Page Contents
- Program Overview
- Concentrations
- Field Exams
- Special Committee
- Concentration: Complex Systems Engineering
- Concentration: Environmental Fluid Mechanics and Hydrology
- Concentration: Environmental Processes
- Concentration: Environmental and Water Resource Engineering
- Concentration: Structural Engineering
- Concentration: Transportation Systems Engineering
Note: This page provides a general overview. For complete and accurate information, please consult with your advisor. For current course offerings and information, refer to the Cornell University Registrar: Courses of Study.
Program Overview
A research-oriented degree program usually completed within four semesters; it requires an independently written thesis and concomitant defense. Admission to this program generally requires an undergraduate degree, or equivalent coursework, in an appropriate field of engineering, although the environmentally-oriented concentrations may be able to accept students who have a strong physical sciences background. Each concentration determines specific course requirements. Each student’s program (course work and research) is individualized and decided upon in consultation with a Special Committee which the student selects and that is made up of faculty from the student’s major and minor subject areas.
The program is intended for those interested in a research or academic career and, generally, continuation into a Ph.D. program. Both the M.Eng. and M.S. degrees are excellent preparation for a Ph.D. program or for a professional career. The final step towards degree completion is passing the M Exam.
Concentrations
-
Complex Systems Engineering
Members of the Complex Systems Engineering concentration are united by the common goal of understanding how systems-level behavior emerges from component wise interactions, by combining mathematical modeling with data science, nonlinear dynamics, numerical simulation, optimization, and stochastic processes methods to enable insightful physical, chemical, and biological modeling of individual system components and their interactions. This research spans a wide range of application domains such as cyber physical systems, environmental fluids, microbial communities, renewable energy, synthetic biology, transportation, infrastructure, and power networks.
-
Environmental Fluid Mechanics and Hydrology
Environmental fluid mechanics and hydrology deal primarily with the occurrence and movement of water and other fluids on the surface of the earth. Civil engineering applications of this discipline traditionally deal with river engineering, the hydrology of surface drainage and runoff, pipelines and conveyance systems, groundwater, flooding and its prevention, coastal processes and nearshore oceanography, hydroelectric generation, water supply and distribution, and fluid measurement.
-
Environmental Processes
The Environmental Processes faculty focus on advancing fundamental knowledge and developing sustainable technologies that can contribute to the paradigm shifts needed to face the most urgent environmental challenges facing human societies such as energy and resources crises and climate change.
-
Environmental and Water Resource Engineering
Research within the Environmental and Water Resources Systems group are concerned with the development and application of quantitative methods for the evaluation, planning and operation of water resource and environmental systems. Efforts address the integration and analysis of engineering and economic-policy issues posed by the need to manage water, land, air and human resources, as well as environmental remediation efforts. The fundamental sciences upon which such analyses are based include hydrology, hydraulics, environmental sciences, biology, and environmental engineering.
-
Structural Engineering
The structural engineer is responsible for the analysis, design, and construction of traditional civil engineering structures including buildings, bridges, concrete dams, tanks, and towers, as well as a great diversity of other structures, such as radio telescopes; reactor containment vessels; cooling towers; railway, automotive, and aerospace vehicles; ships, space stations, and roller coasters.
-
Transportation Systems Engineering
Planning, design and management of multimodal transportation systems is an area in which engineers can contribute to addressing a wide variety of challenges, ranging from congestion to security to environmental impact.
Field Exams (Research Students)
M.S. students take one exam, the M Exam, in order to be awarded their M.S. degree. This exam is required by the Graduate School. It is an oral defense of their thesis and all committee members must attend. Per the Code of Legislation. The Graduate Faculty requires research master’s students writing a thesis to take a final examination upon completion of all degree requirements, no earlier than one month before completion of the minimum registration requirement.
Exam Administration – M Exam
For the M exam, the exam schedule must be submitted to the Graduate School a minimum of seven days in advance of the exam (online form). The schedule and results forms must be signed by all current Special Committee Members of record and the Director of Graduate Studies. Scheduling of exams should be posted by email to the field faculty by the Assistant Director of Graduate Programs. Please send your title and abstract to the Graduate Field Coordinator once the exam is scheduled so an announcement can be drafted. The Results of the Examination (also an online form) must be submitted to the Graduate School within three business days following the exam. Per the Code of Legislation. Please request clarification from the Assistant Director of Graduate Programs with clarifying questions.
Examinations General – M Exam
The M Exam is conducted by the Special Committee and occasionally supplemented by specially invited faculty participants. For a student to pass any of the exams, all members of the special committee must approve. The result of an examination, whether pass or fail, must be reported promptly to both the Graduate School and the Director of Graduate Studies of the field within three business days after the date of the exam.
With the exception that all examinations shall be wholly or partly oral, the special committee has full discretion in the content and conduct of examinations and may require any additional examinations it deems necessary.
Special Commitee
Per the Code of Legislation, the Graduate Faculty requires M.S. students to have identified (or been assigned) a Special Committee Chair or a temporary advisor no later than three weeks after the first registration in the Graduate School (submitted to the Graduate School via Student Center). Per the Code, the Graduate Faculty requires M.S. students to have a full Special Committee no later than the end of the second semester.
Each candidate selects a Special Committee that guides and judges the student’s progress in graduate study. M.S. candidates select a Special Committee Chairman from the major subject area and a Member from a minor subject area that is demonstrated to be distinctly different (in terms of research scope and course requirements) from the student’s major subject area, and sometimes add a third Member representing a second minor or for special thesis supervision. Some concentrations assign provisional advisors at the time of matriculation (ie: Transportation) while others have a meeting of the concentration faculty to discuss how students will be assigned with mentors (ie: Environmental Processes).
Concentration: Complex Systems Engineering
Complex Systems Engineering students should take at least two of the three core courses listed in the Core Courses section below.Students with a strong theoretical background may petition to opt out of one or more of the core courses. Petitions are approved by the advisor and by the ad hoc Q exam committee. In addition to the core courses, students will be required to satisfy the CEE graduate program course requirements. The CSE recommendation is to complement the core courses with foundational modeling and data science courses, as well as domain-specific courses in the student’s research area. A non-exhaustive list of examples is provided below.
Core Courses (Choose two)
-
CEE 6215
Stochastic Modeling of Complex Systems
-
CEE 6736
Mathematical Modeling of Natural & Engineered Systems
-
CEE 6745
Inverse Problems: Theory and Applications
Other Foundational Modeling and Data Science Courses
-
CEE 6000
Numerical Methods for Engineers
-
CHEME 6110
Mathematical Methods of Chemical Engineering Analysis
-
CHEME 6800
Computational Optimization
-
CS 5780
Introduction to Machine Learning
-
CS 5786
Machine Learning for Data Science
-
CS 6241
Numerical Methods for Data Science
-
CEE 6640
Microeconometrics of Discrete Choice
-
CS 6820
Algorithms
-
ECE 5210
Theory of Linear Systems
-
ECE 5412
Bayesian Estimation and Stochastic Optimization
-
ECE 5640
Statistical Inference and Decision
-
MAE 5790
Nonlinear Dynamics and Chaos
-
MAE 6780
Multivariable Control Theory
-
MATH 5200
Differential Equations and Dynamical Systems
-
MATH 5220
Applied Complex Analysis
-
MATH 6230
Differential Games and Optimal Control
-
MATH 6260
Dynamical Systems
-
ORIE 6300
Mathematical Programming I
-
ORIE 6500
Applied Stochastic Processes
-
PHYS 6562
Statistical Physics I
-
PHYS 7653
Statistical Physics II
-
SYSEN 5420
Network Systems and Games
Examples of Domain-specific Courses: Biological Systems
-
BEE 5280
Systems and Synthetic Biology for Sustainable Energy
-
BEE 5600
Molecular and Cellular Bioengineering
-
BME 6130
Advanced Microbiome Engineering
-
PLBIO 6000
Concepts and Techniques in Computational Biology
Examples of Domain-specific Courses: Energy
-
CEE 5200
Economics of the Energy Transition
-
CEE 6420
Energy Technologies and Subsurface Resources
-
CEE 6880
Applied Modeling and Simulation for Renewable Energy Systems
Examples of Domain-specific Courses: Engineered Systems
-
CEE 5795
Sensors for the Built and Natural Environments
-
CEE 6200
Water-Resources Systems Engineering
-
CEE 6790
Time Series Data Analysis for Civil, Mechanical and Geophysical Applications
-
CEE 6800
Engineering Smart Cities
Examples of Domain-specific Courses: Environment
-
CEE 6330
Physical Hydrology in the Built and Natural Environments
-
CEE 6550
Transport, Mixing, and Transformation in the Environment
-
CEE 6585
Biogeochemical Reaction Modeling
Examples of Domain-specific Courses: Fluid and Solid Mechanics
-
CEE 6726
Intermediate Solid Mechanics
-
CEE 7780
Continuum Mechanics and Thermodynamics
-
CHEME 6240
Advanced Fluid Mechanics and Heat Transfer
-
MAE 6010
Foundations of Fluid Mechanics I
Examples of Domain-specific Courses: Transportation
-
CEE 6620
Analysis and Control of Transportation Systems and Networks
-
CEE 6648
Sustainable Transportation Systems Design
Concentration: Environmental Fluid Mechanics and Hydrology
Course requirements are selected and approved by each student’s advisor and special committee. A list of recommended core courses is provided to all incoming students. Typical advisor approved electives will depend on availability in each given semester.
Environmental Fluid Mechanics and Hydrology Core Courses (Recommended)
-
MAE 6010
Fluid Mechanics
-
MAE 6310
Turbulence
-
CEE 6550
Transport and Mixing in the Environment
-
CEE 6000
Advanced Numerical Methods for Engineers
-
CEE 6330
Physical hydrology in the Built and Natural Environments
-
CEE 6370
Experimental Fluid Mechanics
Environmental Fluid Mechanics and Hydrology Electives
-
CEE 6300
Spectral Methods for Incompressible Environmental Flows
-
CEE 6305
Special Topics in Hydraulics and Hydrology: Boundary Layer Meteorology and Urban Climates
-
CEE 6360
Environmental Fluid Mechanics
-
CEE 7360
Turbulence and Mixing in Environmental Stratified Flows
Concentration: Environmental Processes
The Environmental Processes faculty recommends that students select a majority of courses from among the following core courses and elective courses. The core courses are typically offered every academic year and the elective courses are offered less frequently.
Environmental Processes Core Courses
-
CEE 6420
Energy Technologies and Subsurface Resources
-
CEE 6560
Physical/Chemical Processes
-
CEE 6530
Water Chemistry
-
CEE 6565
Waste Water Processes and Resources Recovery
-
CEE 6570
Biological Processes
-
CEE 5510
Microbiology for Environmental Engineering
Environmental Processes Electives
-
CEE 6005-105
Noise in Biology & Environmental Sciences
-
CEE 6XXX
Stochastic Modeling of Complex Systems
-
CEE 6580
Biodegradation and Biocatalysis
-
CEE 6585
Biogeochemical Reaction Modeling
-
CEE 6590
Environmental Organic Chemistry
Environmental Processes Other Relevant Courses
-
BEE 6310
Multivariate Statistics for Environmental Applications
-
CEE 6320
Hydrology
-
CEE 6970
Risk Analysis and Management
-
Concentration: Environmental and Water Resource Engineering
Environmental and Water Resource Engineering Electives
-
CEE 5200
Economics of the Energy Transition
-
CEE 5240
Model Based Systems Engineering
-
CEE 5252
Systems Analysis Behavior and Optimization
-
CEE 5735 / 6736
Mathematical Modeling of Natural and Engineered Systems
-
CEE 5745
Inverse Problems: Theory and Applications
-
CEE 5795
Sensors for the Built and Natural Environments
-
CEE 5820
Global Food, Energy, and Water Nexus
-
CEE 5930
Data Analytics
-
CEE 5970
Risk Analysis and Management
-
CEE 5980
Decision Framing and Analytics
-
CEE 6000
Advanced Numerical Methods for Engineers
-
CEE 6100
Remote Sensing Fundamentals
-
CEE 6XXX
Stochastic Modeling of Complex Systems
-
CEE 6200
Water-Resources Systems Engineering
-
CEE 6330
Physical Hydrology in the Built and Natural Environment
-
CEE 6550
Transport and Mixing in the Environment
-
CEE 6665
Modeling and Optimization for Smart Infrastructure Systems
-
CEE 6660
Multiobjective Systems Engineering Under Uncertainty
-
CEE 6770
Natural Hazards, Reliability, and Insurance
-
CEE 6790
Time Series Data Analysis for Civil, Mechanical and Geophysical Applications
-
CEE 6800
Engineering Smart Cities
-
CEE 6880
Applied Modeling and Simulation for Renewable Systems
-
CEE 6930
Public Systems Modeling
-
BEE 6110
Hydrologic Engineering in a Changing Climate
-
BEE 6310
Multivariate Statistics for Environmental Applications
-
SYSEN 6000
Foundations of Complex Systems
-
SYSEN 5888
Deep Learning
-
ORIE 5300
Optimization I
-
ORIE 5310
Optimization II
-
ORIE 5510
Introduction to Stochastic Processes
-
CS 5780
Introduction to Machine Learning
-
CS 5786
Machine Learning for Data Science
-
CS 5789
Introduction to Reinforcement Learning
Note: This list is not meant to preclude additional electives that can be approved by a student’s graduate advisor or committee member in Environmental and Water Resource Engineering.
Concentration: Structural Engineering
Course requirements are selected and approved by each student’s advisor and special committee. Typical advisor approved electives will depend on availability in each given semester
Structural Engineering Electives (Fall)
-
CEE 5735 / CEE 6736
Mathematical Modeling of Natural & Engineered Systems
-
CEE 5950
Construction Planning and Operations
-
CEE 6000
Numerical Methods for Engineers
-
CEE 6720
Introduction to Finite Element Method
-
CEE 6730
Design of Concrete Structures
-
CEE 6770
Natural Hazards, Reliability, and Insurance
-
CEE 6790
Time Series Data Analysis
-
CEE 7710
Stochastic Problems Engineering and Science
-
MAE 5700
Finite Element Analysis for Mechanical and Aerospace Design
-
MAE 6110
Foundations of Solid Mechanics
-
MAE 6010
Foundations of Fluid Mechanics
-
MAE 6130
Mechanics of Composite Structures
-
MAE 6730
Intermediate Dynamics and Vibrations
-
MAE 5010
Future Energy Systems
-
MAE 6810
Methods of Applied Mathematics
-
ICS 6210
Numerical Analysis and Differential Equations
Structural Engineering Electives (Spring)
-
BME 5810
Soft Tissue Biomechanics
-
CEE 5745 / CEE 6745
Inverse Problems: Theory and Applications
-
CEE 5795
Sensors for the Built and Natural Environments
-
CEE 6725
3D Printing Parts that Don’t Break
-
CEE 6750
Concrete Materials and Construction
-
CEE 6780
Structural Dynamics and Earthquake Engineering
-
CEE 7740
Advanced Structural Concrete
-
CS 6220
Introduction to Scientific Computation
-
MAE 5130
Mechanical Properties of Thin Films
-
MAE 5790
Nonlinear Dynamics and Chaos
-
MAE 6120
Foundations of Solid Mechanics II
-
MAE 6160
Advanced Composite Materials
-
MAE 6640
Mechanics of Bone
-
MAE 6780
Methods of Applied Mathematics
-
IIMSE 6020
Elasticity, Plasticity, and Fracture
-
TAM 6680
Elastic Waves in Solids with Applications
Concentration: Transportation Systems Engineering
Transportation Systems Engineering Core Courses (required)
-
CEE 6620
Analysis and Control of Transportation Systems and Networks
-
CEE 6640
Microeconometrics of Discrete Choice
Transportation Systems Engineering Core Courses (recommended)
-
CEE 6648
Sustainable Transportation Systems Design
-
CEE 5930
Data Analytics
Transportation Systems Engineering Elective Courses
-
CRP 5040
Urban Economics
-
CRP 5080
Intro to Geographic Information Systems
-
CRP 5170
Economic Development
-
CRP 5190
Urban Theory and Spatial Development
-
CRP 5520
Land Use Planning
-
CRP 5840
Green Cities
-
CRP 6090
Urban and Regional Theory
-
CRP 6860
Planning for Sustainable Transportation
-
CEE 5290
Heuristic Methods for Optimization
-
CEE 5900
Project Management
-
CEE 5970
Risk Analysis and Management
-
CEE 6620
Analysis and Control of Transportation Systems and Networks
-
CEE 6640
Microeconometrics of Discrete Choice
-
CEE 6665
Modeling and Optimization for Smart Infrastructure Systems
-
CEE 6930
Public Systems Modeling
-
ECON 5540
Economics of Regulation
-
ECON 6090
Microeconomic Theory
-
AEM 6170
Decision Models for Small & Large Businesses
-
AEM 6320
Public Private Sector Economics Linkages
-
AEM 6330
Devolution, Privatization, & the New Public Management
-
ORIE 5300
Optimization I
-
ORIE 5310
Optimization II
-
ORIE 5510
Introduction to Stochastic Processes
-
ORIE 6580
Simulation Modeling & Analysis
-
NBA 6410
Supply Chain Management