challenges we foresee include: the necessary support from the college\u27s IT department; the use of Microsoft-based web authoring technologies vs. the use of Open Source / freeware counterparts; the need for adequate technical knowledge on the part of our faculty; the need for server-side hardware and software resources

Improving the Quality of Technology-Enhanced Learning for Computer Programming Courses

Teaching computing courses is a major challenge for the majority of lecturers in Libyan higher learning institutions. These courses contain numerous abstract concepts that cannot be easily explained using traditional educational methods. This paper describes the rationale, design, development and implementation stages of an e-learning package (including multimedia resources such as simulations, animations, and videos) using the ASSURE model. This training package can be used by students before they attend practical computer lab sessions, preparing them by developing technical skills and applying concepts and theories presented in lecture through supplementary study and exercises