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Masters Degrees (Mechatronic Engineering)

We have 33 Masters Degrees (Mechatronic Engineering)

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Areas of research include, but are not limited to. evaluation of spacial heterogeneity for the design and layout of experimental sites. Read more
Areas of research include, but are not limited to: evaluation of spacial heterogeneity for the design and layout of experimental sites.
The course

This course builds on the Engineering Department’s long history of working closely with industry teaching students how to apply engineering science to industrial product design. Mechatronics is a multi-disciplinary field of engineering that combines with mechanical, electronic, computer, software, control and systems design engineering in the design and manufacture of useful products. It is an increasingly important discipline as most modern vehicles and machinery incorporate multiple mechatronic systems.

Some of the technologies that mechatronics encompasses include: robotics, vision systems, satellite navigation systems, communications technology, and biometric and other new advanced sensors. Introduction of these new technologies means that engineers cannot rely upon prior knowledge when designing machinery. As a consequence it has become normal practice for new highly technical equipment to be developed by specialist manufacturers, either through subcontract subsystem devolution or commercial partnership.

When developing new products, much of the work of the engineer involves the recombination or reapplication of previously un-combined technologies to solve new problems or enable new functionalities. Engineers therefore need to develop the greatest possible body of knowledge as a resource to call upon during the resolution of novel challenges in new or different environments.

This postgraduate programme builds upon students’ existing engineering skills and knowledge developed through prior education and focuses them into a more specific and applied area of study. This approach is designed to allow students to expand their applied knowledge and develop the necessary powers of analysis required to solve complex design problems. Learning largely takes place through a series of individual and group engineering projects intended to enable students to apply their existing academic skills and knowledge to the design, fabrication and testing of new products or systems. Where applicable, projects will be sponsored and supported by engineering companies and will focus on the development of mechatronic systems, machinery and equipment.

How will it benefit me?

This programme is designed for students with a strong academic background but limited industrial experience. It is intended to expedite the experiential development of these engineers through a series of industrially linked projects. Students will complete the course with a view to taking leading positions in manufacturing companies designing innovative machinery and equipment by employing new and emerging technologies to develop mechatronic systems, machinery and solutions.

Careers

This course provides an understanding of the practical application of engineering science and mathematics to the development of mechatronic systems. It is designed to aid students with good engineering qualifications, but limited applied industrial experience, learn the skills to take leading positions in manufacturing companies designing innovative machinery and equipment by employing new and emerging technologies to develop mechatronic systems, machinery and solutions.

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This MSc in Advanced Engineering Design is aimed at high calibre and ambitious engineering graduates who want to gain expertise in systematically developing complex, multidisciplinary engineering design. Read more

About the course

This MSc in Advanced Engineering Design is aimed at high calibre and ambitious engineering graduates who want to gain expertise in systematically developing complex, multidisciplinary engineering design.

You will learn how to design products requiring embedded intelligence and comprehensive engineering analysis and how to use six CAE software packages.

The programme - accredited by the Institution of Mechanical Engineering (IMechE) - has been developed to fulfil the industry’s need for an integrated course that offers:
teaching of advanced theory, human factors and creativity tools essential to successful product development
training in software, research and applications
practical experience of applying your knowledge and skills through an integrating, real life group project.

Aims

Integration of mechanical, electrical, electronic and control knowledge into a single product is challenging – and this course allows you to appreciate the complexity of modern product design and to develop your expertise.

The Brunel programme aims to create the new generation of engineering designers who can combine knowledge from different areas and produce world class design.

Engineering design is the application of engineering principles, the experience of making, and use of mathematical models and analysis. The design and production of complex engineering products often require the use of embedded intelligence and detailed engineering analysis involving mechanical, electronic and control functions. Advanced theoretical knowledge and a wide range of computer driven tools, methods and methodologies are essential for this process – and the course provides graduates with these essentials.

Course Content

Continued design of modern complex products demands advanced knowledge in mechanical, electronic, manufacturing and control engineering disciplines and human factors in design, and an ability to use advanced engineering software packages, integrating application experience and a capacity to carry on learning.

The Advanced Engineering Design MSc has been developed to produce design engineers who can meet these demands. It contains six taught modules where advanced multi-disciplinary theory is taught. As part of the course, six engineering software packages are also taught. In order to give an integrating application experience in an industrial setup, 'Design Experience', a group project module with an industry, has been included as part of the curriculum.

The dissertation is aimed at providing training in carrying out an in-depth engineering task on a self-learning basis. By the end of the course you will become a confident design engineer equipped with high quality and advanced knowledge and skills to work on design tasks in an advanced computer assisted environment.

Compulsory Modules

Sustainable Design and Manufacture
Manufacturing Systems Design and Economics
Computer Aided Engineering 1
Computer Aided Engineering 2
Design Experience
Dissertation Project

Optional Modules (choose two modules)

Advanced Manufacturing Measurement
Human Factors in Design
Robotics and Manufacturing Automation
Design of Mechatronic Systems

Special Features

Special facilities

MSc Engineering Design students work in a well-equipped design studio with various experiential learning facilities, with computers available for your exclusive use of Engineering Design students.Our investment in laboratory facilities and staff ensures that we can provide an excellent experience in a friendly and supportive environment.

Industry-focused programme

The high standard of our research feeds directly into curriculum design and our teaching, ensuring our graduates are equipped with the most up-to-date techniques, methods and knowledge bases. Our teaching has an excellent reputation and is orientated to the expressed needs of modern enterprises and the industry.
The course is underpinned by the current research still being carried out by the staff in the former academic unit Advanced Manufacturing and Enterprise Engineering which promotes manufacturing as a discipline.  Thus the academics teaching on the Advanced Engineering Design which were part of this unit have strong research portfolios in manufacturing. This research has been judged world leading.  In the 2014 Research Excellence Framework, academics teaching on the course were involved with Brunel’s General engineering submission, one of one of the largest in the UK. The area’s percentage of world leading research doubled, with a significant increase in our research judged as internationally excellent as well. The impact of over 75% of this research was judged to be world leading or internationally excellent. This placed the discipline in the top 20% in the UK terms of research power.

Global reputation

With around 150 postgraduate students from all around the world and substantial research income from the EU, research councils and industry, we are a major player in the field of advanced manufacturing and enterprise engineering.
 
Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

The MSc Advanced Engineering Design is accredited by both the Institution of Mechanical Engineering (IMechE). This will provide a route to Chartered Engineer status in the UK.

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The MSc in Mechatronics is an integration of Electrical and Mechanical Engineering. It has been specifically designed to fulfil the needs of modern industry requiring knowledge in both fields and incorporates a significant input from industry to complement its academic foundations. Read more
The MSc in Mechatronics is an integration of Electrical and Mechanical Engineering. It has been specifically designed to fulfil the needs of modern industry requiring knowledge in both fields and incorporates a significant input from industry to complement its academic foundations.

The course specialises in enabling students to produce mechatronic components which increase performance and energy efficiency, as sought after by industries worldwide.

It will not only help prepare you for an exciting career in the industry, but it will also help prepare you to continue your studies onto a Doctor of Philosophy research programme.

Many distinction-level graduates from this programme stay on for a PhD, often funded in part by the University of Bath.

Learning outcomes

By studying for our MSc in Mechatronics you will learn to:

- implement the concepts of mechatronics design principles to the solution of complex multi-physics engineering systems
- apply artificial intelligence and modern control and computer engineering techniques to improve the performance of modern equipments and devices

Visit the website http://www.bath.ac.uk/engineering/graduate-school/taught-programmes/mechatronics/index.html

Collaborative working

The programme includes traditionally taught subject-specific units and business and group-orientated modular work. These offer you the chance to gain experience in design, project management and creativity, while working with students from other subjects.

You will complete your MSc through an individual research project under the supervision of two supervisors; one from the Department of Electronic & Electrical Engineering (http://www.bath.ac.uk/elec-eng/) and one from Mechanical Engineering (http://www.bath.ac.uk/mech-eng/), assigned to one of our leading research centres (http://www.bath.ac.uk/engineering/research/index.html).

- Group project work
In semester 2 you undertake a cross-disciplinary group activity for your professional development, simulating a typical industrial work situation.

- Individual project work
In the final semester, you undertake an individual research project directly related to key current research at the University, often commissioned by industry.

Structure

See programme catalogue (http://www.bath.ac.uk/catalogues/2015-2016/me/me-proglist-pg.html#H) for more detail on individual units.

Semester 1 (October-January):
The first semester covers the fundamental principles of computational artificial intelligence, integrated engineering control techniques and mechatronic systems modelling and simulation.

- Five taught units
- Includes coursework involving laboratory or small project sessions
- Typically each unit consists of 22 hours of lectures, may involve a number of hours of tutorials/exercises and laboratory activity and approximately 70 hours of private study (report writing, laboratory results processing and revision for examinations)

Further advanced options will give you an in depth knowledge of how electrical and mechanical engineering can be integrated to effect state of the art technologies.

Semester 2 (February-May):
In Semester 2 you will study both technical specialist units and project-based units. You will develop your professional understanding of engineering in a research and design context. You will gain analytical and team working skills to enable you to deal with the open-ended tasks that typically arise in practice in present-day engineering.

- The semester aims to develop your professional understanding of engineering in a business environment and is taught by academic staff with extensive experience in industry
- Group projects in which students work in a multi-disciplinary team to solve a conceptual structural engineering design problem, just as an industrial design team would operate
- Individual project preliminary work and engineering project management units

Summer/Dissertation Period (June-September):
- Individual project leading to MSc dissertation, done under the supervision of two supervisors, one from the Department of Electronic & Electrical Engineering and one from Mechanical Engineering

- Depending on the chosen area of interest, the individual project may involve theoretical and/or experimental activities; for both such activities students can use the department computer suites and well-equipped and newly refurbished laboratories for experimental work. The individual projects are generally carried out under the supervision of a member of academic staff. A number of industrially-based projects are available to students

- Examples of typical projects include the design and control of autonomous robots; undersea tidal wave power generators; and the design and control of high speed mechanisms.

Subjects covered

- Computational intelligence
- Control engineering
- Engineering systems simulation
- Power systems control
- Professional skills for engineering practice
- Signals & information

Career Options

Graduates with knowledge and training in both electrical and mechanical engineering are very much in demand in aerospace, automotive and manufacturing industries.

More and more of the hydraulic and mechanical aspects of these industries are being replaced by mechatronics components to reduce weight and increase performance and energy efficiency.

The career opportunities in the UK and worldwide are very significant. Jobs our recent graduates have secured include:

Product Research Development Engineer, KTP Associate, University of Bath, UK
Project Manager, Guandong Best Control Technology, PR China
Software Engineer, DIAGNOS, UK
Engineer, MAN Diesel & Turbo, USA

About the department

Bath has a strong tradition of achievement in mechanical engineering research and education.

We are proud of our research record: 89% of our research was graded as either world-leading or internationally excellent in the Research Excellence Framework 2014, placing us 10th in the UK for our submission to the Aeronautical, Mechanical, Chemical and Manufacturing Engineering.

We offer taught MSc students the chance to carry out projects within outstanding research groupings.

Our research impact is wide and we are dedicated to working with industry to find innovative solutions to problems that affect all areas of society.

We are consistently ranked among the UK’s top 10 mechanical engineering departments in the annual league tables.

We believe in producing leaders, not just engineers.

We will give you the edge over your competitors by teaching you how technology fits into commercial settings. You will not only have access to cutting edge science and technology, we will also provide you with the skills you need to manage a workforce in demanding business environments.

For further information visit our departmental website (http://www.bath.ac.uk/mech-eng/pgt/).

Find out how to apply here - http://www.bath.ac.uk/study/pg/apply/

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The two MSc programmes in Biomedical Engineering draw on the wide experience of academic staff at Brunel's College of Engineering, Design and Physical Sciences, that ranges from the development of equipment and experiments for use in space, to research carried out in collaboration with hospitals, biomedical companies and research institutions. Read more

About the course

The two MSc programmes in Biomedical Engineering draw on the wide experience of academic staff at Brunel's College of Engineering, Design and Physical Sciences, that ranges from the development of equipment and experiments for use in space, to research carried out in collaboration with hospitals, biomedical companies and research institutions.

The programmes consist of four compulsory taught modules and two optional streams. You can apply to one of the two named degree title awards:

Biomedical, Genetics and Tissue Engineering or
Biomedical, Biomechanics and Bioelectronics Engineering

As well as giving a solid scientific understanding, the course also addresses commercial, ehtical, legal and regulatory requirements, aided by extensive research.

Students who successfully complete the course will have acquired skills that are essential to the modern biomedical and healthcare industry, together with the expertise required to enter into management, product innovation, development and research

Aims

Understanding how the human body works isn’t just required learning for sports coaches, specialists in biomedical engineering can help in the design, development and operation of complex medical devices. They are used in the prevention, diagnosis and treatment, to the characterisation of tissue.

This programme has a strong research and development emphasis. It aims to provide an overall knowledge base, skills and competencies, which are required in biomedical engineering, research activities and in related fields. Students will develop expertise in advanced product development and research.

Course Content

The MSc programmes in Biomedical Engineering are full-time courses, lasting one academic year of 12 consecutive months, from September to September.

The programmes consist of four core (compulsory) taught modules and two optional streams. The Biomedical, Genetics and Tissue Engineering stream has three optional modules. The second stream, Biomedical, Biomechanics and Bioelectrionics Engineering, consists of five optional modules. Students choosing this latter option will be requires to choose 60 credit worth of modules. See below.

The taught modules are delivered to students over two terms; Term 1 (September – December) and Term 2 (January – April) of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

Compulsory Modules:

Compulsory Modules
Biomechanics and Biomaterials
Biomedical Engineering Principles
Design and Manufacture
Innovation and Management and Research Methods
Dissertation

Optional Modules:

Optional Modules
Applied Sensors Instrumentation and Control
Artificial Organs
Biofluid Mechanics
Biomedical Imaging
Design of Mechatronic Systems
Group Project

Special Features

Industry relevance
Scientific understanding is just one part of medical engineering – and the course addresses commercial, ethical, legal and regulatory requirements, with input from Brunel’s extensive industrial contacts.

Excellent facilities
We have extensive and well-equipped laboratories – with notable strength in fluid and biofluid mechanics, IC engines, vibrations, building service engineering, and structural testing. Our computing facilities are diverse and are readily available to all students. The University is fully networked with both Sun workstations and PCs. Advanced software is available for finite and boundary element modelling of structures, finite volume modelling of flows, and for the simulation of varied control systems, flow machines, combustion
engines, suspensions, built environment, and other systems of interest to the research groups.

Foundation course at Brunel
The Pre-Masters is a full-time 14-week course for international students who have marginally fallen below the postgraduate direct entry level and would like to progress onto a Master's degree course in the College of Engineering, Design and Physical Sciences. It combines academic study, intensive English language preparation, study skills and an orientation programme.

Women in Engineering and Computing Programme

Brunel’s Women in Engineering and Computing mentoring scheme provides our female students with invaluable help and support from their industry mentors.

Accreditation

This programme is seeking accreditation by the Institution of Mechanical Engineers (IMechE) post the recent change in available degree routes. The IMechE formerly accredited the MSc Biomedical Engineering and we anticipate no problems in extending this accreditation to the new routes.

Teaching

The taught modules are delivered to students over two terms; Term 1 (September – December) and Term 2 (January – April) of each academic year. The taught modules are examined at the end of each term, and the students begin working on their dissertations on a part-time basis in term 2, then full-time during the months of May to September.

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WHAT YOU WILL GAIN. - Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation
- Practical guidance and feedback from industrial automation experts from around the world
- Live knowledge from the extensive experience of expert instructors
- Credibility and respect as the local industrial automation expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Industrial Automation)** qualification

Next intake is scheduled for June 27, 2016. Applications now open; places are limited.

Now also available on Campus.

INTRODUCTION

The respected International Society of Automation (ISA) estimated that at least 15,000 new automation engineers are needed annually in the US alone. Many industrial automation businesses throughout the world comment on the difficulty in finding experienced automation engineers despite paying outstanding salaries.

The Master of Engineering (Industrial Automation) perfectly addresses this gap in the Industrial Automation industry. The program's twelve core units, and project thesis, provide you with the practical knowledge and skills required. Students with a background in electrical, mechanical, instrumentation and control, or industrial computer systems engineering can benefit from this program.

The content has been carefully designed to provide you with relevant concepts and the tools required in today’s fast-moving work environment. For example, Power Engineering covers major equipment and technologies used in power systems, including power generation, transmission and distribution networks. Programmable Logic Controllers covers in-depth principles of operation of programmable controllers, networking, distributed controllers, and program control strategies. Industrial Process Control Systems combines the process identification and feedback control design with a broad understanding of the hardware, system architectures and software techniques widely used to evaluate and implement complex control solutions. Industrial Instrumentation identifies key features of widely used measurement techniques and transducers combined with microprocessor devices to create robust and reliable industrial instruments. Process Engineering will enable students to evaluate and apply complex process calculations through application of control principles. Industrial Data Communications provides the requisite knowledge to manage modern field buses and industrial wireless systems. Safety Systems provides an introduction to the common safety philosophy of hazard identification, risk management and risk-based design of protection methods and functional safety systems. SCADA and DCS cover hardware and software systems, evaluation of typical DCS and SCADA systems and configuration of DCS controllers. Special Topics enable students to incorporate current technologies and the knowledge acquired from the entire course and thus solve complex Industrial Automation problems.

The Masters project, as the capstone of the course, requires a high level of personal autonomy and accountability, and reinforces the knowledge and skill base developed in the preceding subjects. As a significant research component of the course, this project will facilitate research, critical evaluation and the application of knowledge and skills with creativity and initiative, enabling students to critique current professional practice in the Industrial Automation industry.

ENTRANCE REQUIREMENTS

To gain entry into the Master of Engineering (Industrial Automation), applicants need one of the following:
a) a recognized 3-year bachelor degree in an engineering qualification in a congruent* field of practice with relevant work experience**.
b) a 4-year Bachelor of Engineering qualification (or equivalent), that is recognized under the Washington Accord or Engineers Australia, in a congruent*, or a different field of practice at the discretion of the Admissions Committee.
c) a 4-year Bachelor of Engineering qualification (or equivalent) that is not recognized under the Washington Accord, in a congruent* field of practice to this program.

AND

An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6), or equivalent as outlined in the EIT Admissions Policy.

*Congruent field of practice means one of the following with adequate Industrial Automation content (fields not listed below to be considered by the Dean and the Admissions Committee on a case-by-case basis):
• Industrial Automation
• Industrial Engineering
• Instrumentation, Control and Automation
• Mechanical Engineering
• Mechanical and Material Systems
• Mechatronic Systems
• Manufacturing and Management Systems
• Electrical Engineering
• Electronic and Communication Systems
• Chemical and Process Engineering
• Robotics
• Production Engineering

**Substantial industrial experience in a related field is preferred, with a minimum of two years’ relevant experience.

PROGRAM STRUCTURE

Students must complete 48 credit points comprised of 12 core subjects and one capstone thesis. The thesis is the equivalent of one full semester of work. There are no electives in this course. The course duration is two years full time, or equivalent. Subjects will be delivered over 4 semesters per year. Students will take 2 subjects per semester and be able to complete 8 subjects per year. There will be a short break between semesters. Each semester is 12 weeks long.

LIVE WEBINARS

During the program you will participate in weekly interactive sessions with the lecturers and other participants from around the world. Each unit's weekly live tutorial will last 60 to 90 minutes. We take student availability into consideration wherever possible before scheduling webinar times. All you need to participate is an adequate Internet connection, speakers and a microphone. The software package and setup details will be sent to you at the start of the program.

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

Read less
WHAT YOU WILL GAIN. - Skills and know-how in the latest and developing technologies in safety, risk and reliability. - Practical guidance and feedback from industrial automation experts from around the world. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest and developing technologies in safety, risk and reliability
- Practical guidance and feedback from industrial automation experts from around the world
- Live knowledge from the extensive experience of expert instructors
- Credibility and respect as the local safety, risk and reliability expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Safety, Risk and Reliability)** qualification

Next intake is scheduled for June 26, 2017. Applications now open; places are limited.

INTRODUCTION

A powerful force is driving industrial growth and change, and it’s only getting stronger. That force? Uncertainty. Society increasingly demands more efficient transport, more power production, safer energy exploration and processing, less waste, smarter products and of course, all at lower costs. All these demands spotlight uncertainty, and how we need to manage uncertainty through engineering, science and technology. Modern engineers face an intriguing set of challenges when tackling uncertainty and they have developed some of the smartest methods, tools, techniques and approaches for understanding system safety, risk and reliability.

The Master of Engineering (Safety, Risk and Reliability) is the ideal gateway to boost your capacity to tackle these real world increasingly complex issues. In the 21st century, industry will routinely deal with novel hazardous processing technologies, complex energy grid load-balancing from renewables, driverless cars, artificial vision to augment control and feedback in sub-sea exploration – and the infinitesimal scale of nanotechnologies in bionic engineering. Currently, people are at the heart of many hazardous work environments, exposed to the consequences of uncontrolled events; but soon, artificial intelligence will afford more human tasks to be automated (and present a host of newer risks, in exchange for the retired ones). This progress has to be examined in systematic terms – terms that integrate our understandings of technical fallibility, human error and political decision-making.

This program has been carefully designed to accomplish three key goals. First, a set of fundamental concepts is described in useful, manageable ways that encourage rapid and integrated knowledge-acquisition. Second, that knowledge is applied in creative and imaginative ways to afford practical, career-oriented advantages. Third, the learning that results from the integration of knowledge and application is emboldened by activities and projects, culminating in a project thesis that is the capstone of the program. This carefully designed learning journey will develop factual understanding and also exercise participant’s creativity and design-thinking capabilities. Employers are hungry for these skills, and program graduates can expect a significant advantage when interacting with employers, clients, consultants and fellow engineering peers.

ENTRANCE REQUIREMENTS

To gain entry into this program, applicants need one of the following:
a) a recognized 3-year bachelor degree in an engineering qualification in a congruent* field of practice with relevant work experience**.
b) a 4-year Bachelor of Engineering qualification (or equivalent), that is recognized under the Washington Accord or Engineers Australia, in a congruent*, or a different field of practice at the discretion of the Admissions Committee.
c) a 4-year Bachelor of Engineering qualification (or equivalent) that is not recognized under the Washington Accord, in a congruent* field of practice to this program.

AND
An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6.0) or equivalent as outlined in the EIT Admissions Policy.

* Congruent field of practice means one of the following with adequate Safety, Risk and Reliability content (fields not listed below to be considered by the Dean and the Admissions committee on a case-by-case basis):
• Chemical and Process Engineering
• Electronic and Communication Systems
• Instrumentation, Control and Automation
• Industrial Automation
• Industrial Engineering
• Agricultural Engineering
• Electrical Engineering
• Manufacturing and Management Systems
• Mechanical and Material Systems
• Mechatronic Systems
• Production Engineering
• Mechanical Engineering
• Robotics

**Substantial industrial experience in a related field is preferred, with a minimum of two years’ relevant experience.

PROGRAM STRUCTURE

Students must complete 48 credit points comprised of 12 core subjects and one capstone thesis. The thesis is the equivalent of one full semester of work. There are no electives in this course. The program duration is two years full time, or equivalent. Subjects will be delivered over 4 terms per year. Students will take 2 subjects per term and be able to complete 8 units per year. There will be a short break between terms. Each term is 12 weeks long.

LIVE WEBINARS

During the program you will participate in weekly interactive sessions with the lecturers and other participants from around the world. Each unit's weekly live tutorial will last 60 to 90 minutes. We take student availability into consideration wherever possible before scheduling webinar times. All you need to participate is an adequate Internet connection, speakers and a microphone. The software package and setup details will be sent to you at the start of the program.

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

Read less
WHAT YOU WILL GAIN. - Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation. Read more
WHAT YOU WILL GAIN:

- Skills and know-how in the latest and developing technologies in instrumentation, process control and industrial automation
- Practical guidance and feedback from industrial automation experts from around the world
- Live knowledge from the extensive experience of expert instructors
- Credibility and respect as the local industrial automation expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Industrial Automation)** qualification

Perth Campus next intake is scheduled for June 27, 2016. Applications now open; places are limited.

INTRODUCTION

The respected International Society of Automation (ISA) estimated that at least 15,000 new automation engineers are needed annually in the US alone. Many industrial automation businesses throughout the world comment on the difficulty in finding experienced automation engineers despite paying outstanding salaries.

The Master of Engineering (Industrial Automation) perfectly addresses this gap in the Industrial Automation industry. The program's twelve core units, and project thesis, provide you with the practical knowledge and skills required. Students with a background in electrical, mechanical, instrumentation and control, or industrial computer systems engineering can benefit from this program.

The content has been carefully designed to provide you with relevant concepts and the tools required in today’s fast-moving work environment. For example, Power Engineering covers major equipment and technologies used in power systems, including power generation, transmission and distribution networks. Programmable Logic Controllers covers in-depth principles of operation of programmable controllers, networking, distributed controllers, and program control strategies. Industrial Process Control Systems combines the process identification and feedback control design with a broad understanding of the hardware, system architectures and software techniques widely used to evaluate and implement complex control solutions. Industrial Instrumentation identifies key features of widely used measurement techniques and transducers combined with microprocessor devices to create robust and reliable industrial instruments. Process Engineering will enable students to evaluate and apply complex process calculations through application of control principles. Industrial Data Communications provides the requisite knowledge to manage modern field buses and industrial wireless systems. Safety Systems provides an introduction to the common safety philosophy of hazard identification, risk management and risk-based design of protection methods and functional safety systems. SCADA and DCS cover hardware and software systems, evaluation of typical DCS and SCADA systems and configuration of DCS controllers. Special Topics enable students to incorporate current technologies and the knowledge acquired from the entire course and thus solve complex Industrial Automation problems.

The Masters project, as the capstone of the course, requires a high level of personal autonomy and accountability, and reinforces the knowledge and skill base developed in the preceding subjects. As a significant research component of the course, this project will facilitate research, critical evaluation and the application of knowledge and skills with creativity and initiative, enabling students to critique current professional practice in the Industrial Automation industry.

ENTRANCE REQUIREMENTS

To gain entry into the Master of Engineering (Industrial Automation), applicants need one of the following:
a) a recognized 3-year bachelor degree in an engineering qualification in a congruent* field of practice with relevant work experience**.
b) a 4-year Bachelor of Engineering qualification (or equivalent), that is recognized under the Washington Accord or Engineers Australia, in a congruent*, or a different field of practice at the discretion of the Admissions Committee.
c) a 4-year Bachelor of Engineering qualification (or equivalent) that is not recognized under the Washington Accord, in a congruent* field of practice to this program.

AND

An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6), or equivalent as outlined in the EIT Admissions Policy.

*Congruent field of practice means one of the following with adequate Industrial Automation content (fields not listed below to be considered by the Dean and the Admissions Committee on a case-by-case basis):
• Industrial Automation
• Industrial Engineering
• Instrumentation, Control and Automation
• Mechanical Engineering
• Mechanical and Material Systems
• Mechatronic Systems
• Manufacturing and Management Systems
• Electrical Engineering
• Electronic and Communication Systems
• Chemical and Process Engineering
• Robotics
• Production Engineering

**Substantial industrial experience in a related field is preferred, with a minimum of two years’ relevant experience.

PROGRAM STRUCTURE

Students must complete 48 credit points comprised of 12 core subjects and one capstone thesis. The thesis is the equivalent of one full semester of work. There are no electives in this course. The course duration is two years full time, or equivalent. Subjects will be delivered over 4 semesters per year. Students will take 2 subjects per semester and be able to complete 8 subjects per year. There will be a short break between semesters. Each semester is 12 weeks long.

LIVE WEBINARS

During the program you will participate in weekly interactive sessions with the lecturers and other participants from around the world. Each unit's weekly live tutorial will last 60 to 90 minutes. We take student availability into consideration wherever possible before scheduling webinar times. All you need to participate is an adequate Internet connection, speakers and a microphone. The software package and setup details will be sent to you at the start of the program.

COURSE FEES

EIT provides distance education to students located almost anywhere in the world – it is one of the very few truly global training institutes. Course fees are paid in a currency that is determined by the student’s location. A full list of fees in a currency appropriate for every country would be complex to navigate and, with today’s exchange rate fluctuations, difficult to maintain. Instead we aim to give you a rapid response regarding fees that is customized to your individual circumstances.

We understand that cost is a major consideration before a student commences study. For a rapid reply to your query regarding courses fees and payment options, please query via the below button and we will respond within 2 business days.

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The graduate in Automation and Control Engineering is an expert who can actively participate and take the lead in the executive design and development of products and systems. Read more

Mission and goals

The graduate in Automation and Control Engineering is an expert who can actively participate and take the lead in the executive design and development of products and systems. She/he may take on full responsibility for designing, installing, testing and maintaining complex machines and systems. The goal of the Automation and Control Engineering programme is to provide the graduate with a strong background in fundamental scientific disciplines, such as mathematics and physics, in classical engineering fields, such as thermodynamics, mechanics, electric drives, automatic control, and in the disciplines of the information and telecommunication technology, like computer science, electronics, communication networks. Thanks to the interdisciplinary nature of her/his background, the graduate has all the necessary skills to design or manage systems resulting from the integration of highly diverse components and technologies. This flexibility both in the attitude and in the competences is a significant asset of the Automation and Control Engineer, in view of the large variety of possible applications, of the continuous and rapid evolution of the technologies, as well as of the dynamics of the job market.

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/automation-and-control-engineering/

Career opportunities

Automation and Control Engineering offers challenging and fulfilling careers for engineering technologists in design, research and development, and technical support, in many fields where automation and control are of paramount importance, such as: (a) industry producing manufacturing systems, automatic machines, robotic systems, mechatronic systems; (b) process industry (pulp and paper, energy production and conversion, chemical and petrochemical industry, etc.); (c) transportation systems (ground, marine and aerospace), concerning both the development of vehicles (cars, boats, helicopters, aircrafts, satellites), and the design, management and control of infrastructures; (d) transportation and distribution networks; (e) food industry; (f) electrical appliances and domotics; (g) environmental resources.

Typical companies where the automation and control engineers may operate include those producing and selling automation systems (both hardware and software); companies that use automated production plants or that manage highly complex services; engineering and consulting firms that design and project complex, economically challenging and technologically advanced plants and systems.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Automation_Engineering.pdf
This programme aims at providing the graduates with sound engineering skills to design, develop, implement and manage automation systems for manufacturing plants, industrial processes, mechatronic devices, distribution networks and environmental systems. Graduates have a strong background in the classical engineering fields and in the information and telecommunication technology. The interdisciplinary nature of this programme provides the graduates with all the skills to design/manage systems resulting from the integration of highly diverse technologies.
Graduates will have wide employment opportunities in many fields: industry producing manufacturing systems, automatic machines, robotic systems, mechatronic systems, process industry, transportation systems, transportation and distribution networks, food industry, electrical appliances, home automation and environmental resources.
The programme is taught in English.

Subjects

The mandatory courses are:
- Advanced and multivariable control
- Automation and control laboratory
- Computer aided manufacturing
- Dynamics of electrical machines and drives
- Dynamics of mechanical systems
- Model identification and data analysis
- Software engineering

Among the optional courses:
- Automation and control in vehicles
- Automation of energy systems
- Control of industrial robots
- Production systems control
- Safety in automation systems
- Thesis and final exam

See the website http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/automation-and-control-engineering/

For contact information see here http://www.polinternational.polimi.it/educational-offer/laurea-magistrale-equivalent-to-master-of-science-programmes/automation-and-control-engineering/

Find out how to apply here http://www.polinternational.polimi.it/how-to-apply/

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This course, accredited by the Institution of Mechanical Engineers (IMechE), provides an excellent opportunity to improve your current technical portfolio with a spectrum of engineering operations and project management skills. Read more
This course, accredited by the Institution of Mechanical Engineers (IMechE), provides an excellent opportunity to improve your current technical portfolio with a spectrum of engineering operations and project management skills. As a result, you will enhance your employment prospects and your ability to apply for senior engineering management roles.

The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng(Hons) accredited for CEng, will be able to show that they have satisfied the educational base for CEng registration.

Key features
-The course is designed to complement your engineering degree with a rich spectrum of engineering and project management skills.
-Academic teaching is supported by specialist speakers from industry, keeping you up to date with the challenges and developments in the real world.
-Skills learnt in hands-on practical sessions using the latest software are easily transferred into any working environment.

What will you study?

You will learn how to apply advanced project management and resource optimisation skills, and will be able to identify, evaluate and recommend solutions to critical engineering management problems that need improvement. You will study the important ingredients of running a successful business, and how to improve its operations, productivity and competitiveness by using different management techniques specific to engineering companies. You will be able to develop and manage new projects more effectively and within the given constraints in functions, cost and time. You will also learn how to expand your business through deploying the latest e-commerce and IT techniques.

Throughout the course you will have many hands-on sessions to practise what you have learned in the classroom. These practical skills will be obtained through using specialist software in operation management, quality analysis, business decision modelling, supply chain management and resources simulation. The project dissertation will allow you to develop a chosen field of knowledge which will complement your career ambition. Teamwork, group presentations, case studies and industrial speakers are other highlights of the course, enhancing your learning experience and employability.

Assessment

Coursework, software session reports, group presentation, research project.

Work placement scheme

Kingston University has set up a scheme that allows postgraduate students in the Faculty of Science, Engineering and Computing to include a work placement element in their course starting from September 2017. The placement scheme is available for both international and home/EU students.

-The work placement, up to 12 months; is optional.
-The work placement takes place after postgraduate students have successfully completed the taught portion of their degree.
-The responsibility for finding the placement is with the student. We cannot guarantee the placement, just the opportunity to undertake it.
-As the work placement is an assessed part of the course for international students, this is covered by a student's tier 4 visa.

Details on how to apply will be confirmed shortly.

Course structure

Please note that this is an indicative list of modules and is not intended as a definitive list.

Core modules
-Engineering Projects and Risk Management
-Industrial Operation Management and Resources Simulation
-Engineering Research Techniques, Entrepreneurship and Quality Management
-Engineering Individual Project

Option modules (choose one)
-E-engineering Systems
-Green Engineering and Energy Efficiency
-Mechatronic Design and Automation

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EIT is pleased to bring you the Master of Engineering (Electrical Systems)** program. IN THIS ACCREDITED AND PRESTIGIOUS PROGRAM YOU WILL GAIN. Read more
EIT is pleased to bring you the Master of Engineering (Electrical Systems)** program.

IN THIS ACCREDITED AND PRESTIGIOUS PROGRAM YOU WILL GAIN:
- Skills and know-how in the latest and developing technologies in electrical systems
- Practical guidance and feedback from experts from around the world
- Live knowledge from the extensive experience of expert instructors, rather than from just theoretical information gained from books and college
- Credibility and respect as the local electrical systems expert in your firm
- Global networking contacts in the industry
- Improved career choices and income
- A valuable and accredited Master of Engineering (Electrical Systems)** qualification

The next intake will start on the week of June 27, 2016.

Contact us to find out more and apply (http://www.eit.edu.au/course-enquiry).

** A note regarding recognition of this program in the Australian education system: EIT is the owner of this program. The qualification is officially accredited by the Tertiary Education Quality and Standards Agency (TEQSA). EIT delivers this program to students worldwide.

Visit the website http://www.eit.edu.au/master-engineering-electrical-systems

PROFESSIONAL RECOGNITION

This Master Degree (or Graduate Diploma) is officially accredited by the Tertiary Education Quality and Standards Agency (TEQSA) in Australia.

It is a professional development program and is not currently an entry-to-practice qualification. Engineers Australia are considering this and other programs for those students desiring professional status (e.g. CPEng). However, the outcome of this review may or may not result in a student gaining chartered professional status if he or she does not already possess this.

Additional Entry Requirements

An appropriate level of English Language Proficiency equivalent to an English pass level in an Australian Senior Certificate of Education, or an IELTS score of 6.5 (with no individual band less than 6.0) or equivalent as outlined in the EIT Admissions Policy.

Congruent field of practice means one of the following with adequate electrical engineering content (with fields not listed below to be considered by the Dean and the Admissions committee on a case-by-case basis):

• Electrical Engineering

• Electronic and Communication Systems

• Industrial Engineering

• Instrumentation, Control and Automation

• Mechatronic Systems

• Manufacturing and Management Systems

• Industrial Automation

• Production Engineering

Overview

Electrical power is an essential infrastructure of our society. Adequate and uninterrupted supply of electrical power of the required quality is essential for industries, commercial establishments and residences; and almost any type of human activity is impossible without the use of electricity. The ever-increasing cost of fuels required for power generation, restricted availability in many parts of the world, demand for electricity fueled by industrial growth and shortage of skilled engineers to design, operate and maintain power network components are problems felt everywhere today. The Master of Engineering (Electrical Systems) is designed to address the last-mentioned constraint, especially in today’s context where the field of electrical power is not perceived as being ‘cool’ unlike computers and communications and other similar nascent fields experiencing explosive growth. But it is often forgotten that even a highly complex and sophisticated data centre needs huge amounts of power of extremely high reliability, without which it is just so much silicon (and copper).

This program presents the topics at two levels. The first year addresses the design level where the student learns how to design the components of a power system such as generation, transmission and distribution as well as the other systems contributing to the safety of operation. The topics in the first year also cover the automation and control components that contribute to the high level of reliability expected from today’s power systems. Because of the constraints imposed by the fuel for power generation and the environmental degradation that accompanies power generation by fossil fuels, the attention today is focused on renewable energy sources and also more importantly how to make the generation of power more efficient and less polluting so that you get a double benefit of lower fuel usage and lower environmental impact. Even the best designed systems need to be put together efficiently. Setting up power generation and transmission facilities involves appreciable capital input and complex techniques for planning, installation and commissioning. Keeping this in view, a unit covering project management is included in the first year.

The second year of the program focuses on the highly complex theory of power systems. If the power system has to perform with a high degree of reliability and tide over various disturbances that invariably occur due to abnormal events in the power system, it is necessary to use simulation techniques that can accurately model a power system and predict its behavior under various possible disturbance conditions. These aspects are covered in the course units dealing with power system analysis and stability studies for steady-state, dynamic and transient conditions. The aspect of power quality and harmonic flow studies is also included as a separate unit.

The study of power systems has an extensive scope and besides the topics listed above, a student may also like to cover some other related topic of special interest. The ‘Special Topics in Electrical Power Systems’ unit aims to provide students with the opportunity for adding one ‘state-of-the art’ topic from a list of suggested fields. Examples are: Smart grids, Micro-grids and Geographic Information System (GIS) application in utility environment.

The Masters Thesis which spans over two complete semesters is the capstone of the program, requiring a high level of personal autonomy and accountability, and reinforces the knowledge and skill base developed in the preceding units. As a significant research component of the course, this program component will facilitate research, critical evaluation and the application of knowledge and skills with creativity and initiative, enabling the students to critique current professional practice in the electrical power industry.

WHO WOULD BENEFIT

Those seeking to achieve advanced know-how and expertise in industrial automation, including but not limited to:

- Electric Utility engineers

- Electrical Engineers and Electricians

- Maintenance Engineers and Supervisors

- Energy Management Consultants

- Automation and Process Engineers

- Design Engineers

- Project Managers

- Consulting Engineers

- Production Managers

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New digital technologies are transforming the workplace as companies improve their operational efficiencies and grow using new hybrid business models. Read more
New digital technologies are transforming the workplace as companies improve their operational efficiencies and grow using new hybrid business models. This Master's degree develops your career with this in mind, giving you the knowledge and skills to develop and work with the next generation of smart technologies.

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This advanced course focuses on enabling you to become proficient in communicating across a range of different disciplines and delivering optimised engineering solutions using an integrated multidisciplinary mechatronics approach. Read more

About the course

This advanced course focuses on enabling you to become proficient in communicating across a range of different disciplines and delivering optimised engineering solutions using an integrated multidisciplinary mechatronics approach. You will be exposed to a broad range of engineering disciplines, be able to solve multidisciplinary mechatronics problems and develop the skills to apply a mechatronic approach to the solution of technical problems.

Reasons to Study

• Accredited by the Institution of Engineering and Technology (IET)
ensuring you will benefit from the highest quality teaching, and graduate with a recognised qualification

• Graduate employability
Mechatronic engineers are in high demand as more industries seek to apply advances across a range of engineering disciplines

• Enjoy access to state-of-the-art facilities
including dedicated mechanical, electrical and electronic laboratories especially suited for mechatronics, as well as an for the manufacture of student designs

• Industry placement opportunity
you can chose to undertake a year-long work placement, gaining valuable experience to enhance your practical and professional skills further

• Work with leading research groups
you will be offered opportunities to work on projects with research groups within the faculty, including the Centre for Advanced Manufacturing Processes and Mechatronics, that are engaged in high-class, research and industrial collaboration and consultancy

• Course content relevant to modern day practice
our research informs our teaching, ensuring the course content covers current industry topics and issues

• Excellent graduate prospects
graduates enjoy exciting career opportunities in a range of fields such as robotics and automation, manufacturing, aerospace, material processing, energy and power.

Modules

First semester (September to January)

• Electromechanics
• Mechatronic Systems - Engineering and Design
• Engineering Business Environment and Energy Studies
• Programming and Software Engineering

Second semester (February to May)

• Machine Vision, Robotics and Flexible Automation
• Engineering Systems: Dynamics and Control
• Microprocessor Applications and Digital Signal Processing
• Research Methods

Individual Project (Stage three)

This research can be industrially-based or linked to an industrial partner, attached to one of the mechatronic-related research teams within the faculty or in other collaborating institutions. The research project should be in an area relevant to Mechatronics, where clear evidence of the ability to solve a real multidisciplinary problem is demonstrated. The project assessment involves a formal presentation, production of a technical paper and a thesis.

Optional placement
We offer a great opportunity to boost your career prospects through an optional one year placement as part of your postgraduate studies. We have a dedicated Placement Unit which will help you obtain this. Once on your placement you will be supported by your Visiting Tutor to ensure that you gain maximum benefit from the experience. Placements begin after the taught component of the course has been completed - usually around June - and last for one year. When you return from your work placement you will begin your dissertation.

Teaching and assessment

Teaching is delivered through a variety of methods including lectures, tutorials and laboratories. You will be expected to undertake self-directed study.

Contact and learning hours

For taught sessions you will attend eight modules with a total of 48 hours (four hours per week for 12 weeks each), with eight hours per module per week of average additional self-directed study. For the individual project you normally will spend 13 weeks working five days (eight hours per day) a week to complete it, and have one hour per week contact time with your supervisor.

Academic expertise

Research is carried out by the Mechatronics Research Centre, which holds a considerable number of UK and EU research project grants and has collaborative research links with more than 100 national and international organisations. The group is internationally regarded and specialises in machine design, control and simulation, fluid power systems and motion control.

As part of your studies, you will be offered opportunities to work on projects with research groups within the faculty that are engaged in high-class, leading-edge research and industrial collaboration and consultancy.

During the project element of the course, the Intelligent Machines and Automation Systems (IMAS) Research Laboratory provides access to dedicated research facilities

To find out more

To learn more about this course and DMU, visit our website:
Postgraduate open days: http://www.dmu.ac.uk/study/postgraduate-study/open-evenings/postgraduate-open-days.aspx

Applying for a postgraduate course:
http://www.dmu.ac.uk/study/postgraduate-study/entry-criteria-and-how-to-apply/entry-criteria-and-how-to-apply.aspx

Funding for postgraduate students
http://www.dmu.ac.uk/study/postgraduate-study/postgraduate-funding-2017-18/postgraduate-funding-2017-18.aspx

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Mechatronics is a synergistic combination of precision mechanics, electronics, controls, and computer engineering, combined through a process of integrated design. Read more
Mechatronics is a synergistic combination of precision mechanics, electronics, controls, and computer engineering, combined through a process of integrated design. On the MSc in Mechatronics, the development of skills and advancement of knowledge focus on enabling students to understand the combination, at a high level, of Mechanical and Electronic Engineering and to gain a broad range expertise in these areas.

This is alongside developing a student’s ability to control mechanical systems using analogue and digital electronics. This course will give students an awareness of modern digital embedded platforms for mechatronic systems.

Students will cover subject specific subjects such as Dynamics and Performance of mechanical Systems with the option of Artificial Intelligence or Renewable Energy Systems and Smart Grid alongside cohort taught subjects to develop their management skills and their employability.

The successful postgraduates of the course will acquire the knowledge and understanding, intellectual, practical and transferable skills necessary for the analysis and synthesis of problems in engineering and manufacturing through a combination of experimental, simulation, research methods and case studies.

They can expect to gain work in a range of disciplines within a variety of industries from specialist technical roles to positions of management responsibility.

Why choose this course?

Students who undergo this course will develop knowledge and understanding of the advanced theoretical issues and their practical implementations that underlie recent developments in Mechatronics.

Gain the abilities to evaluate the performance of systems appropriate to Mechatronics by theoretical analysis and/or simulation
Supported by the School which has over 25 years' experience of teaching electronic engineering and has established an excellent international reputation in this field.

We offer extensive lab facilities for engineering students, including the latest software packages.

Careers

Applications are extremely wide ranging covering for example the aerospace industry, road vehicles and trains, medical engineering, materials processing, advanced manufacturing systems, defence systems and consumer electronics. Graduates may therefore expect employment across a very wide range of engineering companies.

Teaching methods

Our enthusiastic staff is always looking for new ways to enhance your learning experience and over recent years, we have won national awards for our innovative teaching ideas. In addition, our staff are active in research and useful elements of it are reflected on the learning experience.

The School of Engineering and Technology has a reputation for innovation in teaching and learning, where nearly all MSc modules are delivered through a combination of traditional face-to-face teaching and backup tutorial's using the University's StudyNet web based facility. StudyNet allows students to access electronic teaching and learning resources, and conduct electronic discussions with staff and other students.

A heavy emphasis is placed on theory and practice, and the School of Engineering and Technology has a policy of using industrial standard software wherever possible.

Structure

Core Modules
-Advanced Reconfigurable Systems and Applications
-Control of Engineering Systems
-Digital Signal Processing and Processes
-Dynamics and Performance of Mechanical Systems
-Embedded Control Systems
-MSc Project
-MSc Projects
-Mixed Mode and VLSI Technologies
-Operations Management
-Operations Management
-Operations Research
-Operations Research

Optional
-Artificial Intelligence
-Renewable Energy Systems and Smart Grids Technology

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Mechatronics is an exciting, growing field that combines mechanical, electronic and control systems to create a complete device. It mostly relates to the mechanical systems that perform relatively fast and precise motions and therefore require sophisticated electronic devices and control algorithms. Read more
Mechatronics is an exciting, growing field that combines mechanical, electronic and control systems to create a complete device. It mostly relates to the mechanical systems that perform relatively fast and precise motions and therefore require sophisticated electronic devices and control algorithms. This hands-on course will help you develop the multidisciplinary knowledge that the fast-moving industrial, commercial and domestic sectors demand of their technical professionals.

The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng(Hons) accredited for CEng, will be able to show that they have satisfied the educational base for CEng registration.

Key features
-Academic teaching is complemented by presentations from industry experts and by industrial trips, such as the UK annual NI Days conference, held in London.
-You will enjoy group assignments, supporting each other's learning and have opportunities to develop your ability to work in teams. You will also benefit from an industry-relevant final project. The presentation, which is part of the final project, will prepare you for your job interview.

What will you study?

Although mechatronics may be perceived in combination with robotics, as robots are indeed fast and precise mechanical systems, it also has wider applications, such as in hard-disk drives for computers, tracking cameras for surveillance applications, intelligent actuators in automotive systems and many other areas including devices used in the field of healthcare and rehabilitation, like intelligent prosthetic devices.

The hands-on approach on the course, using our state-of-the art multidisciplinary laboratories with equipment from National Instruments, Freescale, Agilent Technology and many more, adds value to this postgraduate degree. The course dovetails with research activities of the teaching staff, implementing the latest advances in our research. Utilising applied research, you have the opportunity to do your own research within an individual industry-relevant 'capstone' project. This includes preparation of a scientific paper, giving an opportunity for that first breakthrough into publishing your work.

Assessment

Coursework and/or exams, presentations, industrial or research project.

Work placement scheme

Kingston University has set up a scheme that allows postgraduate students in the Faculty of Science, Engineering and Computing to include a work placement element in their course starting from September 2017. The placement scheme is available for both international and home/EU students.

-The work placement, up to 12 months; is optional.
-The work placement takes place after postgraduate students have successfully completed the taught portion of their degree.
-The responsibility for finding the placement is with the student. We cannot guarantee the placement, just the opportunity to undertake it.
-As the work placement is an assessed part of the course for international students, this is covered by a student's tier 4 visa.

Details on how to apply will be confirmed shortly.

Course structure

Please note that this is an indicative list of modules and is not intended as a definitive list.

Core modules
-Engineering Research Techniques, Entrepreneurship and Quality Management
-Control Systems with Embedded Implementation
-Mechatronic Design and Automation
-Engineering Individual Project

Option modules (choose one)
-Advanced CAD/CAM Systems
-Advanced Control and Robotics
-Digital Signal Processing

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In today's uncertain global competition platform and economy, manufacturing and engineering are two of the most important pinnacles for a sustainable growth of any country. Read more
In today's uncertain global competition platform and economy, manufacturing and engineering are two of the most important pinnacles for a sustainable growth of any country. Many engineering companies require graduates who can demonstrate not only technological, but also managerial and entrepreneurial skill sets. You will be taught how to select advanced manufacturing processes and materials when making new products, and how to turn innovative ideas into real products quickly, timely and within the constraints of available resources, enhancing your employability.

The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer. Accredited MSc graduates who also have a BEng(Hons) accredited for CEng, will be able to show that they have satisfied the educational base for CEng registration.

Key features

-A balanced syllabus blends aspects of technology and management to create a unique skill set, which is much sought after in industry.
-Academic teaching is also complemented by expert speakers from industry, keeping you up to date with the challenges and developments in the real world.
-Many modules are supported by practical workshops using the latest equipment and software. Such practical skills can easily be transferred into the working environment.

What will you study?

You will learn how to analyse complex technical problems and challenges faced by many real-world engineering companies of different sizes. You will also study the operational issues experienced by these companies through real case studies, and how to implement logical solutions under different scenarios. In addition, you will be able to measure the potentials of an engineering company not just through its technological adaptation but also from the entrepreneur viewpoint.

Throughout the course, you will have many hands-on sessions to practise what you have learned in the classroom. These practical skills will be obtained through using specialist software and hardware in engineering functions analysis, CAD/CAM, finite element modelling, operation management, quality analysis, business decision modelling, supply chain management and resources simulation. The project dissertation will allow you to develop a chosen field of knowledge which will complement your career ambition. Teamwork, group presentations, case studies and industrial speakers are other highlights of the course, enhancing your learning experience and employability.

Assessment

Coursework, group presentation, research project and exam.

Course structure

Please note that this is an indicative list of modules and is not intended as a definitive list.

Core modules
-Engineering Research Techniques, Entrepreneurship and Quality Management
-Advanced CAD/CAM Systems
-Mechatronic Design and Automation
-Engineering Individual Project

Option modules (choose one)
-Advanced Stress Analysis and Materials
-Industrial Operation Management and Resources Simulation
-E-engineering Systems
-Green Engineering and Energy Efficiency

Read less

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