More Like this

1. Developing a Summer Engineering Teaching Institute for Community College Engineering Faculty

   Enriquez, A. ; Langhoff, N. ; Dunmire, E. ; Rebold, T. ( June 2018 , American Society for Engineering Education)

   The California Community College system plays an important role in providing affordable and accessible education to diverse student populations by allowing them to complete all of their lower-division course work and then transfer to a four-year institution to complete a bachelor’s degree. However, the increasing divergence of the lower-division requirements among different four-year institutions and among the different fields of engineering, coupled with decreasing enrollments and resources, has forced many community colleges to cancel low-enrollment classes and high-cost programs including those in engineering. To address this issue, four community colleges in the San Francisco Bay Area developed an innovative program titled Creating Alternative Learning Strategies for Transfer Engineering Programs (CALSTEP). Funded by the National Science Foundation through the Improving Undergraduate STEM Education (IUSE) program, CALSTEP aims to enable small-to-medium community college engineering programs to support a comprehensive set of lower-division engineering courses that are delivered either completely online, or with limited face-to-face interactions. In addition to developing and implementing curriculum materials and resources for the core lower-division engineering courses, one of the main components of CALSTEP is disseminating the curriculum widely in California community college engineering programs. This is done through the Summer Engineering Teaching Institute, which is a two-daymore »teaching workshop that introduces community college engineering faculty to the CALSTEP curriculum, and assists faculty in implementing the curriculum and developing alternative teaching and learning strategies to increase enrollment and improve teaching effectiveness. Results of curriculum development and the implementation of the Summer Engineering Teaching Institute will be highlighted in this paper, as well as future plans to maximize the impact of the program in increasing access to engineering education among thousands of community college engineering students and strengthening engineering transfer programs in the state.« less
2. Strengthening Community College Engineering Education Through Collaboration and Technology

   Enriquez, A. G. ; Cheung, E. P. ; Reardon, T. ( June 2013 , ASEE annual conference & exposition)

   There has been a recent increase in awareness of the important role that community colleges play in educating future engineers, especially in broadening participation among students from underrepresented groups. However, budget problems at the state and national levels have resulted in continuing budget cuts in community colleges. With limited resources while responding to increasing variability of lower-division transfer curricula as required by four-year engineering programs, it has become increasingly difficult for small community college engineering programs to support all the courses needed by students to transfer. Meanwhile, transfer admissions have become increasingly more competitive because of budget cuts in four-year universities. As a result, prospective engineering students who attend community colleges with limited or no engineering course offerings are at a disadvantage for both transfer admission as well as time to completion upon transfer. This paper is a description of a collaborative project among community college engineering programs in California to address this problem by aligning engineering curriculum, enhancing teaching effectiveness using Tablet PCs, and increasing access to engineering courses through online education. The project includes a Summer Engineering Teaching Institute designed to assist community college engineering faculty in developing a Tablet-PC-enhanced model of instruction, and implementing online courses. Themore »project also involves a partnership among California community college engineering programs to design and implement a Joint Engineering Program that is delivered online. This paper summarizes the results of the first two years of implementation of the project, and explores its potential to strengthen the community college engineering education pipeline in order to increase and diversify the engineering workforce.« less
3. Strengthening Community College Engineering Programs through Alternative Learning Strategies: Developing Resources for Flexible Delivery of a Materials Science Course

   Dunmire, Erik ; Enriquez, Amelito ; Rebold, Thomas ; Schiorring, Eva ; Langhoff, Nicholas ; Huang, Tracy ( April 2017 , 2017 ASEE Pacific Southwest Section Conference)

   Community colleges provide an important pathway for many prospective engineering graduates, especially those from traditionally underrepresented groups. However, due to a lack of facilities, resources, student demand and/or local faculty expertise, the breadth and frequency of engineering course offerings is severely restricted at many community colleges. This in turn presents challenges for students trying to maximize their transfer eligibility and preparedness. Through a grant from the National Science Foundation Improving Undergraduate STEM Education program (NSF IUSE), three community colleges from Northern California collaborated to increase the availability and accessibility of a comprehensive lower-division engineering curriculum, even at small-to-medium sized community colleges. This was accomplished by developing resources and teaching strategies that could be employed in a variety of delivery formats (e.g., fully online, online/hybrid, flipped face-to-face, etc.), providing flexibility for local community colleges to leverage according to their individual needs. This paper focuses on the iterative development, testing, and refining of the resources for an introductory Materials Science course with 3-unit lecture and 1-unit laboratory components. This course is required as part of recently adopted statewide model associate degree curricula for transfer into Civil, Mechanical, Aerospace, and Manufacturing engineering bachelor’s degree programs at California State Universities. However, offering such amore »course is particularly challenging for many community colleges, because of a lack of adequate expertise and/or laboratory facilities and equipment. Consequently, course resources were developed to help mitigate these challenges by streamlining preparation for instructors new to teaching the course, as well as minimizing the face-to-face use of traditional materials testing equipment in the laboratory portion of the course. These same resources can be used to support online hybrid and other alternative (e.g., emporium) delivery approaches. After initial pilot implementation of the course during the Spring 2015 semester by the curriculum designer in a flipped student-centered format, these same resources were then implemented by an instructor who had never previously taught the course, at a different community college that did not have its own materials laboratory facilities. A single site visit was arranged with a nearby community college to afford students an opportunity to complete certain lab activities using traditional materials testing equipment. Lessons learned during this attempt were used to inform curriculum revisions, which were evaluated in a repeat offering the following year. In all implementations of the course, student surveys and interviews were used to determine students’ perceptions of the effectiveness of the course resources, student use of these resources, and overall satisfaction with the course. Additionally, student performance on objective assessments was compared with that of traditional lecture delivery of the course by the curriculum designer in prior years. During initial implementations of the course, results from these surveys and assessments revealed low levels of student satisfaction with certain aspects of the flipped approach and course resources, as well as reduced learning among students at the alternate institution. Subsequent modifications to the curriculum and delivery approach were successful in addressing most of these deficiencies.« less
4. Developing Resources to Support Comprehensive Transfer Engineering Curricula: Assessing the Effectiveness of a Hybrid Materials Science Course

   https://doi.org/10.18260/p.26769  

   Dunmire, Erik ; Enriquez, Amelito ; Langhoff, Nicholas ; Rebold, Thomas ; Schiorring, Eva ( June 2016 , 2016 ASEE Annual Conference & Exposition)

   A substantial percentage of engineering graduates, especially those from traditionally underrepresented groups, complete their lower-division education at a community college before transferring to a university to earn their degree. However, engineering programs at many community colleges, because of their relatively small scale with often only one permanent faculty member, struggle to offer lower-division engineering courses with the breadth and frequency needed by students for effective and efficient transfer preparation. As a result, engineering education becomes impractical and at times inaccessible for many community college students. Through a grant from the National Science Foundation Improving Undergraduate STEM Education program (NSF IUSE), three community colleges from Northern California collaborated to increase the availability and accessibility of the engineering curriculum by developing resources and teaching strategies to enable small-to-medium sized community college engineering programs to support a comprehensive set of lower-division engineering courses. These resources were developed for use in a variety of delivery formats (e.g., fully online, online/hybrid, flipped face-to-face, etc.), providing flexibility for local community colleges to leverage according to their individual needs. This paper focuses on the development and testing of the resources for an introductory Materials Science course with 3-unit lecture and 1-unit laboratory components. Although most of themore »course resources were developed to allow online delivery if desired, the laboratory curriculum was designed to require some limited face-to-face interaction with traditional materials testing equipment. In addition to the resources themselves, the paper presents the results of the pilot implementation of the course during the Spring 2015 semester, taught using a flipped delivery format consisting of asynchronous remote viewing of lecture videos and face-to-face student-centered problem-solving and lab exercises. These same resources were then implemented in a flipped format by an instructor who had never previously taught the course, at a community college that did not have its own materials laboratory facilities. Site visits were arranged with a nearby community college to afford students an opportunity to complete certain lab activities using traditional materials testing equipment. In both implementations of the course, student surveys and interviews were used to determine students’ perceptions of the effectiveness of the course resources, student use of these resources, and overall satisfaction with the course. Additionally, student performance on assessments was compared with that of traditional lecture delivery of the courses in prior years.« less
5. Strengthening Community College Engineering Programs through Alternative Learning Strategies: Developing an Online Engineering Graphics Course

   Enriquez, Amelito ; Dunmire, Erik ; Rebold, Thomas ; Langhoff, Nicholas ; Huang, Tracy ( April 2017 , 2017 ASEE Pacific Southwest Section Conference)

   There is an increasing recognition among institutions of higher education of the important role that community colleges play in educating future engineers and scientists, especially students from traditionally underrepresented groups. Two-plus-two programs and articulation agreements between community colleges and four-year institutions are growing, allowing community college students to take their lower-division courses at local community colleges and then transfer to a university to complete their baccalaureate degrees. For many small community colleges, however, developing a comprehensive transfer engineering program that prepares students to be competitive for transfer can be challenging due to a lack of facilities, resources, and local expertise. As a result, many community college students transfer without completing the necessary courses for transfer, making timely completion of degrees difficult. Through a grant from the National Science Foundation Improving Undergraduate STEM Education program (NSF IUSE), three community colleges from Northern California collaborated to develop resources and alternative teaching strategies to enable small-to-medium community college engineering programs to support a comprehensive set of lower-division engineering courses that are delivered either completely online, or with limited face-to-face interactions. The biggest challenge in developing such strategies lies in designing and implementing courses that have lab components. This paper focuses on the developmentmore »and testing of the teaching and learning resources for Engineering Graphics, which is a four-unit course (three units of lecture and one unit of lab) covering the principles of engineering drawings, computer-aided design (using both AutoCAD and SolidWorks), and the engineering design process. The paper also presents the results of the implementation of the curriculum, as well as a comparison of the outcomes of the online course with those from a regular, face-to-face course. Student performance on labs and tests in the two parallel sections of the course are compared. Additionally student surveys and interviews, conducted in both the online and face-to-face course are used to document and compare students’ perceptions of their learning experience, the effectiveness of the course resources, their use of these resources, and their overall satisfaction with the course.« less