Bachelor Of Science In Industrial Engineering Handbook
Bachelor of Science in Industrial EngineeringStudent HandbookRevised 8/24/2009Table of ContentsWelcome .1From the Undergraduate Program Chair . 1About the Profession & Program .2Faculty .5Admission Requirements .6Degree Requirements .7Curriculum .9IE Course Descriptions .10Technical Electives .13Non-IE Engineering Electives (Engineering Science Breadth) .15Directed Electives .15Academic Policies .16The Institute of Industrial Engineers (IIE) .17IME DepartmentWayne State University4815 Fourth St.Detroit MI 48201(313) 577-3821http://ime.wayne.edu/
WelcomeFrom the Undergraduate Program ChairOn behalf of the Undergraduate Program Committee and the entireIME faculty, I would like to welcome you to our program. I amdedicated to ensuring that you receive a high-quality, rewardingeducation in Industrial Engineering.Important Contact InformationDepartmentChairUndergraduateProgram ChairAcademicAdvisorDr. Leslie MonplaisirDr. Darin EllisGail Evans(313) 577-3821(313) 577-3296(313)577-2660Leslie.Monplaisir@wayne.edu rdellis@wayne.edu gevans@eng.wayne.eduRoom 2143 MEBRoom 2145 MEBRoom 2045 MEBIndustrial & Manufacturing Engineering DepartmentWayne State University4815 Fourth St.Detroit MI 48201The purpose of this handbook is to provide industrial engineering students atWayne State University a quick and complete source of information andguidelines to curriculum requirements and academic policies. The most upto-date version of this document will be placed on the department web site athttp://ime.wayne.edu. This Handbook is intended to be comprehensive andup-to-date, but is subject to change without notice.Since the UniversityBulletin is published infrequently, this document supersedes the UniversityBulletin with regard to IE requirements and policies.Consult the Academic Advisor or the Undergraduate Program Chair todetermine your official status and current requirements.1
BSIE Student HandbookAbout the Profession & ProgramAbout the Profession & ProgramIndustrial Engineering is concerned with the design, improvement, and installation of integrated systems of people,material, information, equipment, and energy. It draws upon specialized knowledge and skills inthe mathematical, physical, and social sciences together with the principles and methods ofengineering analysis and design to specify, predict, and evaluate the results to be obtained fromsuch systems.- Institute of Industrial Engineers, 2004The industrial engineer is a broadly-trained integration engineer, concerned withenabling complex systems to function effectively. Managing the inventory of aproduction facility, for example, involves issues of production and stocking policy,manufacturing equipment, human resources, customer demand, and supplierrelationships. The industrial engineer must understand the interaction of thecomponents of a system, and coordinate the flow of materials and information toeffectively manage the operation. The industrial engineer plays an important role indefining information needs and developing strategies for decision making based onincomplete knowledge. However, the skills of the industrial engineer have much greaterapplication than to traditional production environments. In a growing service sector ofthe economy including health care delivery, public safety, air transportation, andbanking, for example, issues of resource management, scheduling, quality of service,and systems design are important.Traditionally, the manufacturing engineer was responsible for developing the processcapability to realize the output of design engineering. Today, however, the boundarybetween design and manufacturing engineering is becoming blurred. Both groups worktogether in teams to assure the soundness of design and manufacturability of product.The manufacturing engineer must have an understanding of the design process, but thespecial expertise which is brought by the manufacturing engineer is the knowledge andunderstanding of the production process.Today's production is computer-based and provides flexibility through computer control.The manufacturing engineer is responsible for designing and implementing the cells andproduction lines which become the basic units of manufacture. Increasingly, suchproduction units are becoming parts of an integrated factory system, and are not simplyislands of automation. The manufacturing engineer must understand the multi-layeredcontrol architecture of the integrated factory, and the computer-based technologieswhich enable it.The Department maintains laboratories in systems simulation, computer-aidedmanufacturing, human systems, and concurrent engineering design.2
BSIE Student HandbookAbout the Profession & ProgramProgram Professional ObjectiveBuilding on skills developed in the academic program, and extended by experience andpersonal self-improvement, the graduates of our program have ability to:1. Identify opportunities and formulate solutions which integrate technological andhuman systems to create value, and2. Apply the tools and techniques of industrial engineering to make value-baseddecisions,3. Provide leadership as a member of high performance teams in a diverse globalbusiness environmentProgram Outcomes (Enabling Objectives)Upon completion of the Industrial Engineering Program, our graduates will exhibit skillsnecessary of all engineering professionals, including an ability to:G-1communicate effectively (ABET g)G-2apply fundamental understanding of mathematics and basic science to identify,formulate, and solve engineering problems (ABET a,e)G-3design and conduct experiments, as well as to analyze and interpret data.(ABET b)G-4discuss issues of professional and ethical responsibility (ABET - f)G-5construct engineering solutions which consider the impact in global, economic,environmental, and societal contexts. (ABET h).G-6recognize the need for, and develop an ability to engage in life-long learning(ABET i)G-7an ability to function on multi-disciplinary teams (ABET d)Upon completion of the Industrial Engineering Program, our graduates will exhibitspecial skills to enable them to practice in the field of industrial engineering. They willhave the ability to:IE-1quantify the uncertainties involved in engineering systems and apply the tools ofprobability and statistics in analysis and design.IE-2apply IE tools including statistical methods, operations research, processmanagement, and computer simulation for systems analysis and processdesign. (ABET- e,k)IE-3develop a business case to justify expenditures for new or enhanced tools,equipment, or large-scale integrated systems.IE-4design integrated systems which include: technology, methods, software andhuman elements. (ABET c,d and ABET/IE c)3
BSIE Student HandbookAbout the Profession & ProgramIE-5apply modern management tools such as Total Quality Management,Continuous Improvement, Lean Manufacturing, Six Sigma, and Team Building.(ABET k)IE-6use the computer as a tool for communication, analysis, and design. (ABET k)IE-7discuss contemporary issues which impact the practice of engineering. (ABET j)Note: parenthetical references in the tables above to ABET refer to Criterion 3 of the ABET criteria forAccrediting Engineering Programs (Available Online)Consistency of Program Objectives with University Mission StatementThe Wayne State University mission statement recognizes a dual character of theuniversity and its programs. It is "a national research university. committed to highstandards in research and scholarship". At the same time, the university describes itselfas "an urban teaching university". whose "graduates typically remain to live and workin the area throughout their lives." The Industrial Engineering Program defined by theobjectives stated above, aims to prepare graduates for careers applying skills andknowledge to benefit the manufacturing and service industries in southeast Michigan.AccreditationThe IE Program at Wayne State University is accredited by the EngineeringAccreditation Commission of ABET Inc., 111 Market Place, Suite 1050, Baltimore, MD21202-4012 - telephone: (410) 347-7700, http://www.abet.org. Wayne State Universityis accredited by the North Central Association Commission on Accreditation and SchoolImprovement (NCA CASI).4
BSIE Student HandbookFacultyFacultyNameRoomNo2069Phone No(313)577-3857E-mailResearch Interestskchelst@wayne.eduDecision and Risk Analysis,Engineering Management, UrbanServices, Operations ResearchRatna BabuChinnam2161577-4846r chinnam@wayne.eduIntelligent Engineering Systems,Supply Chain Management, andProduction and OperationsManagement.Darin Ellis2145577-3296rdellis@wayne.eduHuman Factors Engineering, HumanComputer Interactiondfalken@wayne.eduManagement of Technology andGlobal Engineering Mgmt.Kenneth ChelstDon Falkenburg(Emeritus)Julia Gluesing2049577-3821j.gluesing@wayne.eduGlobal engineering management,Leadership, Virtual teamingKyoung-Yun Kim2067577-4396kykim@wayne.eduProduct Development, Processoptimization, Facilities DesignOlugbenga Mejabi2157577-3134mejabi@wayne.eduFlexible Manufacturing, Simulation,Factory Control.Leslie Monplaisir,Department p Decision Support Systems,Integrated Product Development &Computer-Integrated Manufacturing.Alper Murat2051577-3872alper@eng.wayne.eduSupply Chain Management, Logisticsand Distribution Planning, SupplierSelection and Contracting, AppliedOperations ResearchDean Pichette2073577-3821dpichette@wayne.eduProject Management, SystemsEngineeringKen Riopelle2149248-8799619kenriopelle@wayne.eduSocial network models ofcollaborationNanua Singh2155577-7586nsingh@wayne.eduConcurrent Engineering, ComputerIntegrated Manufacturing.Gary Wasserman2169577-3301gwasserm@wayne.eduReliability & Robust Design; SPC;Computer-Intensive AppliedStatistics.Kai Yang2151577-3858kyang@wayne.eduRobust Engineering, QualityEngineering, Operations Research5
BSIE Student HandbookAdmission RequirementsAdmission RequirementsPre-Professional AdmissionFor students to be admitted to the pre-professional program, a 2.5 gpa with a 3.0in math and science courses from high school or community college will be required.Students applying directly from high school must also have a minimum Math ACT scoreof 22 (Math SAT of 550). Students will be required to have completed courses in precalculus, chemistry, and physics. In addition, to be admitted to the pre-professionalprogram, students will have to receive scores on the Mathematics Placement (MP) andChemistry Qualifying (CQ) exams to place them in MAT 2010 and CHM 1225. Studentswho do not meet these requirements will need to complete coursework at Wayne Stateor a community college in order to reach these expected levels.Professional Program Admission:For admission to the professional program and continuation on to 3000- and4000-level Engineering courses, students will need to meet one of the following criteria: Direct from High School – Students must have earned a gpa of 3.5 or above inscience/math, along with a score on the Math ACT 26 or Math SAT 650. Inaddition, their scores on the MP and CQ (see Testing and Placements Servicesat http://www.testing.wayne.edu) must be sufficient for them to enter MAT 2010and CHM 1225/1230. Direct from Community College – Students must have earned a gpa 3.0 in theirMAT sequence (16 cr), CHM 1225/1230, and physics sequence (8 cr), with nograde lower than a C. From Pre-Professional Program – Students must have completed their preprofessional courses with a gpa of 2.5 or above and no grade lower than a C-.Students must also have completed their Critical Thinking and EnglishProficiency Exams.6
BSIE Student HandbookDegree RequirementsDegree RequirementsCandidates for the Bachelor of Science degree must complete a minimum of 124 credits incourse work, including satisfaction of the University General Education Requirements (seeGeneral Education Requirements, ml#14766, online), as outlined in the following curriculum. All course work must be completed inaccordance with the academic procedures of the University and the College governingundergraduate scholarship and degrees; see the following sections in the UndergraduateBulletin: Degree Requirements, Baccalaureate, Academic Regulations, University, Division ofEngineering: B. S. Program.The Bachelor of Science in Industrial Engineering degree program is built on a strong core ofIndustrial Engineering courses. A number of IE Technical Electives allow the student to gaindepth in an area of concentration such as production management or quality engineering. Inaddition to the Technical Electives, the student must complete a Directed Elective to supporttheir plan of work. The directed elective must be approved by the IE undergraduate adviser. Alist of courses appropriate for the directed elective is available from the IE adviser. Students arestrongly encouraged to meet with the IE undergraduate adviser to complete a plan of work fortheir professional program, including both IE core requirements, Technical Electives andDirected Electives.The Engineering Design Project course sequence (IE 4800 and 4880) is a capstone endeavorand is intended to build on and integrate the knowledge that the student has accumulatedthroughout the undergraduate program, and is intended to be taken in the student’s lastacademic year, that is, within 40 credits of graduating. This course sequence is a year-longundertaking. Students enroll for IE 4800 (2 cr.) in their last Fall semester, and spend the termbuilding their teamwork skills and selecting and planning their project. Practical, professionallyrelevant projects are usually selected in concert with the Department’s industrial partners. In theWinter term students enroll in IE 4880 (2 cr.), and engage in an intensive effort to bring their IEskills and knowledge to bear on the problem. Students who intend to take the capstonesequence should consult their academic advisor.In order to qualify to take IE 4800 the student must be in the last year of their program (i.e.,within 40 credits of graduating. For IE 4800 (Fall semester) complete IE 3120, IE 4250, IE4420, and IE 4850. In order to register for IE 4880, students must have taken IE 4800 in theimmediately previous term, plus meet the following requirements: Students must havecompleted IE 4560, IE4260 and be at least co-registered for IE 4310 and IE 4330 (thesecourses will also be accepted as prerequisites).Completing the Industrial Engineering degree program is demanding. Students taking a fullload (16 credits) should plan to spend in excess of 40 hours per week on their academic work.With careful planning and consistent academic progress, it is reasonable to expect to completeall degree requirements within 4 academic years. For transfer students and students with anon-traditional path, plan a minimum of 2 years for the IE professional program (2.5 years ifstarting IE classes in Winter term).The table below provides a summary of the curriculum requirements. Non-engineering courses,cited below by subject rather than by individual course numbers, indicate courses to be selectedin fulfillment of University General Education Requirements. The degree requirements shown inthe curriculum below are in effect as of the publication date of this handbook. However, studentsshould consult an academic advisor for verification of current requirements.7
BSIE Student HandbookDegree RequirementsDescriptionCreditsLife Sciences Course (LS) BIO 1510 (3 cr.) *or* PSY 1010 (4 cr.)3 (or 4)Any Social Sciences Course (SS)3Any Foreign Culture (FC)3Any Historical Studies (HS)3Any American Institutions (AI)3Any Visual and Performing Arts (VP)3PHI 1120 Professional Ethics (PL/EI)3ENG 1020 Introductory College Writing (BC)4ENG 3050 Technical Communication I: Report Writing (IC)3ENG 3060 Technical Communication II: Writing &Speaking (OC)3CHM 1225 Chemical Structure, Bonding and Reactivity (PS)3CHM 1230 Chemical Principles in Laboratory (PS)1MAT 2010 Calculus I4MAT 2020 Calculus II4MAT 2030 Calculus III4MAT 2150 Differential Equations and Matrix Algebra4PHY 2175 General Physics (PS)4PHY 2185 General Physics4BE 1200 Basic Engineering I - Design in Engineering (CL)3BE 1300 Basic Engineering II - Material Science for Engineering Applications3BE 1310 Basic Engineering II – Material Science for Engineering Applications Lab1BE 2100 Basic Engineering III - Probability and Statistics in Engineering3BE 2550 Basic Engineering IV – Numerical Methods & Computer Programming3Engineering Breadth #1 (See Advisor for current list of acceptable courses)4Engineering Breadth #2 (See Advisor for current list of acceptable courses)4IE 3120 Work Design3IE 4250 Engineering Data Analysis3IE 4420 System Simulation3IE 4850 Engineering Economy3IE 4560 Operations Research3IE 4260 Principles of Quality Control3IE 4310 Production Control (WI)3IE 4330 Facilities Design3IE 4800 Engineering Design Project I2IE 4880 Engineering Design Project II2IE Technical Electives (See Advisor for current list of acceptable courses)13Directed Elective (See Advisor for current list of acceptable courses)3TOTAL MINIMUM CREDITS REQUIRED124In addition to these courses, students must complete the Critical Thinking (CT) exam offered throughWSU’s Testing and Placement Services (http://www.testing.wayne.edu), who can be reached at 5773400. Students MUST complete the CT exam by the time they accumulate 60 credits.8
BSIE Student HandbookCurriculumCurriculumSemester by SemesterFreshman YearJunior YearFirst SemesterCreditsMAT 2010 – Calculus I4CHM 1225 –Chem Structure, Bonding & React (PS)3CHM 1230 – Chemical Principles in the Laboratory1ENG 1020 – Introductory College Writing (BC)4B E 1200 – Basic Engg I - Design in Engg (CL)3Total 15First SemesterI E 4850 – Engineering EconomyI E 3120 – Work DesignENG 3050 –Technical Communication I (IC)Historical Studies general education – (HS)PHI 1120 – Professional Ethics (PL/EI)Credits33333Total 15Second SemesterCreditsMAT 2020 – Calculus II4PHY 2175 – General Physics (PS)4B E 1300 – Basic Engg II - Science of Engg Matls3B E 1310 – Basic Engg II - Science of Engg Matls Lab1American Institutions general education– (AI)3Total 15Second SemesterI E 4420 – Systems SimulationI E 4250 – Engineering Data AnalysisENG 3060 – Technical Communication II (OC)1Engineering Breadth Option3Foreign Culture general education– (FC)Credits33343Total 16Sophomore YearSenior YearFirst SemesterCreditsMAT 2030 – Calculus III4PHY 2185 – General Physics4B E 2100 – Basic Engg III - Prob and Stats in Engg31Engineering Breadth Option4Total 15Second SemesterCreditsMAT 2150 – Differential Equations and Matrix Algebra 4BE 2550 – B
Industrial & Manufacturing Engineering Department Wayne State University 4815 Fourth St. Detroit MI 48201 The purpose of this handbook is to provide industrial engineering students at Wayne State University a quick and complete source of information and guidelines to cu
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