FE Curriculum
Forensic Engineering
Forensic engineering is a highly specialized field of engineering
practice requiring engineering expertise and knowledge of legal
procedures. Forensic engineering can be defined as the
application of the engineering sciences to the investigation of
failures or other performance problems. Some forensic engineering
projects or cases require sworn testimony in a court of law or
legal proceeding. Thus, forensic engineers must work in both
the engineering and legal arenas. From an engineering
perspective, forensic engineering deals with the investigation
and reconstruction of failures in buildings, structures,
facilities, vehicles, and other engineered systems. From a legal
perspective, forensic engineering is a fact-finding mission to
learn the most probable cause or causes of a failure. Forensic
engineering requires both scientific skills and high ethical
standards. Forensic engineers must be expert in their field and
impartial in the investigation process. **
Need for Forensic Engineering
Education?
There are at least four reasons why there are no formal forensic
engineering degree programs offered at universities in this
country. First, forensic engineering is not a standard
engineering discipline like mechanical, electrical, or civil
engineering. Forensic engineering encompasses many disciplines,
and it is not easy to offer multi-disciplinary courses which
cross traditional engineering boundaries. Second, forensic
engineering is not a widely known field outside the profession.
Third, universities have not seen the need to include failure
analysis in traditional engineering programs. Finally, and most
important, the demand for forensic engineers is not high when
compared with standard engineering disciplines. Still, there
exists a need for some form of university education in forensic
engineering to help train engineers that are new to the
profession. Several universities do offer a single, elective
graduate course in forensic engineering. Four such courses are
identified below:
| ENGR 5340 | Advanced Topics in Engineering (Introduction to Forensic Engineering), University of Texas at Tyler. |
| CE 5805 | Failure Analysis and Condition Assessment in Civil and Mechanical Engineering, University of Colorado at Denver. |
| EE 595G | Medical Device Accidents and their Engineering Analysis, Purdue University. |
| TECH 525 | Applications in Forensic Engineering Technology, Purdue University. |
A Formal Degree Program?
Due to the specialized nature of forensic engineering, any
forensic engineering degree program should begin at the Masters
Degree level. It is doubtful, however, that any university would
be willing to commit the resources needed to develop a formal
Masters Degree Program in Forensic Engineering. Most graduate
faculty are involved in sponsored research, not engineering
practice, and the demand for graduates is limited. The best
approach is to work within existing graduate degree programs
already in place. For example, most universities today have
graduate degree programs in interdisciplinary engineering where a
student can structure a graduate program of special interest
within two or more engineering departments. One of the main
strengths of an interdisciplinary program is the ability to
tailor the program to the needs and strengths of the individual
student and their specific background. This is especially
important in the field of forensic engineering where an
electrical engineering student will have very different expertise
compared to a mechanical engineering technology student. An
interdisciplinary forensic engineering program would allow for
both students to be trained equally well. Prospective students
should hold a baccalaureate degree in engineering, engineering
technology, or other engineering science discipline that can lead
to registration as a professional engineer. Although not
required, several years engineering experience and qualification
for the Fundamentals of Engineering (FE) examination would be a
plus.
Capabilities of Graduates
Graduates of the program will not be experienced forensic
engineers and will not be qualified immediately to take on
complex investigative or litigation projects. Graduates will,
however, understand the complex relationship that exists between
engineering and the American legal system and know how to conduct
forensic engineering investigations according to the scientific
method and recommended engineering practice. Additionally,
graduates will think critically and communicate with clarity and
precision both orally and in writing. Furthermore, graduates will
be employable in a forensic engineering setting with little
on-the-job training required.
Recommended Plan of Study
The plan of study should consist of a minimum of 33 semester
hours of graduate credit as described below and conform to the
requirements of the graduate school of the university where the
degree is awarded. Core Courses (15 semester hours): A core of 15
semester hours in applied forensic engineering course work is
required. Universities can meet this requirement by employing
adjunct faculty who are practicing forensic engineers and using
university faculty who are part-time consulting forensic
engineers.
| FE 501 (3) | Introduction to Forensic Engineering |
| FE 502 (3) | Product Liability |
| FE 590 (3) | Forensic Engineering Project |
| FE 601 (3) | Advanced Forensic Engineering Techniques |
| FE 602 (3) | Computer Applications in Forensic Engineering |
Required Supporting Courses (nine semester
hours):
Nine semester hours in supporting course work are required. This
requirement can be met with existing courses available at most
universities.
| EG 520 or equiv (3) | Engineering Ethics |
| Math (6) | Mathematical, statistical, or computer sciences beyond ordinary differential equations. |
Elective Courses (nine semester hours): Nine semester hours in closely related engineering electives are required. Courses listed below are typical courses available at many universities. The list is not exhaustive. Other courses may also be available.
| IE 577 (3) | Human Factors in Engineering |
| IE 558 (3) | Safety Engineering |
| IE 590 (3) | Applied Ergonomics |
| CE 524 (3) | Legal Aspects of Engineering Practice |
| CE 503 (3) | Photogrammetry |
| EE 595 (3) | Medical Device Accidents and their Engineering Analysis |
| ME 525 (3) | Combustion |
| TECH 581(3) | Human Error and Human Reliability Assessment |
Methods of integrating the following and similar practical experiences into the plan of study should be considered:
Court experience where expert engineering testimony is given.
Deposition experience where expert engineering testimony is given.
A relevant co-op or internship.
Membership in at least one
professional engineering society that can be related to
forensic engineering.
** Reference: Guidlines for Failure Investigation, American Society of Civil Engineers, 1989.
Final Report of the Forensic Engineering
Curriculum Committee
The Final Report of the Forensic Engineering Curriculum
Committee contains detailed course descriptions, course outlines
in ABET format, and qualifications of the faculty. University
curriculum planners may obtain a free copy
of the Final Report by contacting:
Marvin M. Specter, P.E., L.S., F.NSPE
Executive Director NAFE
174 Brady Avenue
Hawthorne, NY 10532
Tel (Toll Free): 866.NAFEORG
Fax (Toll Free): 877.741.0633
Email: nafe@nafe.org
Website: www.nafe.org
Last update:
01/17/2007
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