ET 5870: Engineering Project Management

ET 5870: Engineering Project Management Course Description: This course provides the student with insights into human and organizational behavior affecting projects, in addition to the quantitative tools for the successful management of engineering projects. The course addresses a variety of project types and deals with how to select, initiate, operate and control as well as terminate a project. The role of project managers and their interaction with the rest of the organization is highlighted. Credit Hours: 3 Prerequisites: ET 3870 or Equivalent Textbook and Other Required Materials: TEXTBOOK: Title: Project Management: A Managerial Approach (7 th Edition) Author: Jack R. Meredith and Samuel J. Mantel Jr. Publisher: John Wiley & Sons Inc. WEB SITE: http://blackboard.wayne.edu/ INSTRUCTOR: Dr. Mukasa E. Ssemakula Rm 60 Engineering Technology Bldg. Tel: (33) 577 8079 Fax: (33) 577 78 Email: m.e.ssemakula@wayne.edu OFFICE HRS: Mon. 0:00 A.M. :30 A.M. Other times by appointment Topics Covered: Week Topic Textbook Reference Introduction, Project Concepts Chapter Project Selection Chapter 3 The Project Manager Chapter 3 4 Project Organization Chapter 5 5 Project Activity Planning Chapter 6 6 Test / Budgeting and Cost Estimation Chapter 7 7 Budgeting and Cost Estimation Chapter 7 8 Project Scheduling Chapter 8 9 Project Scheduling continued Chapter 8 0 Resource Allocation Chapter 9 Resource Allocation continued Chapter 9 Test / Project Monitoring and Control Chapter 0 3 Project Monitoring and Control Chapter 4 Project Evaluation and Termination Chapter & 3 5 Final Examination* *Comprehensive Laboratory Experiments: N/A

Course Learning Objectives: On successful completion of this course, the student will be able to:. Evaluate individual projects and select those that best meet organizational needs [SO a,f]. Describe functions and capabilities of a good project manager and project team. [SO e,i] 3. Develop a project plan including schedules, milestones, and resource needs. [SO d,k] 4. Develop a project budget reflecting the expected costs of planned activities. [SO f] 5. Use graphical tools such as Gantt charts or Arrow networks to represent a project schedule and show inter-activity relationships. [SO d] 6. Allocate the available but limited human and physical resources to a project. [SO a,k] 7. Collect appropriate project information and use it to ensure that the project proceeds according to plan. [SO a,e] 8. Determine whether a project is meeting its goals and when it should end. [SO a,e] GRADING POLICY: Contribution Test Dates Homework * 5% Test # Monday, Feb., 00 Tests (@ 0%) 40% Test # Monday, April, 00 Final Exam (Comprehensive) 35% Final Exam Saturday, May, 00 GRADING SCALE: Letter Grade - Modifier Unmodified + Modifier A 90-93 94+ B 80-8 83-86 87-89 C 70-7 73-76 77-79 D 60-6 63-66 67-69 F 59 or less I Incomplete Work WP Withdraw (Passing at time of withdrawal) WF Withdraw (Failing at time of withdrawal) WN Withdraw (Never showed or no basis for grade) Because the overall score must be at least 70% to get graduate credit, the D grade is not available for graduate students. DEFERRED GRADES: A grade of "I" will only be assigned if a student is not currently failing the course and if there is not a substantial amount of work to be completed. An "I" grade must be made up within one year. Assignment of an I grade will be at the sole discretion of the instructor. WITHDRAWAL POLICY: Last day to drop with a tuition refund: First two weeks of semester. Last day to drop without a withdrawal notation on the transcript: Weeks 3-4. Final day to drop class: Last day of classes. REPEAT POLICY (Effective Fall 006): You must to see an advisor to repeat the same course a third time. If you repeat three different courses, you must see an advisor to repeat a fourth course.

Contributions to MCT Program Student Outcomes: Level BSMCT Program Student Outcomes a. an ability to select and apply the knowledge, techniques, skills, and modern tools of their disciplines to broadly-defined engineering technology activities b. an ability to select and apply a knowledge of mathematics, science, engineering, and technology to engineering technology problems that require the application of principles and applied procedures or methodologies c. an ability to conduct standard tests and measurements; to conduct, analyze, and interpret experiments; and to apply experimental results to improve processes d. an ability to design systems, components, or processes for broadly-defined engineering technology problems appropriate to program educational objectives e. an ability to function effectively as a member or leader on a technical team f. an ability to identify, analyze, and solve broadly-defined engineering technology problems g. an ability to communicate effectively regarding broadly-defined engineering technology activities h. an understanding of the need for and an ability to engage in self-directed continuing professional development i. an understanding of and a commitment to address professional and ethical responsibilities including a respect for diversity j. a knowledge of the impact of engineering technology solutions in a societal and global context 3 k. a commitment to quality, timeliness, and continuous improvement M MCT Design Track: Students in this track will demonstrate the ability to apply principles of materials and mechanics to the design and analysis of mechanical components and mechanisms. M MCT Energy Track: Students in this track will demonstrate the ability to apply principles of thermo-fluid sciences to the design and analysis of energy systems M3 MCT Manufacturing Track: Students in this track will demonstrate the ability to apply principles of materials and production techniques to the planning, implementation, and control of manufacturing processes

Contributions to EET Program Student Outcomes: Level BSEET Program Student Outcomes a. an ability to select and apply the knowledge, techniques, skills, and modern tools of their disciplines to broadly-defined engineering technology activities b. an ability to select and apply a knowledge of mathematics, science, engineering, and technology to engineering technology problems that require the application of principles and applied procedures or methodologies c. an ability to conduct standard tests and measurements; to conduct, analyze, and interpret experiments; and to apply experimental results to improve processes d. an ability to design systems, components, or processes for broadly-defined engineering technology problems appropriate to program educational objectives e. an ability to function effectively as a member or leader on a technical team f. an ability to identify, analyze, and solve broadly-defined engineering technology problems g. an ability to communicate effectively regarding broadly-defined engineering technology activities h. an understanding of the need for and an ability to engage in self-directed continuing professional development i. an understanding of and a commitment to address professional and ethical responsibilities including a respect for diversity j. a knowledge of the impact of engineering technology solutions in a societal and global context 3 k. a commitment to quality, timeliness, and continuous improvement E. the ability to analyze, design, and implement control systems, instrumentation systems, communications systems, computer systems, or power systems. E. the ability to apply project management techniques to electrical/electronic(s) systems E3. the ability to utilize statistics/probability, transform methods, discrete mathematics, or applied differential equations in support of electrical/electronic(s) systems

DISABILITY POLICY: If you have a documented disability that requires accommodations, you will need to register with Student Disability Services (SDS) for coordination of your academic accommodations. The SDS office is located in room 600 of the Undergraduate Library. Their phone number is (33) 577-85 or (33) 577-3365 (TDD only). Once you have your accommodations in place, I will be glad to discuss your special needs with you in private. POLICY ON CHEATING: Cheating is defined by the University as intentionally using or attempting to use, or intentionally providing or attempting to provide, unauthorized materials, information, or assistance in any academic exercise. This includes any group efforts on assignments or exams unless specifically approved by the professor for that assignment/exam. Evidence of fabrication or plagiarism, as defined by the University in its brochure Academic Integrity, will also result in downgrading for the course. Students who cheat on any assignment or during any examination will be assigned a failing grade for the course and may be subject to additional penalties. University / Department Policies: Academic Integrity http://www.doso.wayne.edu/judicial/academic-integrity.htm Code of Ethics for Engineers: WSU library has a tutorial that talks about transmitting ideas, plagiarism, copyright, and citing sources. At the end, there is a quiz. You are encouraged to visit this site then take the quiz at the end. http://www.lib.wayne.edu/services/instruction_tutorials/searchpath/mod6/contents.html The following list gives additional sites: http://onlineethics.org/codes/ http://www.iit.edu/departments/csep/codes/coe/abet-a.html Prepared by: Mukasa E. Ssemakula, Ph.D.