Manufacturing Engineering - MEME – Faculty of Engineering

Manufacturing Engineering – MEME

The MEng degree is course or project-based program, equipping you with skills to enhance and sustain manufacturing processes, fundamental in improving lives and adding societal value.

Length
Full-time and part-time options
Degree
Master of Engineering (Co-op Available)
Type
Course or Project-based
Options

Co-op

Global opportunities

Build a successful career in the manufacturing industry anywhere in the world. If you love to design and operate resource-efficient manufacturing plants this is the program for you.

Flexibility

Recommended 16 months full-time (minimum 12 months and maximum 24 months) or 40 months part-time (domestic only).

From the bleeding-edge tech we have at our disposal to the supportive professors, mentors and a multicultural student base, this program has it all. What’s more, you can customize your learning to create the best springboard to launch your career.

Prasanna Venkatesh, MEME ’18

Admission requirements

Academic Prerequisites

Honours Bachelor’s Degree (4 Year) in Engineering, Sciences, or equivalent.

Anticipated Admission Range
B average (73-76% or 8.0/12) in last two years of study (20 technical courses)
Supplementary Application
Required
Students looking at laptop in the JHE Lobby

How to apply

Prior degree: Engineering or Technology Degree, B average in last two years of study (20 technical courses), equivalent to a McMaster 8.0 GPA out of 12

The Master of Engineering in Manufacturing Engineering is aimed at highly motivated students seeking advanced training in the broad area of Manufacturing. Application for admission to the program may be made through the W Booth School of Engineering Practice and Technology. The program accepts full-time and part-time students – see the Program Structure section for details.

In addition to the general requirements for entry into a graduate program in Engineering, students must hold a degree in Engineering or Technology with at least a B average (equivalent to a McMaster 8.0/12 GPA) in the penultimate and final years.

IELTS/TOEFL: International students are required to present a minimum IELTS score of 6.5 overall (minimum requirements 5.5 in reading and writing and 6 in listening and speaking). Minimum TOEFL score is 88.

Candidates may be enrolled on a full- or part-time basis. Full-time students will complete the degree in twelve consecutive months of study. Students are admitted for September. Part-time students will normally be expected to complete the program in 28 months.

McMaster students may receive advanced standing for up to two courses (note that a maximum of two 600-level courses can count towards a SEPT graduate program) with the approval of the Associate Dean of Graduate Studies.

September 2025 AdmissionsJanuary 2026 Admissions
Application Portal OpensNovember 1, 2024June 15, 2025
International Student DeadlineMarch 14, 2025July 14, 2025
Domestic Student DeadlineJune 30, 2025September 30, 2025

International applicants are encouraged to apply early as the visa application process may take 3 months or more.

Tuition & Fees
30 credit units are required to complete this degree and tuition is paid per credit unit. Please view the per-unit fees for the current academic year here.

Students enrolled in multiple academic years ( e.g. January admission) pay the fees corresponding for the academic year the term is within. The University reserves the right to correct typographical errors or to adjust the Tuition and Fees schedule at any time it deems necessary.

Other Fees:

  • Application Fee: $150.00
  • Online Interview Fee (Kira Talent): $60.00

Post-Acceptance Fees

  • Non-refundable deposit upon acceptance
International Student Non-refundable Deposit$2000
Domestic Student Non-refundable Deposit$500

Step 1: Click on the link above to open your application with McMaster University. Alternatively, please visit the Graduate studies portal.

Step 2: Answer all application-related questions.

Step 3: Register for your online interview (Kira) and ensure that you complete the $60 payment. Note that the $60 is in addition to your $150 application fee. They are separate charges.

  • The registration and payment link are embedded in your application questions.

Step 4: Gather, and upload all required documents.

  • Your current resume or CV, including academic and professional experience
  • Your clearly written Statement of Interest (This is a letter explaining your interest in the program, at a maximum of 2 pages).
  • Recent IELTS or TOEFL scores (within the last 2 years) required for international students. Minimum IELTS score 6.5 overall (minimum requirement 5.5 in reading and writing and 6 in listening and speaking). Minimum TOEFL score is 88. Note that if your medium of instruction was English and this is documented on your transcripts, you do not need to submit an ELP test.
  • Transcripts from all post secondary institutions you have attended.
  • Please note that all documents must be uploaded before application submission. CV, SOI, IELTS/TOEFL and Transcripts are uploaded in the same section of the application.

Step 5: Add Academic Referee contact information.

  • Contact information for 2 Academic References must be entered in online application. Referees will be contacted via our electronic referencing system
    • Academic references are to come from instructors most familiar with your academic work.
    • In cases where an applicant has been away from academic study for 5 or more years, we will consider one professional reference and one academic reference.
    • Please note that we do not accept reference letters uploaded by the applicant.

Step 6: Pay $150 application fee, and submit application.

  • Only submit your application once all the above documents have been uploaded, you have entered contact information for both academic references, and you have paid your Kira fee.
  • *Applications will not be reviewed unless all items noted above are submitted at the time of application*.

Step 7: Complete your Kira interview.

  • Applicants will be sent a link to complete their Kira interview within one week of application submission and Kira fee payment.
  • Applicants will not receive a link unless they have fully submitted their application, and have submitted the $60 Kira fee payment.

Step 8: You will be contacted if there are any issues with your application. Please do not email about the status of your application. Applicants will be contacted once a decision regarding the application has been made.

  • Please note that if you are accepted to one of our programs, you will be required to pay a non-refundable deposit. This deposit is non-refundable if you withdraw your acceptance.
International Student Non-refundable Deposit$2000
Domestic Student Non-refundable Deposit$500

Important Notes:

  • Applications will not be reviewed until all required documents are uploaded, the referees have responded, and the Kira online interview has been completed. All applications must be completed in full in advance of the application deadlines in order to be considered.
  • Official transcripts are not required unless an applicant is granted an offer of admission. Documentation sent via post will not be considered for your application.
  • Applications will not be considered until we receive copies of transcripts noting grades up to at least Term 7 of your undergraduate studies.

Program Structure

The manufacturing sector offers many career opportunities for engineers in discrete manufacturing (e.g. from consumer products to aircraft), and in the biomanufacturing industry (e.g. from liquid biofuels to biopharmaceutical and cell therapy industries). Our program builds on Ontario’s deep history of high-quality manufacturing.

Full-time students are expected to complete the program in 16 months.  The actual duration of studies may be shorter (not less than 12 months) or longer (not more than 24 months), for students who work faster or slower.

Domestic students (Canadian citizens or permanent residents) may complete their MEME degree on a part-time basis and establish their schedule according to how much time they can devote to studies. It is recommended that part-time students complete the program in 32 to 40 months.

The Discrete Manufacturing concentration will equip you with the capabilities to design and operate traditional and additive manufacturing, experiment with different materials, use robots, and monitor and manage production for automotive, aerospace, machinery, household products and other discrete manufacturing industries.

Choosing this concentration will equip you with the capabilities to design and operate traditional and additive manufacturing, experiment with different materials, use robots, and monitor and manage production for automotive, aerospace, machinery, household products and other discrete manufacturing industries.

There are two pathways towards the degree:

  • Project-based pathway: 8 courses (24 units) + project (6 units)
    • 2 to 3 professional development courses
    • 3 to 4 core courses
    • 1 to 2 technical elective courses
    • 2 project courses

Students pursuing the Project-based pathway are required to register for two project courses:

  • MANUFACT 701 – MEng Project in Manufacturing Engineering, Part I (3 units)
  • MANUFACT 701 – MEng Project in Manufacturing Engineering, Part II (3 units)
  • Courses-only pathway: 10 courses (30 units)
    • 2 to 3 professional development courses
    • 4 to 6 core courses
    • 1 to 3 technical elective courses

Professional Development courses:

  • SEP 6EP3 – Entrepreneurial Thinking & Innovation (3 units)
  • SEP 6MK3 – Fundamentals of Marketing (3 units)
  • SEP 6TC3 – Technical Communications (3 units)
  • SEP 709 – Emerging Issues, Technology and Public Policy (3 units)
  • SEP 710 – International Governance and Environmental Sustainability (3 units)
  • SEP 725 – Practical Project Management for Today’s Business Environment (3 units)
  • SEP 760 – Design Thinking (3 units)
  • SEP 770 – Total Sustainability Management (3 units)
  • SEP 773 – Leadership for Innovation (3 units)

Core courses:

  • SEP 6I03 – Sustainable Manufacturing Processes (3 units)
  • SEP 726 – Discrete Manufacturing Processes 1 (3 units)
  • SEP 727 – Discrete Manufacturing Processes 2 (3 units)
  • SEP 729 – Manufacturing Systems (3 units)
  • SEP 731 – Lean Six Sigma for Engineers (3 units)
  • SEP 738 – Artificial Intelligence Methods in Advanced Manufacturing (3 units)
  • SEP 757 – Rapid Prototyping (also Mech Eng 759) (3 units)
  • SEP 780 – Advanced Robotics and Automation (3 units)
  • SEP 6T03 – Properties and processing of composites (3 units)
  • SEP 718 – Industrial Automation (3 units)
  • SEP 736 – Railway Electrification Infrastructure and Technology (3 units)
  • SEP 756 – Introduction to Railway Engineering (3 units)
  • SEP 767 – Multivariate Statistical Methods for Big Data Analysis and Process Improvement (3 units)
  • SEP 776 – Manufacturing Systems 2 (3 units)
  • SEP 777 – Cyber-Physical Systems and Industry 4.0 (3 units)
  • SEP 792 – Railway Signaling and Train Control (3 units)
  • SEP 797 – System Assurance (3 units)

Each concentration area has a set of recommended elective courses.  Students wishing to take an elective course outside of the recommended electives need to obtain a permission from their graduate advisor.

For more details please refer to the Graduate Calendar.

W Booth School of Engineering Practice and Technology strives to offer a full complement of courses every academic year; some of the courses listed here are currently being reviewed. Their offering is subject to the pending internal approval.

Biomanufacturing and Industrial Biotechnology is the common operation that links together all the different market sectors of the world’s biotechnology industry.  It is a diverse field encompassing the massive production scales of the liquid biofuels industry at one end, to the high-quality and highly regulated biopharmaceutical and cell therapy industry at the other. The Master’s Program in Biomanufacturing at W Booth School of Engineering Practice and Technology trains science and technology graduates for leadership roles in this rapidly expanding and vitally important field.

This innovative Master’s program in Biomanufacturing and Industrial Biotechnology combines a foundation in biomanufacturing, bioprocessing and biopharmaceutical theory, with experiential learning in areas including global regulatory affairs, protein characterization, cGMP manufacturing of influenza vaccine, monoclonal antibody production, advanced biomanufacturing and biocatalysis. The curriculum includes academic courses in science and business, along with professional training through case study projects. The program also includes professional skills training in effective oral, electronic, and written communications for both technical and business careers.

Students will develop and run live bioprocessing projects from start to finish, using industry-standard equipment in a simulated cGMP (current good manufacturing practices) environment. Offered with a flexible lecture and laboratory schedule, this concentration is designed for early and mid-career professionals who want to enter the biopharmaceutical industry in a range of capacities, including cell-line development, process development, regulatory compliance, quality assurance/quality control, manufacturing and business development.

There are two pathways towards the degree:

  • Project-based pathway: 8 courses (24 units) + project (6 units)
    • 2 to 3 professional development courses
    • 3 to 4 core courses
    • 1 to 2 technical elective courses
    • 2 project courses

Students pursuing the Project-based pathway are required to register for two project courses:

  • MANUFACT 701 – MEng Project in Manufacturing Engineering, Part I (3 units)
  • MANUFACT 701 – MEng Project in Manufacturing Engineering, Part II (3 units)
  • Courses-only pathway: 10 courses (30 units)
    • 2 to 3 professional development courses
    • 4 to 6 core courses
    • 1 to 3 technical elective courses

Professional Development courses:

  • SEP 6EP3 – Entrepreneurial Thinking & Innovation (3 units)
  • SEP 6MK3 – Fundamentals of Marketing (3 units)
  • SEP 6TC3 – Technical Communications (3 units)
  • SEP 709 – Emerging Issues, Technology and Public Policy (3 units)
  • SEP 710 – International Governance and Environmental Sustainability (3 units)
  • SEP 725 – Practical Project Management for Today’s Business Environment (3 units)
  • SEP 760 – Design Thinking (3 units)
  • SEP 770 – Total Sustainability Management (3 units)
  • SEP 773 – Leadership for Innovation (3 units)

Mandatory courses:

  • SEP 744 – Biomanufacturing (3 units)
  • SEP 767 – Multivariate Statistical Methods for Big Data Analysis and Process Improvement (3 units)

Core courses:

  • SEP 712 – The application of Computation Modeling for Biomanufacturing (3 units)
  • SEP 764 – Novel Therapeutics and Drug Delivery Systems (3 units)
  • SEP 743 – Animal Cell Culture Engineering (3 units)
  • SEP 745 – Bioassays and Biosensors in Biomanufacturing (3 units)
  • SEP 765 – Current Good Manufacturing Practice Downstream Operation (3 units)
  • SEP 6BI3 – Bioinformatics (3 units)
  • SEP 6BS3 – Biotechnology Regulations  (3 units)
  • SEP 729 – Manufacturing Systems (3 units)
  • SEP 749 – Biomedical Engineering (3 units)
  • SEP 766 – Membrane-Based Bioseparation (3 units)
  • BIOMED 799 – Independent Study in Biomedical Engineering (3 units)

Each concentration area has a set of recommended elective courses.  Students wishing to take an elective course outside of the recommended electives need to obtain a permission from their graduate advisor.

For more details please refer to the Graduate Calendar.

W Booth School of Engineering Practice and Technology strives to offer a full complement of courses every academic year; some of the courses listed here are currently being reviewed. Their offering is subject to the pending internal approval.

Students can select additional elective courses from the following list, provided that the approval has been received prior from their program lead:

Note that not all courses are offered every year.

Chemical Engineering

  • CHEM ENG 6B03 – Polymer Reaction Engineering
  • CHEM ENG 6E03 – Digital Computer Process Control
  • CHEM ENG 6X03 – Polymer Processing
  • CHEM ENG 6Z03 – Interfacial Engineering
  • CHEM ENG 752 – Optimization of Chemical Processes
  • CHEM ENG 753 – Systems Modeling and Optimization
  • CHEM ENG 761 – Multivariable, Stochastic and Adaptive Control of Chemical Processes
  • CHEM ENG 764 – Process Control and Design for Operability
  • CHEM ENG 765 – Multivariate Statistical Methods for Big Data Analysis and Process Improvement
  • CHEM ENG 770 – Selected Topics in Polymer Science and Engineering
  • CHEM ENG 773 – Advanced Concepts of Polymer Extrusion
  • CHEM ENG 774 – Advances in Polymeric Materials
  • CHEM ENG 782 – Biopharmaceuticals
  • CHEM ENG 791 – Nanotechnology in Chemical Engineering

Materials Science and Engineering

  • MATLS 6C03 – Modern Iron and Steelmaking
  • MATLS 6H03 – Thin Film Science and Engineering
  • MATLS 6I03 – Sustainable Manufacturing Processes
  • MATLS 6P03 – Properties of Polymeric Materials
  • MATLS 6T03 – Properties and Processing of Composites
  • MATLS 6MS4 – Materials Selection in Design and Manufacturing
  • MATLS 754 – Fracture Mechanics
  • MATLS 771 – Principles of Heterogeneous Kinetics
  • MATLS 780 – Metallic and Non-metallic Coatings

Mechanical Engineering

  • MECH ENG 6B03 – Topics in Product Development
  • MECH ENG 6K03 – Robotics
  • MECH ENG 6L03 – Industrial Design
  • MECH ENG 6Q03 – Mechanical Vibrations
  • MECH ENG 6T03 – Finite Element Applications
  • MECH ENG 6Z03 – CAD-CAM-CAE
  • MECH ENG 702 – Advanced Dynamics of Machines
  • MECH ENG 705 – Advanced Finite Element Analysis
  • MECH ENG 710 – Machine Tool Analysis
  • MECH ENG 714 – Solidification Processing
  • MECH ENG 724 – Solid and Surface Modeling Techniques
  • MECH ENG 728 – Manufacturing Processes I
  • MECH ENG 729 – Manufacturing Systems
  • MECH ENG 734 – Theory of Plasticity
  • MECH ENG 735 – Additive Manufacturing
  • MECH ENG 738 – Manufacturing Processes II
  • MECH ENG 743 – Advanced Mechatronics
  • MECH ENG 751 – Advanced Mechanical Engineering Control Systems
  • MECH ENG 752 – Advanced MEMS Fabrication and Microfluidics
  • MECH ENG 759 – Rapid Prototyping
  • MECH ENG 760 – Electric Drive Vehicles

A maximum of two courses can be selected from the following list:

Electrical Engineering

  • ECE 710 – Engineering Optimization
  • ECE 732 – Non-linear Control Systems
  • ECE 736 – 3D Image Processing and Computer Vision
  • ECE 744 – System-on-a-Chip (SOC) Design and Test: Part I – Methods
  • ECE 778 – Introduction to Nanotechnology

Software Engineering

  • SFWR ENG 6HC3 – The Human Computer Interface

Computer Science

  • COMP SCI 6F03 – Distributed Computer Systems
  • COMP SCI 6TE3 – Continuous Optimization

Computing and Software

  • CAS 771 – Introduction to Big Data Systems and Applications

Manufacturing Engineering

  • MANUF 6RM3 – Robot Mechanics and Mechatronics
  • MANUF 710 – System Analysis Simulation

Other courses in other departments and faculties may be considered with the approval of the Engineering Design Program Lead.

Equipment used for measuring soil density in Geotechnical Lab

Facilities

The lab is equipped with 3D printers and machining equipment. You will develop your skills and comfort working with these tools to make your design vision into an operational prototype in metal or plastic.

Tools and equipment accessible in the lab include:

  • 3D Metal Printers
  • CNC lathe and router
  • PCB soldering station
  • 3D Polymer Printers
  • Laser cutter for plastic sheets
  • Bench scale tools including a drill press, band saw, etc.

Students in the M.Eng. Manufacturing Engineering program can access this facility by appointment. The space can be used for prototyping in course and project work. The SEP 762 Prototyping tools and methods course uses the MARC facility.

Tools and equipment accessible in the lab include:

  • CNC lathe and router
  • PCB soldering station
  • 3D Polymer Printers
  • Bench scale tools including a drill press, band saw, etc.

The facility is located at 200 Longwood Ave.

Houses workstation computers that can be accessed for CAD design and modelling simulation. Access is based on scheduled availability.

Accessible within the ETB 524 studio space. This network supports engineering computing and 3D prototyping via your laptop. This allows you to use your laptop as an interface, while outsourcing the “heavy lifting” of highly detailed design work to a mainframe server.

Student projects

Stackpole International

ProjectDeploying an Industry 4.0 Non-Destructive Testing solution to improve the reliability and throughput of product inspection.

Challenge: Stackpole International, a leader in manufacturing automotive parts using powder metallurgy, engaged a group of our students in a project to develop a new solution for their Non-Destructive Testing work cell. The system they were using was stand-alone and they saw opportunities to improve reliability and connectivity with their production line network. Students analyzed different technologies comparing open-source with commercial packages and custom hardware with off-the-shelf. Students finally developed, built and deployed the new work cell into the partner’s facility.

Canadian National Railway

Project: Re-designing a condensate blowdown valve assembly on to operate in the extreme cold of Canadian winters

ChallengeStudents identified that the design of blowdown valves on trains were inadequately designed to cope with extreme cold weather, resulting in significant delays during the coldest parts of the year. Moisture freezing inside blowdown valves caused brakes to lock in place. The built-in electrical heaters affixed to the valve assembly was not thawing the ice, requiring maintenance crews to use portable heaters and manually de-ice the valves. Students in the program analyzed the system and proposed a solution to redesign the valve assembly so that it could operate in colder temperatures than existing vales.

Westhill Innovation Inc.

Project: Powering transportation refrigeration systems using solar power collected from the top of trailers.

ChallengeWesthill Innovation identified an opportunity to reduce emissions produced while powering refrigeration units and they engaged a group of students to help design a solar panel solution for truck trailers. Truck drivers are mandated to take rest periods while on the road, and while resting they must power refrigeration units using the truck’s diesel engine. By developing a system that allows solar panels to be mounted to the top of a transport trailer, the 425 square feet of space on the roof can charge a battery bank that will power the refrigeration unit and allow drivers to turn off their engines while parked. In the future, this technology could greatly extend the range of electric trucks and feed into the power grid when the trailers are parked for loading and unloading.

Edson Packaging Machinery Ltd.

ProjectDeveloping a Fully Automated Picking and Packaging Solution

Challenge: Edson Packaging Machinery sought our student’s help to develop a robotic solution that could recognize between 1000s of products and identify the those bought by a single customer and place them into one box for shipment. The solution students worked on with Edson would also include a system to create and seal customized box sizes for e-commerce orders, minimizing the need for excess packaging. The final objective of these solutions would be that they need to operate quickly and accurately.

Somak Mukherjee, Raj Patel, Perveen Vasudevan, and Jing Qian

Program: Master of Engineering in Manufacturing Engineering. Class of 2020

Project name: Robotic Greeter – Humanoid Robot with AI Capabilities

Project impact: Somak Mukherjee is investing his energy in fully embracing the age of artificial intelligence.

Exploring the AI field, Somak grew interested in the area of humanoid robotic assistants- robots that can adapt to changes in their environments while continuing to pursue their goals.

In partnership with CareGo Tek Inc., Somak built a software-based platform for humanoid robot development, the TELIA Robot, as well as a map of humanoid robotics platform development. His work tackles a common problem: understanding and replicating human information processing; how the human brain interacts with the real world.

For Somak, his research pulled back the curtain on robotics as an intriguing and challenging research field. “I hope my contribution can play a role in robotics research and the many applications of the 21st century,” he says

Highlights:

  • Humanoid robot, TELIA, that greets and guides customers
  • Supports speech and face recognition
  • Programmable via tablet and other touch screen devices
  • Project partner
  • CareGo Tek Inc.
  • Preparing for success
  • The MEME program gave Somak the tools to combine the disciplines of mechatronics, computer programming and manufacturing to develop a cradle-to-grave prototype robotic system.

Somak currently works as an Assistant Vice President with Citi Canada Technology Services.

Aswin Cmohan and Anirudh Vijayameenakshi

Program: Master of Engineering in Manufacturing Engineering. Class of 2020.

Project name: Automating Wessuc’s Dewatering System

Project impact: This project was part of an effort to optimize Wessuc’s dewatering process to be more lean and efficient. The project focused on automating key areas of the process used by this Southern Ontario wastewater management company. 

Their work included designing process flow charts, creating technical electrical layouts, and developing a Human Machine Interface (HMI) that allowed for remote and onsite system operation. 

Preparing for success: Aswin points to the MEME program’s practical coursework and projects as key components of his learning experience: “The subjects and electives are so in-line to what you will find in an industry,” says Aswin. 

Coursework on Manufacturing Systems, Lean Six Sigma, and Industrial Networks is, according to Asmin, “delivered by professors who have had significant industrial experience. They helped me in gaining a better insight into how an industry functions.”

Project partnerWessuc 

Aswin currently works as a Process Engineer at Vins Plastics, a manufacturer of flexible packaging products located in Southern Ontario.

The fireball family mascot with a fireball sign.

Get involved

If you’re looking for opportunities to engage with the McMaster community beyond your program, you will find a wealth of clubs and co-curricular activities to capture your interests.

This student-run club plans social and professional development events for students in W Booth School of Engineering Practice and Technology students. For more information, please visit: https://gsa.mcmaster.ca/septs/

While the MES is primarily undergraduate focused, there are opportunities for graduate students to get involved as well. Through the MES you can also connect with a multitude of professional association chapters, clubs, conferences, design competitions, hack-a-thons, and more. For further information visit: https://www.macengsociety.ca/

This interdisciplinary, co-curricular program brings together students from across every faculty and program to address challenges in the Hamilton area. It is open to undergraduate and graduate students and a great way to connect with other students, faculty and subject matter experts from different organizations across the region. For additional information, please visit: https://www.eng.mcmaster.ca/macchangers/

For those who like to stay active and social, join one of the many recreational sports leagues that you run through McMaster Athletics & Recreation. Further information can be found here: https://rec.mcmaster.ca/programs/intramural-sports-0

Co-op and Student Life

  • Graduate Co-op

    Master’s and PhD students may complete 4 to 12 months of co-op experience in various types of organizations, including corporations, non-profit organizations, government agencies, startups and research institutions.

    Explore Co-op
  • Engineering Graduate Society

    The EGS actively supports engineering graduate students through events, workshops, bursaries, and collaboration with various campus organizations, focusing on representation, community building, and academic and professional development.

    Visit the EGS site
  • Life in Hamilton

    Hamilton, also known as The Hammer or Steeltown, is a thriving city close to the U.S. border and Toronto, with easy access for students commuting from the Greater Toronto Area via the on-campus GO Bus Terminal.

    Discover Hamilton, ON

How to apply

Understand every step, from applying, to accepting your offer and joining us on campus!

Request more information

Thank you for your interest in our Graduate Studies. Please fill out the form below, and we will connect with you to answer all of your questions.

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