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Masters Degrees (Manufacturing Engineering)

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This newly developed MSc programme aims to take well qualified students (typically those having a good bachelor's degree in Manufacturing Engineering or an equivalent qualification) and to equip them with the skills they need to be employed as professional engineers across a wide range of the Manufacturing Engineering industry. Read more
This newly developed MSc programme aims to take well qualified students (typically those having a good bachelor's degree in Manufacturing Engineering or an equivalent qualification) and to equip them with the skills they need to be employed as professional engineers across a wide range of the Manufacturing Engineering industry.

The distinctive features of this programme include:

• The opportunity to learn within a vibrant research environment which has benefited from major strategic investment via directed SRIF funds of £2.4M into the Cardiff University Structural Performance (CUSP) laboratory, and collaborative industrial partnerships.

• The application of measurement techniques within the recently installed Renishaw Metrology Laboratory, part of a strategic partnership between the School and Renishaw.

• A close involvement with industry ensures that the research has both relevance and meaning, working with some of the world’s most renowned engineering companies.

• Significant inputs into teaching and project work will also be made by members of Cardiff Business School, providing the latest in business and management knowledge and skills.

• A programme which will be informed by up-to-date internationally renowned research expertise undertaken within the School’s Mechanics, Materials and Advanced Manufacturing research theme. These will include the modules in the subject areas of robotics, metrology, manufacturing, informatics, innovation and artificial intelligence/image processing.


This course is presented as a one-year, full time Masters level programme which will comprise two stages and give a total duration of one calendar year.

Stage 1 which will extend for two semesters and consist of predominantly taught modules and a case study as a forerunner to the research project and dissertation in the field of Manufacturing Engineering, Innovation, and Management to the value of 120 credits, and Stage 2, which consists of a Dissertation module worth 60 credits.

Core modules:

Lean Operations
Manufacturing Engineering Innovation and Management Case Study
Manufacturing Engineering Innovation and Management Project
Advanced Mechanical Engineering Project

Optional modules:

Measurement Systems
Manufacturing Informatics
Commercialising Innovation
Artificial Intelligence
Quality and Reliability
Condition Monitoring, Systems Modelling and Forecasting
Management in Industry
Advanced Robotics


A wide range of teaching styles will be used to deliver the diverse material forming the curriculum of the programme, and you will be required to attend lectures and participate in examples classes.

A 10-credit module represents approximately 100 hours of study in total, which includes 24–36 hours of contact time with teaching staff. The remaining hours are intended to be for private study, coursework, revision and assessment. Therefore you are expected to spend a significant amount of time (typically 20 hours each week) studying independently.

At the dissertation stage, you will be allocated a supervisor in the relevant field of research whom you should expect to meet with regularly.

Learning Central, the Cardiff University virtual learning environment (VLE), will be used extensively to communicate, support lectures and provide general programme materials such as reading lists and module descriptions. It may also be used to provide self-testing assessment and give feedback.


Achievement of learning outcomes in the classroom based modules is assessed by University examinations set in January and May/June. The balance between examination and coursework depends upon the modules selected, in addition to a triple module (30-credit) case study.

Award of an MSc requires successful completion of Stage 2, the Dissertation, with a mark of 50% or higher.

Candidates achieving a 70% average may be awarded a Distinction. Candidates achieving a 60% average may be awarded a Merit. Candidates failing to qualify for an MSc may be awarded a Postgraduate Diploma of Higher Education for 120 credits in Stage 1. Candidates failing to complete the 120 credits equired for Stage 1 may still be eligible for the award of a Postgraduate Certificate of Higher Education for the achievement of at least 60 credits.

Career prospects

Employment opportunities for students undertaking the proposed programme will be largely with national and international companies in the manufacturing engineering sector.

You may wish to use the MSc platform to go on to study for a PhD which can lead to an industrial or academic career.

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Want a rewarding and well-paid career as an Engineer but don’t have a first degree in engineering? This Manufacturing Engineering Masters conversion course is just for you. Read more
Want a rewarding and well-paid career as an Engineer but don’t have a first degree in engineering? This Manufacturing Engineering Masters conversion course is just for you.

Course overview

The University of Sunderland has over 100 years experience in teaching engineering and our engineering research has been rated as ‘world-leading’ in the latest Research Excellence Framework. We also have strong industry links with manufacturing giants such as Nissan.

Manufacturing Engineers are creative innovators that revolutionise the way we live and are highly skilled in research, design, technology, processes and equipment. Industry-relevant modules such as Design for Manufacturing and Manufacturing Automation mean you’ll be well-prepared for employment in the sector.

Develop strong managerial, operational and leaderships skills, necessary to become an expert in areas such as advanced maintenance, operations management and quality management.

Benefit from a range of practical activities, industry experts’ lectures and real-world problem-solving workshops hosted by the Institute for Automotive and Manufacturing Advanced Practice (AMAP).

Graduate with the all the necessary skills to start a diverse career in a high-tech industry.

Course content

Independent research is mixed with taught elements and supported by expert’s supervision. Modules on this course include:
-Engineering Principles for Manufacturing (30 Credits)
-Manufacturing Automation (15 Credits)
-Design for Manufacturing (15 Credits)
-Advanced Maintenance Practice (15 Credits)
-Engineering Operations Management (15 Credits)
-Manufacturing Management (15 Credits)
-Qualify Management for Manufacturing (15 Credits)
-Manufacturing Project (60 Credits)

Teaching and assessment

We use a wide variety of teaching and learning methods which include lectures, group work, research, discussion groups, seminars, tutorials and practical laboratory sessions.

Compared to an undergraduate course, you will find that this Masters requires a higher level of independent working.

Assessment methods may include individual written reports and research papers, exams, practical assignments and the Masters project.

Facilities & location

The University of Sunderland has excellent facilities with specialist laboratories and modelling software.

Engineering facilities
Our specialist facilities include laboratories for electronics and electrical power, and robotics and programmable logic controllers. We also have advanced modelling software that is the latest industry standard. In addition, the University is the home of the Institute for Automotive and Manufacturing Advanced Practice (AMAP), which builds on Sunderland’s role as a centre of excellence in the manufacturing and assembly of cars.

University Library Services
We’ve got thousands of books and e-books on engineering topics, with many more titles available through the inter-library loan service. We also subscribe to a comprehensive range of print and electronic journals so you can access the most reliable and up-to-date academic and industry articles.

Some of the most important sources for engineers include:
-British Standards Online which offers more than 35,000 documents covering specifications for products, dimensions, performance and codes of practice
-Abstracts from the Institute of Electrical and Electronics Engineers and Institution of Engineering and Technology. These include journals, conference proceedings, technical reports and dissertations. A limited number of articles are full-text
-Science Direct, which offers more than 18,000 full-text Elsevier journals
-Archives of publications from Emerald, including over 35,000 full-text articles dating back to 1994 that span engineering and management subjects

IT provision
When it comes to IT provision you can take your pick from hundreds of PCs as well as Apple Macs in the David Goldman Informatics Centre and St Peter’s Library. There are also free WiFi zones throughout the campus. If you have any problems, just ask the friendly helpdesk team.

The course is based at our Sir Tom Cowie Campus at St Peter’s. The Campus is on the banks of the River Wear and is less than a mile from the seaside. It’s a vibrant learning environment with strong links to manufacturers and commercial organisations and there is a constant exchange of ideas and people.

Employment & careers

This course equips you for a wide range of engineering management roles throughout the engineering and manufacturing sector. Employers recognise the value of qualifications from Sunderland, which has been training engineers and technicians for over 100 years.

Manufacturing Engineering graduates develop expertise in planning and designing, as well as the modification and optimisation of manufacturing processes. The essential principles of manufacturing engineering apply to all industries and equips you for a wide range of engineering roles throughout the engineering and manufacturing sector.

A Masters degree will also enhance opportunities in academic roles or further study towards a PhD.

On completing this course, you will be equipped as a skilled professional with essential up-to-date knowledge in manufacturing engineering.

Leading market companies employing engineers, include:
-Thales Group
-Jaguar Land Rover (JLR)

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This MSc programme provides its students with an opportunity to extend the technical knowledge acquired on an undergraduate degree programme in mechanical or manufacturing engineering. Read more
This MSc programme provides its students with an opportunity to extend the technical knowledge acquired on an undergraduate degree programme in mechanical or manufacturing engineering.

Though not a specialist Master's degree, the programme provides a broad subject-specific curriculum that provides an opportunity for students to tailor the programme to meet their personal needs, with specialism pursued through a major project.

Many of these projects reflect the key research interests of the Department, such as manufacturing, bulk materials handling and instrumentation. However, projects can be selected from across the discipline from a list provided by the Department. Many projects are derived from our industrial links, and a number are proposed by students, reflecting their personal interests or experience.

The aims of the programme are:

- To provide students with an enhanced base of knowledge and current and reflective practice necessary to initiate a career in mechanical and manufacturing engineering at the professional engineer level

- To enhance specialist knowledge in the area of mechanical and manufacturing engineering which build upon studies at the undergraduate level

- To further develop improved skills of independent learning and critical appraisal

- To develop an extensive insight into industrial applications and requirements

- To develop critical insight of management issues relating to engineering business.

Visit the website http://www2.gre.ac.uk/study/courses/pg/mech/mechmaneng

Engineering - Mechanical

These programmes are designed to provide a broad education which incorporates the methodologies and practices of engineering appropriate to the needs of industry. They include focus on manufacturing systems and technologies as well as the principles of mechanical engineering and supportive technology.

Course content

Research Methodology (15 credits)
Strategy and Management (15 credits)
Process Improvement Techniques (15 credits)
Computer Aided Manufacturing (15 credits)
Materials Selection in Mechanical Design (15 credits)
Quality Engineering (15 credits)
Advanced Principles in Lean Manufacturing (15 credits)
Innovative Manufacturing Processes and Techniques (15 credits)
Individual Project and Dissertation (60 credits)

Fees and finance

Your time at university should be enjoyable and rewarding, and it is important that it is not spoilt by unnecessary financial worries. We recommend that you spend time planning your finances, both before coming to university and while you are here. We can offer advice on living costs and budgeting, as well as on awards, allowances and loans.

Find out more about our fees and the support available to you at our:
- Postgraduate finance pages (http://www.gre.ac.uk/finance/pg)
- International students' finance pages (http://www.gre.ac.uk/finance/international)


Students are assessed through examinations, case studies, assignments, practical work and a dissertation.

Professional recognition

Institution of Engineering and Technology (IET) accreditation (http://www.theiet.org/).

Career options

This programme provides a wide variety of opportunities for mechanical and manufacturing engineers in a range of sectors, from the automotive to the process industries.

Careers and employability

We work with employers to ensure our degrees provide students with the skills and knowledge they need to succeed in the world of work. They also provide a range of work experience opportunities for undergraduates in areas such as civil engineering, manufacturing and business information technology.

Students also benefit from the services provided by the university’s Guidance and Employability Team, including ‘JobShop’, mentoring, volunteering and the student ambassador scheme.

Find out about the teaching and learning outcomes here - http://www2.gre.ac.uk/__data/assets/pdf_file/0011/643925/MSc-Mechanical-and-Manufacturing-Engineering.pdf

Find out how to apply here - http://www2.gre.ac.uk/study/apply

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This programme produces engineers who are highly skilled in the techniques of manufacturing management and its related technologies, providing the basis for effective careers as managers who can meet the challenges of the rapidly changing global manufacturing industry. Read more
This programme produces engineers who are highly skilled in the techniques of manufacturing management and its related technologies, providing the basis for effective careers as managers who can meet the challenges of the rapidly changing global manufacturing industry.

Core study areas include manufacturing system and process modelling, lean and agile manufacture engineering management and business studies, product information systems - product lifecycle management, the innovation process and project management, sustainable development, advanced manufacturing processes and automation, additive manufacturing and a project.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/mechanical-manufacturing/advanced-manuf-eng-mgt/

Programme modules

- Manufacturing System and Process Modelling
The objective of this module is to provide an understanding of manufacturing and its management that recognises breadth and depth of required resources and information. This is done through developing an understanding of the hierarchy of computer based modelling relevant to manufacturing, ranging from the detail of material behaviour in processed parts, through macroscopic process models to the integration of processes within manufacturing systems and higher level business processes.

- Lean and Agile Manufacture
This module allows students to gain an understanding of lean and agile concepts in the manufacturing business, including its distribution chains. Students will learn to specify, design and evaluate an appropriate lean or agile business system.

- Engineering Management and Business Studies
The aim of the module is to introduce the concepts of management techniques that are applicable to running an engineering company. Students will learn to evaluate commercial risk, plan and organise engineering activities for improved company effectiveness and communicate technical and business information to ensure maximum impact.

- Product Information Systems – Product Lifecycle Management
The objectives of this module are for students to understand and critically evaluate the emerging product information systems for designers in the form of Product Lifecycle Management (PLM) systems. Students will learn to use modern information and process modelling techniques to define the information integration and workflow requirements of a PLM configuration.

- The Innovation Process and Project Management
Students will establish a clear overview of the innovation process and an understanding of the essential elements within it. They will learn strategies for planning and carrying out innovative projects in any field.

- Sustainable Development: The Engineering Context
This module provides students with an understanding of the principles and practices of sustainable development and to provide them with an understanding of how engineers can help manufacturing businesses develop into more sustainable enterprises.

- Advanced Manufacturing Processes and Automation
Students will gain an in-depth knowledge of state-of-the-art manufacturing techniques, processes and technologies. They will learn to understand and critically evaluate advanced manufacturing processes and technologies, assessing their advantages and disadvantages.

- Additive Manufacturing
The module will introduce and develop the concepts of Additive Manufacturing (AM) and demonstrate the different AM techniques available at Loughborough University. The module will emphasise the strengths and weaknesses of the various technologies and highlight applications and case studies from the AM industry.

- Projects
In addition to the taught modules, all students undertake an individual major project. Part-time students normally undertake a major project that is based on the needs of their employing company.

How you will learn

You will learn through a carefully balanced combination of lectures, in-class guided workshops, hands-on computer modelling and independent research. Following eight taught modules, students pursue an individual project typically based on the diverse range of industrially focused manufacturing research strengths within the School. Part time students may base their projects on particular needs of their current employer.

Examinations are in January and May / June with coursework throughout the programme. The project is assessed by written report, presentation and exhibition.

Careers and further study

Within national or multinational manufacturing industry companies working as a Manufacturing Engineer, Project Engineer, Systems Analyst or Software Development Specialist. Graduates may also study for an MPhil or PhD with the School’s research groups.


The University offers over 100 scholarships each year to new self-financing full-time international students who are permanently resident in a country outside the European Union. These scholarships are to the value of 25% of the programme tuition fee and that value will be credited to the student’s tuition fee account.
You can apply for a scholarship once you have received an offer for a place on this programme.

Why Choose Mechanical and Manufacturing Engineering at Loughborough?

The School of Mechanical and Manufacturing Engineering is a leader in technological research and innovation, with extensive national and international industrial links, and a long standing tradition of excellent teaching.

Our Industrial Advisory Committee, comprising of engineers at senior levels in the profession, ensures that our programmes contain the optimal balance of subjects and industrial relevance, with our programmes accredited by the Institution of Mechanical Engineers, Institution of Engineering and Technology and Institution of Engineering Designers.

- Facilities
The School has laboratories devoted to disciplines such as; dynamics and control, automation, fluid mechanics, healthcare engineering, internal combustion engines, materials, mechatronics, metrology, optical engineering, additive manufacturing, sports engineering, structural integrity and thermodynamics.

- Research
The School has a busy, multi-national community of well over 150 postgraduate research students who form an important part of our internationally recognised research activities.
We have seven key research centres (Electronics Manufacture, Intelligent Automation, Regenerative Medicine Embedded Intelligence, High Efficiency SCR for Low Emission Vehicles and High Value Manufacturing Catapult Centre) and we are a lead governing partner in the newly formed UK Manufacturing Technology Centre.

- Career prospects
90% of our graduates were in employment or further study within six months of graduating. Our graduates go on to work with companies such as Airbus, BAE Systems, Caterpillar, EDF Energy, Ford, IBM, Jaguar Land Rover, Millbrook Proving Ground, Rolls Royce and Tata Steel.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/mechanical-manufacturing/advanced-manuf-eng-mgt/

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Enhance your career prospects with this Masters in Manufacturing Engineering at Liverpool John Moores University. This postgraduate course is accredited by IMechE, meets Chartered Engineer requirements and has close links with industry. Read more
Enhance your career prospects with this Masters in Manufacturing Engineering at Liverpool John Moores University. This postgraduate course is accredited by IMechE, meets Chartered Engineer requirements and has close links with industry.

•Complete this masters degree in one year full time
•Accredited by the Institution of Mechanical Engineers (IMechE) and meets Chartered Engineer requirements
•Study at one the UK’s leading Engineering Schools
•Programme informed by internationally-acclaimed research in LJMU’s General Engineering Research Institute
•Close industry links and excellent career prospects

The MSc programme will equip you with a range of skills and techniques appropriate for companies working in the field of advanced manufacturing and engineering.

These advanced skills will allow you to make an immediate contribution to a company's manufacturing capability and operation, and to ultimately progress into senior management positions.

The course is designed for graduates wishing to reach senior positions as engineers and technical managers in manufacturing process engineering, with particular emphasis on advanced manufacturing technologies and the application of advanced materials.

In addition, it covers quality engineering, logistics and management skills.

This programme builds on experience developed at undergraduate level and provides a progression route for graduates from relevant programmes in mechanical and manufacturing engineering.

Strong links with an Industry Advisory Committee, provide you with the opportunity to become part of local, national and international organisations and their networks.

Please see guidance below on core and option modules for further information on what you will study.

Level 7

Advanced Materials
Optical Measurement and Inspection
Manufacturing Process Engineering
Manufacturing Management
Research Skills
Project Management
Automation Systems
Supply Chain Modelling
MSc Project
Advanced Engineering Design
Operations Research
Safety and Reliability
Alternative Energy Systems
Modelling Matlab and Simulink
Programming for Engineering

Further guidance on modules

The information listed in the section entitled ‘What you will study’ is an overview of the academic content of the programme that will take the form of either core or option modules. Modules are designated as core or option in accordance with professional body requirements and internal Academic Framework review, so may be subject to change. Students will be required to undertake modules that the University designates as core and will have a choice of designated option modules. Additionally, option modules may be offered subject to meeting minimum student numbers.

Academic Framework reviews are conducted by LJMU from time to time to ensure that academic standards continue to be maintained. A review is currently in progress and will be operational for the academic year 2016/2017. Final details of this programme’s designated core and option modules will be made available on LJMU’s website as soon as possible and prior to formal enrolment for the academic year 2016/2017.

Please email if you require further guidance or clarification.

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This course aims to develop your skills and knowledge in areas such as automotive, aerospace, scientific and manufacturing applications. Read more

About this course

This course aims to develop your skills and knowledge in areas such as automotive, aerospace, scientific and manufacturing applications.

You'll specialise in mechanical and manufacturing engineering, together with broader engineering topics, to gain the knowledge needed for registration as a Chartered Engineer (CEng). This course is flexible, so you'll have lots of choice in the specialist subject modules you take and the ways you learn. You'll study some modules through lectures, tutorials and also online. There is time given to both independent study and group work and your assignment will give you valuable experience of teamwork.

Our close links with local companies such as Toyota, Balfour Beatty and Bombardier, as well as professional bodies, will help you stay up to date with current developments in industry. The overarching aim is to make sure you develop the skills employers are looking for.

You’ll study modules such as:

Research Methods: Application and Evaluation
Advanced Mechanical Modelling and E-manufacturing
Forensic Engineering, Failure Analysis and Prevention
CPD and Strategic Management
Advanced Mechanical Design and Manufacturing Engineering
Environmental Risk and Responsibility
Robotics and Manufacturing Control Systems
Negotiated Module
Independent Scholarship

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The Design and Manufacturing Engineering MSc develops your knowledge and skills in mechanical engineering as well as materials and manufacturing engineering. Read more
The Design and Manufacturing Engineering MSc develops your knowledge and skills in mechanical engineering as well as materials and manufacturing engineering. You have the opportunity to undertake in-depth studies through your research projects.

This one year course is intended for honours graduates (or an international equivalent) in mechanical or mechanical-related engineering, maths, physics or a related discipline, eg automotive, aeronautical or design.

A two year MSc is also available for non-native speakers of English that includes a Preliminary Year.

The taught part of the course consists of major engineering themes such as:
-Sustainable energy management
-Manufacturing materials and processes
-Engineering design
-Computational methods
-Engineering software

Your project is chosen from an extensive range of subjects. Project work can range from fundamental studies in areas of basic engineering science to practical design, make and test investigations.

Recent areas for project work include:
-Design and manufacture
-Thermo-fluid dynamics
-Composite materials
-Bioengineering and biomaterials
-Microelectronic-mechanical systems
-Mathematical and computational engineering modelling

Some research may be undertaken in collaboration with industry.

The course is delivered by the School of Mechanical and Systems Engineering. The School has an established programme of research seminars. These are delivered by guest speakers from academia and industry (both national and international), providing excellent insights into a wide variety of engineering research.

Effective communication is an important skill for the modern professional engineer. This course includes sessions to help develop your ability, both through formal guidance sessions dedicated to good practice in report writing, and through oral/poster presentations of project work.


The taught component of the course makes use of a combination of lectures, tutorials/labs and seminars. Assessment is by written examination and submitted in-course assignments.

The research project (worth 60 credits) is undertaken throughout the duration of the Masters course. Project work is assessed by dissertation and oral/poster presentations. You will be allocated, and meet regularly with, project supervisors.


The courses have been accredited by the Institution of Engineering and Technology (IET) under licence from the UK regulator, the Engineering Council.

Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC).

An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as a Chartered Engineer (CEng).

Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.


The School of Mechanical and Systems Engineering is based in the Stephenson Building. It has both general and specialist laboratories and workshop facilities. These are used for training, course delivery and the manufacture of materials/components needed to support project work.

The Stephenson Building houses one of the largest networked computer clusters on campus (120+ PCs), which supports all of the specialist software introduced and used within the course (eg CAD, stress analysis, fluid dynamics, signal processing packages) in addition to the School’s own cluster (60+ PCs) used for instrumentation and data acquisition laboratories.

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The outstanding calibre of our graduate-level programs, combined with our highly motivated and internationally recognized faculty makes studying mechanical and manufacturing engineering a rewarding and valuable experience. Read more
The outstanding calibre of our graduate-level programs, combined with our highly motivated and internationally recognized faculty makes studying mechanical and manufacturing engineering a rewarding and valuable experience. As a graduate student in mechanical engineering you will have the opportunity to conduct innovative and cutting-edge research.

The high-quality research that is conducted in the Department of Mechanical and Manufacturing Engineering is internationally acknowledged through publications in high-impact journals, prestigious graduate scholarships and media attention. Graduates of the our programs go on to be future industrial and academic leaders.

Our department is home to 33 faculty members, 6 research chairs, 200 graduate students and 500 undergraduates.

What degree programs are offered?

Master of Science
The MSc is a research-based degree that usually takes two years of full-time study beyond the bachelor's degree.

Master of Engineering (course based)
The MEng program is most often taken on a part-time basis and usually takes four to six years of part-time study beyond a bachelor's degree. The MEng program does not provide financial support.

The MEng program is intended for domestic students. International students are admitted into the MSc program where they are eligible for funding.

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This course is for engineers specialising in manufacturing who want to become technical specialists or managers in industrial and manufacturing companies. Read more
This course is for engineers specialising in manufacturing who want to become technical specialists or managers in industrial and manufacturing companies. It enables you to develop both your technical and problem solving skills. Equipped with new ideas, experience and understanding, you can enhance manufacturing effectiveness in a wide range of industries.

It increases your career potential by improving your
• knowledge and experience of manufacturing engineering
• management skills
• ability to take on greater responsibility

You study
• two management modules
• five technical modules
• one optional module

Option modules include computer-aided design/computer-aided manufacture, competitive materials technology and advanced metallic materials.

You complete a masters project with our Centre for Automation and Robotics Research.

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OVERVIEW. In an ever-demanding world market place the need to be competitive in manufacturing is essential. Businesses are reorganizing themselves in response to the challenges and demands of the 21st century and must be flexible and responsive to the changing market requirements. Read more

In an ever-demanding world market place the need to be competitive in manufacturing is essential. Businesses are reorganizing themselves in response to the challenges and demands of the 21st century and must be flexible and responsive to the changing market requirements. Manufacturing companies must produce high quality, cost-effective product in quick response time to customer demand. In order to do this, successful manufacturing companies must embrace the skill and expertise of engineering, business and management.

This course aims to develop manufacturing engineers who will be able to apply technology, business and management skills to respond to the demands of the industry.


Students who enjoy solving problems, making improvements and working with people should apply.

Graduates of the MSc in Manufacturing Engineering have successful progressive careers in the manufacturing industry.

You will have access to the expertise within the Future Manufacturing Applied Research Centre.


On this course you will develop the skills necessary to design and develop lean and competitive manufacturing facilities as well as apply continuous improvement techniques to identify waste. You will learn to identify opportunities for the application of new materials and processes and evaluate appropriate production control system. You will develop the skills to assess manufacturing issues with regards to strategic and financial implications as well as work effectively in a team environment.

The course has the following modules:

Masters project;
research methods for manufacturing;
advanced engineering materials and processes;
automation and robotics;
lean operations;
production planning and scheduling;
advanced manufacturing simulation systems;
project management;
global engineering strategy;
management of quality (option moudle);
manufacturing quality and metrology (option module).

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See the Department website - http://www.rit.edu/kgcoe/program/microelectronic-engineering-1. Read more
See the Department website - http://www.rit.edu/kgcoe/program/microelectronic-engineering-1

The master of engineering in microelectronics manufacturing engineering provides a broad-based education for students who are interested in a career in the semiconductor industry and hold a bachelor’s degree in traditional engineering or other science disciplines.

Program outcomes

After completing the program, students will be able to:

- Design and understand a sequence of processing steps to fabricate a solid state device to meet a set of geometric, electrical, and/or processing parameters.

- Analyze experimental electrical data from a solid state device to extract performance parameters for comparison to modeling parameters used in the device design.

- Understand current lithographic materials, processes, and systems to meet imaging and/or device patterning requirements.

- Understand the relevance of a process or device, either proposed or existing, to current manufacturing practices.

- Perform in a microelectronic engineering environment, as evidenced by an internship.

- Appreciate the areas of specialty in the field of microelectronics, such as device engineering, circuit design, lithography, materials and processes, and yield and manufacturing.

Plan of study

This 30 credit hour program is awarded upon the successful completion of six core courses, two elective courses, a research methods course, and an internship. Under certain circumstances, a student may be required to complete bridge courses totaling more than the minimum number of credits. Students complete courses in microelectronics, microlithography, and manufacturing.


The microelectronics courses cover major aspects of integrated circuit manufacturing technology, such as oxidation, diffusion, ion implantation, chemical vapor deposition, metalization, plasma etching, etc. These courses emphasize modeling and simulation techniques as well as hands-on laboratory verification of these processes. Students use special software tools for these processes. In the laboratory, students design and fabricate silicon MOS integrated circuits, learn how to utilize semiconductor processing equipment, develop and create a process, and manufacture and test their own integrated circuits.


The microlithography courses are advanced courses in the chemistry, physics, and processing involved in microlithography. Optical lithography will be studied through diffraction, Fourier, and image-assessment techniques. Scalar diffraction models will be utilized to simulate aerial image formation and influences of imaging parameters. Positive and negative resist systems as well as processes for IC application will be studied. Advanced topics will include chemically amplified resists; multiple-layer resist systems; phase-shift masks; and electron beam, X-ray, and deep UV lithography. Laboratory exercises include projection-system design, resist-materials characterization, process optimization, and electron-beam lithography.


The manufacturing courses include topics such as scheduling, work-in-progress tracking, costing, inventory control, capital budgeting, productivity measures, and personnel management. Concepts of quality and statistical process control are introduced. The laboratory for this course is a student-run factory functioning within the department. Important issues such as measurement of yield, defect density, wafer mapping, control charts, and other manufacturing measurement tools are examined in lectures and through laboratory work. Computer-integrated manufacturing also is studied in detail. Process modeling, simulation, direct control, computer networking, database systems, linking application programs, facility monitoring, expert systems applications for diagnosis and training, and robotics are supported by laboratory experiences in the integrated circuit factory. The program is also offered online for engineers employed in the semiconductor industry.


The program requires students to complete an internship. This requirement provides a structured and supervised work experience that enables students to gain job-related skills that assist them in achieving their desired career goals.

Students with prior engineering-related job experience may submit a request for internship waiver with the program director. A letter from the appropriate authority substantiating the student’s job responsibility, duration, and performance quality would be required.

For students who are not working in the semiconductor industry while enrolled in this program, the internship may be completed at RIT. It involves an investigation or study of a subject or process directly related to microelectronic engineering under the supervision of a faculty adviser. An internship may be taken any time after the completion of the first semester, and may be designed in a number of ways. At the conclusion of the internship, submission of a final internship report to the faculty adviser and program director is required.

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A manufacturing engineer produces high quality goods using the most cost effective methods while being conscious of any environmental impacts. Read more
A manufacturing engineer produces high quality goods using the most cost effective methods while being conscious of any environmental impacts. They need to be both analytical and creative, be able to work on their own intiative but also as part of a multi-displinary team. This course demonstrates how advanced manufacturing technology and operations management are integrated to improve productivity, reduce the costs of manufacture, and the delivery of products and services can be ensured.

The course covers many aspects of Industrial Engineering and Industrial Management. The wide range of optional modules will enable you to develop your interests in specific areas of technology including flexible manufacturing, rapid product development, and process capability, operations management including quality and supply chain management and also ergonomics and human factors.

Students will develop: the ability to communicate ideas effectively in written reports, verbally and by means of presentations to groups knowledge and understanding of industrial methods and the needs of manufacturing industries the ability to plan and undertake an individual project interpersonal, communication and professional skills.

Previous projects have included:
Evaluation of micromachining systems
Design for microassembly
Laser deposition in manufacturing
Lean applications in a local aeroengine manufacturer
Production of AI/TiC metal matrix composites
Electrical Discharge Machining Study of a machining allow for Aerospace Applications
Design of an innovative holding device for enabling the walking of a free-leg hexapod

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This course is for practising engineers or new graduates who want to become technical specialists developing engineering solutions for the food and drink industry. Read more
This course is for practising engineers or new graduates who want to become technical specialists developing engineering solutions for the food and drink industry. It is suited to graduates with a mechanical, electrical, food science or technology background.

Through a combination of management, food, and technical modules, you focus on areas of need identified by industry. These include:
-Lean and supply chain.
-Food processing.
-Environmental management.
-Automation, control and robotics.
-Process efficiency.
-Food quality and safety.
-Manufacturing and process improvement.
-Packaging and maintenance.

You gain experience of designing experiments and testing food engineering systems in our specialist engineering and food laboratories. By applying your technical knowledge to practical challenges faced by industry, you build the skills to develop innovative solutions to problems. You also learn how these techniques can improve product quality and reduce environmental impact while maintaining industrial competitiveness.

During the course you attend guest lectures from industry experts, and work on real life case studies and projects. You also experience advanced level research by taking part in real life studies. This means your learning is based in the real world of industry and increases your employability when you graduate.

During the course you complete a consultancy project. Recent masters level projects have covered topics such as:
-The use of robotics to automatically peel a grape
-Voice controlled automation for the packaging of food products
-Innovative machine vision techniques to determine the condition of fruit

Students have also completed projects spanning areas of food engineering such as:
-Innovative packaging design.
-Sustainable processing.
-The modelling of complex fluid flows.
-The reclamation of energy using innovative heat exchangers.

The course is supported by our new National Centre of Excellence for Food Engineering, which has been developed with the food and drink industry and is guided by a board of industry members.

Professional recognition

This course is delivered by Sheffield Hallam University working in partnership with the National Skills Academy for Food and Drink and the Food and Drink Federation.

Course structure

Full time – 1 year.
Part time – 2 years study plus a work-based project.
Starts September and January.

Core modules
-Sustainability, energy and environmental management
-Lean operations and six sigma
-Contemporary issues in food operation
-Food processing, safety and quality management
-Industrial automation
-Manufacturing systems
-Processing and packaging machinery
-Consultancy project and dissertation
This module combines the various technical and managerial strands of the course into a major piece of research with an element of originality. This involves working with the Centre for Food Engineering and its industrial partners on projects relating to key sector challenges. The project typically takes approximately 600 hours to complete and deepens the knowledge gained in the taught components of the course.

Optional modules
You choose one from: advanced control methods; equipment engineering and design; rheology and multi-phase flow.

Assessment: coursework, group project, examinations, dissertation.

Other course requirements

Overseas students
-India – a first class BE in an relevant discipline or a good second class BE with a strong performance in core engineering subjects.
-China – a four year Bachelor degree in a relevant discipline with an overall average of at least 80 per cent or equivalent.
-Other countries – a good honours degree or equivalent in a relevant subject.
Applicants from countries whose first language is not English must normally produce evidence of competence in English. An IELTS score of 6.0 with 5.5 in all skills is the standard for non-native speakers of English. If your English language skill is currently below the required level we recommend you consider a Sheffield Hallam University Pre-sessional English course which will enable you to achieve an equivalent English level.

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The Advanced Design & Manufacturing Institute (ADMI) MEng is offered by Queen’s University and Western University, and is designed for working engineering graduates. Read more
The Advanced Design & Manufacturing Institute (ADMI) MEng is offered by Queen’s University and Western University, and is designed for working engineering graduates. The program is delivered in class, part-time, and on weekends. You can choose to complete the program in as little as two years. This exciting program is designed to give practicing engineers the technical knowledge and business and management skills necessary for them to advance to the forefront of their profession.

Visit the website: http://grad.uwo.ca/prospective_students/programs/program_NEW.cfm?p=3

How to apply

For information on how to apply, please see: http://grad.uwo.ca/prospective_students/applying/index.html

Financing your studies

As one of Canada's leading research institutions, we place great importance on helping you finance your education. It is crucial that you devote your full energy to the successful completion of your studies, so we want to ensure that stable funding is available to you.
For information please see: http://grad.uwo.ca/current_students/student_finances/index.html

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Surrey were the pioneers of sophisticated ‘micro-satellites’ in the 1980s. Read more
Surrey were the pioneers of sophisticated ‘micro-satellites’ in the 1980s.

Since then, our sustained programme of building complete satellites, performing mission planning, working with international launch agencies and providing in-orbit operations has kept us at the forefront of the space revolution –utilising new advances in technology to decrease the cost of space exploration.


Our Masters in Space Engineering programme is designed to give you the specialist multidisciplinary knowledge and skills required for a career working with space technology and its applications.

Surrey students have access to all aspects of the design and delivery of spacecraft and payloads, and as a result are very attractive to employers in space-related industries.

As we develop and execute complete space missions, from initial concept to hardware design, manufacturing and testing, to in orbit operations (controlled by our ground station at the Surrey Space Centre), you will have the chance to be involved in, and gain experience of, real space missions.


This programme is studied full-time over one academic year and part-time students must study at least two taught technical modules per academic year. It consists of eight taught modules and a project. The following modules are indicative, reflecting the information available at the time of publication. Please note that not all modules described are compulsory and may be subject to teaching availability and/or student demand.
-Space Dynamics and Missions
-Space Systems Design
-Space Robotics and Autonomy
-Satellite Remote Sensing
-RF Systems and Circuit Design
-Space Avionics
-Advanced Guidance, Navigation and Control
-Launch Vehicles and Propulsion
-Advanced Satellite Communication Techniques
-Spacecraft Structures and Mechanisms
-Space Environment and Protection
-Standard Project


Our philosophy is to integrate the acquisition of core engineering and scientific knowledge with the development of key practical skills (where relevant). To fulfil these objectives, the programme aims to:
-Attract well-qualified entrants, with a background in Electronic Engineering, Physical Sciences, Mathematics, Computing & Communications, from the UK, Europe and overseas
-Provide participants with advanced knowledge, practical skills and understanding applicable to the MSc degree
-Develop participants' understanding of the underlying science, engineering, and technology, and enhance their ability to relate this to industrial practice
-Develop participants' critical and analytical powers so that they can effectively plan and execute individual research/design/development projects
-Provide a high level of flexibility in programme pattern and exit point
-Provide students with an extensive choice of taught modules, in subjects for which the Department has an international and UK research reputation

Intended capabilities for MSc graduates:
-Underpinning learning– know, understand and be able to apply the fundamental mathematical, scientific and engineering facts and principles that underpin space engineering.
-Engineering problem solving - be able to analyse problems within the field of mobile and satellite communications and more broadly in electronic engineering and find solutions
-Engineering tools - be able to use relevant workshop and laboratory tools and equipment, and have experience of using relevant task-specific software packages to perform engineering tasks
-Technical expertise - know, understand and be able to use the basic mathematical, scientific and engineering facts and principles associated with the topics within space engineering.
-Societal and environmental context - be aware of the societal and environmental context of his/her engineering activities
-Employment context - be aware of commercial, industrial and employment-related practices and issues likely to affect his/her engineering activities
-Research & development investigations - be able to carry out research-and- development investigations
-Design - where relevant, be able to design electronic circuits and electronic/software products and systems


The programme provides opportunities for students to develop and demonstrate knowledge and understanding, skills, qualities and other attributes in the following areas:

General transferable skills
-Be able to use computers and basic IT tools effectively
-Be able to retrieve information from written and electronic sources
-Be able to apply critical but constructive thinking to received information
-Be able to study and learn effectively
-Be able to communicate effectively in writing and by oral presentations
-Be able to present quantitative data effectively, using appropriate methods
-Be able to manage own time and resources
-Be able to develop, monitor and update a plan, in the light of changing circumstances
-Be able to reflect on own learning and performance, and plan its development/improvement, as a foundation for life-long learning

Underpinning learning
-Know and understand scientific principles necessary to underpin their education in electronic and electrical engineering, to enable appreciation of its scientific and engineering content, and to support their understanding of historical, current and future developments
-Know and understand the mathematical principles necessary to underpin their education in electronic and electrical engineering and to enable them to apply mathematical methods, tools and notations proficiently in the analysis and solution of engineering problems
-Be able to apply and integrate knowledge and understanding of other engineering disciplines to support study of electronic and electrical engineering.

Engineering problem-solving
-Understand electronic and electrical engineering principles and be able to apply them to analyse key engineering processes
-Be able to identify, classify and describe the performance of systems and components through the use of analytical methods and modelling techniques
-Be able to apply mathematical and computer-based models to solve problems in electronic and electrical engineering, and be able to assess the limitations of particular cases
-Be able to apply quantitative methods relevant to electronic and electrical engineering, in order to solve engineering problems
-Understand and be able to apply a systems approach to electronic and electrical engineering problems

Engineering tools
-Have relevant workshop and laboratory skills
-Be able to write simple computer programs, be aware of the nature of microprocessor programming, and be aware of the nature of software design
-Be able to apply computer software packages relevant to electronic and electrical engineering, in order to solve engineering problems

Technical expertise
-Know and understand the facts, concepts, conventions, principles, mathematics and applications of the range of electronic and electrical engineering topics he/she has chosen to study
-Know the characteristics of particular materials, equipment, processes or products
-Have thorough understanding of current practice and limitations, and some appreciation of likely future developments
-Be aware of developing technologies related to electronic and electrical engineering
-Have comprehensive understanding of the scientific principles of electronic engineering and related disciplines
-Have comprehensive knowledge and understanding of mathematical and computer models relevant to electronic and electrical engineering, and an appreciation of their limitations
-Know and understand, at Master's level, the facts, concepts, conventions, principles, mathematics and applications of a range of engineering topics that he/she has chosen to study
-Have extensive knowledge of a wide range of engineering materials and components
-Understand concepts from a range of areas including some from outside engineering, and be able to apply them effectively in engineering projects

Societal and environmental context
-Understand the requirement for engineering activities to promote sustainable development
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk issues
-Understand the need for a high level of professional and ethical conduct in engineering

Employment context
-Know and understand the commercial and economic context of electronic and electrical engineering processes
-Understand the contexts in which engineering knowledge can be applied (e.g. operations and management, technology development, etc.)
-Be aware of the nature of intellectual property
-Understand appropriate codes of practice and industry standards
-Be aware of quality issues
-Be able to apply engineering techniques taking account of a range of commercial and industrial constraints
-Understand the basics of financial accounting procedures relevant to engineering project work
-Be able to make general evaluations of commercial risks through some understanding of the basis of such risks
-Be aware of the framework of relevant legal requirements governing engineering activities, including personnel, health, safety and risk (including environmental risk) issues

Research and development
-Understand the use of technical literature and other information sources
-Be aware of the need, in appropriate cases, for experimentation during scientific investigations and during engineering development
-Be able to use fundamental knowledge to investigate new and emerging technologies
-Be able to extract data pertinent to an unfamiliar problem, and employ this data in solving the problem, using computer-based engineering tools when appropriate
-Be able to work with technical uncertainty

-Understand the nature of the engineering design process
-Investigate and define a problem and identify constraints, including environmental and sustainability limitations, and health and safety and risk assessment issues
-Understand customer and user needs and the importance of considerations such as aesthetics
-Identify and manage cost drivers
-Use creativity to establish innovative solutions
-Ensure fitness for purpose and all aspects of the problem including production, operation, maintenance and disposal
-Manage the design process and evaluate outcomes
-Have wide knowledge and comprehensive understanding of design processes and methodologies and be able to apply and adapt them in unfamiliar situations
-Be able to generate an innovative design for products, systems, components or processes, to fulfil new needs

Project management
-Be able to work as a member of a team
-Be able to exercise leadership in a team
-Be able to work in a multidisciplinary environment
-Know about management techniques that may be used to achieve engineering objectives within the commercial and economic context of engineering processes
-Have extensive knowledge and understanding of management and business practices, and their limitations, and how these may be applied appropriately


We often give our students the opportunity to acquire international experience during their degrees by taking advantage of our exchange agreements with overseas universities.

In addition to the hugely enjoyable and satisfying experience, time spent abroad adds a distinctive element to your CV.

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