Standards in Civil Engineering Design Education

In the United States, requirements in the Accreditation Board for Engineering and Technology (ABET) engineering criteria provide a strong incentive to integrate engineering codes and standards into civil engineering undergraduate curricula. Under the current criteria, specifically Criterion 4, appropriate engineering standards must be incorporated into the major design experience. The purpose of this paper is to discuss the current ABET Engineering Criteria requirements with respect to engineering standards and suggest some ways standards can be included in both the technical and nontechnical portions of undergraduate curricula.     

Integrating Management Breadth in Civil Engineering Education

At the beginning of the 21st century, there is a wider awareness that the civil engineering industry has become a global industry. The rapid increase in foreign ownership of firms in the United States along with the globalization of economic markets is reminding professionals that they must be aware of global events before they impact local operating conditions. In response to these developments, university programs must begin to broaden their focus to include subjects that address new economy realities. Specifically, the time to begin exposing students to management topics such as entrepreneurship, financial management, and global economics has arrived. If the civil engineering industry is going to evolve into a new economy business, it will require individuals who are as comfortable with the financial and technological components of the business as they are with design or construction fundamentals.     

Civil Engineering Education and Complex Systems

Civil engineering is an interdisciplinary field, and most of the projects designed and built represent very complex systems, both during the construction phase and in the built phase. This research describes how a course in land development that included engineering design elements, lectures that also touched on other related fields, and a field journal assignment at a “green” (sustainable) construction site facilitated students’ understanding of complex systems. Results suggest that this course design facilitates the development of students’ proficiencies in several skill sets, and can increase students’ understanding of the complexity involved in civil engineering projects.     

Computer Imagery and Visualization in Civil Engineering Education

Higher education institutions in the United Kingdom have invested significantly in the implementation of communication and information technology in teaching, learning, and assessment of civil and building engineering—with mixed results. This paper focuses on the use of digital imagery and visualization materials to improve student understanding. It describes ways in which these materials are being used in the civil and building engineering curriculum, and, in particular, how distributed performance support systems (DPSS) can be applied to make more effective use of digital imagery and visualization material. This paper centers on the extent to which DPSS can be used in a civil and building vocational and continuing professional development context by tutors in the form of an electronic course delivery tool and by students in the form of an open-access student information system. This paper then describes how a DPSS approach to education is being adopted at Loughborough University as part of the CAL-Visual project. After highlighting the main aims and objectives of the project and describing the system, this paper discusses some of the issues encountered during the design and implementation of a DPSS and presents some preliminary results from initial trials.     

Impact of Nanotechnology on Future Civil Engineering Practice and Its Reflection in Current Civil Engineering Education

Current civil engineering education should address the need to provide a broad vision, develop the higher-order skills of future civil engineers, enable them to adopt emerging technologies, and formulate innovative solutions to complex problems. This paper introduces relevant nanotechnology developments to convey the new vision and inspire creativity in civil engineering. It also presents a pedagogical framework for integrating nanotechnology education into a civil engineering curriculum and cultivating self-regulated learning and creativity skills for civil engineering students. The pedagogical framework includes the introduction of nanotechnology innovations and other relevant innovative technologies, and explicit instructions on cognitive strategies for facilitating and inspiring self-regulated learning and creativity. It is implemented with problem/project-based learning for a cocurricular project that requires self-regulated learning and creativity. This pedagogical framework provides a model for integrating emerging technology education and higher-order skill development into existing engineering curriculum. The outcomes from the implementation of the pedagogical framework are presented, and their further improvements are discussed.     

Assessment of Communications and Collaborative Learning in Civil Engineering Education

Recently, employers have indicated that they are not totally satisfied with the individualistic approach of the average engineering graduate. This may be due to the fact that, today, in many companies, team goals, team contributions, and team rewards often supersede individual actions. In fact, some authorities believe that the development of critical thinking, collaborative learning, communication, and leadership skills is vital for engineering programs, as well as for students. The findings of this study suggest that students have accepted the concept of collaborative teaching and learning. As an example, the evaluation of student-teaching presentations was found to be above average with scores greater than “B” for all categories. In addition, comments indicate that a course utilizing the concepts of collaborative learning and teamwork was interesting and informative and could be of assistance to respondents in future endeavors. Studies also indicate that undergraduates prefer classroom discussion and problem solving, group interaction, teamwork, and the opportunity for student input rather than formal lectures. Also, the results suggest students perceive that they have mastered communication skills in their civil engineering classwork. For comparative purposes, the findings of this investigation can be utilized by other institutions and departments that may wish to study their curriculum.     

Assessment of the Computing Component of Civil Engineering Education

This paper presents the results of two surveys conducted by the American Society of Civil Engineers’ Task Committee on Computing Education of the Technical Council on Computing and Information Technology to assess the current computing component of the curriculum in civil engineering. Previous surveys completed in 1989 and 1995 have addressed the question of what should be taught to civil engineering students regarding computing. The surveys reported in this paper are a follow-up study to the two earlier surveys. Key findings of the study include: (1) the relative importance of the top four skills (spreadsheets, word processors, computer aided-design, electronic communication) has remained unchanged; (2) programming competence is ranked very low by practitioners; (3) the importance and use of geographic information system and specialized engineering software have increased over the past decade; (4) the importance and use of expert systems have significantly decreased over the past decade; and (5) the importance and use of equation solvers and databases have declined over the past decade.     

Student Assessment of a Problem-Based Learning Experiment in Civil Engineering Education

This paper describes an experiment with problem-based learning (PBL), an instructional methodology used in response to the challenges posed by today’s professional education. Contrary to the conventional model that places an application problem after concepts or topics have been introduced, PBL uses the problem to initiate learning. Besides promoting the construction of knowledge, it may also contribute to the development of some skills and attitudes deemed important for engineers’ professional practice. This research, of a qualitative nature, intended to investigate how students evaluate this methodology and its potential to attain the educational goals set for the course. In order to answer the research question, the methodology was implemented in the civil engineering curriculum of a Brazilian public university. The results herein presented, deriving mainly from classroom observations and an end-of-course questionnaire, show that most of the students evaluate the methodology positively. Even considering the short duration of the course and its small number of credits, it may also have promoted the development of some skills and attitudes besides knowledge acquisition.     

Enhancing Civil Engineering Education and ABET Criteria through Practical Experience

The Accreditation Board for Engineering and Technology (ABET) has adopted a revised set of criteria for accrediting engineering programs. Nevertheless, as in the past, civil engineering departments will be required to demonstrate proficiency in specific subject areas which are included in the ABET program criteria. This paper investigates how civil engineering students at Lamar University improved their understanding of various subject areas required by ABET and listed in the Program Criteria for Civil and Similarly Named Engineering Programs and the General Criteria (professional component) by being involved with cooperative, part-time, and summer work experiences. In particular, the findings suggest that both undergraduate and graduate students believe that three areas have been greatly enhanced with engineering work. They include structural engineering, project management/scheduling and estimating, and teamwork. In addition, undergraduates perceive that their understanding of health and safety issues and ethical considerations has also increased. In contrast, graduate students believe that their knowledge of hydraulics, hydrology, and water resources, constructability, and economic factors has been enhanced by civil engineering work experiences.     

Incorporating the Social Dimension of Sustainability into Civil Engineering Education

Social sustainability is often overlooked in favor of environmental and economic considerations in civil engineering (CE) education. To help address this issue, this paper presents two instructional approaches to introduce students to social sustainability by using a conceptual model derived from four dimensions of social sustainability: community involvement, corporate social responsibility, safety through design, and social design. In the first instructional approach, the instructor is the primary facilitator; in the second approach, the students become the experts, sharing their knowledge with their peers. Methods to assess student understanding of these dimensions, such as concept mapping, are proposed. By providing the conceptual model and methods to teach it, this paper is for the purpose of assisting those teaching the social dimensions of sustainability to CE students, who will gain an understanding of how their technical decisions affect social sustainability.     

Raising the Bar for Civil Engineering Education: Systems Thinking Approach

The civil engineering profession has been undergoing an identity search. With the advent of information technology and the global market, competition from engineering offices elsewhere and from other local professions is unprecedented. Technical engineering knowledge is no longer a guarantee for career success; rather a combination of numerous professional skills is required. The growing unease of civil engineers about their undefined role in the knowledge economy has led many to question civil engineering education. Although there is a push to enhance the humanistic and business aspects of the curriculum, there is a shove in the opposite direction to strengthen the technical content and keep abreast of technical change. Discussion of this socioeconomic problem within the ASCE forum has often used linear deterministic thinking that is characteristic of technical problems. Social and economic systems are usually more complex and harder to understand than technological systems. If we start making new policies to address the problems of the profession based on fuzzy, incomplete, and imprecise mental models, we may end up with counterintuitive results. This paper proposes a systems thinking approach to the reform of civil engineering education based on System Dynamics modeling, a feedback-based object-oriented modeling paradigm. Such a tool can capture the dynamic nature of complex systems and the nonlinear feedback loops that are often responsible for counterintuitive results of policy making.     

Forensics and Case Studies in Civil Engineering Education: State of the Art

This paper reviews the state of the art in the use of forensic engineering and failure case studies in civil engineering education. The study of engineering failures can offer students valuable insights into associated technical, ethical, and professional issues. Lessons learned from failures have substantially affected civil engineering practice. For the student, study of these cases can help place design and analysis procedures into historical context and reinforce the necessity of lifelong learning. Three approaches for bringing forensics and failure case studies into the civil engineering curriculum are discussed in this paper. These are stand-alone forensic engineering or failure case study courses, capstone design projects, and integration of case studies into the curriculum. Some of the cases have been developed and used in courses at the United States Military Academy and the Univ. of Alabama at Birmingham, as well as at other institutions. Finally, the writers have tried to assemble many of the known sources of material, including books, technical papers, and magazine articles, videos, Web sites, prepared PowerPoint presentations, and television programs.     

Crisis of Civil Engineering Education in Information Technology Age: Analysis and Prospects

The brightest students entering postsecondary education are often attracted by routes other than engineering that are perceived more likely to yield careers of higher prestige and greater returns. For civil engineering in particular, this is further compounded by the fact that the field is not traditionally viewed as a high-tech discipline. Thus, student quality, enrollment, and research funding in civil engineering programs have been declining across North America. The conservative construction industry is part of the problem; adjustments of this aging cartel to the new economy are still at the embryonic level. Civil engineering educators are facing the question, How do we change the “hard hat down in the ditch” image of civil engineering in the minds of the new information technology generation? This paper presents an analysis of possible causes of this problem and a vision for potential future solutions.     

A Course on Engineering Leadership

Because of the increased recognition of the need for leadership training within all subcultures of the engineering profession, an overview of a one-credit-hour course on leadership skills is provided. The intent of the course is to broaden the students' perspective on engineering practice, to develop an awareness that engineering is more than just the completion of technical assignments, and to introduce skills and characteristics that are necessary for them to assume positions of leadership as they advance along their career paths. Rather than a concentrated effort on one aspect of leadership, the philosophy that underlies the course is one of exposure to a broad spectrum of leadership skills. As such, the course includes discussions of the following topics: leadership theories, motivation, public policy, ethics, creativity, communication, research methods, and personality type. Recommendations on course readings and paper topics are provided.