Assessment Plan and Program Educational Objectives. Computer Engineering Program. Electrical Engineering Program

Assessment Plan

and

Program Educational Objectives

for the

Computer Engineering Program

and

Electrical Engineering Program

of the

School of Information

Technology and Engineering

at

Contents

Summary of Program Assessment Plan for Computer Engineering and Electrical Engineering Computer Engineering Program Outcomes Assessments Summary

Electrical Engineering Program Outcomes Assessments Summary Program Objectives Assessment Summary

Changes to CpE Program Changes to EE Program

CpE and EE Quality Assurance Process CpE and EE Program Assessment Plan CpE Program Educational Objectives CpE Program Outcomes and Assessment EE Program Educational Objectives EE Program Outcomes and Assessment

Minutes of Feb 11, 2000 ECE Advisory Committee

Computer Engineering Program Outcomes Assessments Summary

Fall 2000

-The formal documentation of the assessment process has just been implemented. While there is little direct data available at this time to demonstrate that our three graduates satisfy the Program Outcomes, the process for collecting high quality data is in place for continuous process

improvement as the number of graduates increases.

Based on data from courses involving computer engineering students, from surveys of ECE classes required by computer engineering students, from surveys of alumni and employers of the electrical engineering program which shares many requirements with computer engineering, the Computer Engineering Program Outcomes were assessed.

(a) an ability to apply knowledge of mathematics, science and engineering

Based on course Assessments; IT&E Senior and ECE Alumni (only EE responses, but the programs are quite similar) Surveys:

All students demonstrate the ability to apply math, science and engineering. Recommendations:

1. Work with the Math and Physics Departments to include more pertinent electrical engineering problems into the basic math and science curriculum. [Action: Math/Science Outcome faculty team.]

2. Consider introducing material into technical elective courses to extend students’ abilities to apply knowledge of VLSI design and testing , high performance computing, and computer-network design and analysis. [Action: CpE faculty.]

(b) an ability to design and conduct experiments, as well as to analyze and interpret data Based on lab reports and IT&E Senior and ECE Alumni and Employer (only EE responses, but the programs are quite similar) Surveys:

Students have demonstrated good performance conducting experiments and analyzing and interpreting data, and acceptable performance on designing experiments.

Recommendations:

1. Revise additional lab manuals to reduce stet-by-step procedures and to require students to design the experiments and experimental setups. [Action: Lab courses Coordinating Faculty.]

2. Prepare sample Lab Report formats to encourage more data interpretation. [Action: Undergraduate Committee.]

(c) an ability to design a system, component, or process to meet desired needs

Based on Design Projects; Course Assessments; and IT&E Senior, ECE Alumni and Employer (only EE responses, but the programs are quite similar) Surveys:

have successfully applied them to design a system, component or process to meet desired needs.

Recommendations:

1. Watch student performance with VHDL and INTROL C cross-compiler (new to CpE/EE Programs) to ensure the percent of students successfully using them rises as the experience with them increases. [Action: ECE 332, ECE 445 and ECE 447 instructors.] 2. Establish a standing committee to review design project abstracts in order to establish quality control and assess the level of design which is in these projects in order to maintain it at the existing high level. [Action: Design Outcome faculty team.] (d) an ability to function on multi-disciplinary teams

Based on Course Assessments: and Fall 2000 Undergrad, IT&E Senior, ECE Alumni (only EE responses, but the programs are quite similar), and Physics faculty Surveys: Students are able to successfully work in team environments.

Recommendations:

1. Include formal teaming in ECE 447 or/and ECE 449. [Action: CpE faculty.]

2. Encourage interaction with industry via student organization activities and seminars. [Action: Teaming Outcome faculty team.]

3. Develop new Assessment tool of Entrance/Exit Surveys for courses involving teams and Survey questions related to coop/intern/part-time/full-time work teaming

experiences. [Action: Teaming Outcome faculty team.] ( e) an ability to identify, formulate, and solve engineering problems

Based on Design Projects; IT&E Senior, ECE Alumni (only EE responses, but the programs are quite similar) and GMU Senior Surveys:

By graduation all but a few students can identify, formulate and solve engineering

problems. The aspect that more students show lesser ability is in “identifying” problems. Recommendation: Upper level classes’ content be examined to ascertain where increased exposure to the need to “identify” problems can be included or the ability to “identify” problems can be discussed. [Action: ECE faculty teaching ECE 4xx courses and Engineering Problems Outcome faculty team.]

(f) an understanding of professional and ethical responsibility Based on Course Assessments; and IT&E Senior Surveys:

All students recognize aspects of professional and ethical responsibility Recommendations: No changes. Continue appropriate emphasis. (g) an ability to communicate effectively

Based on Project Reports; Course Assessments; Student and Faculty Evaluations; and IT&E Senior Surveys:

Students are able to communicate technical material adequately in writing and orally when they graduate.

Recommendations:

1. Include COMM 100, Public Speaking, in the Computer Engineering Program. [Action: CpE faculty.]

2. Establish a requirement for a written work portfolio. [Action: ECE faculty]

3. Consider how ENGL 302, Advanced Composition, performance can be integrated into, or be prerequisite for, aspects of the program. [Action: Communications Outcome faculty team.]

(h) the broad education necessary to understand the impact of engineering solutions in a global and societal context

Based on IT&E Senior, ECE Alumni (only EE responses, but the programs are quite similar) and GMU Senior Surveys:

Students feel strongly that they do have an understanding of the impact of engineering solutions in a global and societal context.

Recommendation: No changes in the program, but do recommend a continued and perhaps broadened use of technical classes to discuss global and societal impacts of both the technology and decisions/solutions involving the technology. [Action: all faculty.] (i) a recognition of the need for, and an ability to engage in life-long learning

Based on Course Assessments; IT&E Senior and ECE Alumni (only EE responses, but the programs are quite similar) Surveys; ECE graduate classes’ demographics:

All students respond in a manner that reflects knowledge of both the need for and the ability to pursue line-ling learning.

Recommendations:

1. Arrange for more student-alumni interaction. [Action: Life-long Learning Outcome faculty team.]

2. Track student activities in graduate work. [Action: Associate Chair.]

3. Encourage course activities encouraging use of web-based research. [Action: all faculty.]

(j) a knowledge of contemporary issues

Based on In-class, ECE Alumni (only EE responses, but the programs are quite similar) , and IT&E Senior Surveys:

Recommendation: No program changes are recommended, but it is recommended that faculty present information showing how contemporary issues are involved in

technology. [Action: all faculty.]

(k) an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.

Based on Resumes; Course Assessments; IT&E Senior, GMU Senior, and ECE Alumni (only EE responses, but the programs are quite similar) Surveys:

All students have developed good ability with a range of software and hardware techniques, skills and modern engineering tools.

Recommendation: No change. Ensure course tools remain at the forefront of technology. (l) a knowledge of the use of cutting-edge technologies and advanced systems in use in industry

Based on Resumes; Senior Level Design Projects; Fall 2000 Undergrad Survey: Graduating students demonstrate a reasonable knowledge of cutting-edge technologies and advanced systems.

Recommendations:

1. Consider ways to better integrate work experience with academic activities. [Action Cutting-edge Outcome faculty team.]

2. Require/encourage “cutting-edge technologies” or “advanced systems” to be part of Senior Level Design Projects. [Action: ECE faculty.]

It is recommended that the following six Outcomes be reviewed in Spring 2001, initiating the biannual review cycle.

(a) an ability to apply knowledge of mathematics, science and engineering (d) an ability to function on multi-disciplinary teams

(g) an ability to communicate effectively

(h) the broad education necessary to understand the impact of engineering solutions in a global and societal context

(i) a recognition of the need for, and an ability to engage in life-long learning

Electrical Engineering Program Outcomes Assessments Summary

Fall 2000

-The formal documentation of the assessment process has just been implemented, the process for collecting high quality data is in place for continuous process improvement.

Based on data from courses involving electrical engineering students, from surveys of ECE classes required by electrical engineering students, from surveys of alumni and employers of the electrical engineering program, the Electrical Engineering Program Outcomes were assessed. (a) an ability to apply knowledge of mathematics, science and engineering

Based on course Assessments; IT&E Senior and ECE Alumni Surveys: All students demonstrate the ability to apply math, science and engineering. Recommendations:

1. Work with the Math and Physics Departments to include more pertinent electrical engineering problems into the basic math and science curriculum. [Action: Math/Science Outcome faculty team.]

2. Consider introducing material into technical elective courses to extend students’ abilities to apply knowledge of VLSI design and testing , high performance computing, and computer-network design and analysis. [Action: CpE faculty.]

(b) an ability to design and conduct experiments, as well as to analyze and interpret data Based on lab reports and IT&E Senior and ECE Alumni and Employer Surveys: Students have demonstrated good performance conducting experiments and analyzing and interpreting data, and acceptable performance on designing experiments.

Recommendations:

1. Revise additional lab manuals to reduce stet-by-step procedures and to require students to design the experiments and experimental setups. [Action: Lab courses Coordinating Faculty.]

2. Prepare sample Lab Report formats to encourage more data interpretation. [Action: Undergraduate Committee.]

(c) an ability to design a system, component, or process to meet desired needs

Based on Design Projects; Course Assessments; and IT&E Senior, ECE Alumni and Employer Surveys:

Most graduating students have mastered the of automated design tools and have successfully applied them to design a system, component or process to meet desired needs.

Recommendations:

CpE/EE Programs) to ensure the percent of students successfully using them rises as thee experience with them increases. [Action: ECE 332, ECE 445 and ECE 447 instructors.] 2. Establish a standing committee to review design project abstracts in order to establish quality control and assess the level of design which is in these projects in order to maintain it at the existing high level. [Action: Design Outcome faculty team.] (d) an ability to function on multi-disciplinary teams

Based on Senior Design Projects; Course Assessments: and Fall 2000 Undergrad, IT&E Senior, ECE Alumni, and Physics and ECE 492/493 faculty Surveys:

Students are able to successfully work in team environments. Recommendations:

1. Include requirement for project teams in ECE 492/493. [Action: all faculty.]

2. Encourage interaction with industry via student organization activities and seminars. [Action: Teaming Outcome faculty team.]

3. Develop new Assessment tool of Entrance/Exit Surveys for courses involving teams and Survey questions related to coop/intern/part-time/full-time work teaming

experiences. [Action: Teaming Outcome faculty team.] ( e) an ability to identify, formulate, and solve engineering problems

Based on Design Projects; IT&E Senior, ECE Alumni and GMU Senior Surveys: By graduation all but a few students can identify, formulate and solve engineering

problems. The aspect that more students show lesser ability is in “identifying” problems. Recommendation: Upper level classes’ content be examined to ascertain where increased exposure to the need to “identify” problems can be included or the ability to “identify” problems can be discussed. [Action: ECE faculty teaching ECE 4xx courses and Engineering Problems Outcome faculty team.]

(f) an understanding of professional and ethical responsibility

Based on Course Assessments; and IT&E Senior and ECE Alumni and Employers Surveys:

All students recognize aspects of professional and ethical responsibility Recommendations: No changes. Continue appropriate emphasis. (g) an ability to communicate effectively

Based on Project Reports; Course Assessments; Student and Faculty Evaluations; and IT&E Senior and ECE Alumni and Employer Surveys:

when they graduate. Recommendations:

1. Establish a requirement for a written work portfolio. [Action: ECE faculty]

2. Consider how ENGL 302, Advanced Composition, performance can be integrated into, or be prerequisite for, aspects of the program. [Action: Communications Outcome faculty team.]

(h) the broad education necessary to understand the impact of engineering solutions in a global and societal context

Based on IT&E Senior, ECE Alumni and GMU Senior Surveys:

Students feel strongly that they do have an understanding of the impact of engineering solutions in a global and societal context.

Recommendation: No changes in the program, but do recommend a continued and perhaps broadened use of technical classes to discuss global and societal impacts of both the technology and decisions/solutions involving the technology. [Action: all faculty.] (i) a recognition of the need for, and an ability to engage in life-long learning

Based on Course Assessments; IT&E Senior and ECE Alumni Surveys; ECE graduate classes’ demographics:

All students respond in a manner that reflects knowledge of both the need for and the ability to pursue line-ling learning.

Recommendations:

1. Arrange for more student-alumni interaction. [Action: Life-long Learning Outcome faculty team.]

2. Track student activities in graduate work. [Action: Associate Chair.]

3. Encourage course activities encouraging use of web-based research. [Action: all faculty.]

(j) a knowledge of contemporary issues

Based on In-class, ECE Alumni, and IT&E Senior Surveys:

Most students indicate that they have a sufficient knowledge of contemporary issues. Recommendation: No program changes are recommended, but it is recommended that faculty present information showing how contemporary issues are involved in

technology. [Action: all faculty.]

(k) an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.

and Employers Surveys:

All students have developed good ability with a range of software and hardware techniques, skills and modern engineering tools.

Recommendation: No change. Ensure course tools remain at the forefront of technology. (l) a knowledge of the use of cutting-edge technologies and advanced systems in use in industry

Based on Resumes; Senior Level Design Projects; Fall 2000 Undergrad Survey: Graduating students demonstrate a reasonable knowledge of cutting-edge technologies and advanced systems.

Recommendations:

1. Consider ways to better integrate work experience with academic activities. [Action Cutting-edge Outcome faculty team.]

2. Require/encourage “cutting-edge technologies” or “advanced systems” to be part of Senior Level Design Projects. [Action: ECE faculty.]

It is recommended that the following six Outcomes be reviewed in Spring 2001, initiating the biannual review cycle.

(a) an ability to apply knowledge of mathematics, science and engineering (d) an ability to function on multi-disciplinary teams

(g) an ability to communicate effectively

(h) the broad education necessary to understand the impact of engineering solutions in a global and societal context

(i) a recognition of the need for, and an ability to engage in life-long learning

Computer Engineering Program and Electrical Engineering Program

Objectives Assessments Summary

(Scheduled for Spring 2003)

-The assessment process has just been implemented. -The present Objectives (which are the same for both the Computer Engineering and the Electrical Engineering Programs) were based on the 1994 Electrical Engineering Program Objectives, and, in their present, modified, form, were given final approval in Spring 2000. We are confident that these Objectives are appropriate for our programs now and for the next three years. Consequently, unless assessment of the derived Outcomes indicates serious problems, we will plan on a Spring 2003 (3 years) thorough review of the Objectives.

Computer Engineering Program Change

Fall 1998

-Program Initiation

During 1997, the faculty developed the Computer Engineering Program. The ECE Department faculty approved the program on September 3, 1997.

This Program was approved December 1, 1997 by the School of Information Technology and Engineering

The Program was approved by the GMU Board of Visitors during Spring 1998.

On June 12, 1998 the Program was approved by the State Council of Higher Education for Virvinia (SCHEV).

Electrical Engineering Program Change

Fall 1999

-Communications Requirement

During Spring 1999, the previous option of taking either public speaking or a “technical writer” oriented Technical Report Writing course was considered and removed, and the public speaking course was specifically required.

Feedback Sources

This change resulted from feedback from several directions. Interaction with industry managers and alumni “in the field” (i.e. via the “Off sITE Conversations” trips to companies coordinated by the George Mason Career Services Office) communicated that speaking was really more of a problem than writing. Talking to students during advising showed that they were more

“concerned” or “scared” to get up in front of others and make presentations than they were about writing. This was primarily either because they had not done this type of speaking or they had not had instruction in doing it.

Effective Date

Electrical Engineering Program Change

Fall 1997

-First Two Years Curriculum Redesign

A team of faculty examined the first two years of the electrical engineering curriculum and proposed a broad redesign that was subsequently implemented in Fall 1997.

To motivate and excite freshmen about the field of electrical engineering we introduced a new course, ECE 101, Introduction to Information Technology. This course with web

documented lectures and with lab experiments, gives an introduction to electrical engineering from the point of view of modern communications. The course has become very successful and it is now also taught (in a simplified form) to non-engineering students in the Information Technology Minor program.

Feedback Source

In student surveys of “challanging” courses, ECE 285, Circuit Analysis I, the first ECE course student experienced was often mentioned. Faculty were concerned that retention could be affected.

To provide an early introduction to mathematical and computational tools of electrical engineering, we introduced a new course at the sophomore level, ECE 201, Introduction to Electrical Engineering.

Feedback Source

An early support for creating this new course came from feedback from students who indicated that the lab-only course on MATLAB that we were presenting did not seem to prepare them adequately to perform in the subsequent signals and systems course.

To provide students with a solid background in the important area of signals and systems, we created two new courses, ECE 220 and ECE 320, which covered continuous signals and discrete signals respectively. These courses replaced the single Signals and Systems course that had been designed to cover continuous analysis and some discrete analysis.

Feedback Source

These new courses also reflected the input to faculty from our alumni (often in conversations with faculty teaching the graduate classes that these alumni were now taking) who indicated that more of the discrete signals and systems (z-transform) techniques were needed by industry

To provide students with more interesting hands-on lab experience earlier in their electrical engineering program we created a new course, ECE 280, Electric Circuit Analysis, which included a laboratory component as well as covering most of the lecture material previously contained in the two semester electric circuit analysis sequence.

Feedback Source

This also reflected feedback from graduating seniors via the Senior Seminar survey questions in which the seniors indicated that they really felt they could benefit from more and earlier lab experience. The redesign of the lecture content reflected the feedback from alumni regarding the material they used (and did not use) when first starting out in their careers after graduation.

Additional Valuable Feedback

Additionally, we obtained feedback from long term, experienced, industry managers which led us to understand that our earlier decision to eliminate the full 4xx level breadth of the electrical engineering program had disadvantages both for industry and for our graduates’ long-term careers. This feedback indicated that industry did need engineers with this type of breadth, both to bring a full range of ideas and knowledge to the design team, and for flexibility of job

assignments within projects or companies. Consequently this “feedback on a change” allowed us to make the necessary correction right away by again requiring all four of the upper level foundation courses (ECE 421, ECE 433, ECE 445, ECE 460).

Summary

Consequently, by using knowledge of the new ABET accreditation criteria, having time to propose and develop new courses, using feedback from industry managers (a constituency that had not been thoroughly surveyed in early Spring), informal feedback from students in the first half of their program, and further feedback from alumni and seniors, we were able to create an exciting redesign of the curriculum.

Effective Date

This change became effective in Fall 1997.

Follow-on Feedback

We have already had feedback from seniors via the Senior Seminar survey questions (in 1998-99) that the ECE 201 - ECE 220 sequence is definitely working. They understand more when the MATLAB tool is integrated with theory and application examples and problems.

Electrical Engineering Program Change

Fall 1996

-Reduction to 120 Credit Hours

During the early part of Spring semester, 1996 the program was reduced from 129 hours to 120 hours. This was accomplished by reviewing feedback from seniors which had been obtained via the survey questions at the end of the Senior Seminar course and via surveys of alumni regarding their initial job positions and need for specific knowledge at that time.

Action: The Digital Circuit Design course was moved from a category of “required” to

“technical elective”.

Feedback supporting action: This decision was based on electrical engineering graduates

indicating that it was more “device detailed” than was needed for entry level positions in Northern Virginia.

Action: The requirement to take all four of the 4xx level courses that “capped” the basic

knowledge of the foundation or core areas was reduced to a requirement to take any three.

Feedback supporting action: Both seniors and alumni indicated that required breadth at the

4xx level, if it precluded taking some student-preferred technical elective, was not necessary or in the best interests of graduates looking for their first position and who needed to demonstrate a higher level of knowledge in a specific electrical engineering area to get their preferred jobs.

Action: The Engineering Economics course was removed, but one of the existing Social Science

elective courses which was part of the General Education requirement was changed to a required Economics course in order to maintain a knowledge of the importance of economics on

engineering in industry.

Effective Date

Computer Engineering and Electrical Engineering Programs

School of Information Technology and Engineering

Quality Assurance Process

Initiated or Scheduled Comments Process Steps

Done _{Fall 00}

Spring 01 Fall 01 Spring 02 Fall 02 Spring 03 Fall 03

Review mission of GMU

and Undergrad IT&E X X Every 3 years or whenever GMU or IT&E specificallyannounce a change. By ECE Undergrad Committee (EUC).

Identify/Review Program

Objectives X X

Approved by Industrial Advisory and Student Committees in 2000. Every 3 years. By EUC. Determine/Review Program

Outcomes X X X

Every 2 years. By EUC. Identify/Review learning

experiences for Program

Outcomes X X X X

Each year ½ of the Outcomes will be Assessed and appropriate Reviews conducted by each Outcome Faculty Team and EUC.

Determine/Review assessment strategies for each Program Outcome

X X X X Each year ½ of the Outcomes will be Assessed andappropriate Reviews conducted by each Outcome Faculty Team and EUC.

Develop feedback process to incorporate assessment findings into curriculum revision process

X X

Feedback process of Course Assessments to subsequent instructors; Outcomes Assessments to ECE Undergrad. Committee to ECE faculty not expected to change. Will be reviewed in 2002 and every 4 years by EUC. Develop/Review assessment

instruments for each

Program Outcome X X X

Instruments (surveys, student work, focus groups) will be reviewed for “effectiveness” along with first overall review of Outcomes Assessments. Then every two or three years. By each Outcome Faculty Team and EUC. Conduct Course assessments

by collecting, analyzing, and interpreting data

X X X X X X X X Every semester a course is offered. By instructor. Accomplish non-course

assessment instruments _{X X X X X X X X}

Each semester: Graduating Seniors GMU and IT&E (EBI) Survey; Senior Project Self-Evaluations. Each year: ECE Alumni/Supervisor Survey. By Department personnel.

Conduct Outcomes assessments by collecting, analyzing, and interpreting data

X X X X

Each year ½ of the Outcomes will be Assessed by each Outcome Faculty Team and EUC.

Use assessment results in curriculum revision process

X X X X X X X X

Course Assessments will be reviewed by subsequent course instructor. Major recommendations will be passed by instructor to EUC. Outcome Assessments (½ each year) will be reviewed by EUC and

recommendations passed on to Chair or faculty as appropriate.

Conduct Objectives

assessments X X Every two years in light of assessments of allOutcomes. By EUC with report to faculty; Advisory Committees.

Program Assessment Plan

for

Computer Engineering and Electrical Engineering

Assessment of the Computer Engineering Program and Electrical Engineering Program is accomplished by assessment of the Program Educational Objectives established for the Programs. This assessment may lead to changes in how the Program Objectives are

accomplished, or in how subsequent assessments are accomplished, or in the Program Objectives themselves, in order to improve the Programs. While assessment of aspects of the Programs in general is a continuous, on-going, “informal” process by the faculty, this Plan establishes a formal, documented, structure that addresses the assessment of each entire Program on a periodic schedule.

The Program Objectives are supported by more detailed Program Outcomes. Assessment of Program Outcomes is accomplished by periodic assessments of evidence supporting the Outcomes. This evidence may include information such as Instructor Course Assessments; student work; surveys of “in-process” students, graduating students, alumni, supervisors of alumni, industry representatives and faculty; student, alumni and industry committees, “focus” groups and panels; and informal interaction between faculty and students, alumni and industry representatives. These assessments may lead to changes in how the Program Outcomes are accomplished, or in how subsequent assessments are accomplished, or in the Program Outcomes themselves, in order to improve the Programs. Such changes may be reflected in changes in course content or presentation, changes in Program/Degree requirements, changes in procedures for faculty/student interaction, changes in extra-curricular opportunities for students, or in other aspects of the Programs that could contribute to an improvement in the Programs.

Program Educational Objectives – Achievement and Assessment

The Program Objectives are addressed throughout the courses making up the curriculum and through extra curricular opportunities such as industry trips and presentations and student organizations.

Achievement of Program Objectives is determined by analysis of the assessments of the Program Outcomes. Program Outcomes and Program Educational Objectives (presented later) shows how the general Program Objectives are mapped onto the more specific Program Outcomes. The Program Objectives are reviewed every three years in the Spring semester by the Undergraduate Curriculum Committee considering input from the Department Advisory Committee, the ECE Undergraduate Student Advisory Committee and faculty, and data from assessments of the Program Outcomes. Recommended changes are presented to the entire Department faculty for consideration and approval, with final review by the ECE Department Advisory Committee and student groups each Fall. The final Program Objectives are then published in the George Mason University catalog and other appropriate media. Any changes in

curriculum needed as a result of Program Objectives changes are then addressed, starting with the Undergraduate Curriculum Committee.

ECE Department Advisory Committee

The ECE Department Advisory Committee has the responsibility for reviewing existing and proposed Departmental Mission and Objectives statements and degree and certificate programs, and providing input to the Department on these or other issues of interest. The ECE Department Advisory Committee is composed of:

1. Dr. Harry Dietrich, Head, High Frequency Materials and Devices Section, Naval Research Laboratory

2. Mr. Bruce Gallemore, Vice President, Technologies Division, Digital System Resources, Inc.

3. Mr. Tom Krappweis, Senior System Engineering Manager, Lockheed-Martin Federal Systems Inc.

4. Dr. Sumner Matsunaga, General Manager, Electronic Systems Directorate, The Aerospace Corporation

5. Mr. Hank Orejuela, Vice President, Information and Advanced Systems, Raytheon Systems Company

6. Dr. Donald Reago, Director, Science and Technology Division, Night Vision Laboratory, US Army

7. Mr. Paul Tatum, Regional Systems Engineering Manager, Service Providers, Southern Area, Sun Microsystems

8. Mr. Carroll Wright, Chief Technologist, government Solutions, Lucent Technologies.

ECE Undergraduate Student Advisory Committee

The ECE Undergraduate Student Advisory Committee has the responsibility for making

recommendations regarding the curriculum, standards, and academic policies of the Department. The ECE Undergraduate Student Advisory Committee is composed of:

1. Mr. Varun Aggarwal, Junior, Computer Engineering 2. Ms. Sheila Anwari, Junior, Electrical Engineering

3. Ms. Christine Huynh, Senior, Computer Engineering, Vice Chair 4. Mr. A. Glenn Richardson, Senior, Electrical Engineering

5. Dr. Alok Berry, ECE Department Representative

6. Dr. William Sutton, ECE Department Representative, Chair

The Program Outcomes are addressed throughout the courses making up the curriculum and through extra curricular opportunities such as industry trips and presentations and student organizations.

Achievement of Program Outcomes is determined by analysis of the assessments of appropriate evidence supporting the Outcomes. This evidence may include information such as Instructor Course Assessments; student work; surveys of “in-process” students, graduating students, alumni, supervisors of alumni, industry representatives and faculty; student, alumni and industry committees, “focus” groups and panels; and informal interaction between faculty and students, alumni and industry representatives. These assessments may lead to changes in how the

Program Outcomes are accomplished, or in how subsequent assessments are accomplished, or in the Program Outcomes themselves, in order to improve the Programs. Such changes may be reflected in changes in course content or presentation, changes in Program/Degree requirements, changes in procedures for faculty/student interaction, changes in extra-curricular opportunities for students, or in other aspects of the Programs that could contribute to an improvement in the Programs. The Computer Engineering Program Outcomes and Curriculum Courses table (presented later) shows the mapping of Program Outcomes onto curricula courses – both technical courses and as part of the general education component.

The Program Outcomes are reviewed on a bi-annual basis (half the Outcomes are reviewed each year) in the Fall semester, by teams of ECE faculty assigned to each of the Outcomes,

considering evidence as mentioned above. Recommended changes are included in the Outcome Assessment Recommendation/Summary for use in the review and assessment of Program Objectives. Any recommendations that are course/instructor specific are immediately addressed to the course instructor. Any changes in curriculum needed as a result of the assessment of Program Outcomes are addressed to the Undergraduate Curriculum Committee. Major changes by the faculty are reviewed by the ECE Department Advisory Committee and student groups.

Assessment Measures

To provide information from which to draw assessment conclusions the following are used. Course exams and homework

Questionnaires/quizzes in follow-on courses Project and laboratory reports

Presentation evaluations Surveys

a. Senior surveys (administered by: GMU, IT&E and ECE) b. Alumni surveys (administered by: GMU and ECE) c. In-progress student surveys

d. Student focus group comments (ECE Undergraduate Student Advisory committee, student organizations)

e. Course evaluations by students

f. Industry surveys (from Career Services Office and as an adjunct to alumni surveys)

Assessment Process

The primary on-going assessment process involves each course instructor, for each offering of each course and section, gathering evidence of student performance (exams, homework, lab and project reports, project and presentation evaluations, faculty evaluations) related to each of the Outcomes identified for that course and making an instructor-assessment of the performance of students in each of the Outcomes. This Course Assessment is prepared at the end of the semester and will consider the prior Course Assessments plus student work and observations from the course offering. The Course Assessment plus the supporting examples of student work will be added, prior to the start of the next semester, to the Course Assessment Notebook maintained in the Department Library. Recommendations for “obvious” or urgent changes which an instructor could make are immediately provided to the subsequent offering instructor.

In early Spring this Outcomes-oriented Course Assessment material is provided to the

appropriate ECE faculty “Outcome Teams”. The results of surveys are added to each Outcome Notebook as the data becomes available. Senior surveys are done at the School of IT&E level in conjunction with the graduation application process. Results are subsequently provided to the Programs. The University administers a Senior Survey at the time of graduation. The results of this survey are made available to the Schools and Departments shortly after the end of the semester. The University also administers Alumni surveys. Results are subsequently provided to the Programs. Alumni surveys and Industry surveys are done by the ECE Department,

normally during late Spring/early Summer. Committee/group minutes are added to the Outcome Notebook as appropriate. Student focus groups are organized, as needed, by the Department Associate Chair during the regular academic year, taking advantage of student organizations’ volunteers. The faculty Outcome Team, during every other Spring, examines the prior Outcome Assessments, and material from the previous two years (two sets of Spring, Summer, Fall) and prepares an updated Outcome Assessment. The new Outcome Assessment plus selected supporting examples of student work are then added to the Outcome Assessment Notebook maintained in the Department Library.

Each Summer/Fall the six new Outcome Assessments will be compiled by the Undergraduate Curriculum Committee and an annual report will be prepared and will be provided to the faculty, the Department Advisory Committee and to the ECE Undergraduate Student Advisory

Committee. Recommendations for making improvements to the Programs will be included as appripriate.

The faculty will take action on the recommendations. The Department Advisory Committee and the ECE Undergraduate Student Advisory Committee will review and comment on the Report back to the Undergraduate Curriculum committee and the faculty.

Computer Engineering Program Educational Objectives

The objectives of the Computer Engineering Program are as follows:

The program educational objectives of the Computer Engineering program are to:

1. provide students with the fundamental knowledge and methodologies of electrical or computer engineering, including the opportunity to learn appropriate experimental and computational tools, essential for a successful career.

2. provide students with an awareness of, and skills in, life-long learning and self education. 3. cultivate teamwork, technical writing and oral communication skills.

4. provide students with an appreciation of engineering's impact on society and the professional responsibilities of engineers.

5. provide students with an opportunity to acquire an understanding of the engineering

profession and to observe the use of cutting-edge technologies and advanced systems in use in industry through direct interaction with industry, including internships and cooperative education experiences.

These objectives are consistent with the mission and objectives of the University, the School of Information Technology and Engineering, and the Electrical and Computer Engineering

Department.

The Mission Of George Mason University

“George Mason University will be an institution of international academic reputation providing

a superior education enabling students to develop critical, analytical, and imaginative thinking and to make well founded ethical decisions. The university will prepare students to address the complex issues facing them in society and to discover meaning in their own lives. The university will be a resource of the Commonwealth of Virginia serving private and public sectors and will be an intellectual and cultural nexus between Northern Virginia, the nation, and the world. “

Undergraduate Education Mission and Goals of the School of Information Technology and Engineering

“The Undergraduate Education mission of the School of Information Technology and

Engineering (IT&E) is to provide a quality education in support of the needs of Virginia and the nation.”

The goal of the School of Information Technology and Engineering undergraduate programs is to graduate students that:

1. Are technically competent;

2. Are prepared for ethical professional practice; 3. Can communicate effectively;

4. Can work as members or leaders of technical teams; 5. Are prepared for a lifetime of learning; and

6. Understand the global nature and impact of information technology and engineering.

Undergraduate Education Mission of the Electrical and Computer Engineering Department

“The undergraduate education mission of the Electrical and Computer Engineering Department

is to provide a quality education for electrical engineering and computer engineering students in support of the needs of Virginia and the nation.”

Constituencies of the Computer Engineering Program

The significant constituencies of the computer engineering program are:

Undergraduate Computer Engineering Students: The undergraduate computer engineering

students are represented by students enrolled in ECE classes, members of student organizations, and the ECE Undergraduate Student Advisory Committee (USAC). Selected from student applications, the members of the USAC are tasked with making recommendations regarding the curriculum, standards, and academic policies of the Department. This organization is one of the primary interfaces with the undergraduate computer engineering student constituents.

Computer Engineering Alumni: The computer engineering graduates/ alumni are represented

by the ECE Alumni Association and by alumni enrolled in ECE graduate programs’ classes. The ECE Department Alumni Association has as one of its mission goals to provide advice and ideas to the department related to programs within the department. Many computer engineering graduates remain in the Northern Virginia area. These individuals return to George Mason for their graduate work. When in ECE classes, they “chat” with the ECE faculty regarding their work experiences.

ECE Departmental Faculty: The faculty are involved via committees (Undergraduate

Curriculum Committee, Awards Committee, Undergraduate Recruitment Committee) and as the Department-as-a-whole.

Industry, Government and Academia: These constituents are involved via the ECE

Department Advisory Committee and graduate students enrolled in graduate level courses. The ECE Department Advisory Committee has the responsibility of reviewing existing and proposed Departmental Mission and Objectives statements and degree and certificate programs, and providing input to the Department on these or other issues of interest.

Development of Computer Engineering Program Objectives

The present computer engineering Program Objectives were initially proposed during the program’s first semester, Fall 1998, (following the official approval of the program by the State Council of Higher Education for Virginia - SCHEV - in Spring 1998) as revisions to the

electrical engineering Program Objectives of 1994 which had been used in creating the computer engineering program. These revised objectives were initiated by the Undergraduate Curriculum Committee, a standing committee appointed by the Department Chair each year. The Committee consists of four faculty, representing the four major areas of electrical and computer engineering within the department: electronics, computer engineering, communications/ signal processing and controls/robotics. This committee is responsible for course and curriculum development proposals for presentation to the Department-as-a-whole. The proposed Program Objectives were distributed to and discussed by the Department-as-a-whole and approved via vote in December 1998.

Subsequently these Program Objectives were presented to the ECE Department Advisory Committee for review and comment in Spring 2000. The Advisory Committee provided input regarding aspects of the Objectives that should receive emphasis and followed this with an expression of approval of the Program Objectives as presented to the Committee. This cycle resulted in the addition of a specific mention of direct observation and interaction with industry. These objectives are published in the University catalog, in the advising handbook and on the computer engineering program web page.

While the original Program Objectives had been developed by faculty having informal

interaction with the undergraduate computer engineering students, formal discussions were held with members of student organizations such as Eta Kappa Nu and the student chapter of IEEE. In each case the student reaction was of approval of the range and content of the Program Objectives.

Computer Engineering Program Outcomes and Assessment

In order to facilitate Program Assessment, more detailed Program Outcomes were established supporting the Program Educational Objectives. The twelve Program Outcomes (a-l) are: (a) an ability to apply knowledge of mathematics, science, and engineering

(b) an ability to design and conduct experiments, as well as to analyze and interpret data (c) an ability to design a system, component, or process to meet desired needs

(d) an ability to function on multi-disciplinary teams

(e) an ability to identify, formulate, and solve engineering problems (f) an understanding of professional and ethical responsibility (g) an ability to communicate effectively

(h) the broad education necessary to understand the impact of engineering solutions in a global and societal context

(i) a recognition of the need for, and an ability to engage in life-long learning (j) a knowledge of contemporary issues

(k) an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.

(l) a knowledge of the use of cutting-edge technologies and advanced systems in use in industry The Program Outcomes a-k listed above relate directly to the outcome requirements of

Accreditation Board for Engineering and Technology (ABET) EC 2000 Criterion 3a-k. Program Outcome l is unique to the George Mason program.

The relation of the a-l Program Outcomes, above, to the five Program Educational Objectives is shown in the Computer Engineering Program Outcomes and Program Educational Objectives table.

Program Outcomes and Program Educational Objectives

Outcomes Apply knowledge of math, science and engineering Design and conduct experiments, as well as to analyze and interpret data Design a system, component, or process to meet desired needs Function on a multi-disciplinary team Identify, formulate, and solve engineering problems Understand professional and ethical responsibility Communicate effectively Broad education necessary to understand the impact of engineering solutions in a global and societal context Recognize the need for, and ability to engage in life-long learning Knowledge of contemporary issues Use the techniques, skills, and modern engineering tools necessary for engineering practice Have knowledge of the use of cutting-edge technologies and advanced systems in use in industry Objectives

%

_%

_%

_%

_%

_%

provide students with the fundamental knowledge and methodologies of electrical or computer engineering, including the opportunity to learn appropriate experimental and computational tools, essential for a successful career.

provide students with awareness of, and skills in, life-long learning and

self education

%

%

%

%

%

cultivate teamwork, technical writing

and oral communication skills.

%

%

provide students with an

appreciation of engineering's impact on society and the professional

responsibilities of engineers

%

%

%

provide students with an opportunity to acquire an understanding of the engineering profession and to observe the use of cutting-edge technologies and advanced systems in use in industry through direct interaction with industry, including internships and cooperative education experiences

Assessment of Computer Engineering Program Outcomes

Outcome a: an ability to apply knowledge of mathematics, science, and engineering

This outcome is addressed by mathematics, basic sciences, and all the engineering and computer science courses. This is the core of an engineering education.

Assessed by performance on exams and assignments in courses. Assessed by questionnaires or quizzes in follow-on courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome b: an ability to design and conduct experiments, as well as to analyze and interpret data

This outcome is addressed by the basic sciences’ labs, the core courses with accompanying labs (ECE 201, 220, 280, 333, 334, 331, 332, CS 112) and upper level/advanced labs ECE 434, 435, 429, 447, 449)

Assessed by performance as shown in lab reports and assignments in courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome c: an ability to design a system, component, or process to meet desired needs

This outcome is addressed by a mixture of core courses (ECE 280, 220, 333, CS 112, 211, 310) and upper level (ECE 442, 445, 447) courses.

Assessed by performance as shown in project reports and assignments in courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome d: an ability to function on multi-disciplinary teams

This outcome is addressed by a number of courses from the freshman level to the Senior Capstone course. 1. The freshman ENGR 107, Engineering Fundamentals, course involves students in group projects while being mentored by juniors and seniors. This results in a wide range of types of students (40% of ENGR 107 students are not declared engineering students) as well as capabilities.

2. The physics labs are team-lab courses. These teams can consist of engineers, physicists, computer science students as well as other non-engineering disciplines.

3. CS 310 has students working on large software programs in a team environment, composed of hardware and software oriented students.

software strengths, who bring a variety of skills to the team. Assessed directly in surveys of students and alumni.

Outcome e: an ability to identify, formulate, and solve engineering problems

This outcome is addressed throughout the curriculum, particularly in ECE 220, 331, 333, 433 and then in the Senior Capstone Project. Problems in the mathematics, physics and computer science courses also involve engineering problem solving.

Assessed by performance on project, assignments and exams in courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome f: an understanding of professional and ethical responsibility

This outcome is addressed in a number of courses. Throughout the curriculum the GMU Honor Code is

emphasized. It's applicability to homework, team projects and exams is discussed. Some ECE faculty require a written essay on the Engineering Code of Ethics and the GMU Honor Code. ENGR 107, Engineering

Fundamentals, presents ethics as related to product development. ECE 491, Engineering Seminar, has a presentation on Professional Engineering Registration - procedures, values. ECE 491, Engineering Seminar, has a presentation/participation activity on "office" ethics as well as a presentation/discussion on professional engineering ethics. Students are evaluated on the "office" ethics participation activity and are required to respond to short answer questions on Professional Registration and the Engineering Code of Ethics in the final exam.

Assessed by performance on assignments and exams in courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome g: an ability to communicate effectively

This outcome is addressed in the freshman and junior level composition courses, two literature courses, lab and project reports, the Senior Seminar, ECE 491, course and by the two Writing Intensive courses, one of which is the Senior Capstone Project which involves both written and oral reports.

Assessed by presentation evaluations, performance on the ECE 491 presentations and via project and lab reports. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

and societal context

This outcome is addressed by the general education component of the program, in ENGR 107 by outside speakers, directly in ECE 491 and informally throughout the curriculum by faculty injecting references to the globalization of technology.

Assessed in surveys of students and alumni.

Outcome i: a recognition of the need for, and an ability to engage in life-long learning

This outcome is addressed to some extent in the majority of the required major related courses, but it is

specifically addressed in ECE 491, in which a short term, 5-year and 10-year goal Career Plan is prepared. This outcome is also addressed in all incoming computer engineering orientation programs.

Assessed and documented by ECE 491 Career Plan. Assessed directly in surveys of students and alumni.

Outcome j: a knowledge of contemporary issues

This outcome is addressed by the general education component of the program. Instructors in upper level courses also are encouraged to relate the course material to problems they are aware of via their research. Assessed in surveys of students and alumni.

Outcome k: an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice

This outcome is addressed by most of the curriculum technical courses. The current policy, based on

discussions with students and industry representatives, is to integrate analysis, design and simulation tools used in industry (C++, MATLAB, VHDL, SPICE) in all appropriate courses.

Assessed by performance on projects, assignments and Senior Capstone Projects. Documented through supporting material collected from course instructor.

Assessed in surveys of students and alumni.

Outcome l: a knowledge of the use of cutting-edge technologies and advanced systems in use in industry

This outcome is addressed in senior technical electives, Senior Capstone Project and by regularly scheduled trips to the high tech companies surrounding George Mason.

Computer Engineering Program Outcomes and Curriculum Courses

Computer Engineering Program

M A TH 125 M A TH 113 M A TH 114 M A TH 213 M A TH 214 M A TH 203 STAT 344 PH YS 160/250 PH YS 260/350 PH YS 261/351 PH YS 262/352 ENGR 107 CS 1112 C S 211 C S 265 C S 310 C S 471 EC E 201 EC E 220 EC E 280 EC E 331 EC E 332 EC E 333 EC E 334 EC E 431 EC E 445 EC E 442 EC E 447 EC E 449 EC E 462 or C S 455 TEC H ELEC TEC H ELEC TEC H ELEC EC E 491 TEC H ELEC LAB

ENGL 101 ENGL 302 LIT ELEC

( 2 ) ECON 103 AR EA C ELEC H U M /SS ELEC CRITERIA

Apply knowledge of math, science and

engineering T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T Design and conduct experiments, as

well as to analyze and interpret data T T T T T T T T T T T T

Design a system, component, or

process to meet desired needs T T T T T T T T T T T T T T T T T T T T T T

Function on a multi-disciplinary team _{T T T T}

Identify, formulate, and solve

engineering problems T T T T T T T T T T T T T T T T T T T T T T T

Understand professional and ethical

responsibility T T T T T T T T

Communicate effectively _{T T T T T T T T T T T T T T T T T T T T T T T T T}

Broad education necessary to understand the impact of engineering solutions in a global and societal context

T T T T T T T T T

Recognize the need for, and ability to

engage in life-long learning T T T T T T T T T T T T T T T T T T T T T T T T T T T T T

Knowledge of contemporary issues _{T T T T T T T T}

Use the techniques, skills, and modern engineering tools necessary for engineering

practice T T T T T T T T T T T T T T T T T T T T T T T T T T T T T T

Have knowledge of the use of cutting-edge technologies and advanced systems in use

Electrical Engineering Program Educational Objectives

The objectives of the Electrical Engineering Program are as follows:

The program educational objectives of the Electrical Engineering program are to:

1. provide students with the fundamental knowledge and methodologies of electrical or computer engineering, including the opportunity to learn appropriate experimental and computational tools, essential for a successful career.

2. provide students with an awareness of, and skills in, life-long learning and self education. 3. cultivate teamwork, technical writing and oral communication skills.

4. provide students with an appreciation of engineering's impact on society and the professional responsibilities of engineers.

5. provide students with an opportunity to acquire an understanding of the engineering

profession and to observe the use of cutting-edge technologies and advanced systems in use in industry through direct interaction with industry, including internships and cooperative education experiences.

These objectives are consistent with the mission and objectives of the University, the School of Information Technology and Engineering, and the Electrical and Computer Engineering

Department.

The Mission Of George Mason University

“George Mason University will be an institution of international academic reputation providing

a superior education enabling students to develop critical, analytical, and imaginative thinking and to make well founded ethical decisions. The university will prepare students to address the complex issues facing them in society and to discover meaning in their own lives. The university will be a resource of the Commonwealth of Virginia serving private and public sectors and will be an intellectual and cultural nexus between Northern Virginia, the nation, and the world. “

Undergraduate Education Mission and Goals of the School of Information Technology and Engineering

“The Undergraduate Education mission of the School of Information Technology and

Engineering (IT&E) is to provide a quality education in support of the needs of Virginia and the nation.”

The goal of the School of Information Technology and Engineering undergraduate programs is to graduate students that:

1. Are technically competent;

2. Are prepared for ethical professional practice; 3. Can communicate effectively;

4. Can work as members or leaders of technical teams; 5. Are prepared for a lifetime of learning; and

6. Understand the global nature and impact of information technology and engineering.

Undergraduate Education Mission of the Electrical and Computer Engineering Department

“The undergraduate education mission of the Electrical and Computer Engineering Department

is to provide a quality education for electrical engineering and computer engineering students in support of the needs of Virginia and the nation.”

Constituencies of the Electrical Engineering Program

The significant constituencies of the electrical engineering program are:

Undergraduate Electrical Engineering Students: The undergraduate electrical engineering

students are represented by students enrolled in ECE classes and members of student

organizations and the ECE Undergraduate Student Advisory Committee (USAC). Selected from student applications, the members of the USAC are tasked with making recommendations

regarding the curriculum, standards, and academic policies of the Department. This organization will be one of the primary interfaces with the undergraduate electrical engineering student constituents.

Electrical Engineering Alumni: The electrical engineering graduates/ alumni are represented

by the ECE Alumni Association and by alumni enrolled in ECE graduate programs’ classes. The ECE Department Alumni Association has as one of its mission goals to provide advice and ideas to the department related to programs within the department. Many electrical engineering graduates remain in the Northern Virginia area. These individuals return to George Mason for their graduate work. When in ECE classes, they “chat” with the ECE faculty regarding their work experiences.

ECE Departmental Faculty: The faculty are involved via committees (Undergraduate

Curriculum Committee, Awards Committee, Undergraduate Recruitment Committee) and as the Department-as-a-whole.

Industry, Government and Academia: These constituents are involved via the ECE

Department Advisory Committee and graduate students enrolled in graduate level courses. The ECE Department Advisory Committee has the responsibility of reviewing existing and proposed Departmental Mission and Objectives statements and degree and certificate programs, and providing input to the Department on these or other issues of interest.

Development of Electrical Engineering Program Educational Objectives –

Establishment and Review

The present electrical engineering Program Objectives were initially proposed in Fall 1998 by the Undergraduate Curriculum Committee as revisions to the Program Objectives established in 1994. The Undergraduate Curriculum Committee is a standing committee appointed by the Department Chair each year. The Committee consists of four faculty, representing the four major areas of electrical and computer engineering concentration: electronics, computer engineering, communications/signal processing and controls/robotics. This committee is responsible for course and curriculum development proposals for presentation to the

Department-as-a-whole. The proposed Program Objectives were distributed to and discussed by the Department-as-a-whole and approved via vote in December 1998.

Subsequently these Program Objectives were presented to the ECE Department Advisory Committee for review and comment in Spring 2000. The Advisory Committee provided input regarding aspects of the Objectives that should receive emphasis and followed this with an expression of approval of the Program Objectives as presented to the Committee. This cycle resulted in the addition of a specific mention of direct observation and interaction with industry. These objectives are published in the University catalog, in the advising handbook and on the electrical engineering program web page.

While the original Program Objectives had been developed by faculty having informal

interaction with the undergraduate electrical engineering students, formal discussions were held with members of student organizations such as Eta Kappa Nu and the student chapter of IEEE. In each case the student reaction was of approval of the range and content of the Program Objectives.

Electrical Engineering Program Outcomes and Assessment

In order to facilitate Program Assessment, more detailed Program Outcomes were established supporting the Program Educational Objectives. The twelve Program Outcomes (a-l) are:: (a) an ability to apply knowledge of mathematics, science, and engineering

(b) an ability to design and conduct experiments, as well as to analyze and interpret data (c) an ability to design a system, component, or process to meet desired needs

(d) an ability to function on multi-disciplinary teams

(e) an ability to identify, formulate, and solve engineering problems (f) an understanding of professional and ethical responsibility (g) an ability to communicate effectively

(h) the broad education necessary to understand the impact of engineering solutions in a global and societal context

(i) a recognition of the need for, and an ability to engage in life-long learning (j) a knowledge of contemporary issues

(k) an ability to use the techniques, skills, and modern engineering tools necessary for engineering practice.

(l) a knowledge of the use of cutting-edge technologies and advanced systems in use in industry The Program Outcomes a-k listed above relate directly to the outcome requirements of

Accreditation Board for Engineering and Technology (ABET) EC 2000 Criterion 3a-k. Program Outcome l is unique to the George Mason program.

The relation of the a-l Program Outcomes, above, to the five Program Educational Objectives is shown in the Program Outcomes and Program Educational Objectives table.

Program Outcomes and Program Educational Objectives

Outcomes Apply knowledge of math, science and engineering Design and conduct experiments, as well as to analyze and interpret data Design a system, component, or process to meet desired needs Function on a multi-disciplinary team Identify, formulate, and solve engineering problems Understand professional and ethical responsibility Communicate effectively Broad education necessary to understand the impact of engineering solutions in a global and societal context Recognize the need for, and ability to engage in life-long learning Knowledge of contemporary issues Use the techniques, skills, and modern engineering tools necessary for engineering practice Have knowledge of the use of cutting-edge technologies and advanced systems in use in industry Objectives

%

_%

_%

_%

_%

_%

provide students with the fundamental knowledge and methodologies of electrical or computer engineering, including the opportunity to learn appropriate experimental and computational tools, essential for a successful career.

provide students with awareness of, and skills in, life-long learning and

self education

%

%

%

%

%

cultivate teamwork, technical writing

and oral communication skills.

%

%

provide students with an

appreciation of engineering's impact on society and the professional

responsibilities of engineers

%

%

%

provide students with an opportunity to acquire an understanding of the engineering profession and to observe the use of cutting-edge technologies and advanced systems in use in industry through direct interaction with industry, including internships and cooperative education experiences

Assessment of Electrical Engineering Program Outcomes

Outcome a: an ability to apply knowledge of mathematics, science, and engineering

This outcome is addressed by mathematics, basic sciences, and all the engineering and computer science courses. This is the core of an engineering education.

Assessed by performance on exams and assignments in courses. Assessed by questionnaires or quizzes in follow-on courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome b: an ability to design and conduct experiments, as well as to analyze and interpret data

This outcome is addressed by the basic sciences’ labs, the core courses with accompanying labs (ECE 101, 201, 220, 280, 333, 334, 331, 332, CS 112) and upper level/advanced labs ECE 434, 435, 447, 449)

Assessed by performance as shown in lab reports and assignments in courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome c: an ability to design a system, component, or process to meet desired needs

This outcome is addressed by a mixture of core courses (ECE 280, 220, 333, 320, CS 112, 211) and upper level (ECE 421, 433, 445) and the Senior Design Project courses.

Assessed by performance as shown in project reports and assignments in courses. Documented through supporting material collected from course instructor.

Assessed directly in surveys of students and alumni.

Outcome d: an ability to function on multi-disciplinary teams

This outcome is addressed by a number of courses from the freshman level to the Senior Design Project.

1. The freshman ENGR 107, Engineering Fundamentals, course involves students in group projects while being mentored by juniors and seniors. This results in a wide range of types of students (40% of ENGR 107 students are not declared engineering students) as well as capabilities.

2. The physics labs are team-lab courses. These teams can consist of engineers, physicists, computer science students as well as other non-engineering disciplines.

3. The Senior Design Project involves teams of students with different concentration areas who bring a variety of skills to the team.