2005 - 2006 Calendar

Faculty of Engineering and Applied Science

Faculty List
Office of Co-operative Education

Plan of Operation for the Co-operative Engineering Program

Flowchart of Engineering Program
Chart of the Undergraduate Engineering Core Program
Chart of Bridging Program for Civil Engineering
Chart of Bridging Program for Electrical and Computer Engineering Programs
Chart of Bridging Program for Mechanical Engineering Program
Chart of Bridging Program for Ocean and Naval Architectural Engineering
Chart of Civil Engineering Curriculum
Chart of Civil Engineering - Offshore Oil and Gas Option (OOGE)
Chart of Computer Engineering Curriculum
Chart of Computer Engineering - Offshore Oil and Gas Option (OOGE)
Chart of Electrical Engineering Curriculum
Chart of Electrical Engineering Curriculum- Offshore Oil Gas Option (OOGE)
Chart of Mechanical Engineering Curriculum
Chart of Mechanical Engineering - Offshore Oil and Gas Option (OOGE)
Chart of Ocean and Naval Architectural Engineering
Chart of Ocean and Naval Architectural Engineering - Offshore Oil and Gas Option (OOGE)

dash Engineering Programs: Civil, Computer, Electrical, Mechanical, Ocean and Naval Architectural, and Continuing Engineering Education

Bachelor of Engineering Degree Program

dash Master of Engineering Fast-Track Option

Engineering Regulations

Course List

Employers Participating in Co-operative Engineering Program

Continuing Engineering Studies



FACULTY LIST

Dean

Gosine, R.G., B.Eng. Memorial, Ph.D. Cambridge, P.Eng.; Winner of the President's Award for Outstanding Research, 1997-1998, Perto-Canada Young Innovator, 1998; Professor, Electrical and Computer Engineering

Associate Dean (Graduate Studies and Research)

Venkatesan, R., B.E.(Hons.) Madurai, M.Sc.E., Ph.D. New Brunswick, P.Eng.; Professor, Electrical and Computer Engineering

Associate Dean (Undergraduate Studies)

Quaicoe, J.E., B.Sc.(Eng.) Ghana, M.A.Sc., Ph.D. Toronto, P.Eng.; Winner of the President's Award for Distinguished Teaching, 2001-2002; Professor, Electrical and Computer Engineering

Director, Continuing Engineering Education

Husain, T., B.Sc.Eng.(Hons.) Aligarh, M.Eng. AIT Bangkok, Ph.D. British Columbia, P.Eng.; Professor, Civil Engineering

Director, Ocean Engineering Research Centre

Veitch, B.J., B.Eng., M.Eng. Memorial, Dr.Tech., Lic.Tech. Helsinki, P.Eng.; Petro Canada/Terra Nova Project Junior Research Chair in Ocean Environmental Risk Engineering, Associate Professor, Ocean and Naval Architectural Engineering; Winner of the President's Award for Outstanding Research, 2004-2005

Manager, Finance and Administration

Pitcher, D., B.Comm.

Engineering Laboratory Manager

Gries, K.

Laboratory Director

Hookey, N.A., B.Eng. Memorial, M.Eng., Ph.D. McGill, P.Eng.; Associate Professor, Mechanical Engineering

Professores Emeriti

Sharp, J.J., B.Sc., A.R.C.S.T., M.Sc. Glasgow, Ph.D. Strathclyde, F.I.C.E., F.C.S.C.E., F.EIC, P.Eng., C.Eng.

Walsh, J., B.Eng.(Hons.) TUNS, Ph.D. Calgary, P.Eng.

Professor

Meisen, A., B.Sc. Imperial College London, M.Sc. Caltech, Ph.D. McGill, P.Eng., F.C.I.C., F.C.A.E., F.I.E.I. Eurlng; President

Honorary Research Professors

Clark, J.I., B.Sc. Acadia, B.Eng. TUNS, M.Sc. Alberta, Ph.D. TUNS, P.Eng.

Molgaard, J., B.Sc. Belfast, Ph.D. Leeds, P.Eng.

Honorary Professor

Williams, F.M., B.A. Toronto, Ph.D. Simon Fraser

CIVIL ENGINEERING DISCIPLINE

Chair

Marzouk, H.M., B.Sc. Cairo, M.Sc., Ph.D. Saskatchewan, FCSCE, P.Eng.; Professor

Professors

Jordaan, I.J., B.Sc.(Eng.), M.Sc.(Eng.) Witwatersrand, Ph.D.London, P.Eng.; University Research Professor, Awarded 1997

Lye, L.M., B.Sc.(Hons.) Bolton Inst., Ph.D. Manitoba, F.C.S.C.E., P.Eng.; Winner of the President's Award for Distinguished Teaching, 2003-2004

Swamidas, A.S.J., B.E.(Hons.), M.Sc.(Eng.) Madras, Ph.D., I.I.T. Madras, P.Eng.

Associate Professors

Adluri, S.M.R., B.Tech., J.N.T. Univ., M.Tech. I.I.T. Kanpur, M.A.Sc., Ph.D. Windsor

Coles, C.A., B.Eng., M.Eng., Ph.D. McGill

Niefer, R.A., B.Sc., Ph.D. Windsor

Phillips, R., B.Sc.(Hons.) Bristol, M.Phil., Ph.D. Cambridge, P.Eng.; Joint appointment with C-CORE

Popescu, R., B.Sc., Ph.D. Bucharest, M.A., Ph.D. Princeton, P.Eng.

Assistant Professors

Hawboldt, K.A., B.Sc. Saskatchewan, M.Sc., Ph.D. Calgary, P.Eng.; Joint appointment with Civil and Mechanical

Hussein, A., B.Sc.(Eng.) Ain Shams University, M.Eng., Ph.D.Memorial, P.Eng.

Kandil, K.A., B.Sc.(Hons.), M.Sc. Ain Shams University, Ph.D. Carleton

ELECTRICAL AND COMPUTER ENGINEERING DISCIPLINE

Chair

Heys, H.M., B.E.Sc. Western Ontario, Ph.D. Queen's, P.Eng.; Associate Professor

Professors

Bruce-Lockhart, M.P., S.B., S.M., M.I.T., P.Eng.

Jeyasurya, B., B.Tech. I.I.T. Madras, M.Tech. I.I.T. Bombay, Ph.D. New Brunswick, P.Eng.

Moloney, C.R., B.Sc.(Hons.) Memorial, M.A.Sc., Ph.D. Waterloo; NSERC/Petro-Canada Chair for Women in Science and Engineering (Atlantic Region)

Rahman, M.A., B.Sc. (Eng.) Bangladesh, M.A.Sc. Toronto, Ph.D. Carleton, F.I.E.E.E., F.I.E.E., L.F.I.E., F.E.I.C., C.Eng., P.Eng.; University Research Professor, Awarded 1993

Associate Professors

George, G.H., B.Sc. Southampton, Ph.D. Wales (U.C. Cardiff), Cert.Ed., (C.N.A.A.), F.R.A.S.

Gill, E.W., B.Sc., B.Ed., M.Eng., Ph.D. Memorial

Norvell, T.S., B.Sc.(Hons.) Dalhousie, M.Sc., Ph.D. Toronto

O'Young, S.D., B.Eng. Saskatchewan, M.A.Sc., Ph.D. Waterloo, P.Eng.

Assistant Professors

Ahmed, M.H., B.Sc., M.Sc., Ain-Shams, Ph.D. Carleton

Iqbal, M.T., B.Sc. UET Lahore, M.Sc., QAU Islamabad, Ph.D. Imperial College, London; P.Eng.

Li, C., B.Eng., M.Eng. Harbin Institute of Technology, Ph.D. Memorial

Masek, V., Dipl.Ing. University of West Bohemia, M.Sc., Ph.D. University of Electro-Communications, Tokyo

Peters, D.K., B.Eng. Memorial, M.Eng., Ph.D. McMaster, P.Eng.


MECHANICAL ENGINEERING DISCIPLINE

Acting Chair

Sabin, G.C.W., B.Sc., M.Sc. Simon Fraser, Ph.D. Windsor, P.Eng.; Professor

Professors

Booton, M., B.A.Sc., M.A.Sc., Ph.D. Toronto, P.Eng.

Hinchey, M.J., B.A.Sc., M.A.Sc., Ph.D. Toronto, P.Eng.

Seshadri, R., B.E.(Hons.) Jabalpur, M.Tech. I.I.T. Madras, M.Sc., Ph.D. Calgary, FCSME, FEIC, FASME, P.Eng.; Canada Research Chair in Asset Integrity Management

Sharan, A.M., B.Tech., I.I.T. Bombay, M.S. Wash. State, Ph.D. Concordia, P.Eng.

Associate Professors

Hookey, N.A., B.Eng. Memorial, M.Eng., Ph.D. McGill, P.Eng.

Khan, F.I., B.Sc.(Eng.) AMU, M.E. IIT Roorkee, Ph.D. Pondicherry

Lobo, L.J., B.Tech.(Hons.) I.I.T. Bombay, M.A.Sc. Waterloo

Munaswamy, K., B.E., S.V. Univ. Tirupathy, M.Tech., Ph.D., IIT Madras, P.Eng.

Shirokoff, J.W., B.Sc.(Eng.), Ph.D. Queen's, P.Eng.

Assistant Professor

Abdi, M.A., B.Sc., M.Sc. Tehran Polytechnic, Ph.D. British Columbia, P.Eng.

Hawboldt, K.A., B.Sc. Saskatchewan, M.Sc., Ph.D. Calgary, P.Eng.; Joint appointment with Civil and Mechanical

Mann, G.K.I., B.Sc. University of Moratuwa, M.Sc. Loughborough University of Technology, Ph.D. Memorial; C-Core Junior Chair in Intelligent Systems

Muzychka, Y.S., B.Eng. Memorial, M.A.Sc., Ph.D. Waterloo, P.Eng.; Petro-Canada Young Innovator Award 2004


OCEAN AND NAVAL ARCHITECTURAL ENGINEERING DISCIPLINE

Chair

Daley, C.G., B.E.Sc. Western Ontario, M.S.E. Princeton, Dr. Tech. Helsinki, P.Eng.; Professor

Professors

Bass, D.W., B.Sc. Hull, Cert.Ed. London, M.Phil. Birkbeck College, Ph.D. Warwick

Bose, N., B.Sc., Ph.D. Glasgow, F.S.N.A.M.E., C.Eng., P.Eng.; Winner of the President's Award for Outstanding Research, 1992-1993; Canada Research Chair in Offshore and Underwater Vehicles Design

Friis, D.A., B.Sc. Newcastle, M.B.A. Toronto, Siv. Ing., P.Eng.

Haddara, M.R., B.Sc. Ain-Shams, M.S., Ph.D. Berkeley, C.Eng., P.Eng.

Johansen, T.E., B.A.Sc., M.Sc. Ph.D. University of Oslo; Canada Research Chair in Petroleum Reservoir Engineering and Characterization

Assistant Professor

Qiu, W., B.Eng., M.A.Sc. Dalian University of Technology, Ph.D. Dalhousie

OIL AND GAS GROUP

Abdi, M.A., B.Sc., M.Sc., Tehran Polytechnic, Ph.D. British Columbia, P.Eng.

Bose, N., B.Sc., Ph.D. Glasgow, F.S.N.A.M.E., C.Eng., P.Eng.; Winner of the President's Award for Outstanding Research, 1992-1993; Canada Research Chair in Offshore and Underwater Vehicles Design

Hawboldt, K.A., B.Sc. Saskatchewan, M.Sc., Ph.D. Calgary, P.Eng

Husain, T., B.Sc.Eng.(Hons.) Aligarh, M.Eng. AIT Bangkok, Ph.D. British Columbia, P.Eng.

Johansen, T.E., B.A.Sc., M.Sc. Ph.D. University of Oslo; Canada Research Chair in Petroleum Reservoir Engineering and Characterization

Khan, F.I., B.Sc.(Eng.) AMU, M.E. IIT Roorkee, Ph.D. Pondicherry

Masek, V., Dipl.Ing. University of West Bohemia, M.Sc., Ph.D. University of Electro-Communications, Tokyo

Muzychka, Y.S., B.Eng. Memorial, M.A.Sc., Ph.D. Waterloo, P.Eng.; Petro-Canada Young Innovator Award 2004

Veitch, B.J., B.Eng., M.Eng. Memorial, Dr.Tech., Lic.Tech. Helsinki, P.Eng.; Petro Canada/Terra Nova Project Junior Research Chair in Ocean Environmental Risk Engineering; Winner of the President's Award for Outstanding Research, 2004-2005

Cross-Appointment, Adjunct, Professional Affiliate

Bajzak, D., B.Sc.F., M.F. British Columbia, Ph.D. Syracuse, N.Y.; Adjunct Professor

Barrette, P.D., B.Sc. Ottawa, M.Sc. Memorial, Ph.D. Laval; Adjunct Professor

Colbourne, D.B., B.Eng. Memorial, S.M. MIT, Ph.D. Memorial, P.Eng.; Adjunct Professor (NRC-IOT)

Croasdale, K.R., B.Sc.(Eng.) London, P.Eng.; Adjunct Professor (K.R. Croasdale & Associates Ltd.)

Eigenbrod, K.D., Dipl. Ing. Tech. University Darmstadt, Ph.D. Alberta; Adjunct Professor (Lakehead University)

Frederking, R.M.W., B.Eng. Alberta, M.Sc. London, Ph.D. Illinois, P.Eng.; Adjunct Professor (Canadian Hydraulics Centre, NRC)

Jones, S.J., B.Sc., Ph.D. Birmingham; Adjunct Professor (NRC-IOT)

Kosar, K.M., B.Sc. British Columbia, M.Sc., Ph.D. Alberta; Adjunct Professor (EBA Engineering Consultants Ltd.)

Liu, P., B.Eng. Wuhan Jiao Tong, M.Eng., Ph.D. Memorial; Adjunct Professor

McKenna, R., B.Sc. Queen's, M.A.Sc., Ph.D. Waterloo; Cross-Appointment (C-CORE)

Navin, F., B.Eng. McMaster, M.Sc. Missouri, Ph.D. Minnesota; Adjunct Professor (University of British Columbia)

Randell, C., B.Eng. Lakehead, M.A.Sc., Ph.D. Victoria, P.Eng.; Cross Appointment (C-CORE)

Reinhardt, W.D., Dipl. Ing. Technische Universitat Braunschweig, Ph.D. Waterloo; Adjunct Professor (Babcock and Wilcox)

Sadiq, R., B.Eng. UET, Pakistan, M.Eng. IPHER, M.Eng. KFUMP, Ph.D. Memorial; Adjunct Professor (IRC/NRC)

Timco, G.W., B.Sc. Brock, M.Sc., Ph.D. Western; Adjunct Professor (Canadian Hydraulics Centre, NRC, Ottawa)

Walker, D., B.Eng., Ph.D. Memorial, P.Eng.; Adjunct Professor (Marineering Ltd.)

Williams, C., B.A.Sc.(Hons.), M.A.Sc., Ph.D. British Columbia; Adjunct Professor (NRC-IOT)


OFFICE OF CO-OPERATIVE EDUCATION

Program  Manager

White, L.H., B.Sc. Memorial, B.Eng. Nova Scotia Technical College, M.Eng., B.A. Memorial, P.Eng.

Coordinators

Coish, R., B.Eng. Memorial, P.Eng.

Hudson, J.F., B.Eng. McGill, P.Eng.

Jacobs, W.K., B.Eng. Memorial, P.Eng.

Oldford, D.B., B.Sc. Memorial, B.Eng. Dalhousie

Raheja, A., B.Eng. Bangalore, M.B.A. Memorial


PLAN OF OPERATION FOR CO-OPERATIVE ENGINEERING PROGRAM

YEAR 2003 2004 2005 2006 2007 2008

Sept
to
Dec
Jan
to
April
May
to
Aug
Sept
to
Dec
Jan
to
April
May
to
Aug
Sept
to
Dec
Jan
to
April
May
to
Aug
Sept
to
Dec
Jan
to
April
May
to
Aug
Sept
to
Dec
Jan
to
April
May
to
Aug
Sept
to
Dec
CLASS
OF
2004
WORK
TERM
6
Term 8













CLASS
OF
2005
Term 6 WORK
TERM
5
Term 7 WORK
TERM
6
Term 8










CLASS
OF
2006
WORK
TERM
3
Term 5 WORK
TERM
4
Term 6 WORK
TERM
5
Term 7 WORK
TERM
6
Term 8







CLASS
OF
2007
Term 3 WORK
TERM
2
Term 4 WORK
TERM
3
Term 5 WORK
TERM
4
Term 6 WORK
TERM
5
Term 7 WORK
TERM
6
Term 8




CLASS
OF
2008
Term 1 Term 2 WORK
TERM
1
Term 3 WORK
TERM
2
Term 4 WORK
TERM
3
Term 5 WORK
TERM
4
Term 6 WORK
TERM
5
Term 7 WORK
TERM
6
Term 8

CLASS
OF
2009
Terms A/B Term 1 Term 2 WORK
TERM
1
Term 3 WORK
TERM
2
Term 4 WORK
TERM
3
Term 5 WORK
TERM
4
Term 6 WORK
TERM
5
Term 7 WORK
TERM
6
CLASS
OF
2010



Terms A/B Term
1
Term
2
WORK
TERM
1
Term
3
WORK
TERM
2
Term
4
WORK
TERM
3
Term
5
WORK
TERM
4
Term
6

FLOWCHART OF UNDERGRADUATE ENGINEERING PROGRAM







































CHART OF THE UNDERGRADUATE ENGINEERING CORE PROGRAM

Term A Term B
Term 1 Term 2
MATH 1000
DIFFERENTIAL
CALCULUS
MATH 1001
INTEGRAL CALCULUS

1405
ENGINEERING MATHEMATICS I
2422
ENGINEERING MATHEMATICS II
CHEMISTRY 1050 or equivalent CHEMISTRY 1051 or equivalent
COMPLEMENTARY STUDIES 2205
CHEM. & PHY. OF ENG. MAT. I
PHYSICS 1050 or equivalent PHYSICS 1051 or equivalent
1313
MECHANICS I
2313
MECHANICS II

ELECTIVE*

ELECTIVE*

1333
ELECTRIC
CIRCUITS
2420
STRUCTURED PROGRAMMING
ENGLISH ELECTIVE*
1504
ENGINEERING GRAPHICS
2503
ENGINEERING DESIGN

Additional Courses Required of
Fast Track Students
ENGLISH COMPLEMENTARY STUDIES

Notes:
* Two of these three electives must be complementary studies electives and the other is a free elective.
Courses in Terms A & B are taken on a credit basis. Terms 1 and 2 must each be passed on a block average.


CHART OF THE BRIDGING PROGRAM FOR CIVIL ENGINEERING

Fall Term Winter Term
1405 ENGINEERING
MATHEMATICS I
2422 ENGINEERING
MATHEMATICS II
3423 PROBABILITY
AND STATISTICS
2205 CHEMISTRY & PHYSICS
OF ENGR MATERIALS I
3610 EARTH SCIENCES 2313 MECHANICS II
3731 MATERIALS OF CONSTRUCTION 2420 STRUCTURED
PROGRAMMING
ENGLISH COMPLEMENTARY
STUDIES

CHART OF THE BRIDGING PROGRAM FOR THE ELECTRICAL AND COMPUTER ENGINEERING PROGRAMS

Fall Term Winter Term
1405
ENGINEERING MATHEMATICS I
2422
ENGINEERING MATHEMATICS II
1313
MECHANICS I
2313
MECHANICS II
3821
CIRCUIT ANALYSIS
2205
CHEMISTRY AND PHYSICS OF MAT.I
3861
DIGITAL LOGIC
ST 2510
STATISTICS FOR PHYSICAL SCIENCE
3891
ADVANCED PROGRAMMING
PM 2320
DISCRETE MATHEMATICS
ENGLISH COMPLEMENTARY STUDIES

NOTE: Students from the Electrical and Computer Engineering Technology program are required to take a course in structured programming at the College of the North Atlantic before admission into the Bridging Program.


CHART OF THE BRIDGING PROGRAM FOR THE
MECHANICAL ENGINEERING PROGRAM

Fall Term Winter Term
1405 ENGINEERING
MATHEMATICS I
2422 ENGINEERING
MATHEMATICS II
3901 THERMODYNAMICS 2205 CHEMISTRY & PHYSICS
OF ENGR MATERIALS I
3933 MECHANISMS AND MACHINES 2313 MECHANICS II
3205 CHEMISTRY & PHYSICS OF
ENGR MATERIALS II
2420 STRUCTURED
PROGRAMMING
ENGLISH COMPLEMENTARY STUDIES

CHART OF BRIDGING PROGRAM FOR OCEAN AND NAVAL ARCHITECTURAL ENGINEERING

Fall Term Winter Term
1405 ENGINEERING
MATHEMATICS I
2422 ENGINEERING
MATHEMATICS II
3423 PROBABILITY
AND STATISTICS
2205 CHEMISTRY & PHYSICS OF
ENGR MATERIALS I
3901 THERMODYNAMICS 2313 MECHANICS II
3205 CHEMISTRY & PHYSICS OF ENGR MATERIALS II 2420 STRUCTURED
PROGRAMMING
ENGLISH COMPLEMENTARY STUDIES



CIVIL ENGINEERING CURRICULUM CHART

FALL
SPRING
WINTER
FALL
SPRING 
WINTER

TECHNICAL ELECTIVES
TERM 3
TERM 4
TERM 5
TERM 6
TERM 7
TERM 8

TERM 7
TERM 8
3610
EARTH
SCIENCES
4102
ENGR.
ECONOMICS
COMP.
STUDIES
ELECTIVE
6101
ASSESS OF
TECHNOLOGY
7704
DESIGN OF STEEL
STR.
8700
C.E.
PROJECT

7706
STRUCTURAL
ANALYSIS II
8705
STRUCT BLDG
SYSTEMS
3703
SURVEYING
GEOMATICS
4312
MECHANICS
SOLIDS I
5312
MECHANICS OF
SOLIDS II 
6705
STRUCTURAL
ANALYSIS I
7713
HYDROLOGY
WATER RES 
8749
CONSTRUCTION
PLAN

7748
PROJ. PLAN &
CONTROL
8751
COASTAL &
OCEAN ENGR
3844
ELECT COMP &
SYSTEMS
4322
THERMAL
SCIENCES
5708
CIVIL ENGR.
SYSTEMS
6723
GEOTECH
ENGR II
7745
HIGHWAY
ENGR.
TECHNICAL
ELECTIVE

7716
HYDROTECH
ENGR.
8713
MUNICIPAL
ENGR.
3423
PROBABILITY & STATISTICS
4717
APPLIED ENVIR.
SCIENCE & ENGR.
5713
FLUID
MECHANICS
6713
HYDRAULICS.
TECHNICAL
ELECTIVE
TECHNICAL
ELECTIVE

7723
GEOTECH
ENGR. III
8717
ENVIR.
ASSM
3731
MATERIALS OF
CONSTRUCTION
4422
NUMERICAL
METHODS
5706
CONCRETE
STRUCTURES
6707
CONCRETE &
MASON STR.
TECHNICAL
ELECTIVE 
TECHNICAL
ELECTIVE 

7718
ENVIRONMENTAL
GEOTECH 
8746
TRAFFIC & TRANS. ENGR
COMP. STUDIES
ELECTIVE
(Fast Track)
4723
GEOTECH
ENGR. I
5434
APPLIED
ANALYSIS
6740
CONTRACT LAW
& LABOUR
RELATIONS




8790-8791
SPECIAL TOPICS


NOTES:
1) Some of the technical electives listed above may not be offered every year. A list of the current offerings is available from the Discipline Chair and the Associate Dean (Undergraduate).
2) From time to time, a technical elective may be offered in a term other than indicated on the above chart.




CIVIL ENGINEERING - OFFSHORE OIL AND GAS OPTION (OOGE)
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8
3610
EARTH SCIENCE
4422
INTRO. TO NUM. METHODS
COMPLEMENTARY
STUDIES ELECTIVE
6705
STRUT. ANALYSIS
7748
PROJECT PLANNING
8600
OOGE PROJECT
3703
SURVEYING
4102
ENGR. ECON.
5708
CIVIL ENGR. SYSTEMS
6723
GEOTECH. II
7706
FINITE ELEMENTS
8748
CONSTRUCTION
PLANNING
3423
PROB. & STATS.
4312
MECH. OF SOLIDS I
5312
MECH. OF SOLIDS II
6740
CONTRACT LAW
7704
STEEL DESIGN
CE ELECTIVE
3844
BASIC ELEC. COMP. & SYS.
4322
THERMAL SCIENCE
5713
FLUIDS
6101
ASSESS. OF TECH.
7601
GEO. APP. IN
OFFSHORE ENGR.
OOGE ELECTIVE
3731
CE MATERIALS
4717
ENV. SCI/ENGR.
5706
CONCRETE
STRUCTURES
6601
INTRO. OFFSHORE
PET. ENGR.
OOGE ELECTIVE OOGE ELECTIVE

4723
GEOTECH ENGR 1
5434
APP. ANALYSIS
6713
HYDRAULICS


NOTE: Bold and OOGE slots are courses from the Offshore Oil and Gas Engineering Option

Common Courses

6601. Introduction to Offshore Petroleum Engineering
7601. Geosciences Applied in Offshore Engineering
8600. Offshore Oil and Gas Engineering Project

Electives

7602. Subsea Engineering
7603. Ocean Ice Engineering
7680. Supervisory Control and Data Acquisition
8680. Process Control and Instrumentation
8670. Reliability Engineering
8671. Safety and Risk Engineering
8672. Environmental Aspects of Offshore Oil Development
8673. Subsea Geotechnical Engineering
8674. Design for the Ocean and Ice Environments
8675. Offshore Structures and Materials
8690. Reservoir Engineering
8691. Petroleum Production Engineering
8692. Drilling Engineering for Petroleum Exploration and Production
8693. Petroleum Facilities Engineering
8694. Downstream Processing


COMPUTER ENGINEERING CURRICULUM

ELECTRICAL AND COMPUTER CORE COMPUTER ENGINEERING
TECHNICAL ELECTIVES
FALL SPRING WINTER FALL SPRING WINTER
FALL SPRING WINTER
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8
TERM 6 TERM 7 TERM 8
3423
PROBABILITY &
STATISTICS
4102
ENGINEERING
ECONOMICS
COMPLEMENTARY
STUDIES
ELECTIVE
6101
ASSESSMENT OF
TECHNOLOGY
7800
ELEC / COMP
DESIGN
PROJECT I
8800
ELEC / COMP
DESIGN
PROJECT II

6891
FORMAL
PROG
METHODS
7855
COMMUNICATIONS
ELECTRONICS
8821
DIGITAL
SIGNAL
PROCESSING
3821
CIRCUIT
ANALYSIS
4823
INTRO.
SYSTEMS &
SIGNALS
5821
CONTROL
SYSTEMS I
6871
COMMUNICATIONS
PRINCIPLES
7824
DISCRETE -
TIME SYSTEMS
& SIGNALS
8879
DIGITAL
COMMUNICATIONS

6825
CONTROL
SYSTEMS II
7814
ELECTROMAG FOR
COMMUNICATIONS
8893
CONCURRENT
PROGRAMMING
3422
DISCRETE
MATHEMATICS
4423
NUMERICAL
METHODS
FOR EE
5891
DESIGN &
ANALYSIS OF
ALGORITHMS
6806
PROJECT
DESIGN LABS
7863
OPERATING
SYSTEMS &
FILE
ORGANIZATION
TECHNICAL
ELECTIVE

COMPUTER
SCIENCE
ELECTIVE
7858
INDUSTRIAL
CONTROLS &
INSTRUMENTATION
8863
LSI DESIGN
3891
ADVANCED
PROGRAMMING
4892
DATA
STRUCTURES
5895
SOFTWARE DESIGN
6876
VOICE & DATA
COMMUNICATIONS
7893
SOFTWARE
ENGINEERING
TECHNICAL
ELECTIVE


7944
ROBOTICS &
AUTOMATION
8826
FILTER
SYNTHESIS
3861
DIGITAL
LOGIC
4862
MICROPROCESSORS
5865
DIGITAL
SYSTEMS
6861
COMPUTER
ARCHITECTURE
TECHNICAL
ELECTIVE
TECHNICAL
ELECTIVE



8874
TELECOMM.
SYSTEM
DESIGN

COMPLEMENTARY
STUDIES ELECTIVE
(Fast-track
students only)
4854
ELECTRONIC
DEVICES &
CIRCUITS
5854
ANALOG
ELECTRONICS
TECHNICAL
ELECTIVE
TECHNICAL
ELECTIVE




8801-8805
SPL. TOPICS
IN COMP.
ENGG.

NOTES: (1) From time to time, a technical elective may be offered in a term other than indicated on the                               above chart.
                    (2) Computer Science electives require the permission of both the Department of Computer                                    Science and the Faculty of Engineering and Applied Science.






COMPUTER
SCIENCE
ELECTIVE




COMPUTER ENGINEERING CURRICULUM - OFFSHORE OIL AND GAS OPTION (OOGE)

ELECTRICAL AND COMPUTER CORE COMPUTER ENGINEERING
TECHNICAL ELECTIVES
FALL SPRING WINTER FALL SPRING WINTER WINTER
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8 TERM 8
3423
PROBABILITY & STATISTICS
4102
ENGINEERING ECONOMICS
COMPLEMENTARY
STUDIES ELECTIVE
6101
ASSESSMENT OF TECHNOLOGY

8600
OIL & GAS
PROJECT
8821
DIGITAL SIGNAL
PROCESSING
3821
CIRCUIT
ANALYSIS
4823
INTRO. SYSTEMS
& SIGNALS
5821
CONTROL
SYSTEMS I
6871
COMMUNICATIONS
PRINCIPLES
7824
DISCRETE-TIME
SYSTEMS &
SIGNALS
8879
DIGITAL
COMMUNICATIONS
8893
CONCURRENT PROGRAMMING
3422
DISCRETE
MATHEMATICS
4423
NUMERICAL
METHODS FOR EE
5891
DESIGN &
ANALYSIS OF
ALGORITHMS
6806
PROJECT DESIGN LABS
7863
OPERATING
SYSTEMS &
FILE
ORGANIZATION
8680
PROCESS CONTROL
& INSTRUMENTATION
8863
LSI DESIGN
3891
ADVANCED
PROGRAMMING
4892
DATA STRUCTURES
5895
SOFTWARE
DESIGN
6876
VOICE & DATA
COMMUNICATIONS
7893
SOFTWARE
ENGINEERING
OOGE ELECTIVE 8826
FILTER SYNTHESIS
3861
DIGITAL LOGIC
4862
MICROPROCESSORS
5865
DIGITAL SYSTEMS
6861
COMPUTER
ARCHITECTURE
7680
SUPERVISORY
CONTROL &
DATA
ACQUISITION
TECHNICAL
ELECTIVE
8874
TELECOMM.
SYSTEM DESIGN

COMPLEMENTARY
STUDIES ELECTIVE
(Fast-track students only)
4854
ELECTRONIC
DEVICES &
CIRCUITS
5854
ANALOG
ELECTRONICS
6601
INTRODUCTION
TO
PETROLEUM ENGG.
7601
GEO. APPLNS.
IN
PETRLM.
PRODN.

8801-8805
SPL. TOPICS IN
COMP. ENGG.

NOTES: (1) From time to time, a technical elective may be offered in a term other than indicated on the above chart.
(2) Computer Science electives require the permission of both the Department of Computer Science and the Faculty of Engineering and Applied Science.
(3) The OOGE elective is selected each year from courses listed in the Calendar. A list of the course offerings is available from the Associate Dean (Undergraduate Studies).
COMPUTER SCIENCE ELECTIVE


ELECTRICAL ENGINEERING CURRICULUM

ELECTRICAL AND COMPUTER CORE ELECTRICAL ENGINEERING
TECHNICAL ELECTIVES
FALL SPRING WINTER FALL SPRING WINTER FALL SPRING WINTER
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8 TERM 6 TERM 7 TERM 8
3423
PROBABILITY &
STATISTICS
4102
ENGINEERING
ECONOMICS
COMPLEMENT.
STUDIES
ELECTIVE
6101
ASSESSMENT OF
TECHNOLOGY
7800
ELEC / COMP
DESIGN
PROJECT I
8800
ELEC / COMP
DESIGN
PROJECT II
6876
VOICE &
DATA COMMNS.
7855
COMMUNICATIONS
ELECTRONICS
8821
DIGITAL
SIGNAL
PROCESSING
3821
CIRCUIT
ANALYSIS
4823
INTRO.
SYSTEMS &
SIGNALS
5821
CONTROL
SYSTEMS I
6871
COMMUNICATIONS
PRINCIPLES
7824
DISCRETE-TIME
SYSTEMS &
SIGNALS
8826
FILTER
SYNTHESIS
6825
CONTROL
SYSTEMS II
7846
POWER
ELECTRONICS
8845
POWER
SYSTEM
OPERATION

3422
DISCRETE
MATHEMATICS
4423
NUMERICAL
METHODS FOR EE
5432
ADVANCED
CALCULUS
6806
PROJECT
DESIGN LABS
7858
INDUSTRIAL
CONT. &
INSTM.
TECHNICAL
ELECTIVE

7811
ANTENNAS
8879
DIGITAL
COMMUNICATIONS

3891
ADVANCED
PROGRAMMING
4892
DATA
STRUCTURES
5842
ELECTROMECH.
DEVICES
6843
ROTATING
MACHINES
7844
POWER SYSTEM
ANALYSIS
TECHNICAL
ELECTIVE

7944
ROBOTICS &
AUTOMATION
5865
DIGITAL
SYSTEMS

3861
DIGITAL LOGIC
4862
MICROPROCESSORS
5812
BASIC
ELECTROMAG.
6813
ELECTROMAG. FIELDS
TECHNICAL ELECTIVE TECHNICAL ELECTIVE
4322
THERMAL
SCIENCES
8874
TELECOMM.
SYSTEM
DESIGN

COMPLEMENTARY
STUDIES ELECTIVE
(Fast-track students only)
4854
ELECTRONIC
DEVICES &
CIRCUITS
5854
ANALOG
ELECTRONICS
TECHNICAL
ELECTIVE
TECHNICAL
ELECTIVE



8882
BIOMEDICAL
ENGINEERING

NOTE: From time to time, a technical elective may be offered in a term other than indicated on the above                  chart.





8806-8809
SPL. TOPICS
IN ELEC.
ENGG.





ELECTRICAL ENGINEERING CURRICULUM - OFFSHORE OIL AND GAS OPTION (OOGE)

ELECTRICAL AND COMPUTER CORE ELECTRICAL ENGINEERING
TECHNICAL ELECTIVES
FALL SPRING WINTER FALL SPRING WINTER WINTER
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8 TERM 8
3423
PROBABILITY &
STATISTICS
4102
ENGINEERING
ECONOMICS
COMPLEMENT.
STUDIES
ELECTIVE
6101
ASSESSMENT OF
TECHNOLOGY

8600
OIL & GAS
PROJECT
8821
DIGITAL SIGNAL
PROCESSING
3821
CIRCUIT
ANALYSIS
4823
INTRO. SYSTEMS
& SIGNALS
5821
CONTROL
SYSTEMS I
6871
COMMUNICATIONS
PRINCIPLES
7824
DISCRETE-TIME
SYSTEMS &
SIGNALS
8826
FILTER
SYNTHESIS
8845
POWER SYSTEM
OPERATION

3422
DISCRETE
MATHEMATICS
4423
NUMERICAL
METHODS FOR
EE
5432
ADVANCED
CALCULUS
6806
PROJECT DESIGN
LABS
7858
INDUSTRIAL
CONT. & INSTM.
8680 PROCESS CONTROL & INSTRUMENTATION
8879
DIGITAL
COMMUNICATIONS

3891
ADVANCED
PROGRAMMING
4892
DATA
STRUCTURES
5842
ELECTROMECH.
DEVICES
6843
ROTATING
MACHINES
7844
POWER SYSTEM
ANALYSIS
OOGE ELECTIVE
5865
DIGITAL SYSTEMS

3861
DIGITAL LOGIC
4862
MICROPROCESSORS
5812
BASIC
ELECTROMAG.
6813
ELECTROMAG.
FIELDS
7680
SUPERVISORY CONTROL & DATA ACQUISITION

TECHNICAL
ELECTIVE
8874
TELECOMM.
SYSTEM DESIGN

COMPLEMENTARY
STUDIES ELECTIVE
(Fast-track students
only)
4854
ELECTRONIC
DEVICES &
CIRCUITS
5854
ANALOG
ELECTRONICS
6601 INTRODUCTION TO PETROLEUM ENGG. 7601
GEO. APPLNS. IN PETRLM. PRODN.


8882
BIOMEDICAL
ENGINEERING

NOTES: (1) From time to time, a technical elective may be offered in a term other than indicated on the above chart.
(2) The OOGE elective is selected each year from courses listed in the Calendar. A list of the course offerings is available from the Associate Dean (Undergraduate Studies).
8806-8809
SPL. TOPICS IN
ELEC. ENGG




MECHANICAL ENGINEERING CURRICULUM

MECHANICAL ENGINEERING CURRICULUM


TECHNICAL ELECTIVES
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8
TERM 7 TERM 8
3205
CHEMISTRY &
PHYSICS OF
ENGINEERING
MATERIALS II
4102
ENGINEERING
ECONOMICS
COMPLEMENTARY
STUDIES
ELECTIVE
3423
PROBABILITY
& STATISTICS
7936
MECHANICAL
PROJECT I
8936
MECHANICAL
PROJECT II

7934
FINITE
ELEMENT
ANALYSIS
8904
FLOW
STRUCTURE
INTERACTIONS
3844
BASIC
ELECTRICAL
COMPONENTS
& SYSTEMS
4312
MECHANICS
OF SOLIDS I
5312
MECHANICS
OF SOLIDS II
6101
ASSESSMENT
OF
TECHNOLOGY
7901
HEAT-
TRANSFER II
8903
MECHANICAL
SYSTEMS

7943
PRODUCTION
AND
OPERATIONS
MANAGEMENT
8935
PRESSURE
COMPONENT
DESIGN
3901
THERMO-
DYNAMICS I
4422
INTRODUCTION
TO
NUMERICAL
METHODS
5435
ADVANCED
CALCULUS
6901
HEAT
TRANSFER I
7903
MECHANICAL
EQUIPMENT
TECHNICAL
ELECTIVE

7944
ROBOTICS
AND
AUTOMATION
8943
COMPUTER
INTEGRATED
MANUFACTURING
3933
MECHANISMS
& MACHINES
4901
THERMO-
DYNAMICS II
5926
MECHANICAL
COMPONENT
DESIGN I
6925
AUTOMATICS
CONTROL
ENGINEERING
7962
COMPUTER
AIDED
ENGINEERING
TECHNICAL
ELECTIVE

7945
MACHINE
DYNAMICS
8944
QUALITY
MANAGEMENT
AND
CONTROL
3941
PRODUCTION
TECHNOLOGY
4913
FLUID
MECHANICS I
5913
FLUID
MECHANICS II
6926
MECHANICAL
COMPONENT
DESIGN II
TECHNICAL
ELECTIVE
TECHNICAL
ELECTIVE


8963
NONDESTRUCTIVE
EVALUATION
COMPLEMENTARY
STUDIES ELECTIVE
(Fast-track
students only)
4933
ELECTRO/
MECHANICAL
SYSTEMS
5932
MECHANICAL
VIBRATIONS
6972
INDUSTRIAL
MATERIALS






NOTES:    1)  Some of the technical electives listed above may not be offered every year.  A list of the current offerings is available from the Discipline Chair and the Associate Dean (Undergraduate).
                  2)  Students are permitted to replace a maximum of two technical electives listed above with two OOGE technical electives listed under Electives, Mechanical Engineering- Offshore Oil and Gas Engineering Option Chart.



MECHANICAL ENGINEERING - OFFSHORE OIL AND GAS OPTION (OOGE)

MECHANICAL ENGINEERING - OFFSHORE OIL AND GAS OPTION (OOGE)
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8
3933
MECH. & MACH.
4933
ELEC./MECH. SYS.
COMPLEMENTARY STUDIES ELECTIVE 3423
PROB. & STATS.
7936
MECH. PROJ. I
8600
OOGE PROJECT
3205
CHEM. AND PHYS.
OF MATERIALS II
4102
ENGR. ECON.
5913
FLUIDS II
6925
AUT CONTROL ENGR.
7901
HEAT TRANSFER II
8903
MECHANICAL
SYSTEMS
3941
PROD. TECH.
4312
MECH. OF
SOLIDS I
5312
MECH. OF SOLIDS II
6901
HEAT TRANSFER
7903
MECHANICAL
EQUIPMENT
OOGE ELECTIVE
3844
BASIC ELEC. COMP.
& SYS.
4422
INTRO. TO NUM.
METHODS
5435
ADV. CALCULUS
6101
ASSESS. OF TECH.
7601
GEO. APP. IN
OFFSHORE ENGR.
OOGE ELECTIVE
3901
THERMO. I
4901
THERMO. II
5926
MECH. COMP.
DESIGN I
6926
MECH. COMP.
DESIGN II
OOGE ELECTIVE OOGE ELECTIVE

4913
FLUID MECH I
5932
MECH. VIBRATIONS
6601
INTRO. OFFSHORE
PET. ENGR
.


NOTE: Bold and OOGE slots are courses from the Offshore Oil and Gas Engineering Option

Common Courses

6601. Introduction to Offshore Petroleum Engineering
7601. Geosciences Applied in Offshore Engineering
8600. Offshore Oil and Gas Engineering Project

Electives

7602. Subsea Engineering
7603. Ocean Ice Engineering
7680. Supervisory Control and Data Acquisition
8680. Process Control and Instrumentation
8670. Reliability Engineering
8671. Safety and Risk Engineering
8672. Environmental Aspects of Offshore Oil Development
8673. Subsea Geotechnical Engineering
8674. Design for the Ocean and Ice Environments
8675. Offshore Structures and Materials
8690. Reservoir Engineering
8691. Petroleum Production Engineering
8692. Drilling Engineering for Petroleum Exploration and Production
8693. Petroleum Facilities Engineering
8694. Downstream Processing


OCEAN AND NAVAL ARCHITECTURAL ENGINEERING


TECHNICAL
ELECTIVES

TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8 TERM 8
3054
OCEAN
ENGR
 HYDROSTATICS
4061
MAR PROD & ENG MANG
COMPLEMENTARY
STUDIES
ELECTIVE
6002
SHIP HULL STRENGTH
7002
SHIP STRUC
ANA & DESIGN
8000
DESIGN PROJECT
8030
HYDROELASTICITY
3205
CHEM & PHYS
 OF MATERIALS II
4102
ENGINEERING ECONOMICS
5011
RES & PROP
6045
MAR ENGR
SYSTEMS
7005
FLOAT OCEAN STRUCT DESIGN
8054
ADVANCED MARINE VEHICLES
8003
SMALL CRAFT
DESIGN
3423
PROBABILITY AND STATISTICS
4312
MECH OF
SOLIDS I
5312
MECH OF SOLIDS II
6030
DYN. AND MAN.
OF OCEAN VEH.
7033
MARINE HYDRODYNAMICS
PHYS 4300
ADVANCED PHYSICAL OCEANOGRAPHY
8048
MAINT. OF ENGR.
SYSTEMS
3844
BASIC ELECTRICAL COMP & SYS
4422
INTRODUCTION TO NUMERICAL METHODS
5435
ADVANCED CALCULUS
6020
MARINE
PROPULSION
7052
OCEAN SYSTEMS
DESIGN
8058
SUBMERSIBLES
DESIGN
8090
SP TOPICS
IN MAR HYD
3901
THERMODYNAMICS I
4901
THERMODYNAMICS II
5926
MECH COMPONENT DESIGN I
6101
ASSESSMENT OF
TECHNOLOGY
7601
GEO. APP. IN
OFFSHORE ENGR.
TECHNICAL
ELECTIVE
8091
SP TOPICS
IN STRUCT
COMPLMENTARY
STUDIES ELECTIVE

(Fast Track
Students Only)

4913
FLUID MECHANICS I
5932
MECH VIBRATIONS
6925
AUTO CONTROL ENGR


8092
SP TOPICS
IN MAR ENGR

OCEAN AND NAVAL ARCHITECTURAL ENGINEERING - OFFSHORE OIL AND GAS
OPTION (OOGE)

OCEAN AND NAVAL ARCHITECTURAL ENGINEERING - OFFSHORE OIL AND GAS OPTION (OOGE)
TERM 3 TERM 4 TERM 5 TERM 6 TERM 7 TERM 8
3054
OCEAN ENG
HYDROSTATICS
4061
MAR PROD &
ENG MANG
COMPLEMENTARY STUDIES ELECTIVE 6002
SHIP HULL STRENGTH
7002
SHIP STRUC ANA & DESIGN
8600
OOGE PROJECT
3205
CHEM & PHYS
OF MATERIALS II
4102
ENGINEERING ECONOMICS
5011
RES AND PROP
6925
AUTO CONTROL ENGINEERING
7005
FLOAT OCEAN
STRUCT DESIGN
PHYS. 4300
ADVANCED PHYSICAL
OCEANOGRAPHY
3423
PROBABILITY AND STATISTICS
4312
MECH OF SOLIDS I
5312
MECH OF SOLIDS II
6030
DYN AND MAN
OF OCEAN VEH
7033
MARINE
HYDRODYNAMICS
8058
SUBMERSIBLES
DESIGN
3844
BASIC ELECTRICAL
COMP & SYS
4422
INTRODUCTION TO NUMERICAL
METHODS
5435
ADVANCED CALCULUS
6101
ASSESSMENT OF TECHNOLOGY
7052
OCEAN SYSTEMS
DESIGN
OOGE ELECTIVE
3901
THERMODYNAMICS I
4901
THERMODYNAMICS II
5926
MECH COMPONENT
DESIGN I
6045
MAR ENG
SYSTEMS
7601
GEO. APP. IN
OFFSHORE ENGR.
OOGE ELECTIVE

4913
FLUID MECHANICS I
5932
MECH VIBRATIONS
6601
INTRO. OFFSHORE
PET. ENGR.


NOTE: Bold and OOGE slots are courses from the Offshore Oil and Gas Engineering Option

Common Courses

6601. Introduction to Offshore Petroleum Engineering
7601. Geosciences Applied in Offshore Engineering
8600. Offshore Oil and Gas Engineering Project

Electives

7602. Subsea Engineering
7603. Ocean Ice Engineering
7680. Supervisory Control and Data Acquisition
8680. Process Control and Instrumentation
8670. Reliability Engineering
8671. Safety and Risk Engineering
8672. Environmental Aspects of Offshore Oil Development
8673. Subsea Geotechnical Engineering
8674. Design for the Ocean and Ice Environments
8675. Offshore Structures and Materials
8690. Reservoir Engineering
8691. Petroleum Production Engineering
8692. Drilling Engineering for Petroleum Exploration and Production
8693. Petroleum Facilities Engineering
8694. Downstream Processing


FACULTY OF ENGINEERING AND APPLIED SCIENCE

ENGINEERING DEGREE PROGRAMS

CONTINUING ENGINEERING EDUCATION


ENGINEERING

Terms A, B, 1 and 2 comprise the core program taken by all students. The specialized programs of Civil, Computer, Electrical, Mechanical, and Ocean and Naval Architectural Engineering are offered in Terms 3 through 8. Where electives are available in Complementary Studies the selection must be approved by the Associate Dean (Undergraduate Studies). All electives in Terms 3 through 8 must be approved by the appropriate Discipline Chair.

CIVIL ENGINEERING
COMPUTER ENGINEERING
ELECTRICAL ENGINEERING
MECHANICAL ENGINEERING
OCEAN AND NAVAL ARCHITECTURAL ENGINEERING

CIVIL ENGINEERING

In the nineteenth century, Civil Engineering was defined as, "The art of directing the great sources and powers of nature...for the use and convenience of man". Still valid today, the definition indicates that civil engineers are involved in serving people by providing some of the essentials (e.g. water supplies, shelter and transportation) necessary for civilized life. The oldest of the engineering professions, Civil Engineering deals with the planning, design, and construction of such things as roads, railways, harbours, docks, tunnels, bridges, buildings, water supplies, hydroelectric power development, and sewage collection, treatment and disposal systems.

The program provides a broad introduction to the scientific principles and engineering techniques necessary for an understanding of the fundamental problems tackled by civil engineers.

COMPUTER ENGINEERING

Computer Engineering is the design and analysis of computer systems applied to the solution of practical problems. It encompasses both hardware and software design in applications ranging from telecommunications and information systems to process control and avionics. Computer Engineering students learn the mathematics of discrete as well as continuous systems, the design of digital machines such as processors and memories, the fundamentals of software design, and the principles used in communications systems such as telephone networks and the Internet. Computer Engineering shares many fundamentals with Electrical Engineering, and these are covered in a common curriculum up to and including Term 4. Although students must decide to take Computer or Electrical Engineering prior to Term 3, they are not required to select between Computer and Electrical Engineering until the completion of Term 4. In Terms 5 and 6, students who have selected the Computer Engineering program will take a core appropriate to the program. In recognition of the considerable diversity of careers available to computer engineers, students are given latitude in the final three terms to choose from a wide range of electives in various speciality areas. Electives can be tailored to meet the needs of those who plan to go straight into industry as well as those who wish to join the increasing number of our graduates who are pursuing advanced degrees.

ELECTRICAL ENGINEERING

Electrical Engineering is a broad field involving topics from the design of motors to the design of communication systems. Areas of study include control systems, electromagnetics and antennas, power systems, electronics, communications, and computer hardware and software. Electrical Engineering shares many fundamentals with Computer Engineering, and these are covered in a common curriculum up to and including Term 4. Although students must decide to take Computer or Electrical Engineering prior to Term 3, they are not required to select between Computer and Electrical Engineering until the completion of Term 4. Upon entering Term 5, students who have selected the Electrical Engineering program will spend a further two terms taking a core appropriate to the program. In recognition of the considerable diversity of careers available to electrical engineers, students are given latitude in the final two terms to choose from a wide range of electives in various speciality areas. Electives can be tailored to meet the needs of those who plan to go straight into industry as well as those who wish to join the increasing number of our graduates who are pursuing advanced degrees. 

MECHANICAL ENGINEERING

Mechanical Engineering is a highly diversified discipline encompassing the design, manufacture, and utilization of mechanical and thermal energy systems for the service of society. This activity requires a thorough knowledge of materials, mathematics, and the physical sciences, and an ability to apply this knowledge to the synthesis of economical and socially acceptable solutions to engineering problems.

The Mechanical Program provides students with a sufficiently general background to engage in the diverse activities of Mechanical Engineering. The judicious selection of elective courses in Terms 7 and 8 permits students who have identified specific areas of interest to direct their programs accordingly. Electives may be chosen from those designated as Mechanical Engineering or, with approval, from courses offered by other disciplines within and outside engineering. Students can thereby tailor their programs to meet career goals in areas such as research and development, industry, design, resource utilization, offshore development and ocean engineering.

OCEAN AND NAVAL ARCHITECTURAL ENGINEERING

Naval architects conceive, design and construct ships, offshore structures and other floating equipment to survive and operate in a marine environment and to serve the needs of the ocean-going community. A naval architect is an engineer with the working knowledge of several disciplines and expertise in one of the basic areas of structural, hydrodynamical, or marine systems design. The role of naval architects now reaches beyond the confines of shipyards and design offices.

The Ocean and Naval Architectural Engineering Program is the only accredited undergraduate program specifically in naval architecture in Canada. The program is designed both to provide graduates for the traditional role in shipbuilding and to provide for highly qualified professionals who can work in related ocean industries such as marine services; offshore engineering; submersibles and other advanced marine vehicles. The undergraduate program is also a thorough preparation for graduate studies, research and consulting in ocean engineering.

CONTINUING ENGINEERING EDUCATION

The Faculty of Engineering and Applied Science has a firm commitment to Continuing Engineering Education. A variety of seminars and short courses are offered in St. John's and in other centres so that practising engineers may participate in Continuing Engineering programs aimed at maintaining and improving their competence.


BACHELOR OF ENGINEERING DEGREE PROGRAM

NOTE: Students intending to undertake the Engineering program should note that it is possible to enter Term A or Term 1 only in the Fall semester (September of each year). Attention is also drawn to the admission regulations below.

The Bachelor of Engineering Degree at Memorial University of Newfoundland is set up as a Co-operative Program, under which regular full-time academic study is alternated with equal periods of full-time work in positions related to the student's future career.

PROGRAM OF STUDY
COMPLEMENTARY STUDIES COURSES
COMPUTING FOUNDATIONS
MASTER OF ENGINEERING FAST-TRACK OPTION
ENGINEERING REGULATIONS


PROGRAM OF STUDY

It is possible for students to pursue studies in Civil, Computer, Electrical, Mechanical, or Ocean and Naval Architectural Engineering. Students in each program may also choose to pursue offshore oil and gas engineering options in the last three terms of the program.

Courses in the engineering program are normally taken in blocks as shown in the appropriate discipline program chart. However, a student who has previously met a technical elective requirement in a given semester or wishes to defer it, may request an exemption or deferral by applying to the Associate Dean who will consult the appropriate Discipline Chair. A minimum grade of 70% is required for credit to be given towards a student's engineering program for any technical elective taken outside the normal blocks as shown in the charts.

A student who has previously completed a required course (or its equivalent) with a minimum grade of 70% may request an exemption by applying to the Associate Dean. A student cannot defer required courses.

In either of the above cases, a student who has been granted an exemption or a deferral will not be required to take a replacement course in that academic term and the student's promotion from that academic term will be based on the remaining courses as shown in the program chart. Notwithstanding the above, a student must maintain status as a full-time student to remain in the Engineering Program and can be exempt from or defer at most one technical elective or required course in an academic term. A student's request which has been initially denied by the Associate Dean, will be forwarded to the Faculty's Committee on Undergraduate Studies.

While it is recommended that complementary studies courses be taken as shown in the program charts, this is not a requirement except in the case of admission/promotion to Academic Term 1 which requires a course in English and a complementary studies elective to be included in the admission average.

The Engineering Program consists of ten academic terms and six work terms. For historic reasons, the first two academic terms are designated A and B with the remaining eight being numbered one through eight. All students must complete a prescribed core of courses in the first four academic terms. Upon entering Term 3 (the fifth Academic Term), students begin to specialize in their academic program and must select a specialization in either (1) Civil Engineering, (2) Mechanical Engineering, (3) Ocean and Naval Architectural, or (4) Electrical and Computer Engineering. Upon entering Term 5, students in Electrical and Computer Engineering must select either the Electrical or Computer Engineering program. Some of the courses offered in Academic Terms 3 to 8 are taken by all students, others are offered for more than one program, but most technical courses in Academic Terms 3 to 8 are specific to the individual programs. Students should refer to the charts preceding this section for the detailed course requirements in each phase of their program.

General Management of the work terms in the Co-operative Engineering Program is the responsibility of the Faculty Office of Co-operative Education. The Office, through its coordinators, is responsible for assisting potential employers to become involved in the program, for the continual development of employment opportunities, for counselling of students, for monitoring them on their work assignments and for the evaluation of the work term.

There is an "Engineering Profession Seminar" which is a three hour seminar offered in the fall term to Term I students. Issues include, but are not limited to: professional practice, gender issues, bearing of the Professional Engineers and Geoscientists of Newfoundland and Labrador code of ethics on students' behaviour.

Public and personal safety concerns are developed in the student through a number of avenues. Special non credit seminars by the Office of Co-operative Education are given to the Term 2 students which introduce the student to the work environment and include discussion on occupational health and safety legislation. During the Winter semester a one-day first-aid course is conducted which is a compulsory component of the engineering program. A student may be exempted from the requirement if evidence of previous first-aid certification is provided. Following the Winter semester engineering final examinations a one-day seminar dealing with public, personal and industrial safety, occupational health and safety legislation, quality issues and professional practice is given. An examination on material presented in this seminar is held on the following day. A pass on this exam is a program requirement. Safety concepts continue to be stressed throughout the curriculum in all programs, particularly in the design courses, and many students receive special safety training from their employers during the work terms.

Students must satisfy the first-aid and the health and safety requirements or receive an exemption from the Committee on Undergraduate Studies of the Faculty to be permitted to register for Academic Term 3.

By being exposed to the world of work, under supervision, during their academic careers, students are provided with a broader and richer preparation for life and work. The experience gained in the industrial and professional environment should give them maturity and breadth of understanding, so enabling them to define more clearly their educational and career interests and objectives. Much of the experience gained in this type of program would not be available to students until after graduation in a conventional program. This experience makes a significant contribution to their total education.

During work terms students are brought into direct contact with the engineering profession, exposed to actual practical problems, expected to assume ever increasing responsibility in employment as their education advances, and introduced to engineering projects and installations far beyond the scope of those which could be provided in the University. The experience should provide maturing prospective engineers with an early appreciation of the economic, social and personal aspects of Engineering through direct association with professionals in a technical environment.

Matching between students and employers is accomplished through a placement process which is the responsibility of the Office of Co-operative Education. Job notices are posted and students may apply for up to twelve interviews. Employers' representatives interview students, after which the employers rank students in order of preference.

Job offers are made to students based on employer rankings. Students are then placed to fit expressed preferences. The Faculty does not guarantee placement, but every effort is made to ensure that appropriate employment is made available. In the case of students who are required to withdraw from the program, the Faculty has no responsibility for placement until they have been re-admitted to the program.

Salaries paid to co-operative students are determined within the employer's own wage structure, and can be expected to increase as the student progresses through the program and assumes more responsibility. However, students should not expect the income from work terms to make them completely self-supporting.

Students in the Co-operative Program give permission to prospective employers, in the course of the interview process, to have access to their records, which contain their academic marks and their work term evaluations. After placement, students may not withdraw from a specific job situation unless prior permission is obtained from the Office of Co-operative Education.

A list of employers participating in the Co-operative Engineering Program can be found under EMPLOYERS PARTICIPATING IN CO-OPERATIVE EDUCATION ENGINEERING TRAINING.

The Co-operative Program affords an excellent preparation for a career requiring such high standards of professional judgement.

Upon the successful completion of the undergraduate program in Engineering as approved by the Faculty Council and Senate, candidates will be awarded the degree of Bachelor of Engineering.

COMPLEMENTARY STUDIES COURSES

It is clear that our society is becoming increasingly dependent on technology. This imposes the requirement that Professional Engineers not only be technically able but also be prepared to exercise social responsibility in the execution of their work. Course projects oriented toward professional practice, the work terms, the complementary studies component of the academic curriculum and a continuing emphasis on public and personal safety throughout the entire program help to develop responsible attitudes. Moreover, the students learn to communicate effectively with their colleagues, other professionals and the rest of the community on issues extending beyond specialized technical matters.

The Complementary Studies component has been developed to make students aware of the function and responsibilities of the Professional Engineer in society and the impact that engineering in all its forms has on environmental, economic, social and cultural aspects of our society. This complements the technical expertise and communications skills developed and practised in all components of the program. 

Students who have previously met a complementary studies requirement before the semester in which it is scheduled and students who wish to defer a complementary studies requirement to a later semester, may request an exemption or deferral by applying to the Associate Dean (Undergraduate). Students who have been granted an exemption or a deferral will not be required to take a replacement course in that term and their promotion from that academic term will be based on the remaining technical courses.

The Complementary Studies component is the same for all programs and consists of a minimum of 21 credit hours as follows:

1. Term A or B (3 credit hours): English 1080 (or equivalent) or English 1020

2. Terms A and B (6 credit hours): Two complementary studies electives chosen from lists provided by the Office of the Associate Dean (Undergraduate). These courses are drawn from the humanities, social sciences, arts and management and one of these courses is intended to provide experience with writing.

3. Term 1 (3 credit hours): Complementary studies elective chosen from a list provided by the Office of the Associate Dean (Undergraduate). This course must be second year or higher and it is intended to provide experience with the central issues, methodologies and thought processes of the humanities and social sciences.

4. Term 4 (3 credit hours): Engineering Economics - Engineering 4102

5. Term 5 (3 credit hours): The Engineering Profession - Engineering 5101

6. Term 6 (3 credit hours):  One of: Engineering 6101- Assessment of Technology ,  Sociology 2120 - Technology and Society,  Philosophy 2801- Technology-, or Women’s Studies 4107-  Women and Technological Change

7. For graduation, students must pass each of the seven complementary studies courses described in sections 1 - 6 and they must obtain at least a 60% average across these courses.

COMPUTING FOUNDATIONS

Engineering students are expected to have a firm foundation in the fundamentals of using computers. Recognizing that students' backgrounds may vary widely, the Faculty offers workshops from time to time, directed particularly towards students in Term 1 and 2. Attendance at workshops is voluntary; it is each individual student's responsibility to ascertain whether or not they require the material on offer. Once a workshop has been given, however, it will be assumed all students have a competence in the material taught.

MASTER OF ENGINEERING FAST-TRACK OPTION

Students registered in academic term 7 of a Memorial Univerity of Newfoundland undergraduate engineering program are eligible to apply for admission to a Master of Engineering fast-track option. The purpose of the option is to encourage students interested in pursuing graduate studies to begin their graduate program while still registered as an undergraduate student. While enrolled in the option, a student may complete some of the M.Eng. Degree requirements and, hence, potentially be able to graduate earlier from the M.Eng. Program. For further details and the regulations regarding the option, refer to the regulations governing the degree of Master of Engineering.


ENGINEERING REGULATIONS

NOTE, APPEALS, WAIVERS, AND EXEMPTIONS
ADMISSION MODES
ADMISSION
EXAMINATION AND PROMOTION


NOTE: A student may appeal against any decision of the Faculty as indicated below, and any Faculty regulation may be waived by Faculty Council or, on behalf of the Council, by the Appeal Committee or Committee on Undergraduate Studies of the Faculty, as follows, provided that no UNIVERSITY REGULATIONS - GENERAL ACADEMIC REGULATIONS (UNDERGRADUATE) is contravened by the waiver. Appeals, and applications from students for a waiver or other variance of the Engineering and Applied Science Regulations, must be submitted in writing to the Office of the Associate Dean (Undergraduate) for submission to the appropriate committee. Unless otherwise stated in the pertinent portion of the Regulations, the time limit for an application for the waiver or other variance, is as stated below in this Note.

(a) A waiver of an admission requirement may be granted by the Committee on Undergraduate Studies upon recommendation by the Faculty Admissions Committee.

(b) Appeals against decisions of the Faculty Admissions Committee and appeals against promotion decisions of Faculty Council will be considered by the Faculty Appeal Committee. An appeal against promotion decisions of Faculty Council will normally only be considered upon presentation of evidence which has not been placed before Faculty Council. Any such appeal must be made within one month of the issue of the decision of the Admission Committee or within one month of the issue of results by the Registrar, as the case may be. When a student has requested a re-read of an examination paper which may affect an appeal that appeal must nevertheless be made within one month of the issue of the original results, and consideration of the appeal will be delayed until the result of the re-read is available.

(c) Except as noted in (d) below, a request for exemption from a course or courses required in the Engineering program, the substitution of a course by another course, or any other variation of the requirements of the academic terms, will be considered by the Faculty Committee on Undergraduate Studies upon recommendation by the Associate Dean (Undergraduate) in an application concerning Core courses, or upon recommendation by the relevant Discipline Chair concerning all other courses. Any such request must be received at least one week before the last day to add courses in the semester in question.

(d) With sufficient justification, students in academic terms 7 and 8 may be permitted to substitute one of the listed technical electives in each term with an appropriate course from another engineering program or another academic unit within the University. Such a substitution requires the permission of the appropriate Discipline, which will normally consider whether the substitution is consistent with the student's program and career objectives as well as whether the substituted course is suitable for a final year engineering student. In such cases, it is the student's responsibility to make sure he/she is qualified to register for the proposed course.

(e) A request for exemption from a work term, and for any other variation in the requirements for the work terms, will be considered by the Faculty Committee on Undergraduate Studies, upon recommendation by the Office of Co-operative Education. 

Any such request must be received before or on the last day to drop courses without academic prejudice in the semester in question. Only when the circumstances which may justify a variance in the requirements occur unavoidably after this drop date, will a later application be entertained, at the discretion of the Committee.
 
An appeal against a decision by the Faculty Appeal Committee or by the Committee on Undergraduate Studies of the Faculty should be directed to the Senate Committee on Undergraduate Studies.

ADMISSION MODES

Direct Entry: Students may apply for direct entry into first year Engineering when they apply to the University from high school. Direct admission from high school is normally based upon the student being admitted to the University and having sufficient prerequisites in Mathematics and the Physical Sciences to be able to complete First Year Engineering courses in their first year of University.

Fast Track: Exceptionally well prepared students may apply for direct entry into second year Engineering (Term 1) from high school. Direct admission into second year is normally based upon a student being admitted to the University, having advanced placement equivalent to University credit in Physics, Mathematics and Chemistry and having an admission average of at least 80% in the final year of high school.

Entry from within the University: students registered in other programs within, or other campuses of, the University may apply for entry into second year Engineering (Term 1). Such entry is normally based upon the same criteria as promotion from first year Engineering into second year (see section 5) under Examinations and Promotions.

Bridging Programs: The Faculty of Engineering and Applied Science has bridging programs which allow certain diploma graduates to enter the Engineering program with advanced standing. In each case the bridging program consists of two academic terms: Fall and Winter semesters, followed by entry into Academic Term 4 of the appropriate discipline.

To be admitted to the bridging program students must have graduated from the diploma program with a cumulative average of at least 75%.

The currently approved bridging programs are:

(1) Civil Engineering Technology from the College of the North Atlantic to the Civil Engineering Program.

(2) Electrical Engineering Technology or Electronics Engineering Technology from the College of the North Atlantic to the Electrical or Computer Engineering Program.

(3) Mechanical Engineering Technology (Power) or Mechanical Engineering Technology (HVAC) from the College of the North Atlantic to the Mechanical Engineering Program.

(4) Naval Architecture Program or Marine Systems Design Program at the Fisheries and Marine Institute of Memorial University of Newfoundland to the Ocean and Naval Architectural Engineering Program.

(5) Techniques d'architecture navale at the Institut maritime du Québec, Rimouski, to the Ocean and Naval Architectural Engineering Program.

Other Entry: Students are occasionally admitted to later terms in Engineering from other institutions. Such entry is normally based on a detailed analysis of the student's record and is handled on a case by case basis.

ADMISSION

1) All complete applications for admission or readmission to the Faculty of Engineering and Applied Science must be submitted to the Office of the Registrar. A complete application includes an application to Engineering, an application to the University (for those who have not registered for courses in Memorial University of Newfoundland in either of the two preceding semesters) and supporting documentation (when necessary). Application forms are available at the Office of the Registrar and the General Office of the Faculty of Engineering and Applied Science. Applications to Term A or Term 1 should be submitted no later than March 1st of the year in which admission is sought. The Faculty Admissions Committee will begin reviewing applications after this date.

NOTE: Students intending to register for courses at this University or at another institution during the summer months who are considering entry into Engineering must still apply by March 1st.

Applications for all subsequent terms should be submitted at least two months prior to the commencement of that term. Any application received after the relevant deadline will be considered as time and space permit.

Attention is also drawn to the subsequent admission regulations and to the fact that readmission to the University does not necessarily constitute admission to Engineering.

2) Admission to the Faculty of Engineering and Applied Science is on the basis of a competition for a limited number of places. The primary criterion used in reaching decisions on applications for admission is the Admission Committee's judgement of the likelihood of an applicant succeeding in the program.

Subsequent entry into a specialized program within the Faculty of Engineering and Applied Science (Civil, Electrical, Computer, Mechanical, Ocean & Naval Architectural) is also on the basis of a competition for a limited number of places.

Success in the program depends on meeting the requirements of both academic and work terms. The Admissions Committee will assess the likelihood of an applicant being able to meet the promotions requirements outlined below.

The Faculty expects students admitted to the program to have and retain the knowledge and skills corresponding to the admission criteria listed in these regulations. This grounding in mathematics and the sciences, and the ability to communicate in writing and orally are the foundation of all the academic courses and the work terms in the program. The student is expected to build on this foundation, developing the technical and communication skills expected of a professional engineer. The Faculty may require confirmation, through an interview or other means, that an applicant is able to meet the expectations of the Faculty in this respect.

A student of engineering should be able to obtain a work term position through the job competition for each work term but the University does not guarantee to place the student in a full-time paid position in each work term. Placement will depend on the availability of positions and choices made by both employers and students. Employers are only likely to offer positions to students who can demonstrate the academic and personal qualities which fit them for the work concerned. Students must be able to communicate in job applications and interviews and as required during the work term. Some assistance in the strengthening of communication skills is available for all students in the Faculty and in particular for students who initially have some difficulty in meeting these requirements. Nevertheless a student who cannot meet the demands of the job competition may be required by the Faculty to withdraw until he or she can demonstrate an ability to continue in the program.

3) In evaluating applications the Admissions Committee takes into account the strengths and weaknesses in a candidate's academic background, and motivation towards obtaining an engineering degree. Students with weak overall academic records are unlikely to be admitted.

4) Applicants seeking admission through transfer from another institution must have achieved an equivalent standing in comparable subjects. The applicant is responsible for having certified documentation to this effect forwarded from the relevant institution(s) to the Office of the Registrar.

5) Students from areas where English is not the common language must provide certified translations of documentation and may be required to prove, by test, their proficiency in English.

6) An applicant for admission with advanced standing is responsible for having certified documentation attesting to his or her academic and relevant work experience forwarded from the university(s) or institution(s) previously attended to the Office of the Registrar. Each such application when complete will be considered by the Faculty Admissions Committee. No applicant will be admitted beyond Term 5. Because of the importance of the work experience in the cooperative program three work terms are considered an absolute minimum requirement

7) An applicant of mature age who has been away from full-time formal education for at least four years may be admitted, if the applicant can satisfy the Admissions Committee that he or she has the knowledge and capability to succeed in the program. This knowledge may, for instance, have been acquired in studies to a sufficiently high level in engineering or another discipline.

8) Engineering students to whom promotion is denied are no longer in the Engineering program. Subject to Sections 12 and 14 of the regulations on Examinations and Promotions, such students may be permitted to repeat unsuccessful terms. Those wishing to do so must apply for readmission in accordance with the Faculty and University readmission regulations. These applications will be judged by the Faculty Admissions Committee.

EXAMINATION AND PROMOTION

Academic Terms
Work Terms

1) The Faculty constitutes the examining body for all engineering examinations. The standing of every student will be assessed at the end of each academic term beyond Terms A and B and at the end of each Work Term by Faculty Council. The decisions of Faculty Council will be issued to individual students by the Registrar. The status of students in Terms A and B will be governed by the UNIVERSITY REGULATIONS - GENERAL ACADEMIC REGULATIONS (UNDERGRADUATE) of the University.

2) Any student has the right to appeal any decision made by the Faculty in regard to his or her promotion. Any such appeal must be made in writing to the Chairman of the Appeals Committee, Faculty of Engineering and Applied Science, within one month of the issue of results by the Registrar.

3) To be promoted a student must, in addition to obtaining the requisite marks and average, complete and deliver all laboratory, project work, and work reports as required.

4) The Faculty Council or the Appeals Committee of the Faculty of Engineering and Applied Science may promote a student notwithstanding promotion requirements given below. A decision of this nature will be made only for reasons acceptable to Faculty Council or the Appeals Committee as appropriate, and in the case of a student thought likely to succeed in future terms. 

Academic Terms

5) Students registered in Engineering for academic Term B must have completed a minimum of 30 credit hours and satisfy the following criteria to be able to be promoted to academic Term 1:

a) The student must obtain credit in each of the following courses: English 1080 (or equivalent) or English 1020, Chemistry 1051 (or equivalent), Physics 1051 (or equivalent), and Mathematics 1001.

b) The student must obtain 3 credit hours in each of Chemistry, Physics, and Mathematics, in addition to those specified in (a).

c) The student must obtain 9 credit hours in addition to those specified in (a) and (b). At least 6 credit hours of these must be complementary studies electives (found under COMPLEMENTARY STUDIES COURSES). Students who have completed only 3 credit hours in complementary studies may be admitted to the program in which case they will be required to obtain 3 more credit hours prior to graduation.

d) The student must obtain an average of 65% in the set of courses comprising Chemistry 1051 (or equivalent), Physics 1051 (or equivalent) and Mathematics 1001, English 1080 (or equivalent) or English 1020, and 3 credit hours of complementary studies.

e) The student must obtain at least 60% in each of Chemistry 1051 (or equivalent), Physics 1051 (or equivalent), and Mathematics 1001.

6) For the purposes of promotion extra courses required of students as a condition of entry directly into academic Term 1 (or later) will be considered part of their program.

7) At the end of any academic Terms 1 to 7, a student must have an average in the technical courses taken in the current academic term (all courses except those defined in the section COMPLEMENTARY STUDIES COURSES) of at least 60% to continue in the program. Students with an average of at least 60% and with a mark of at least 50% in each technical course taken as part of their program will be given a clear promotion. Students with an average of a least 60% and with one or more marks below 50% in technical courses taken as part of their program will be given a probationary promotion.

8) At the end of the academic Term 8, a student must have an average in the technical courses taken in academic Term 8 of at least 60% with a mark of at least 50% in each technical course taken as part of the program and a 60% average in the seven complementary studies courses described in the section COMPLEMENTARY STUDIES COURSES, to be recommended for graduation. A student with an average of at least 60% and with one or more marks below 50% in technical courses taken as part of the program will be given a probationary status. A student with a probationary status at the end of academic Term 8 will not be recommended for graduation until the student's status is transferred to that of a clear promotion.

9) Transfer from a probationary status to a clear promotion or, in the case of academic Term 8 to be recommended for graduation, will entail satisfying the Faculty that the student is competent in the subject of the course in which the student has failed to achieve 50%. In the case of engineering courses, this will normally entail re-examination, upon which the student will be declared to have passed or failed a test of competency in the subject concerned, without the assignment of a numerical grade on the test. Non-engineering technical courses which have been failed will normally have to be repeated or replaced with an alternate course.

10) A student with a probationary promotion at the end of academic Term 1 will be re-examined in the subject matter of the failed course(s) no later than the 1st week of the subsequent semester. A student who is successful in all the required re-examinations will be promoted to academic Term 2.

Failure to submit to re-examination or a failure in re-examination will result in denial of promotion.

11) A student with a probationary promotion at the end of academic Terms 2 to 7 will continue to the subsequent work term. However, entry into the next academic term will normally be allowed only when the Faculty is satisfied, through the re-examination provided for in section 9, that the student is competent in the subject matter of the failed courses.

12) A re-examination after academic Terms 2 to 8 will be at a time determined by the Faculty, but not later than the first week of the second semester after the semester in which the course was failed. Failure to submit to the re-examination or failure in the re-examination will result in denial of promotion or, in the case of course failures in academic Term 8, denial of a recommendation for graduation.

13) Re-examination may be deferred, subject to the UNIVERSITY REGULATIONS - GENERAL ACADEMIC REGULATIONS (UNDERGRADUATE) governing deferred final examinations; however, a student who is successful in a deferred re-examination may not be permitted to register for the subsequent academic term if the deferred re-examination is after the normal registration period for that term.

14) Students denied promotion with an average mark below 60% may be readmitted to the program and will normally be required to repeat all the work of the term, including courses which have been passed. With the permission of the Faculty Committee on Undergraduate Studies, an elective course may be replaced by a course deemed to be equivalent.

15) Students denied promotion with an average mark of at least 60% will be required to repeat just the failed courses, in a semester when the courses are normally offered (along with other courses in the University if the student so wishes).

16) A student may not repeat a given academic term more than once when repetition is due in part or entirely to a failure to achieve the average mark required for promotion, and a student may not repeat more than two academic terms in the entire program for which repetition is required for this reason. Academic terms or courses repeated because of failure to achieve a pass mark in individual courses, while the required overall average for the term was achieved, are excluded from this prohibition.

17) Students may be required to withdraw from the program at any time if, in the opinion of the Faculty Council, they are unlikely to profit from continued attendance.

18) For clear promotion during a bridging program, students are required to have an overall average in each semester of at least 60%, and 50% in each subject. Students who fail one or more subjects but maintain an overall average of 60% qualify for a probationary promotion, subject to a re-examination in the failed subjects.

Students promoted from the Winter Term of a bridging program will be admitted to Term 4 of the appropriate Engineering Program. 

Work Terms

19) Work terms are scheduled in the "Plan of Operation for the Co-operative Engineering Program". Work terms and academic terms must be completed in the sequence shown. The dates for starting and finishing each work term are shown in the University Diary. Successful completion of the work term requirements is prerequisite to graduation.

20) A competition for work term employment is organized by the Office of Co-operative Education as outlined in the Engineering Student Co-op Handbook. Students are encouraged to spend two consecutive work terms with a given employer provided suitable work is available.

21) Students may obtain their own work term jobs outside the competition. Such jobs must be confirmed by letter from the employer and approved by the Office of Co-operative Education on or before the first day on which the student commences work.

A student may, with the permission of the Office of Co-operative Education, be self employed during a work term, provided that the student and the Office of Co-operative Education agree at the start of the work term on the information to be provided to the Office so that it can evaluate the student's work during the term.

A student who is unable to obtain a work term job or work in approved self employment within four weeks from the start of the work term will be expected to undertake work under contract to a client within the Faculty, another entity in the University, a company, municipality, non-profit organization, or the like. The contract work may be part-time, or occupy only a portion of the semester, and may allow the student to earn an income in other ways. The contract, whether paid or unpaid, must be approved by the Office of Co-operative Education.

When neither an approved full-time work position nor an approved contract has been obtained in work Terms 1, 2, or 3, the Faculty Committee on Undergraduate Studies may approve a program which provides the affected students with technical and professional experience expected in these work terms. The program must be such that the development of the students' technical and professional development, including the development of the students' communication skills, through the program can be monitored and assessed by the Office of Co-operative Education with criteria equivalent to those used for full-time paid work term positions. Normally, a student may not take part in this type of program more than twice.

22) A student may be exempted from any work term requirements if he or she submits medical and/or other evidence to support such exemption, to the Committee on Undergraduate Studies through the Office of Co-operative Education. Also see Note (e) under Engineering Regulations.

23) A communication component must be completed for each work term. The communications requirement for each work term is specified in the course description for the work term and is covered in more detail in the Co-op Student Handbook. The actual format will depend on the specific requirements of the Faculty for the work term. If an employer designates a written report to be confidential, a non-disclosure agreement must be completed to legally protect the confidential material. Written documents must be submitted on or before the deadline date shown in the University Diary. Presentations, when required, will normally be given at the University at a time arranged by the Faculty Office of Co-operative Education.

24) The overall evaluation of the work term is the responsibility of Engineering Co-operative Education. Work term grades are submitted to the Faculty Council of Engineering and Applied Science at the end of each work term. The work term evaluation consists of two components: student work term performance as evaluated by a co-ordinator, given input from the employer, and a communications component evaluated by a co-ordinator or delegate. Each component is evaluated separately.

Evaluation of the work performance will result in one of the following classifications: EXCELLENT, ABOVE AVERAGE, SATISFACTORY, NEEDS IMPROVEMENT, UNSATISFACTORY.

Evaluation of the communications component will result in one of the following classifications: EXCELLENT, ABOVE AVERAGE, SATISFACTORY, UNSATISFACTORY.

Overall evaluation of the work term will result in the assignment of one of the following final grades:

a) Pass with Distinction: To receive a recommendation of PASS WITH DISTINCTION, a student needs to obtain an evaluation of EXCELLENT in both the communication and work performance components of the work term.

b) Pass: To receive a recommendation of PASS a student must achieve an evaluation of SATISFACTORY or better in the communication component and a NEEDS IMPROVEMENTor better in the performance component of the work term.

c) Fail: A student receiving an UNSATISFACTORY in either or both the communication and performance components of the work term will receive a recommendation of FAIL.

For promotion from the work term, a student must obtain PASS WITH DISTINCTION or PASS.

25) Students who fail a work term will normally repeat that work term in a work situation approved by the Office of Co-operative Education. A given work term may be repeated only once, and not more than two work terms may be repeated in the entire program.

Notwithstanding the above, a student who does not achieve a passing grade and who in the opinion of the Faculty Council can benefit from a remedial program, may be permitted an extension of time not to exceed the end of the Regular Registration Period of the subsequent semester to complete the requirements of the work term.

26) Students who fail to honour an agreement to work with an employer, or who leave the co-operative employment without prior approval of the Office of Co-operative Education, or who conduct themselves in such a manner as to cause their discharge from the job, will normally be awarded a Failed Work Term.

NOTE: Students should also refer to the UNIVERSITY REGULATIONS - GENERAL ACADEMIC REGULATIONS (UNDERGRADUATE) of the University.


FACULTY OF ENGINEERING AND APPLIED SCIENCE COURSE LIST

COURSE NUMBERING

With the exception of Engineering 1000, courses offered by the Faculty of Engineering and Applied Science are identified by a four-digit numbering system, each digit signifying the following:

FIRST - Academic term during which the course is normally offered

SECOND - The primary areas of study, namely:
1 - Complementary Studies
2 - Structure and Behaviour of Materials
3 - Physical Concepts
4 - Mathematics
5 - Engineering Design
6 - Resource-Related
7 - Civil Engineering
8 - Electrical and Computer Engineering
9 - Mechanical Engineering
0 - Ocean and Naval Architectural Engineering

THIRD - Course grouping within areas or programs

FOURTH - Course sequence or revision.

COURSE LIST

In accordance with Senate's Policy Regarding Inactive Courses, the course descriptions for courses which have not been offered in the previous three academic years and which are not scheduled to be offered in the current academic year have been removed from the following listing. For information about any of these inactive courses, please contact the Dean of the Faculty.

TERM 1 COURSES
TERM 2 COURSES
TERM 3 COURSES
TERM 4 COURSES
TERM 5 COURSES
TERM 6 COURSES
TERM 7 COURSES
TERM 8 COURSES



TERM 1 COURSES

NOTE: All students take a Complementary Studies elective in Term 1 (For a list of electives see  COMPLEMENTARY STUDIES COURSES).

1000. An Introduction to Engineering. - inactive course.

1313. Mechanics I. Statics with an Introduction to Dynamics. Introduction to vector algebra. Coplanar and non-coplanar force systems, equivalent force systems, moments and equilibrium, emphasizing the use of free body diagrams. Analysis of trusses, frames and machines. Dry friction. Centers of gravity and centroids. Moments of inertia of areas. Geometric aspects of particle motion (kinematics).

1333. Basic Electrical Concepts and Circuits. Electrical charge, the electric field, energy and voltage, electric current; the magnetic field and its relation to current; sources of electromotive force. Basics of signals and waveforms, periodicity, average and root-mean-square values. Conduction, charge storage, and magnetic flux changes as a basis for component models as resistance, capacitance, and inductance; power and energy relationships. Kirchhoff's laws; formulation and solution for simple circuits; equivalent circuits; Thevenin and Norton representations. The sinusoidal steady state for R-L-C circuits; energy transfer and power, energy storage and reactive power; phasor methods. Relevant laboratory exercises.
NOTE: Credit cannot be obtained for both Engineering 1333 and 2333.

1405. Engineering Mathematics I. Linear systems and matrices, vector spaces, sequences & series, complex numbers, parametric and polar curves.

1504. Engineering Graphics. Graphics Fundamentals: This part of the course covers the fundamentals of effective graphic communication skills, including drawing with instruments, freehand sketching, orthographic projections of solid objects, auxiliary views, sections, three dimensional pictorials, dimensioning and tolerances, working drawings, and assembly drawings. Computer Graphics: This part of the course introduces the use of a computer aided design package for the construction of two-dimensional drawings and three-dimensional models of engineering objects. These models are used for creating all the necessary projections for the production of engineering drawings. The engineering graphics principles and visualization skills developed in the graphics portion of the course are employed and reinforced.

TERM 2 COURSES

2205. Chemistry and Physics of Engineering Materials I. An introduction to the structure and properties of engineering materials, in particular metals, semiconductors, ceramics, glasses and polymers. Topics include a review of atomic bonding, discussion of basic crystalline and amorphous structures, point and line defects, and the role these structural features play in elastic and plastic deformation, yield, fracture, glass transition, thermal conductivity, thermal expansion, specific heat and electrical conductivity. Relevant laboratory exercises.

2313. Mechanics II. Kinematics and Kinetics of Rigid Bodies. Kinematics, review of particle kinematics, rigid body kinematics in a plane, introduction to rigid body kinematics in 3-D. Kinetics (particle and rigid body theory), force-acceleration, work-energy, impulse momentum. Engineering applications of rigid body kinematics and kinetics.

2420. Structured Programming. Simple programs and the programming environment. An introduction to computer architecture - hardware, instructions and data. The major control structures as building blocks for computer programs. Variables, constants and data types, representations, ranges and declarations. Simple input/output processes and data formatting. Strings. Functions, subroutines and the basic issues of modularity. Programming style. Sequential files.

2422. Engineering Mathematics II. Partial differentiation, ordinary differential equations, Laplace transforms, applications.

2503. Engineering Design. This course introduces students to the design process through project based activities. Students will develop a systematic approach to open-ended problem solving. Topics incorporated into the design activities include the development of problem statements and design criteria, solution generation, solution evaluation, feasibility analysis, team work, project management and effective communications. The lab portion of the course provides exposure to practical design issues, familiarity with common shop practice and tools, and an opportunity to fabricate some of the proposed design solutions.

200W. Professional Development Seminars. - inactive course.

001W. Engineering Work Term I (Spring Semester). For most students this Work Term represents their first experience in an engineering or related work environment and as such represents the first opportunity to evaluate their choice of pursuing an engineering education. Students are expected to learn, develop and practice the basic standards of behaviour, discipline and performance normally found in their work environment.

The communications component for Work Term 1 consists of two documents which must be submitted for evaluation; additional communications requirements (e.g. technical report, manual) may be requested by the employer. The two documents to be submitted to the Engineering Co-operative Education Office are:

1. Personal Job Diary
2. Work Term Journal or Short Technical Report or Portfolio.

Detailed guidelines for the preparation of these documents are provided in the Engineering Student Co-op Handbook. These documents should be submitted or postmarked no later than the last official day of the work term as shown in the University Calendar.

011W. Engineering Practice Program. This program is intended to improve the student's skills in oral and written communication, comprehension, problem solving and analysis. The program will normally be an alternative to the first work term encountered by the student and may only be taken on the recommendation of the Office of Co- operative Education and the approval of the Faculty Committee on Undergraduate Studies. The student will be evaluated in this program and must achieve a mark of 60% in order to be promoted to the subsequent academic term. 

TERM 3 COURSES

3054. Ocean Engineering Hydrostatics. This is an introductory course to naval architecture and marine engineering. It discusses the basic principles of the statics of rigid floating or submerged structures. These include: ships, offshore platforms and submersibles. Methods of analysis of the hydrostatics, stability and trim, damage stability and the statics of mooring systems are introduced. Applications are also discussed.

3205. Chemistry and Physics of Engineering Materials II. Aspects of chemical and physical processes and microscopic structure relevant to the production and use of engineering materials, focusing on metals, alloys, silicates, portland cement, plastics and adhesives, composites, and wood. Topics include solid-state solutions and compounds, alloy structures, phase diagrams, reaction rates, solid-state transformations, polymerization, oxidation and corrosion, hardness, creep, fatigue, fracture toughness, and visco-elastic deformation. Relevant laboratory exercises.

3422. Discrete Mathematics for Engineering. An introduction to discrete mathematics including a selection of topics such as propositional logic, introductory predicate logic, mathematical reasoning, induction, sets, relations, functions, integers, graphs, trees, and models of computation.

3423. Probability and Statistics. Probability; probability distributions; probability densities; sampling distribution; hypothesis testing; regression and correlation.

3610. Earth Sciences for Civil Engineering. Introduction to basic concepts in Geology and Mining with emphasis on applications in Civil, Geological, Mining and Environmental Engineering through the use of case histories. Includes the study of rocks and minerals in selected field and laboratory exercises.

3703. Surveying and Geomatics. Plane surveying: distance, elevation, and angle measurements; horizontal and vertical curves; plane survey calculations; area and volume computations. Photogrammetry: sensors and platforms, mathematics of photogrammetry; instruments and equipment, photogrammetric products, digital photogrammetry, remote sensing, and introduction to global positioning and geographical information systems (GIS). A surveying field school to introduce students to the use of surveying equipment and mapping will be held in the first two weeks of the term. Relevant laboratory exercises.

3731. Materials of Construction. Physical properties of common construction materials, primarily metals, woods, concrete and asphalt; examination of properties with respect to design and use of end product; design procedures for concrete and asphalt; introduction to the use of reference handbooks and manufacturers specifications. Introduction to reinforced concrete. Relevant laboratory exercises.

3821. Circuit Analysis. Review of elementary circuits, wye-delta transformation, bridge circuits; transient analysis of first- and second -order circuits; sinusoidal steady state analysis, phasor diagrams, maximum power transfer, frequency selective circuits (filters); Laplace transforms in circuit analysis (transients, steady state, transfer function). Relevant laboratory exercises.

3844. Basic Electrical Components and Systems. (Non-Electrical Engineering Students) Introduction to electrical engineering; review of circuit concepts and analysis; operational amplifiers; filters; analog electronics and instrumentation; transducers; basics of rotating machinery and transformers; models, characteristics and applications of dc motors, induction motors, synchronous motors and transformers; introduction to motor control; plant power system; electrical safety.

3861. Digital Logic. Number systems and arithmetic, Boolean algebra; combinational logic circuits: gates, memory devices, programmable logic devices; asynchronous sequential logic circuits: flip-flops, counters, registers; synchronous sequential logic circuits: races and hazards, introduction to algorithmic state machines; design with digital integrated circuits. Relevant laboratory exercises.

3891. Advanced Programming. Advanced procedural language programming; data structures, user defined types, unions and pointers; modularization techniques, scope and data hiding; object-oriented programming; classes, objects and attributes; data encapsulation, member and non-member functions; overloading, methods and friend functions; inheritance, sub- and super-classes.

3901. Thermodynamics I. Macroscopic approach to heat, work, and energy; properties of pure substances; conservation of mass; conservation of energy for open and closed systems; thermal efficiency and coefficients of performance; the second law of thermodynamics and its corollaries; entropy; second law analysis of thermodynamic systems; second law efficiency. Relevant laboratory exercises.

3933. Mechanisms and Machines. Overview of mechanisms within machines; graphical and matrix methods for analysis of moving mechanisms; kinematics and kinetics of planar mechanisms; dynamic formulations: Newton-Euler and Lagrangian; loads on mechanisms; synthesis of mechanisms. Synthesis project. Relevant laboratory exercises.

3941. Production Technology. Overview of production; production strategies; dimensioning and tolerancing; basic material removal processes; forming and shaping processes; casting, molding, extrusion and joining processes; computer aided machining; new technologies. Relevant laboratory exercises.

002W. Engineering Work Term 2 (Winter Semester). Students are expected to further develop and expand their knowledge and work- related skills thus enabling them to accept increased responsibility and challenge. Students should also demonstrate an ability to deal with increasingly complex word-related concepts and problems.

The communications component for Work Term 2 consists of two documents: an Industry Company Profile (ICP) which must be submitted for evaluation and a Job Diary which will not be submitted but must be available for review during monitoring. Additional documents (e.g. technical report, manual) may be requested by the employer. The ICP consists of a general industry profile, a company profile, an outline of the student's role within the company and supporting documents. The words Industry and Company are used here in a broad sense and include governments, regulatory agencies etc. Detailed guidelines for the preparation of the ICP are provided in the Co-op Student Handbook. The ICP should be submitted or postmarked no later than the last official day of the work term as shown in the University Calendar. 

TERM 4 COURSES

NOTE: Engineering 4102 is a required Complementary Studies course.

4061. Marine Production Management. Introduction to engineering and related management information systems; demand forecasting; planning and scheduling; plant layout including assembly line balancing, process and group technology layout, fixed position layout, plus flexible manufacturing, just in time, and computer integrated manufacturing concepts; productivity measurement and management; introduction to quality management; tendering and bidding on contracts; human resource management.

4102. Engineering Economics. Introduction to concepts in the determination of the economic feasibility of engineering undertakings, especially the time value of money-interest rates, depreciation, replacement, economic life, present value, rate of return, payback period. Other topics will include financing, supply and demand, private and social cost estimations, secondary and intangible benefits and costs, benefit-cost models, economic risk analysis, economic optimization.

4312. Mechanics of Solids I. Axial force, shear and bending moment. Stress-strain relations. Torsion. Bending and shearing stress in beams. Thin cylinders. Compound stresses. Transformation of stress. Relevant laboratory exercises.

4322. Thermal Sciences. Fundamental concepts associated with thermodynamics, fluid dynamics and heat transfer; first and second laws of thermodynamics; system and control volume analysis; classification of flows; introduction to boundary layers and drag; convection, conduction and radiation heat transfer; thermal insulation and calculation of R-values; cooling of electrical components.

4422. Introduction to Numerical Methods. Errors; numerical stability; solution of linear and nonlinear equations and systems; introduction to eigenvalues and eigenvectors; function and data approximations; numerical differentiation and integration of functions; numerical solution of ordinary differential equations. Relevant computer laboratory exercises.

4423. Numerical Methods for Electrical Engineers. Introduction to numerical methods including analysis of errors; interpolation; solution of linear systems of equations; eigenvalues and eigenvectors; solution of nonlinear equations; optimization methods; numerical differentiation and integration; solution of ordinary differential equations; random number generators; introduction to simulation methods. Relevant computer laboratory exercises.

4717. Applied Environmental Science and Engineering.Nature and scope of environmental problems; concept of sustainable development; natural environmental hazards; introduction to ecology, microbiology and epidemiology; basic concepts of environmental quality parameters and standards; solid and hazardous wastes; atmospheric, noise, and water pollution, their measurements, and control. Relevant laboratory exercises.

4723. Geotechnical Engineering I. Introduction to soil as a three-phase material; physical and mechanical properties; structure; classification of soils; hydraulic properties; permeability; effective stress concept in soils; shear strength, types of tests and applications; one-dimensional consolidation theory. Relevant laboratory exercises.

4823. Introduction to Systems & Signals. Introduction to systems and signals; mechanical and electrical analogues; principles of linear superposition and time invariance; definition, properties, and use of the delta function; applications of complex functions and variables; impulse and step responses; input-output relations of continuous-time systems in terms of convolution and transfer functions; frequency response plots; the Fourier transform and applications; applications of Laplace transform to filtering, communications, and controls. Relevant laboratory exercises.

4854. Electronic Devices and Circuits. Principles of operation of the diode, bipolar junction transistor and metal-oxide semiconductor, field-effect transistor; terminal characteristics, graphical analysis; biasing of devices; device and circuit models of dc, small-signal and high-frequency analysis; single-stage amplifiers; differential and multi-stage amplifiers; digital electronics; applications of electronic devices; design of regulated dc power supplies and mid-frequency signal amplifiers using discrete components; computer-aided analysis and design of electronic circuits. Relevant laboratory exercises.

4862. Microprocessors. Microprocessor architecture. Assembly language programming: addressing modes, table look up. Memory mapped devices. Interfacing techniques: parallel, serial. Timing control. Analog input and output. Computer displays. Relevant laboratory exercises.

4892. Data Structures. Fundamental data structures; recursive structures and programming techniques; modularity and reusability; time complexity and efficient data structures; procedure abstraction; data abstraction and precise documentation of data structures.

4901. Thermodynamics II. Thermodynamic cycles: power and refrigeration applications; human comfort and air conditioning: mixture of gases and vapours, humidity, psychometrics; chemically reacting mixtures; combustion. Relevant laboratory exercises.

4913. Fluid Mechanics I. Fluid statics; fluid flow phenomena; control volume analysis of fluid motion; conservation of mass, momentum and energy; Bernoulli equation; head losses. Applications of conservation laws: flow measurement devices; pipe networks; momentum devices; dimensional analysis. Boundary layer phenomena. Lift and drag. Relevant laboratory exercises.
NOTE: Credit may not be obtained for both Engineering 5713 and Engineering 4913.

4933. Electro-mechanical Systems. Review of motors and sensors; hydraulics and pneumatics; basics of automatic control: control system simulation; digital electronics; computer based controllers; programmable miniature controllers; direct digital controllers; programmable logic controllers. Case studies. Synthesis project. Relevant laboratory exercises.

003W. Engineering Work Term 3 (Fall Semester). Students should have the sufficient academic grounding and work experience to contribute in a positive manner to the engineering design and problem solving processes practiced in the work environment. Students can become better acquainted with their chosen discipline, can observe and appreciate the attitudes, responsibilities, and ethics normally expected of engineers. Students are expected to show greater independence and responsibility in their assigned work functions.

The communications component for Work Term 3 consists of preparing a formal, descriptive technical report which must be submitted for evaluation. Students are also expected to keep a job diary. Additional communication requirements may be requested by the employer. The technical descriptive report should describe a technical process, project, procedure or investigation chosen from the student's work environment. Guidelines for the preparation of a descriptive technical report are provided in the Co-op Student Handbook. The report should be submitted or postmarked no later than the last official day of the work term as shown in the University Calendar. 

TERM 5 COURSES

NOTE: All students take an approved Complementary Studies elective in Term 5. The elective is chosen from a list provided by the Office of the Associate Dean.

5011. Resistance and Propulsion of Ships I. Phenomena resisting the motion of ships and some factors considered in the design of the marine screw propeller. The topics include the resistance due to friction, wave making, form appendage, wind and waves, squat, blockage, and shallow water effects, and also include the estimation of powering using methodical series and statistical methods as well as a treatment of the resistance of some specialist vessels, e.g. semisubmersibles and hydrofoils. Topics considered in the design of the marine screw propeller include propeller theory, blade sections, blade strength, methodical series charts, efficiency elements, lifting line calculations, cavitation, and propellers in non-uniform flow. Relevant laboratory exercises are provided.

5101. The Engineering Profession. Origins and development of Engineering as a profession and an examination of its values. The place of technology in society and the nature of technological decisions.

5312. Mechanics of Solids II. Failure theories for ductile and brittle materials; statically determinate and indeterminate beams; elastic bending of beams; impact loads; stability of columns with centric and eccentric loads; plastic bending of beams; plastic hinges. Relevant laboratory exercises.

5432. Advanced Calculus. (Electrical). Vector Calculus, partial differential equations, Fourier series, boundary value problems.

5434. Applied Mathematical Analysis. (Civil). Numerical and analytical solution of systems or ordinary differential equations using predictor-corrector and Runge-Kutta methods; boundary value problems, eigenvalue problems, numerical dsolution of partial differential equations using the methods of finite differences, (SOLR) successive over-relaxation and characteristics, simplex method for linear programming; numerical Fourier Analysis.

5435. Advanced Calculus. Overview of vector calculus; Gauss's theorem; Stokes' theorem; Green's theorem. Partial differential equations for mechanical systems: classification and solution. Calculus of variations: functionals for mechanical systems; Lagrangian formulation of dynamics.

5706. Design of Concrete Structures. Review of concrete mix design; design methods and requirements, strength of rectangular sections in bending, balanced condition at ultimate strength with tension reinforcement, bending with both tension and compression reinforcement; serviceability, deflections, flexural crack control for beams and one-way slabs; shear strength, inclined cracking, and shear reinforcement; bond stress and development of reinforcement; T-sections in bending; members in compression and bending; length effects, lateral ties, spiral reinforcement and longitudinal bar placement. Relevant laboratory exercises.

5708. Design of Civil Engineering Systems. Introduction to civil engineering systems, optimization in design, risk and decision analysis, and measurements; risk management, uncertainty associated with competition, optimizing using mathematical programming; introduction to dynamic programming and network analysis; applications of systems techniques to various subdisciplines of civil engineering.

5713. Fluid Mechanics. Properties of fluids; fluid statics; buoyancy and stability; kinematics, continuity, energy and momentum principles; energy and hydraulic gradelines; laminar and turbulent flow; introduction to boundary layers, drag, jets and wakes; fluid measurement; principles of similitude and modelling. Relevant laboratory exercises.
NOTE: Credit may not be obtained for both Engineering 5713 and Engineering 4913.

5812. Basic Electromagnetics. Coulomb's law and electric field intensity; electric flux density and Gauss' law; electrostatic potential and energy; conductors, dielectrics, and capacitance; Laplace's and Poisson's equations; the steady magnetic field; magnetic forces and magnetic materials; steady magnetic field and static electric field.

5821. Control Systems I. Introduction to control systems, negative feedback, on/off and PID controllers; mathematical modeling of electromechanical systems; transfer functions and state space models, block diagram reduction, introduction to signal flow graphs; controller realization using op-amps; steady state and transient response analysis; Routh’s stability criterion; basic control actions and response of control systems; root locus analysis and design; analysis and design of compensators in time domain; frequency response analysis; bode diagram; gain and phase margins; compensator design in frequency domain; Nyquist stability criterion; introduction to PID controller tuning methods; analysis and design of control systems using Matlab. Relevant laboratory exercises.

5842. Electromechanical Devices. Introduction to fundamental principles of energy conversion; review of three-phase systems; magnetic fields and circuits; transformer models, performance and applications; basic concepts of rotating machines; translational and rotational transducers; characteristics, performance and control of dc machines; principles of ac generators and motors. Relevant laboratory exercises.

5854. Analog Electronics. Fundamental feedback equations and their applications; feedback topologies in electronics; operational amplifiers: ideal models and circuits, and detailed analysis of specifications; bias currents, offset voltages, CMRR, noise, slew rate and bandwidth; interface circuits, comparators, sample-and-hold, A/D and D/A converters; phase-locked loops; computer-aided design and analysis of electronic circuits. Relevant laboratory exercises.

5865. Digital Systems. Review of basic topics in logic design; advanced minimization techniques; design of combinational and sequential circuits with programmable logic devices (PLDs); topics in state machine design; asynchronous sequential circuits; introduction to microprogramming; central processing unit design; memory management; parallel processing; advanced computer architectures; design automation; design for testability; digital system reliability; transmission line effects.

5891. Design and Analysis of Algorithms. Basic combinatorial analysis; recursive algorithms; complexity analysis; sorting and searching; problem solving strategies; complexity classes; computability and undecidability.

5895. Software Design. The development process: requirement analysis, design, iterative development, design documentation; an introduction to the Unified Modeling Language: use cases, class diagrams and sequence diagrams; an introduction to software design patterns: creational patterns, structural patterns and behavioural patterns; object-oriented, modular decomposition. The course includes a major design project.

5913. Fluid Mechanics II. Differential analysis of fluid motion; conservation of mass: continuity equation; conservation of momentum: Navier-Stokes equations; conservation of energy; inviscid incompressible flows; low Reynolds number flows; boundary layer flows; compressible flows. Relevant laboratory exercises.

5926. Mechanical Component Design I. Review of loads and stresses; design of springs, power screws, threaded fasteners, clutches, brakes, belt drives, spur gears, and gear trains. Synthesis project. Relevant laboratory exercises.

5932. Mechanical Vibrations. Free and forced vibrations of single and multi-degree of freedom systems; response to periodic and non-periodic excitations; vibration isolation and control; vibration measurement. Relevant laboratory exercises.

004W. Engineering Work Term 4 (Spring Semester). Students should anticipate greater participation in their selected engineering discipline and become more experienced and proficient with the appropriate design procedures. Students are expected to acquire improved speed and accuracy in their work and at the same time, be willing to accept greater responsibility and to function with less direct supervision. The use and importance of recently acquired analytical skills in engineering analysis should become more apparent and be applied when appropriate. The purpose and application of specifications and codes should be demonstrated when necessary.

The communication component for Work Term 4 consists of an oral presentation on a technical subject taken from the student's work environment; additional communication requirements may be requested by the employer. Preferably the topic should be specifically related to the students's work. The presentation should be of 10 minutes duration and will be given on campus in a formal setting after students have returned to class. A written summary is also required. Guidelines for the preparation of this oral presentation are provided in the Co-op Student Handbook. 

TERM 6 COURSES

NOTE: Engineering 6101 is a required Complementary Studies course for all students.

6002. Ship Hull Strength. Longitudinal strength, still water and wave bending moment, shear and bending moment curves, Smith Correction, section modulus calculation, torsion and racking forces. Bulkhead and girder scantlings, portal frame analysis by moment distribution and energy method. Finite element analysis. Use of Classification Society rules for design of midship section.

6020. Marine Propulsion. This is a second course in marine screw propellers and ship powering which includes design and analysis of marine propellers and unconventional propulsion devices. Significant emphasis is placed on systems such as waterjets; podded and azimuthing propulsors; contra-rotating propellers; high efficiency devices such as van wheels, wake equalizing ducts, swirl vanes; ducted propellers; novel devices such as oscillating propulsors to wind propulsion; design of ice-class marine propellers; and ship powering evaluation methods for vessels with compound propulsors. Relevant laboratory exercises.

6030. Dynamics and Maneuvering of Ocean Vehicles. Applications of the linearised equations of motion to ocean vehicle problems with single and multiple degrees of freedom. Dynamics and maneuvering of marine vehicles: motions in calm water and in waves; hydrodynamics effects such as added mass, radiation and viscous damping; strip theory; irregular motions; and systems for course keeping and motion control. Relevant laboratory exercises.

6045. Marine Engineering Systems. Shafting system design; shafting system vibration analysis, study of exciting forces and moments, and balancing of reciprocating and rotating machinery; heat transfer and marine heat exchangers; incompressible fluid flow and piping system design and selection of appropriate pumping devices. Relevant laboratory exercises.

6101. Assessment of Technology. This course deals with the issues of the impact of technology on society from an economic, environmental and sociological point of view. Public safety as an engineering responsibility will also be covered. Students will be expected to participate in group discussions, write a number of essays and give oral presentations.

6601. Introduction to Offshore Petroleum Engineering. Introduction to the offshore oil and gas engineering industry; the harsh environment; types of platforms and structures; the field surveying process; and exploration phase of offshore oil development. An introduction to petroleum fluids, equipment and processes. Composition and physical properties of liquid and gaseous petroleum fluids. Production drilling and completion methods and equipment. Producing mechanisms. Separation and compression processes and equipment. Instrumentation and control systems. Transportation systems. Refinery processes.
Instructional hours per week: 3 lecture hours.

6705. Structural Analysis I. Structure classification and loads. Building code provisions. Analysis of statically determinate arches and frames. Shear and moment diagrams for frames. Influence lines for statically determinate structures. Approximate analysis of indeterminate trusses and frames. The force method of analyzing indeterminate beams and frames. Introduction to slope deflection method. Moment distribution method. Relevant laboratory exercises.

6707. Design of Concrete and Masonry Structures. Design methods for reinforced concrete two-way slabs. Two-way slabs supported on walls and stiff beams. Design of two-way slab systems, direct design method and equivalent frame method. 
Design of concrete retaining walls and basement walls, Engineered masonry, allowable masonry stresses, mortar stress, analysis and design of flexural members, axial load and bending in unreinforced and reinforced walls, columns and masonry shear walls. Relevant Laboratory exercises.

6713. Hydraulics. Flow in pipe systems and networks; uniform and non-uniform flow in channels; rotodynamic machinery, pumps, turbines and associated conduits; hydraulic models; introduction to bed scour and erosion. Relevant laboratory exercises.

6723. Geotechnical Engineering II. Pressure in soils beneath loaded areas; immediate and consolidation settlement; differential settlement; plastic equilibrium in soils; flownets; stability of slopes; introduction to bearing capacity theories. Relevant laboratory exercises.

6740. Contract Law and Labour Relations. Introduction to law as it applies to engineering activity; the nature of law and legal processes, including standard forms; liens, bonds and insurances. The labour movement in North America; examination of union philosophies and managerial attitudes; labour law and collective bargaining; disputes and settlements.

6806. Project Design Labs in Electrical and Computer Engineering. This course includes a team project. Students are expected to apply previously acquired knowledge in an integrated fashion to the solution of an electrical/computer engineering problem. An open-ended problem will be chosen to emphasize all phases of the development process including problem definition, design, implementation, and testing, and students will be required to demonstrate that given objectives and specifications have been met. Written and oral project reports will be required.

6813. Electromagnetic Fields. Faraday's law; displacement current and modified Ampere's circuital law; Maxwell equations; Poynting's theorem; plane waves; transmission lines; rectangular and circular waveguides.

6825. Control Systems II. Sampled data systems; design of digital control systems using transform techniques; state space models for single- and multi-input/output systems; observability, controllability; state feedback without and with integral controller structure, state observers; quadratic optimal regulator and tracking control strategies; introduction to stability and control of non-linear systems.

6843. Rotating Machines. Fundamentals of rotating machines; design of machine windings; polyphase and single phase induction motor theory and applications; synchronous machine theory; stability and control of synchronous generators; control and protection of rotating machines; introduction to special-purpose machines. Relevant laboratory exercises.

6861. Computer Architecture. Memory management; microprogramming; parallel processing system principles; modern computer architectures; sample devices.

6871. Communication Principles. Review of signal representation and analysis; distortionless signal transmission, baseband vs. passband transmission; amplitude modulation including double sideband suppressed carrier (DSB-SC) AM, large carrier AM, quadrature AM (QAM), single sideband (SSB) AM, vestigial sideband (VSB) AM, and the super-heterodyne receiver; frequency/phase modulation (FM/PM) including bandwidth, generation and demodulation, and pre-emphasis and de-emphasis; sampling theorem, pulse amplitude modulation (PAM), pulse code modulation (PCM), delta modulation.

6876. Voice and Data Communications. Introduction to communication networks such as the telephone network and the Internet; flow control and error control; circuit switching; packet switching; local area networks; internetworking; communication architectures and protocols.

6891. Formal Programming Methods. Fundamentals of formal program specification, derivation, and verification; data refinement; rudiments of formal language theory including regular expressions, CFGs, and top-down and bottom-up parsing; system specification methods such as statecharts and SCR.

6901. Heat Transfer I. Introduction to the three modes of heat transfer. Steady-state, one-dimensional heat conduction: thermal resistance; thermal sources and sinks; fins; contact resistance. Steady-state, multi-dimensional heat conduction: shape factors. Unsteady-state heat conduction: lumped capacity analysis; Heisler charts. Radiation heat transfer: physical mechanism; radiation circuits and shields. Convection heat transfer: empirical correlations. Relevant laboratory exercises.

6925. Automatic Control Engineering. Background review; feedback concept; unit impulse response function; transfer functions; block diagrams; controllers; system stability: characteristic equations, Routh Hurwitz criteria, root locus plots, Nyquist plots, Bode plots; performance measures; performance adjustment: compensation; nonlinear phenomena: limit cycles, practical stability. Synthesis project. Relevant laboratory exercises.

6926. Mechanical Component Design II. Failure modes and mechanisms; stress concentrations; design of transmission shafts, bolted connections, welded joints, roller and hydrodynamic lubrication bearings. Codes and standards. Relevant laboratory exercises.

6972. Industrial Materials. Physical and mechanical properties; industrial materials: metals and metal alloys, ceramics and polymers, composite materials; failure modes and mechanisms; non-destructive testing and evaluation; damage tolerant materials; material treatments; materials selection. Relevant laboratory exercises.

005W. Engineering Work Term 5 (Winter Semester). Students may expect to be involved in design projects to the extent of preparing formal proposals and reports, including specifications and plans. Self confidence and initiative should be sufficiently developed at this stage to enable a student to work at such functions with limited supervision.

The communications component for Work Term 5 is a formal technical report. The subject should be taken from the student's work or work environment and should deal with a project or problem worked on during the term. The report should be documented according to engineering standards. Guidelines for a formal technical report are provided in the Co-op Student Handbook. The report should be submitted or postmarked no later than the last official day of the work term as shown in the University Calendar. 

TERM 7 COURSES

7002. Ship Structural Analysis and Design. Review of longitudinal strength. Principal stress distributions and stress trajectories. Local strength analysis. Panels under lateral load. Columns and stanchions. Panels in buckling under uniform edge compression loading and panels under shear and combination loading. Rational midship section design synthesis based on stress and loading hierarchy. Primary, secondary and tertiary stresses as criteria of strength in ship structural design, including grillage aspects.

7005. Floating Ocean Structure Design. The analysis of forces on ocean structures and structural characteristics of circular steel shell hulls. Topics include wave loading theory; wind loading; stability and trim; pressure vessel design theory and codes; combined bending and pressure loads; consideration given to various vessels including floating platforms, articulated columns and buoys.

7033. Marine Hydrodynamics. Fundamental equations of hydrodynamics, boundary layers; potential flow, added mass, damping, circulation, and vorticity; numerical methods for hydrodynamic coefficients; water waves and loading for regular and irregular seas.

7052. Ocean Systems Design. Preliminary design methods for the design of marine platforms and vehicles from mission statement to the selection of one or more acceptable solutions. Weight and cost estimating, power requirements estimating, and selection of principal design characteristics. Economic and operational evaluation of alternative solutions. Relevant design laboratory projects.

7601. Geosciences Applied in Offshore Engineering. An introductory course related to the effect of marine sedimentary environments on engineering applications. The course introduces basic concepts in geology and geophysics of the offshore environment. Sediments are studied with special reference to seismic and acoustic methods to remotely determine their mechanical properties. Specific geological hazards (earthquakes, tsunami, turbidity currents, shallow gas, gas hydrates) are assessed in terms of the sediment location and mechanical strength. Examples are drawn from case histories on the Newfoundland Shelf and Slope.
Instructional hours per week: 3 lecture hours.

7602. Subsea Engineering. - inactive course.

7603. Ocean Ice Engineering. - inactive course.

7680. Supervisory Control and Data Acquisition. Data acquisition and intelligent field devices; distributed systems and field bus technology; programmable logic controllers and programming standards; operator control interface; supervisory control and data acquisition; enterprise organization. Relevant laboratory exercises.
Instructional hours per week: 3 lecture hours; 2 laboratory hours.

7704. Design of Steel Structures. Limit states design concepts. Material strength and cross-section properties. Structural steel material standards and products. Design of tension members, axially loaded compression members, and the effective length concept. Design of beams and beam-columns. Design of welded and bolted connections. Example of simple steel building design, illustrating typical roof and wall systems, and interior and exterior columns. Relevant laboratory exercises.

7706. Structural Analysis II. Matrix stiffness method for structures: trusses, beams and frames. Degrees of freedom, statics/deformation matrices, element/structural local/global stiffness matrices, load vector, assembly/solution of the matrix equations. Matrix force method. Finite element method for truss, beam and plane stress/ strain problems: Nodal/generalized displacements, displacement functions, strain-displacement and stress-strain matrices. Force- displacement matrix, transformation/assembly/solution of matrix equations. Use of a personal computer matrix/finite-element method software for solving truss, frame and plane stress/strain problems. Relevant laboratory exercises.

7713. Hydrology and Water Resources. Precipitation, snowmelt, infiltration, runoff and streamflow; statistical treatment of hydrologic data; hydrograph analysis and synthesis; evaporation, groundwater; structure design floods; reservoir storage and flood routing; urban run-off and drainage. Relevant laboratory exercises.

7716. Hydrotechnical Engineering. The theory and application of steady gradually-varied flow in artificial and natural open channels together with an introduction to appropriate software; erosion protection and mobile-boundary hydraulics; problems with ice in rivers. The design of spillways, energy dissipaters, and culverts; physical scale models. Introduction to waterhammer and surge tanks. Relevant laboratory exercises.

7718. Environmental Geotechniques. Basic soil mineralogy; soil water interaction; typical wastes and contaminants; soil contaminant interaction; introduction to advection, adsorption, and diffusion; basic contaminant transport modeling for solutes and NAPL; site investigation and sampling; containment structures and liners; design and monitoring of landfills; relevant field work and laboratories.

7723. Geotechnical Engineering III. Subsurface exploration and site characterization; offshore geotechnical engineering; embankment dams; deep foundations; behaviour of soil materials under static and dynamic loads; numerical methods in geotechnical engineering; practical application of geotechnical engineering principles to foundation and earth structure design and construction.

7745. Highway Engineering. Design and construction of highways including driver, vehicle and road characteristics; highway location and geometric design; soil classification; subgrade and base materials; highway drainage; flexible and rigid pavement; highway economics. Relevant laboratory exercises.

7748. Project Planning and Control. Introduction to types of contracts, project delivery approaches, and prevailing contractual relationships; basic project management techniques for network planning and scheduling (CPM and PERT); principles of resource productivity databases, preliminary estimating, and detailed bid preparation; quantitative approaches for effective control of time, cost, resource, quality, and value of constructed facilities; use of computer software for scheduling, estimating, and control.

7800. Electrical and Computer Engineering Design Project I (1 cr. hr.). Each student is required to work independently on the development of the specification and design for a project of Electrical / Computer Engineering pertinence. Projects will normally be open-ended and involve design of hardware and / or software components. Lectures will be scheduled as required.

7811. Antennas. Fundamentals of electromagnetic radiation; antennas and antenna impedance; dipole antennas; antenna arrays; long wire antennas; aperture-type antennas; receiving antennas.

7813. Electromagnetics for Communications II. Review of electromagnetic wave propagation in transmission lines; Smith's chart and impedance matching; wave propagation in twisted pair wires, coaxial cables, striplines, rectangular waveguides, circular waveguides and optical waveguides; radiation and antennas.

7814. Electromagnetics for Communications. Vector calculus; Green, Stokes and Gauss' theorems; Maxwell's differential and integral equations; steady-state and time-varying aspects of Maxwell's equations; uniform plane wave propagation in various media; applications of electromagnetics in communications.

7824. Discrete-Time Systems and Signals. Sampling Theory; elementary discrete-time signals; discrete-time linear and time-invariant systems; the convolution sum; linear constant-coefficient difference equations; the discrete-time Fourier series; the discrete-time Fourier transform; frequency response; frequency mapping from continuous-time to discrete-time; the Fast Fourier Transform (FFT); the z-transform and transfer functions; introduction to digital filter design techniques; digital signal processing applications. Relevant software lab exercises will be included.

7844. Power System Analysis. Introduction to electric power systems; per unit quantities; transmission line parameters; modelling of power system components; single line diagrams; network equations formulation; bus impedance and admittance matrices; load flow analysis and control; design of reactive power compensation for power system performance enhancement; tap changing, auto and control transformers for power system application; symmetrical components; fault studies. Relevant laboratory exercises and computer-aided analysis and design.

7846. Power Electronics. Overview of power semiconductor switches; introduction to energy conversion and control techniques; uncontrolled rectifiers; phase-controlled converters; switch-mode dc/dc converters; variable frequency dc/ac inverters; ac/ac converters; design of thyristor commutation circuits, gate and base drive circuits, and snubber circuits; thermal models and heatsink design. Relevant laboratory exercises.

7855. Communications Electronics. Introduction to communications systems components; review of linear amplifies; linear amplifier design and characteristics using s-parameters; power amplifiers; mixers; oscillators; modulator/demodulator circuits and subsystems; integration of subsystems into analog and digital communication systems. Relevant laboratory exercises and computer-aided analysis and design.

7858. Industrial Controls and Instrumentation. Control and instrumentation system components; control devices and transducers; instrumentation and signal processing circuits; analog/digital interface circuitry and data acquisition systems; noise, grounding and shielding; analog and digital controllers; programmable logic controllers and microcontrollers; design of closed-loop control systems; applications in process and robot control; design and implementation of PC-based virtual instrumentation; design, implementation, and testing of process control subsystems. Relevant laboratory exercises and projects.

7863. Operating Systems and File Organization. History, evolution, and philosophy of operating systems; process scheduling, synchronization and management; memory and device management; file systems and database systems; security and protection; communications and networking; distributed and real-time systems.

7893. Software Engineering. The process of software development; issues related to large-scale software projects; the goals of software engineering; life cycles; documentation; software project management; software specification and development from feasibility to maintenance; safety critical systems; tools; standards. This course includes a team project.

7901. Heat Transfer II. Numerical heat transfer. Fundamentals of convection heat transfer: thermal boundary layer; heat transfer coefficients; heat transfer in turbulent boundary layers. Empirical correlations for forced and natural convection heat transfer. Introduction to phase change heat transfer. Design of heat transfer devices and processes. Relevant laboratory exercises.

7903. Mechanical Equipment. Performance characteristics of mechanical equipment: fluid power devices; heat transfer devices; mechanical drives. Relevant laboratory exercises.

7934. Finite Element Analysis. Basis of the finite element method. Continuum mechanics applications: beam problems; fluid mechanics problems; heat transfer problems. Relevant computer laboratory exercises.

7936. Mechanical Project I. This is the first of two capstone design courses in the Mechanical Discipline. In this course mechanical students are organized into small groups or teams which must complete a common design challenge. The project is presented as an open ended problem statement with specific performance objectives. The system must be designed, prototyped and tested during the course of the term. Each team acts as a small consulting firm and is required to document its project planning as well as its design.

7943. Production and Operations Management. Overview of production and operations management; plant layout and process planning; process flow analysis and simulation; capacity planning and scheduling; inventory and resource management; manufacturing accounting principles; process costing; activity based costing. Relevant computer laboratory exercises.

7944. Robotics and Automation. Industrial robot arms: direct and inverse kinematics, kinetics, singular configurations, dynamics formulations, motion and load control, trajectory planning; setup and programming of automation equipment; introduction to machine vision: hardware and software; industrial applications. Relevant laboratory exercises.

7945. Machine Dynamics. - inactive course.

7962. Computer Aided Engineering. Advanced Computer Aided Design (CAD): parametric construction and assembly modelling, computer animation, finite element modelling applications; Computer Aided Manufacturing (CAM) software for Computer Numerically Controlled (CNC) machine code generation; Coordinate Measurement Machines (CMM) and reverse engineering for rapid prototyping applications; data exchange and data management. Relevant laboratory exercises.

006W. Engineering Work Term 6 (Fall Semester). In this final Work Term students should be expected to be entrusted with the supervision of others and of certain aspects of engineering projects, as required by the employer. In so doing the student should exercise and demonstrate the many professionally related qualities expected of a graduate engineer about to embark on a professional career.

The communications component for Work Term 6 will take the form of a feasibility study, an operations manual, a project report or other technical report. The student may use a format or structure conforming to the employer's practice. In such cases the student should provide documentary material on the standards for this form of report. The report should be submitted or postmarked no later than the last official day of the work term as shown in the University Calendar.

TERM 8 COURSES

8000. Ocean and Naval Architectural Engineering Project. Execution of design project selected and approved in Term 7. The project must illustrate the application of previous design related courses, i.e., decision methods, impact assessments and application of technology. The subject may be ship design, marine system, directed research or a unique design solution. Lectures will be scheduled as required.

8003. Small Craft Design. The fundamentals of naval architecture as practiced in small craft design are presented and a methodology developed for a variety of craft: tenders, lifeboats, planning vessels, dinghies, coastal cruisers and large, state of the art racing yachts. The emphasis is on recreational craft of all sizes, with special emphasis on sailing vessels. Special topics, such as choice of material of construction, scantlings, performance prediction, seaworthiness, tank testing, modern construction materials and techniques are covered. Specific design problems unique to small craft will be covered such as; mast design and sail area determination, and the state of the art in performance prediction. Students will do a design of their choice over duration of the course. Small weekly design studies will be required.

8030. Hydroelasticity. - inactive course.

8048. Maintenance of Engineering Systems. - inactive course.

8054. Advanced Marine Vehicles. Concepts used in the design of advanced marine vehicles. Emphasis will be given to: structural design of craft constructed from fibre reinforced plastics; high speed marine vehicles (powering, structures, seakeeping and model testing); small craft. Relevant laboratory exercises.

8058. Submersibles Design. Formulation of mission statement, understanding various design constraints and reviewing the historical developments of submersibles design. Study of the hydrostatics principles of floatation, stability and control of submersibles. Performing resistance and propulsion calculations. Study of maneuvering and control equations. Survey of different materials and their selection criteria. Design of pressure hulls. Structural design of submersibles. Study of various support systems. Relevant laboratory exercises.

8090. Special Topics in Marine Hydrodynamics.

8091. Special Topics in Marine Structures.

8092. Special Topics in Marine Engineering.

8401. Nonlinear Optimization - inactive course.

8441. Experimental Design for Engineers - inactive course.

8600. Offshore Oil and Gas Engineering Project. A multidisciplinary design project that illustrates the application of previous engineering science and design related courses. Projects will be done by teams of students with individuals concentrating their participation in their own engineering discipline. The project topic will be from the offshore oil and gas engineering industry. Lectures will be schedules as required.
Instructional hours per week: 1 lecture hour; 6 laboratory hours.

8601 to 8610. Special Topics Related to Engineering.These are seminar courses and/or personal study for undergraduates in their final terms who wish to gain more specialized knowledge in a particular field of Engineering than is possible through the standard course offerings. This will allow for one or more students to gain in-depth knowledge of a special topic through directed self-study and/or seminars. The student's discipline group will consider suggestions for Study Topics courses. Such a course should normally be approved by the Undergraduate Studies Committee at least three months before the start of the semester in which it is to be taken.
Prerequisites: Permission of the student's Discipline Chair.

8614. Occupational Hazards and Hygiene - inactive course.

8621. Oceanography for Engineers - inactive course.

8623. Remote Sensing - inactive course.

8624. Fisheries Engineering - inactive course.

8641. Management Systems II - inactive course.

8643. Work Systems Design - inactive course.

8670. Reliability Engineering. Introduction to reliability engineering; Physics of failure and failure mechanisms; Reliability measures and assessment; Reliability of components and parts; Complex System Reliability and Availability Analysis; Field Reliability Assessment; Case Studies and Project.
Instructional hours per week: 3 lecture hours; 2 laboratory hours.

8671. Safety and Risk Engineering. Overview of safety and risk issues in the offshore oil and gas industry; Regulatory requirements; Hazards and structured analysis tools; Risk Terminology and Quantified risk analysis (QRA) techniques; and Safety assessment studies; Project and case studies.
Instructional hours per week: 3 lecture hours; 2 laboratory hours.

8672. Environmental Aspects of Offshore Oil Development. Overview of offshore oil drilling operations; International and Canadian regulatory requirements for discharges; waste management; On and offshore treatment technologies; Physical fate of contaminants in marine environment; chemical selection; Oil spill response; Acute and Chronic effects of pollutants on marine habitats; environmental protection plans; environmental effects monitoring; baseline characterization; Ecological risk assessment; Methodology for assessing impacts; Life cycle value assessment methodology.
Instructional hours per week: 3 lecture hours; 2 laboratory hours.

8673. Subsea Geotechnical Engineering. - inactive course.

8674. Design for the Ocean and Ice Environments. - inactive course.

8675. Offshore Structures and Materials. - inactive course.

8680. Process Control and Instrumentation. Measurement of pressure, level, flow and temperature; safety valves and safety relief devices; calibration; process analyzer and sample handling systems; instrumentation in hazardous locations; control system safety and reliability; feedback systems; control systems simulation; control examples. Relevant laboratory exercises.
Instructional hours per week: 3 lecture hours; 2 laboratory hours.

8690. Reservoir Engineering. Fluid pressure regimes, oil recovery factors, calculation of hydrocarbon volumes, reservoir rock characteristics, reservoir fluid properties, porosity and permeability, material balance, well test analysis.
Instructional hours per week: 3 lecture hours.

8691. Petroleum Production Engineering. Procedures and equipment necessary for preparing a well to produce hydrocarbons and maximizing flow rate during the life of the well. Well completion configurations, tubulars, packers and subsurface flow control devices, completion and workover fluids, perforating oil and gas wells, formation damage, surfactants for well treatment, hydraulic fracturing, acidizing, scale deposition, removal, prevention, workover and completion rigs, and artificial lift.
Instructional hours per week: 3 lecture hours.

8692. Drilling Engineering for Petroleum Exploration and Production. The course covers both offshore and onshore drilling operations and includes: rotary drilling rig operations, well construction sequence, drill string, drill bits, wellbore hydraulics, casing and wellheads, cementing, well control, directional and horizontal drilling, well planning and fishing operations, and extended reach, horizontal and multi-lateral well drilling techniques.
Instructional hours per week: 3 lecture hours.

8693. Petroleum Facilities Engineering. Design of oil and gas field separation and treatment facilities: principles of facilities engineering, pressure vessel design, piping systems, oil, gas and water separation, heaters and treating systems, valves, pumps, hydrates, heat exchange units and indirect fired heaters, gas treatment, facilities optimization, and de-bottle necking.
Instructional hours per week: 3 lecture hours.

8694. Downstream Processing. The course content includes: oil and natural gas processing; oil and gas storage facilities and their design; oil and gas separation processes; petroleum refining processes; and an overview of petrochemical industries.
Instructional hours per week: 3 lecture hours.

8700. Civil Engineering Project. A practically oriented design project integrated over the five areas in which Civil programs are offered. Students will operate in consultant groups and will complete a design for a typical Civil Engineering undertaking. Lectures will be scheduled as required.

8705. Structural Building Systems. Geometries, loads, safety and serviceability, procedure of using the national building code for evaluating the governing loads on structural members. Design of low rise concrete, timber and steel buildings. Lateral load-resisting elements and bracing systems. Design of foundation systems, footing design, pile cap design, pile group analysis using elastic centre method and inclined pile analysis. Prestressed concrete concepts: strength of flexural members, shear reinforcement for prestressed concrete beams. Relevant Laboratory exercises.

8706. Analysis and Design of Structural Components - inactive course.

8707. Maintenance and Rehabilitation of Structures - inactive course.

8713. Municipal Engineering. Planning of municipal services; estimating water demands; design and analysis of water distribution systems and appurtenances; methods of water treatment; estimating waste water quantity; design of sanitary sewer systems; methods of waste water treatment; solid waste disposal and management. Relevant laboratory, field trips, and case studies.

8717. Environmental Assessment, Monitoring and Control. Environmental assessment, audits, law and regulations; water and air quality modelling; environmental risk assessment; pollution monitoring and sampling network designs; statistical analysis; site remediation and hazardous waste management. Relevant laboratory and field exercises.

8746. Traffic and Transportation Engineering. Traffic engineering studies; fundamental principles of traffic flow; intersection control; highway capacity and level of service; pavement maintenance and rehabilitation; introduction to airport engineering. Relevant laboratory exercises.

8751. Coastal and Ocean Engineering. The coastal and ocean environment; ocean circulation and properties; waves and tides; instrumentation and measurement. Additional topics will be drawn from the areas of hydraulic, geotechnical and structural engineering. Relevant laboratory/field exercises.

8749. Construction Planning Equipment and Methods. Construction equipment selection and utilization; earthmoving including use of explosives; case studies of major civil projects; principles of project planning and control; computer applications to the construction industry. Relevant laboratory/field exercises.

8790-8799. Special Topics in Civil Engineering.

8800. Electrical and Computer Engineering Design Project II. Each student is required to work independently on a design project having Electrical/Computer Engineering pertinence, and to present written and oral reports on this work. Projects will normally be open-ended and involve design, implementation and testing of hardware and/or software components. Lectures will be scheduled as required.

8801--05. Special Topics in Computer Engineering.

8806-09. Special Topics in Electrical Engineering.

8813. Propagation and Diffraction - inactive course.

8821. Digital Signal Processing.  Review of discrete-time systems and signals and sampling theory; transform analysis of discrete-time LTI systems; implementation of digital filter systems; design of IIR and FIR digital filters; discrete Fourier transform and the Fourier analysis of signals; applications of digital signal processing.

8826. Filter Synthesis. Introduction to analog filters; descriptive terminology, transfer functions and frequency response of filters; design of first order passive and active filters; design and analysis of biquad circuit, Sallen key circuit, multiple feedback circuit and state variable filter; RC-CR transformation; inductance simulation circuit; cascade design principle; design of filters with maximally flat magnitude response; design of filters with equal ripple magnitude response; design of Bessel-Thomson filters; analysis and design of switched capacitor filters; use of Matlab for design of analog filters. Relevant laboratory exercises.

8845. Power System Operation. Generator scheduling: economic operation, reliability and unit commitment; power system stability; power system protection.

8846. Power Electronic Systems - inactive course.

8863. Introduction to LSI Design. Introduction to ASICs and ASIC design methodology; basic concepts of digital logic design tools and ASIC technology libraries; partitioning for logic synthesis and VHDL coding; constraining designs, synthesizing, simulation and optimization; design for testability; layout and post-layout optimization and SDF generation; static timing analysis. Relevant laboratory exercises.

8874. Telecommunications System Design - inactive course.

8878. Image Communications. - inactive course.

8879. Digital Communications. Baseband digital transmission; intersymbol interference (ISI), partial response signalling, maximum likelihood receiver, matched filter, correlation receiver and error probability performance; source coding; the concept of information; entropy, Huffman code; linear predictive coding; channel coding; block codes, convolutional codes; modulation and coding trade-offs; bandwidth and power efficiency, spread spectrum techniques.

8882. Biomedical Engineering. The physiology of nerves, muscle and the cardiovascular and cardiopulmonary systems; engineering measurement techniques as applied to these systems - electrodes and transducers; electromedical equipment - the ECG machine, defibrillators, electrosurgical units and patient monitors; medical imaging - X-ray, CT scanner and Nuclear Medicine; industrial considerations - work, heat, human factors, electrical safety and CSA codes. Relevant laboratory exercises.

8893. Concurrent Programming. Review of operating systems concepts. Survey and classification of parallel and distributed architectures; vector processor, array processor, shared-memory multiprocessor, message-passing multicomputer, distributed systems, and computer networks. Shared-memory and message-passing programming techniques. Study of classical concurrent problems; critical section, producer/consumer, readers/writers, dining philosophers, and resource allocation. Correctness of concurrent programs: partial and total correctness, safety and liveness properties. Performance analysis of algorithm-architecture combinations. Relevant programming assignments.

8903. Mechanical Systems. Mechanical systems design. System simulation and control. Performance optimization and evaluation. Equipment selection for overall system design. Case studies. Relevant laboratory exercises.

8904. Flow Structure Interactions. Vortex shedding phenomena. Lifting surface oscillations. Membrane and panel flutter. Pipe flow vibrations. Hydraulic transients. Tube bundle vibrations. Acoustics of enclosures. Wave structure interactions. Relevant laboratory exercises.

8935. Pressure Component Design. Traditional design methods; load types: sustained, cyclic, impact; failure modes and mechanisms; incremental collapse; plastic shakedown; residual and thermal stresses; limit analysis: upper and lower bound approximations; damage tolerant design; rational design procedures; case studies: cylinders; plates; shells. Relevant laboratory exercises.

8936. Mechanical Project II. This is the second of two capstone design courses in the Mechanical Discipline. Building on the skills acquired in the first, student teams each choose a unique design challenge and then proceed to generate a solution. The problem statements are often drawn from industry and, where possible, interdisciplinary interaction is encouraged (for example, with business, computer science, or other engineering disciplines). In most cases, the problem proponent will act as the "client" and the team is expected to manage the client interaction process as well. Significant emphasis is placed on both oral and written communication of both the process and the results. Where possible, each system, or a critical component of it, will be prototyped and tested.

8943. Computer Integrated Manufacturing. - inactive course.

8944. Quality Management and Control. - inactive course.

8962. Corrosion and Corrosion Control. Forms of corrosion. The electrochemical nature of the corrosion process. The mixed potential theory - Purbaix Diagrams and Evan Diagrams. Corrosion testing, control use by use of materials, selection, cathodic protection, inhibitors and coatings. Case studies of selected corrosion problems. Relevant laboratory exercises.

8970-8979. Special Topics in Mechanical Engineering.


EMPLOYERS PARTICIPATING IN CO-OPERATIVE EDUCATION ENGINEERING PROGRAM

Abitibi-Consolidated Inc., Grand Falls-Windsor, NL
Abitibi-Consolidated Inc., Stephenville, NL
Adam's Construction Inc., Bishop's Falls, NL
AKAC Inc., Victoria, BC
Aker Maritime Kiewit Contractors, Marystown, NL
Aker Maritime Kiewit Contractors, Milton, ON
Aker Maritime Kiewit Contractors, Saint John, NB
Aker Maritime Kiewit Contractors, St. John's, NL
Alcatel, Ottawa, ON
Aliant, St. John's, NL
Aluminerie Alouette, Sept-Isle, QC
AMEC, St. John's, NL
American Bureau of Shipping, Houston, TX
ASCO, Aberdeen, Scotland
Atlantic Maintenance Systems, Bull Arm, NL
Aurum Acoustics, St. John's, NL
Avalon Controls Ltd., St. John's, NL

Baader Canpolar East Inc., St. John's, NL
BAE-Newplan Group Ltd., St. John's, NL
Baker Atlas, Kuwait
Baker Hughes, St. John's, NL
Baker Hughes-Baker Atlas, Grand Prairie, AB
T. E. Beach, Ascension Islands
Beaver Trusses, St. John's, NL
BMT Fleet Technology, Ottawa, ON
Boatspeed, Australia
Bowater, Thunder Bay, ON
Bridger Design Associates Ltd., St. John's, NL
Browning Harvey Ltd., St. John's, NL

C.A.C.E Construction, Gloucester, ON
Cabot Habitat for Humanity, St. John's, NL
G. J. Cahill Ltd., St. John's, NL
Canada Green Technology, St. George, NB
Canada-Newfoundland Offshore Petroleum Board, St. John's, NL
Canadian Coast Guard, St. John's, NL
Canadian Forces, Fredericton, NB
Canadian Forces, Richelain, QC
Canadian Security Establishment, Ottawa, ON
Carey Geoenvironmental Engineering, Baddeck, NS
Carmichael Engineering, St. John's, NL
Cathexis Innovations, St. John's, NL
Cavendish Farms, Kensington, PEI
C-CORE, St. John's, NL
Centre for Marine Simulation, St. John's, NL
Centre Stone Inc., Mississauga, ON
CH2M Hill Canada, Waterloo, ON
Chulalongkorn University, Thailand
City of Mount Pearl, Mount Pearl, NL
City of St. John's, St. John's, NL
Coleman Management Services Ltd., Corner Brook, NL
College of the North Atlantic, Stephenville, NL
Communications Security Establishment, Ottawa, ON
Community Access Program, Deer Lake, NL
ConocoPhillips Marine, Houston, TX
Consilient Technologies Corporation, St. John's, NL
Consolidated Technologies Ltd., St. John's, NL
Convergys, St. John's, NL
Crosbie Engineering, St. John's, NL

Dalcan, Barrie, ON
Dana Brake Parts, Guelph, ON
Darkwood Technologies, St. John's, NL
Defence Construction Canada, Gander, NL
Dept of Environment, Corner Brook, NL
Dept of Environment, Grand Falls-Windsor, NL
Dept of Environment, St. John's, NL
Dept of Fisheries & Oceans, St. John's, NL
Dept of Mines & Energy, Buchan's, NL
Dept of Municipal & Provincial Affairs, St. John's, NL
Dept of Municipal Affairs, Corner Brook, NL
Dept of National Defence, Hull, QC
Dept of National Defence, Kingston, ON
Dept of National Defence, St. John's, NL
Dept of Transportation & Works, Clarenville, NL
Dept of Transportation & Works, Corner Brook, NL
Dept of Transportation & Works, Deer Lake, NL
Dept of Transportation & Works, Gander, NL
Dept of Transportation & Works, Goose Bay, NL
Dept of Transportation & Works, Grand Falls-Windsor, NL
Dept of Transportation & Works, St. John's, NL
Design Build Management Inc., St. John's, NL
Design Management Group, Gander, NL
Design Services Ltd., St. John's, NL
Det Norske Veritas (DNV), Halifax, NS
Det Norske Veritas (DNV), Marystown, NL
Det Norske Veritas (DNV), St. John's, NL
DF Barnes Ltd., St. John's, NL
ND Dobbin, St. John's, NL
Donovan Homes, Mount Pearl, NL
DY 4 Systems Inc., Ottawa, ON

East Coast Kayaks, St. John's, NL
East Coast Tubulars Ltd., St. John's, NL
EMCO Offshore, Mount Pearl, NL
EnCana, Fort Nelson, BC
EnCana, Hythe, AB
EnCana, Sexsmith, AB
Environment Canada, Gatineau, QC
ESCO Ltd., Port Hope, ON
ExxonMobil Canada, St. John's, NL
EYE Marine Consultants, Dartmouth, NS

Felcon Ventures Inc., Gander, NL
FMC Sofec, Houston, TX
Fracflow Consultants Inc., St. John's, NL
Future SET, St. John's, NL

Gazzola Paving, Etobicoke, ON
General Motors, Oshawa, ON
George's Small Engine Repair, Grand Falls-Windsor, NL
Global Santa Fe, Houston, TX
GmbH & Co. KG, Germany
Grand Atlantic Seafoods, St. Lawrence, NL
Grand Bank Seafoods, Grand Bank, NL
GRI Simulations, St. John's, NL
Gros Morne National Park, Rocky Harbour, NL

Halifax Water Commission, Halifax, NS
Hatch Associates, Vancouver, BC
Hawkco King Rendouf, St. John's, NL
Heerma Marine Contractors, Leiden
Helsinki University of Technology, Helsinki, Finland
HIMA, Germany
Hold Fast Engineering, St. John's, NL
Humber Valley Resort, Pasadena, NL
Husky Energy, Calgary, AB
Husky Energy, St. John's, NL

IBM Canada Ltd., Markham, ON
IKM Testing, St. John's, NL
Imperial Oil Ltd., Calgary, AB
Imperial Oil Ltd., Cold Lake, AB
IMV Projects, Calgary, AB
INCO, Mississauga, ON
INCO, Thompson, MB
Incoretec Inc., St. John's, NL
Industry Canada, St. John's, NL
Institute for Ocean Technology, St. John's, NL
International Transaction Systems, Mississauga, ON
Iron Ore Company of Canada, Labrador City, NL
Irving - Forest Services, St. George, NB
Irving Paper, Saint John, NB
Irving Tissue, Saint John, NB

Jacques Whitford & Associates Ltd., St. John's, NL
James Floyd Landscaping Arch., St. John's, NL
James Paton Memorial Hospital, Gander, NL
JNE Consulting, Hamilton, ON

K & P Contrating Ltd., Flatrock, NL
Kavanagh Construction, St. John's, NL
Kellogg Brown & Root, Houston, TX
Kellogg Brown & Root, St. John's, NL
Kento, Mount Pearl, NL
Kiewit Offshore Services, Marystown, NL
K-LOR, Calgary, AB
Kvaerner Masa Marine, Vancouver, BC

Larcan Inc., Mississauga, ON
Lear Corporation, Kitchener, ON
Lester Farms, St. John's, NL
Linamar Corporation, Guelph, ON
Livingston International Inc., Toronto, ON
Lloyd's Register, Aberdeen, Scotland
Logan Drilling, Parson's Pond, NL
London Marine Consulting, London, England
London Offshore Consultants, London, England
Lotek Engineering Inc., Newmarket, ON
Lotek Wireless Inc., St. John's, NL

M & M Offshore, St. John's, NL
Macrotronics, Cold Lake, AB
MAE Design, Manuels, NL
Maersk Contractors, St. John's, NL
Magna Contracting, St. John's, NL
Marco Services Ltd., St. John's, NL
Marine Services International, Mount Pearl, NL
MDS Nordian Inc., Ottawa, ON
Mechanical Works Inc., Labrador City, NL
Memorial University of Newfoundland - Department of Computing &     Communications, St. John's, NL
Memorial University of Newfoundland - Department of Earth Science,     St. John's, NL
Memorial University of Newfoundland - Faculty of Engineering and Applied Science, St. John's, NL
Memorial University of Newfoundland - Department of English, St. John's, NL
Memorial University of Newfoundland - Department of Facilities Management, St. John's, NL
Memorial University of Newfoundland - Department of German, St. John's, NL
Memorial University of Newfoundland - Fisheries and Marine Institute, Foxtrap, NL
Memorial University of Newfoundland - Fisheries and Marine Institute,     St. John's, NL
Memorial University of Newfoundland - Department of Technical Services, St. John's, NL
Metal World Inc., St. John's, NL
Metalcraft Marine Services, Kingston, ON
MGI Ltd., St. John's, NL
MI Swaco, Halifax, NS
Molson Canada, St. John's, NL
Morrison Hershfield, Ottawa, ON

Nautel Ltd., Hachetts Cove, NS
NavSim Technologies, St. John's, NL
Neill & Gunter ltd., Halifax, NS
Newdock, St. John's, NL
Newfoundland & Labrador Housing Ltd., St. John's, NL
Newfoundland & Labrador Hydro, Churchill Falls, NL
Newfoundland & Labrador Hydro, Holyrood, NL
Newfoundland & Labrador Hydro, St. John's, NL
Newfoundland Design Associates Ltd., St. John's, NL
Newfoundland Geosciences Ltd., St. John's, NL
Newfoundland Power Inc., Corner Brook, NL
Newfoundland Power Inc., St. John's, NL
Newfoundland Transshipment Ltd., Arnold's Cove, NL
Newlab Engineering Ltd., Clarke's Beach, NL
Newtech Instruments Ltd., St. John's, NL
Newton Engineering, St. John's, NL
Noble Drilling (Canada) Ltd., St. John's, NL
Norsk Hydro Canada, St. John's, NL
Nortel Networks, Ottawa, ON
North Atlantic Lumber Inc., Glenwood, NL
North Atlantic Refining Ltd., Come By Chance, NL
North Eastern Constructors Ltd., Bull Arm, NL
Northland Contracting Inc., Bay Bulls, NL
Nova Consultants, St. John's, NL

Oceanic Consulting Corporation, St. John's, NL
Ocean's Ltd., St. John's, NL
Ollerhead & Associates, Yellowknife, NWT
Ontario Power Generation, Pickering, ON

PCL Construction, Ottawa, ON
PCL Construction, Toronto, ON
Peter Kiewit & Sons, Mattice, ON
Peter Kiewit & Sons, St. John's, NL
Peter Kiewit & Sons, Voisey's Bay, NL
Petro Canada, Calgary, AB
Petro Canada, Drayton Valley, AB
Petro Canada, St. John's, NL
POPEK Engineering Ltd., Grand Prairie
Poseion Marine Consultants, St. John's, NL
Bruce Power, Tiverton, ON
Pratt & Whitney Canada Inc., Enfield, NS
Provincial Consultants Ltd., St. John's, NL
Public Works/Government Services Canada, Argentia, NL
Public Works/Government Services Canada, Corner Brook, NL
Public Works/Government Services Canada, Halifax, NS
Public Works/Government Services Canada, Ottawa, ON
Public Works/Government Services Canada, Saint John, NB
Public Works/Government Services Canada, St. John's, NL
Pyramid Construction Ltd., St. John's, NL

Q. B. D. Cooling Systems Inc., Brampton, ON
Quadratec Inc., St. John's, NL
Quality Management Institute, Brampton, ON
Queen's University, Kingston, ON

Radio Shack, Mount Pearl, NL
Reardon Construction & Development, St. John's, NL
Registry Services, St. John's, NL
Research in Motion (RIM), Ottawa, ON
Research in Motion (RIM), Waterloo, ON
J. L. Richards, Ottawa, ON
RJG Construction, Marystown, NL
Robert Allan Ltd., Vancouver, BC
Roger's Cable, St. John's, NL
RSW Inc., Montreal, QC
Rutter Technologies Inc., St. John's, NL

SAM Electronics, Rotterdam
Sandvine Inc., Waterloo, ON
Sasktel (Saskatchewan Telecom), Regina, SK
Schlumberger Canada Ltd., Mount Pearl, NL
Schlumberger Canada Ltd., Nisku, AB
Schlumberger Canada Ltd., Red Deer, AB
SEA Systems Ltd., St. John's, NL
Seaway Marine Transport, St. Catherine's, ON
SGE Acres Ltd., St. John's, NL
Shiner, Mosely & Assoc., Corpus Christi, TX
Southern Construction Ltd., Trepassey, NL
Spectrol Group, St. John's, NL
Stantec, Mississauga, ON
Steag, Cologne, Germany
Steag, Surat, India
Stratos Global, St. John's, NL
Structural Design Inc., St. John's, NL
Subsea 7, Aberdeen, Scotland

Technip-Coflexip, Aberdeen, Scotland
Technip-Coflexip Offshore Canada Ltd., St. John's, NL
Terra Nova Marine, Mount Pearl, NL
Terra Nova Shoes Ltd., Harbour Grace, NL
The Salvation Army, Dildo, NL
R. W. Tiller Structural Engineering Inc., St. John's, NL
Toromount Process, Calgary, AB
Town of Grand Bank, Grand Bank, NL
Town of Grand Falls-Windsor, Grand Falls-Windsor, NL
Town of Lewisporte, Lewisporte, NL
Transocean Seco Forex, St. John's, NL
Transport Canada, Ottawa, ON
Tristar Mechanical Ltd., Mount Pearl, NL

Vancouver Shipyard, Vancouver, BC
Varcon Inc., St. John's, NL
Verafin Inc., St. John's, NL
Voisey's Bay Nickel Company Ltd., St. John's, NL
Voisey's Bay Nickel Company Ltd., Voisey's Bay, NL

Weather Shore Windows, Trepassey, NL
Webbed Toed Workshop, St. John's, NL
WESI, Dartmouth, NS
A. D. Williams Engineering Ltd., Calgary, AB


CONTINUING ENGINEERING STUDIES

In this current era of technological advancement it is necessary that practicing engineers continually keep pace with the changes relevant to their area of interest in order that the public trust, legislated to them, is justified and maintained. Although the primary responsibility for this rests with the individual engineer there is a need for a structured means, other than existing graduate programs, to abet this continuing educational process. The Faculty of Engineering and Applied Science, through its Continuing Engineering Studies Committee and with the endorsement of the Professional Engineers and Geoscientists of Newfoundland and Labrador (PEG-NL), has developed the following programs of seminars and short courses for this purpose. These programs are one means by which practicing engineers may maintain and improve their competence.

The content of each program is formulated and prepared to reflect an anticipated need, or in response to a need expressed by the professional community. Information on each pending program is advertised in the media and in selected professional and trade correspondence. Although the programs are directed at practicing engineers other interested persons with equivalent background may participate. The Faculty, however, reserves the right to restrict participation as stipulated by specific admission requirements or as it otherwise deems appropriate or necessary. If response warrants, each program (or some part thereof) is then presented in St. John's (on or off-campus), or in any other centre as required. Instruction is normally the responsibility of a team of university, industry, and government specialists selected for that program. A participant's successful completion of each program's requirements is recognized by the University in the form of a testamur, certificate, or diploma as designated to the particular program.

Further information may be obtained through the office of the Director of Continuing Engineering Education.

DIPLOMA PROGRAMS

CERTIFICATE PROGRAMS

APPLICATION FOR ADMISSION

ADMISSION REQUIREMENTS

EXEMPTIONS AND EQUIVALENT CREDIT

SUBSTITUTE COURSES

FORMAT

EVALUATION

FACULTY

PERIOD OF STUDY

TESTAMUR PROGRAMS

PROGRAM CANCELLATION

LIST OF COURSES


DIPLOMA PROGRAMS

A diploma program comprises an integrated series of seminars, short courses and other study session directed at a specific subject area.

A diploma program consists of a minimum of seven courses plus a project course. The program of instruction is comprised of three components: a core component consisting of a minimum of three courses, an elective component consisting of a minimum of four courses, in addition to a project course. The project course usually has weight to that of two regular courses. The program normally requires a minimum of three terms to complete.

The Continuing Engineering Education Committee, on behalf of Faculty Council, determines the courses that constitute a diploma program from the list of courses given at the end of this section. The Committee can also choose other available University courses to be included in a diploma program.

The following is a list of diploma programs offered by the Faculty:

Diploma in Advanced Studies in Civil, Electrical and Computer, Mechanical and Ocean Engineering

Diploma in Advanced Studies in Environmental Engineering and Applied Science

Diploma in Advanced Studies in Safety, Risk and Integrity Engineering

Diploma in Engineering Management

CERTIFICATE PROGRAMS

A certificate program comprises an integrated series of seminars, short courses and other study sessions directed at a specific subject area. A minimum of six courses plus a project is required. Each certificate program is comprised of three components: a core component consisting of a minimum of three courses, an elective component consisting of at least three courses and a project course. The project course usually has the same weight as a regular course.

The Continuing Engineering Education Committee, on behalf of Faculty Council, selects the list of courses, which constitutes a certificate program from the list of courses given at the end of this section. The Committee can also choose other available University courses to be included in a diploma program. Currently, the Faculty offers a certificate program in Electrical Maintenance for Engineers. The program normally requires a minimum of two terms to complete.

APPLICATION FOR ADMISSION

The diploma and certificate programs are the responsibility of the Faculty of Engineering and Applied Science and are intended for professional engineers. Applications for admission should be made to the program on appropriate forms available from Continuing Engineering Education, Faculty of Engineering and Applied Science. Entry to the program is not normally restricted to any particular time of year, rather completed applications are judged by an Admissions Committee as soon as possible after they reach the CEE office. To ensure that applications are processed as quickly as possible, applicants should provide complete documentation and transcripts with the application form.

ADMISSION REQUIREMENTS

Normal entrance requirement is one of the following:

a) Membership in the Professional Engineers and Geoscientists of Newfoundland and Labrador (PEG-NL).

b) A Bachelor of Engineering degree from a recognized university, and three years experience in engineering work.

Individuals who do not possess the qualifications listed above may be admitted to the certificate or diploma program if they can satisfy the Faculty of Engineering and Applied Science that they have qualifications and experience which ensure a reasonable chance of success in the program.

EXEMPTIONS AND EQUIVALENT CREDIT

A student who has taken previous technical courses which have not been applied for previous credit may be exempted from taking similar courses in a Diploma Program, up to a maximum of two courses. Normally courses taken within the past two years and for which the student's work was formally evaluated will be considered for exemption. Exemption for courses taken more than two years in the past may be granted by the Admissions Committee.

Students requesting exemptions should apply in writing to the Director of Continuing Engineering Education, with supporting documentation about the course(s) they hope to use for substitute(s). Documentation must include an official course outline or calendar description and a transcript of the grade(s) obtained.

SUBSTITUTE COURSES

Where a course in a Diploma Program has had to be cancelled, registrants to this course may be allowed to attend a similar course which may be offered as part of some other program at the University, should space permit. They will receive credit for the substitute course towards their diploma.

Students requesting credit for substitute courses should apply in writing to CEE prior to taking the course with an official outline or calendar description of the course(s) they wish to substitute.

FORMAT

The format of the courses offered as part of this program will be varied. In addition to the normal lecture-type courses offered at evening sessions, there may be day seminars, and short intense courses running a week or more. The format for courses offered in any semester will be announced by CEE prior to the beginning of that semester.

EVALUATION

Each course in the diploma program will contain an evaluation procedure established by the instructor for that course. A mark of 60% must be achieved in each course taken in order to obtain credit.

FACULTY

Most courses are offered by a team of instructors drawn from the Faculty of Engineering and Applied Science, other faculties, and specialists from industry.

PERIOD OF STUDY

Normally a student will complete the Diploma Program in two years. If he/she cannot complete it in two years, the student may apply to the Diploma Committee for an extension, which may be granted for one year. A maximum of three extensions may be granted. This means that the total extended period including the normal time of two years will not exceed five years.

TESTAMUR PROGRAMS

A testamur program is normally a single course, seminar, symposium, or other study session directed at a specific subject area and which is presented over a one to four day period. Normally there are no evaluation procedures applied to these programs.

Specific testamur programs are not listed in the Calendar. Brochures containing information on the subject matter, fees, dates, places, and registration are distributed through an extensive mailing list, and advertised in the media and selected trade and professional correspondence. A registration form is contained in each brochure or is available from the Director of Continuing Engineering Education.

PROGRAM CANCELLATION

The Faculty reserves the right to postpone or cancel any program, in whole or in part, due to insufficient advance registration or for any other reason it deems appropriate. Any fees paid in advance will be returned subject to the terms and conditions on the registration form.

LIST OF COURSES

ENGC 9000. Basic Safety, Reliability, Risk Concepts and Legislation

ENGC 9001. Statistical Quality Control and Design of Industrial Experiments

ENGC 9002. Uncertainty, Risk and Reliability Analysis for Engineers

ENGC 9003. Risk and Decision Analysis Applied to Engineering Systems

ENGC 9004. Advanced Reliability and Risk Analysis

ENGC 9007. Corrosion Engineering

ENGC 9008. Fire and Explosion Engineering

ENGC 9009. Introduction to Petroleum Technology

ENGC 9010. Introduction to Sub-Sea Technology

ENGC 9011. Introduction to Drilling Technology

ENGC 9012. Reliability of Software, Safety Critical Electrical/Electronic Systems

ENGC 9013. Reliability of Structural Systems

ENGC 9014. Fatigue and Fracture Mechanics

ENGC 9015. Introduction to Environmental Engineering

ENGC 9017. Environmental Risk Analysis

ENGC 9018. Overview and Introduction to Ergonomics

ENGC 9019. Introduction to Occupational Medicine

ENGC 9020. Introduction to Occupational Hygiene

ENVSCI/ENG 6002. Environmental Chemistry and Toxicology

ENGC 9500. Technical Communications

ENGC 9512. Project Planning and Management

ENGC 9600. Project Course for Diploma Programs

ENGC 9612. Waste Management

ENGC 9614. Municipal Solid Waste Management

ENGC 9620. Environmental Sampling and Analysis I

ENGC 9621. Introduction to Environmental Statistics

ENGC 9622. Environmental Management System

ENGC 9624. Computer Applications in Environmental Science and Engineering

ENGC 9625. Environmental Sampling and Analysis II

ENGC 9630. Air Pollution

ENGC 9800. Project Course for Certificate Programs

ENGC 9810. Computer Applications I for Certificate Programs

ENGC 9812. Computer Applications II for Certificate Programs

ENGC 9820. Electric Machines and Power Electronics

ENGC 9822. Electrical Power Systems Analysis and Design

ENGC 9825. Electrical Equipment and Standards



Please direct inquiries to adeanugs@engr.mun.ca.


Last modified on April 26, 2005 by R. Bruce

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