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Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Electronic and Electrical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017). Read more

Visit our website for more information on fees, scholarships, postgraduate loans and other funding options to study Electronic and Electrical Engineering at Swansea University - 'Welsh University of the Year 2017' (Times and Sunday Times Good University Guide 2017).

As a student on the Master's course in Electronic and Electrical Engineering, you will develop specialist skills aligned with the College of Engineering’s research interests and reflecting the needs of the electronics industry.

Key Features of MSc in Electronic and Electrical Engineering

The MSc Electronic and Electrical Engineering course covers the ability to apply the knowledge gained in the course creatively and effectively for the benefit of the profession, to plan and execute a programme of work efficiently, and to be able, on your own initiative, to enhance your skills and knowledge as required throughout your career in Electronic and Electrical Engineering.

Students on the Electronic and Electrical Engineering course benefit from the use of industry-standard equipment, such as a scanning tunnelling microscope for atomic scale probing or an hp4124 parameter analyzer for power devices, for simulation, implementation and communication.

During the Electronic and Electrical Engineering course there will be the opportunity to choose and apply suitable prototyping and production methods and components, gain knowledge in constructing and evaluating advanced models of various manufacturing techniques, and be able to differentiate, analyse and discuss various product lifetime management solutions and how they affect different sectors of Electronic and Electrical Engineering industry.

The MSc in Electronic and Electrical Engineering programme is modular in structure. Students must obtain a total of 180 credits to qualify for the degree. This is made up of 120 credits in the taught element (Part One) and a project (Part Two) that is worth 60 credits and culminates in a written dissertation in Electronic and Electrical Engineering. Students on the Electronic and Electrical Engineering course must successfully complete Part One before being allowed to progress to Part Two.

Part-time Delivery mode of MSc in Electronic and Electrical Engineering

The part-time scheme of the MSc in Electronic and Electrical Engineering is a version of the full-time equivalent MSc in Electronic and Electrical Engineering scheme, and as such it means lectures are spread right across each week and you may have lectures across every day. Due to this timetabling format, the College advises that the scheme is likely to suit individuals who are looking to combine this with other commitments (typically family/caring) and who are looking for a less than full-time study option in Electronic and Electrical Engineering.

Those candidates seeking to combine the part-time option with full-time work are unlikely to find the timetable suitable, unless their job is extremely flexible and local to the Bay Campus.

Modules on Electronic and Electrical Engineering

Modules on the MSc Electronic and Electrical Engineering course can vary each year but you could expect to study:

Communication Skills for Research Engineers

Energy and Power Electronics Laboratory

Power Semiconductor Devices

Advanced Power Electronics and Drives

Wide Band-Gap Electronics

Power Generation Systems

Modern Control Systems

Advanced Power Systems

Signals and Systems

Digital Communications

Optical Communications

Probing at the Nanoscale

RF and Microwaves

Wireless Communications

Facilities for Electronic and Electrical Engineering

The new home of the Electronic and Electrical Engineering programme is at the innovative Bay Campus which provides some of the best university facilities in the UK, in an outstanding location.

Engineering at Swansea University has extensive IT facilities and provides extensive software licenses and packages to support teaching. In addition the University provides open access IT resources.

Find out more about the facilities used by Electronic and Electrical students at Swansea University, including the electronics lab on our website.

Links with Industry

At Swansea University, Electronic and Electrical Engineering has an active interface with industry and many of our activities are sponsored by companies such as Agilent, Auto Glass, BT and Siemens.

Electronic and Electrical Engineering has a good track record of working with industry both at research level and in linking industry-related work to our postgraduate courses. We also have an industrial advisory board that ensures our taught courses including the MSc in Electronic and Electrical Engineering maintain relevance.

Our research groups work with many major UK, Japanese, European and American multinational companies and numerous small and medium sized enterprises (SMEs) to pioneer research. This activity filters down and influences the project work that is undertaken by all our postgraduate students including those on the MSc in Electronic and Electrical Engineering.

Careers

Electronic and Electrical Engineering graduates find employment in industry, research centres, government or as entrepreneurs in a wide range of careers, from a design and development role for electronic and electrical equipment or as a technological specialist contributing to a multi-disciplinary team in a range of fields, including medicine, travel, business and education.

Research

The Research Excellence Framework (REF) 2014 ranks Engineering at Swansea as 10th in the UK for the combined score in research quality across the Engineering disciplines.

The REF assesses the quality of research in the UK Higher Education sector, assuring us of the standards we strive for.

World-Leading Research

The REF shows that 94% of research produced by our academic staff is of World-Leading (4*) or Internationally Excellent (3*) quality. This has increased from 73% in the 2008 RAE.

Research pioneered at the College of Engineering harnesses the expertise of academic staff within the department. This ground-breaking multidisciplinary research informs our world-class teaching with several of our staff leaders in their fields.

With recent academic appointments strengthening electronics research at the College, the Electronic Systems Design Centre (ESDC) has been re-launched to support these activities.

The Centre aims to represent all major electronics research within the College and to promote the Electrical and Electronics Engineering degree.

Best known for its research in ground-breaking Power IC technology, the key technology for more energy efficient electronics, the Centre is also a world leader in semiconductor device modelling, FEM and compact modelling.



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The program aims to form Master graduates with a comprehensive and solid scientific and technological background in Electronics Engineering, able to design and to use electronic devices, electronic circuits and electronic systems of any complexity as well as to promote the diffusion of electronic technologies in the fields of human activity where benefits can be envisaged. Read more

Mission and goals

The program aims to form Master graduates with a comprehensive and solid scientific and technological background in Electronics Engineering, able to design and to use electronic devices, electronic circuits and electronic systems of any complexity as well as to promote the diffusion of electronic technologies in the fields of human activity where benefits can be envisaged.
To meet these training needs, the Master of Science in Electronics Engineering bases its roots on a full spectrum of basic courses (mathematics, classical and modern physics, computer science, signal theory, control and communications, basic electronic circuits) that are prerequisites required from the Bachelor, and focuses on the most advanced disciplines in electronic design (analog and digital electronics, solid state physics and devices, microelectronics, optoelectronics, sensors and electronic instrumentation, communications and control systems) to provide a complete and updated preparation. Upon graduating, students will have developed a “design oriented” mindset and acquired a skill to use engineering tools to design solutions to advanced electronic challenges in scientific and technological fields.

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

Career opportunities

Thanks to the deep and solid scientific and technological knowledge provided, Master of Science graduates in Electronics Engineering will be able to hold positions of great responsibility, both at technical and management level, in a wide variety of productive contexts:
- Scientific and technological research centers, national and international, public or private;
- Industries of semiconductors, integrated circuits and in general of electronic components;
- Industries of electronic systems and instrumentation, such as consumer electronics (audio, video, telephone, computers, etc.), optoelectronics, biomedical, etc.;
- Electromechanical industries with high technological content such as aeronautics, transportation, aerospace, energy, robotics and plant automation, etc.;
- Work as a freelance in the design and fabrication of custom electronic systems.

Presentation

See http://www.polinternational.polimi.it/uploads/media/Electronics_Engineering_01.pdf
The Master of Science in Electronics Engineering aims to form graduates with a comprehensive and solid scientific and technological knowledge in the field of Electronics, able to design and to use electronic devices, electronic circuits and electronic systems of any complexity as well as to promote the diffusion of electronic technologies in the fields of human activity where benefits can be envisaged. The course focuses on the most advanced aspects of Electronics (analog and digital integrated circuits design, solid state devices, microelectronics, optoelectronic devices and sensors, electronic instrumentation, communications and control systems) to provide a complete and updated professional preparation. Upon graduating, students will have developed a “design oriented” mindset enabling them to successfully deal with the complex needs of today’s industrial system. They will have also acquired a skill to use engineering tools to design solutions to advanced electronic challenges in scientific and technological fields as well as a maturity to hold positions of great responsibility both at technical and management level. The programme is taught in English.

Required background from Bachelor studies

The Master of Science in Electronics Engineering bases its roots on a full spectrum of knowledge that students are expected to have successfully acquired in their Bachelor degree, like advanced mathematics, classical and modern physics, computer science, signal and communication theory, electric circuits and feedback control, basic electronic devices and analog & digital circuit analysis.

Subjects

- Analog & Digital Integrated Circuit Design
- MEMS and Microsensors
- Electronic Systems
- Electron Devices and Microelectronic Technologies
- Signal recovery and Feedback Control
- Optoelectronic Systems and Photonics Devices
- RF Circuit Design
- Power Electronics
- Semiconductor Radiation Detectors
- FPGA & Microcontroller System Design
- Biochip and Electronics Design for Biomedical Instrumentation

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

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

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

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Instrumentation and control engineers are highly sought after in a range of industries including oil and gas, petrochemicals, chemical engineering, manufacturing, research, transport and infrastructure. Read more

Instrumentation and control engineers are highly sought after in a range of industries including oil and gas, petrochemicals, chemical engineering, manufacturing, research, transport and infrastructure.

Course details

There are three routes you can select from to gain a postgraduate Master’s award:

  • MSc Instrumentation and Control Engineering - one-year full time
  • MSc Instrumentation and Control Engineering - two-years part time
  • MSc Instrumentation and Control Engineering (with Advanced Practice) – two years full time

The one-year programme is a great option if you want to gain a traditional MSc qualification – you can find out more here. This two-year master’s degree with advanced practice enhances your qualification by adding to the one-year master’s programme an internship, research or study abroad experience.

The MSc Instrumentation and Control Engineering (with Advanced Practice) offers you the chance to enhance your qualification by completing an internship, research or study abroad experience in addition to the content of the one-year MSc. This programme helps you develop your knowledge and skills in instrumentation, electronics and control engineering. And you develop your ability to synthesise information from a variety of sources and make effective decisions on complex instrumentation and control engineering problems.

What you study

For the MSc with advanced practice, you complete 120 credits of taught modules, a 60-credit master’s research project and 60 credits of advanced practice.

Examples of past MSc research projects:

  • effects of particle size on gas-solid flow measurement using dynamic electrostatic meters
  • an investigation of self-turning and predictive control with MATLAB
  • modelling and control of hot air blow rig PT326
  • wireless controlled car with data acquisition
  • BCD to 6-3-1-1 code converter design using VHDL
  • comparative evaluation of turning techniques for MPC
  • digital traffic signal controller design
  • proteus control board test site
  • design of temperature measurement system
  • control system design for stepping motor.

Course structure

Core modules

  • Data Acquisition and Signal Processing Techniques
  • Digital Control and Implementation
  • Hydrocarbon Production Engineering
  • Identification and Model Predictive Control
  • Project Management and Enterprise
  • Research and Study Skills
  • Research Project (Advanced Practice)
  • Robust Control Systems
  • Signal Conditioning and Data Processing

Advanced Practice options

  • Research Internship
  • Study Abroad
  • Vocational Internship

Modules offered may vary.

Teaching

How you learn

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems. 

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

In addition to the taught sessions, you undertake a substantive MSc research project and the Advanced Practice module. This module enables you to experience and develop employability or research attributes and experiential learning opportunities in either an external workplace, internal research environment or by studying abroad. You also critically engage with either external stakeholders or internal academic staff, and reflect on your own personal development through your Advanced Practice experience.

How you are assessed

Assessment varies from module to module. It may include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Your Advanced Practice module is assessed by an individual written reflective report (3,000 words) together with a study or workplace log, where appropriate, and through a poster presentation.

Employability

An instrumentation and control engineer may be involved in designing, developing, installing, managing and maintaining equipment which is used to monitor and control engineering systems, machinery and processes. As a graduate you can expect to be employed in a range of sectors including industries involved with oil and gas, petrochemicals, chemical engineering, manufacturing, research, transport and infrastructure.



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Control Engineering is a multi-disciplinary subject, with applications across a wide range of industrial sectors. The Control Systems Group in… Read more

Control Engineering is a multi-disciplinary subject, with applications across a wide range of industrial sectors. The Control Systems Group in the School of Electrical and Electronic Engineering at the University of Manchester has been running an MSc course in Advanced Control and Systems Engineering since 1968. The course is geared for graduates from a variety of scientific and engineering disciplines.

The aims of the course are to:

  • provide an advanced education in control and systems engineering, emphasising modern theoretical developments and their practical application
  • give a sound fundamental understanding of the principles underlying the operation of control systems
  • enable students to apply modern control principles in various areas of industry

Students acquire a range of intellectual skills that cover the design, analysis and simulation of control systems. A strong emphasis is placed on practical and transferable skills through laboratory exercises and the use of software packages.

Coursework and assessment

The taught part of the course comprises six course units of 15 credits each. This is assessed by written examinations, coursework and laboratory reports.

A strong feature of the course is the dissertation project, which constitutes 60 Credits. The project introduces students to cutting edge control theory and applications.

Course unit details

Typical course units include Control and Computer Laboratory, Linear Optimal Control, Intelligent Systems, Non-linear Controllers & Systems, Self-tuning and Adaptive Systems, Manufacturing Automation and Data Engineering, Fault Detection and Diagnosis, and Process Control Systems.

Disability support

Practical support and advice for current students and applicants is available from the Disability Advisory and Support Service. Email: 

Career opportunities

In 2008 we celebrated the 40 th anniversary of our MSc course. In that time graduates of the course have achieved top ranking industrial and academic positions in their home countries, in the UK and around the world.

Graduates from the course are employed in a variety of industries, including process and petro-chemical industries, manufacturing, power generation and the automotive and aerospace sectors. Recently there has been a surge in demand for control engineers in the field of biomedicine. More generally feedback control and systems engineering skills play an important part in an ever widening range of high tech applications.

The MSc can also be used a spring board for postgraduate research. Approximately 50% of the current PhD students in the Control Systems Group are graduates from the MSc course.



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Automation, control and robotics are pervasive enabling technologies found in almost every modern technical system, particularly in manufacturing and production. Read more

Automation, control and robotics are pervasive enabling technologies found in almost every modern technical system, particularly in manufacturing and production. They combine the diverse and rapidly expanding disciplines of automation, control, mechanics, software and signal processing.

This course is ideal if you wish to develop comprehensive knowledge and understanding of • classical and modern control theory • industrial automation • systems analysis • design and simulation • robotics.

You gain the ability to apply principles of modelling, classical and modern control concepts and controller design packages in various areas of industry. You also learn how to design and exploit automation and robotic systems in a range of manufacturing and industrial applications.

The course has six core modules which cover the major aspects of industrial automation and control systems engineering and robotics, ranging from classical linear control system design to non-linear, optimal and intelligent control systems, including distributed control systems, robotics, computer networks and artificial intelligence.

You also choose two optional modules relevant to automation and control to suit your interests. For example, if you wish to work in the manufacturing industry you can choose manufacturing systems or machine vision. There is the opportunity to study one or two management modules if you wish to apply yourself to a more managerial role.

To gain the masters you complete a major research-based project, which can be focused on an area of your particular interest or career need.

You work alongside staff from the Electrical, Electronic and Control Engineering Group and the Centre for Automation and Robotics Research (CARR) at Sheffield Hallam. This provides the opportunity to work with active researchers.

Professional recognition

This course is seeking accreditation by the Institution of Engineering and Technology (IET) on behalf of the Engineering Council for the purposes of fully meeting the academic requirements for registration as a Chartered Engineer. The MSc will meet, in part, the exemplifying academic benchmark requirements for registration as a Chartered Engineer; graduates who have a BEng (Hons) accredited for CEng will be able to show that they have satisfied the further learning requirement for CEng accreditation.

Course structure

Core modules

  • industrial automation
  • control of linear systems
  • advanced control methods
  • robotics
  • applicable artificial intelligence

Options

Choose two from

  • software engineering
  • computer networks
  • project and quality management
  • sustainability, energy and environmental management
  • machine vision
  • digital signals processing
  • manufacturing systems
  • mixed signal design
  • electrical energy systems
  • efficient machines and electromagnetic applications.

MSc

  • project and dissertation

Assessment

  • coursework
  • examination
  • presentation
  • MSc project report

Employability

This course provides you with the knowledge and skills for further advanced study in this area.

You can also apply your skills in an industrial setting for automated manufacturing, control system design, or in the wide range of industries that exploit intelligent robotics. Graduates from this course find career opportunities in areas including • automation and control • process and petrochemical • biomedical • manufacturing • energy • automotive • aerospace.

You can also pursue careers in engineering design and development, engineering research, engineering consultancy and engineering management.

Completing this course combined with further work-based experience enables you to gain Chartered Engineer status.



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We worked with industry professionals to develop an MSc Applied Instrument and Control programme that is accredited by the Institute of Measurement and Control (InstMC). Read more

We worked with industry professionals to develop an MSc Applied Instrument and Control programme that is accredited by the Institute of Measurement and Control (InstMC). It covers both the latest developments in the field and the industry knowledge we've gained through years of experience.

You'll acquire a specialised skillset and expertise that's highly desirable to employers, making you a competitive candidate for rewarding careers in many industries, with oil and gas pathways available. The programme draws on relevant case studies with real-world implications, so you'll gain practical knowledge that you can apply on the job from day one.

The programme also fulfils the Engineering Council's further learning requirements for registration as a Chartered Engineer.

  • Gain a solid foundation in measurement science and control theory
  • Practise data acquisition and instrument networking
  • Study analysis of systems for condition monitoring
  • Investigate fault detection and control system design
  • Complete a hands-on project in the industry for experiential learning

At GCU, you'll find a welcoming community of people like yourself - hardworking, career-focused individuals with the vision and discipline to pursue meaningful work. We'll help you develop the tools to be successful, in your career and in your life.

We hope you'll use those tools to make a positive impact on your community and contribute to the common good through everything you do.

What you will study

The curriculum has been developed in consultation with industry and can be broadly grouped in three areas: the introduction of new facts and concepts in measurement and control; the application of facts and concepts to real measurement problems and systems; and subjects which are of general importance to the professional engineer, for example safety and safety management and management ethics and project planning.

Students complete eight taught modules - four in trimester A and four in trimester B; and a Masters project in trimester C.The MSc project will be carried out at the student's workplace; this can be in an area relevant to the company's production/maintenance function, thus providing maximum benefit to both the company and the individual.

Control Systems

Consolidates advanced classical and modern control design techniques emphasising the practical considerations in applying control design in an industrial environment. The appropriateness and difficulties encountered in applying various design techniques in practice will be explored. In particular system sensitivity, robustness and nonlinearity will be studied.

Data Acquisition and Analysis

Develops the ability to evaluate, in a given situation, the most appropriate strategy for acquiring data and understand the merits of this strategy with respect to other approaches. A range of modern time and frequency domain analysis techniques will also be discussed.

Industrial Case Studies

Following on from the foundation in measurement and instrumentation provided by the Measurement Theory and Devices module, students will now be equipped to study in depth instrumentation in industrial processes. This module will cover aspects of designing sensor systems for industrial measurements, instrument control, system troubleshooting and optimisation in industrial applications.

Distributed Instrumentation

Develops the ability to evaluate, in a given situation, the most appropriate strategy for acquiring and transmitting data and understand the merits of this strategy with respect to other approaches. A wide range of different instrument communication and networking techniques will be studied. In addition the module provides practical experience of hardware setup and software development, relating to these techniques.

Industrial Process Systems

Identification and system modelling from real data play an important role in this module. This approach thus leads to more complex and realistic models that can be used to design more robust and reliable controllers that take into account problematic physical effects such as time-delays and sensor noise. The module will cover more advanced aspects of control design such as feed forward and multivariable control.

Measurement Systems

A range of advanced measurement systems will be studied in depth. Sensors, signal processing, low-level signal measurements, noise-reduction methods and appropriate measurement strategies will be applied to industrial and environmental applications. The influence of environmental factors and operation conditions will be considered in relation to the optimisation of the measurement system.

Measurement Theory and Devices

Adopts a generalised approach to measurement theory and devices, allowing students to become familiar with the characteristics of measurement systems in terms of the underlying principles. In this way, the students will be able to develop a systems approach to problem solving. They should find this methodology to be a considerable benefit to them when they have to apply their expertise to solving more complex industrial measurement problems.

Professional Practice

Develops the students' ability to select, develop and plan an MSc research project, to research and critically analyse the literature associated with the project and to present research findings effectively, it will also provide students with the ability to apply a competent process of thinking to project planning and give them a critical understanding of safe and ethical working.

Accreditation

The programme is accredited by the Institute of Measurement and Control (InstMC) as meeting the Engineering Council’s further learning requirements for registration as a Chartered Engineer.

Graduate prospects

The MSc Applied Instrumentation and Control offers graduates a highly focused skillset that's valuable to an extremely wide range of industries - any business that benefits from the measurement of process variables and environmental factors. For instance, chemicals, pharmaceuticals, optics and optoelectronics, medical instrumentation and more.

Across these industries, you might focus on computer-controlled instrumentation systems, process instrumentation, technical management and sales, process control and automation, sensor development and manufacturing, instrument networking, industrial development or test and measurement systems.

You might also pursue a career with a company that designs and manufactures measurement systems.



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We worked with industry professionals to develop an MSc Applied Instrument and Control programme that is accredited by the Institute of Measurement and Control (InstMC). Read more

We worked with industry professionals to develop an MSc Applied Instrument and Control programme that is accredited by the Institute of Measurement and Control (InstMC). It covers both the latest developments in the field and the industry knowledge we've gained through years of experience.

You'll acquire a specialised skillset and expertise that's highly desirable to employers, making you a competitive candidate for rewarding careers in many industries, with oil and gas pathways available. The programme draws on relevant case studies with real-world implications, so you'll gain practical knowledge that you can apply on the job from day one.

The programme also fulfils the Engineering Council's further learning requirements for registration as a Chartered Engineer.

  • Gain a solid foundation in measurement science and control theory
  • Practise data acquisition and instrument networking
  • Study analysis of systems for condition monitoring
  • Investigate fault detection and control system design
  • Complete a hands-on project in the industry for experiential learning

At GCU, you'll find a welcoming community of people like yourself - hardworking, career-focused individuals with the vision and discipline to pursue meaningful work. We'll help you develop the tools to be successful, in your career and in your life.

We hope you'll use those tools to make a positive impact on your community and contribute to the common good through everything you do.

What you will study

The curriculum has been developed in consultation with industry and can be broadly grouped in three areas: the introduction of new facts and concepts in measurement and control; the application of facts and concepts to real measurement problems and systems; and subjects which are of general importance to the professional engineer, for example safety and safety management and management ethics and project planning.

Students complete eight taught modules - four in trimester A and four in trimester B; and a Masters project in trimester C.The MSc project will be carried out at the student's workplace; this can be in an area relevant to the company's production/maintenance function, thus providing maximum benefit to both the company and the individual.

Control Systems

Consolidates advanced classical and modern control design techniques emphasising the practical considerations in applying control design in an industrial environment. The appropriateness and difficulties encountered in applying various design techniques in practice will be explored. In particular system sensitivity, robustness and nonlinearity will be studied.

Data Acquisition and Analysis

Develops the ability to evaluate, in a given situation, the most appropriate strategy for acquiring data and understand the merits of this strategy with respect to other approaches. A range of modern time and frequency domain analysis techniques will also be discussed.

Industrial Case Studies

Following on from the foundation in measurement and instrumentation provided by the Measurement Theory and Devices module, students will now be equipped to study in depth instrumentation in industrial processes. This module will cover aspects of designing sensor systems for industrial measurements, instrument control, system troubleshooting and optimisation in industrial applications.

Distributed Instrumentation

Develops the ability to evaluate, in a given situation, the most appropriate strategy for acquiring and transmitting data and understand the merits of this strategy with respect to other approaches. A wide range of different instrument communication and networking techniques will be studied. In addition the module provides practical experience of hardware setup and software development, relating to these techniques.

Industrial Process Systems

Identification and system modelling from real data play an important role in this module. This approach thus leads to more complex and realistic models that can be used to design more robust and reliable controllers that take into account problematic physical effects such as time-delays and sensor noise. The module will cover more advanced aspects of control design such as feed forward and multivariable control.

Measurement Systems

A range of advanced measurement systems will be studied in depth. Sensors, signal processing, low-level signal measurements, noise-reduction methods and appropriate measurement strategies will be applied to industrial and environmental applications. The influence of environmental factors and operation conditions will be considered in relation to the optimisation of the measurement system.

Measurement Theory and Devices

Adopts a generalised approach to measurement theory and devices, allowing students to become familiar with the characteristics of measurement systems in terms of the underlying principles. In this way, the students will be able to develop a systems approach to problem solving. They should find this methodology to be a considerable benefit to them when they have to apply their expertise to solving more complex industrial measurement problems.

Professional Practice

Develops the students' ability to select, develop and plan an MSc research project, to research and critically analyse the literature associated with the project and to present research findings effectively, it will also provide students with the ability to apply a competent process of thinking to project planning and give them a critical understanding of safe and ethical working.

Graduate prospects

The MSc Applied Instrumentation and Control offers graduates a highly focused skillset that's valuable to an extremely wide range of industries - any business that benefits from the measurement of process variables and environmental factors. For instance, chemicals, pharmaceuticals, optics and optoelectronics, medical instrumentation and more.

Across these industries, you might focus on computer-controlled instrumentation systems, process instrumentation, technical management and sales, process control and automation, sensor development and manufacturing, instrument networking, industrial development or test and measurement systems.

You might also pursue a career with a company that designs and manufactures measurement systems.



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The Department of Electronic and Electrical Engineering is seeking to appoint an MPhil / MRes student to conduct research for the Eco-Innovation Cheshire and Warrington Industry Collaboration programme. Read more

The Department of Electronic and Electrical Engineering is seeking to appoint an MPhil / MRes student to conduct research for the Eco-Innovation Cheshire and Warrington Industry Collaboration programme. Postgraduate fees are paid by the industrial sponsor for UK/EU students.

This studentship is part funded by the European Regional Development Fund (ERDF).

Background

The sponsor company designs and manufactures energy-efficient control and monitoring systems for the refrigeration industry. With 30 years of industry experience and a focus on energy efficiency and energy reduction, the company delivers direct and indirect energy savings, improved control and greater operational efficiency worldwide.

The proposed innovation adds an exciting new subsystem to optimise and significantly improve the accuracy and efficiency of the refrigeration process. It could be applied in a number of formats worldwide to deliver: lower energy consumption; reduced equipment operation; reduced equipment maintenance and lower costs for retailers. The technology has the potential to save mega-tonnes of carbon and significantly contribute to the UK’s climate change targets by 2030. In this project, you will apply your electronics and electrical engineering skills to: developing a suitable and commercially viable hardware sensor; verifying sensor placement and analysing digital signals.

This is an exciting opportunity to gain skills and experience in the highly-marketable areas of DSP and the Internet of Things.

Summary of research tasks and work programme

1.   Establish and verify a low cost, robust and reliable sensor.

2.   Verify the sensor's ability to detect key signals for use with digital signal processing analysis.

3.   Verify the best position and mount for optimised/accurate data and digital signal analysis.

4.   Verify the sensor can operate in the varying conditions created by the refrigeration process.

5.   Provide a report and evidence of the research and conclusions to the University of Chester and the company.

Skills and knowledge

1.   Knowledge of DSP tools such as MATLAB, Audacity or similar.

2.   Skilled in electronics design for sensor interfaces.

3.   Capability to use DSP tools and build interface circuits to micro processors.

Qualifications:

First degree (2:1 or above) in Electronic and Electrical Engineering, Control Engineering, Manufacturing and Mechanical Engineering or Mathematics (essential).

You will be a motivated and dynamic person, with a demonstrable capability to conduct independent research.

Applicants whose first language is not English must provide evidence of proficiency to IELTS 6.5 with no less than 5.5 in each band or equivalent.

Funding

This studentship attracts a tax exempt stipend of £15,000 per annum. Post graduate fees are funded for UK/EU based students. International students will be required to make an additional contribution to their post graduate fees. The successful applicant will be invited to choose whether to pursue an MPhil or MRes, depending on their career objectives, however minor variations in funding and course structure and duration will apply. Further details on this are available from Dr Andrew McLauchlin +44 (0)1244 512494.

Application process

A completed University of Chester Postgraduate Research Degree (MPhil/MRes) application form including contact details of two referees (at least one must be familiar with your most recent academic work).

Candidates should apply online via the University of Chester website page https://www.chester.ac.uk/research/degrees/studentships and specify their reference number when applying. The reference number is: RA001801

Availability for interview

Shortlisted candidates will be notified soon after the closing date. Interviews will normally be held in the two weeks following the closing date.

Further information

Prospective applicants are encouraged to initially contact Dr Gerard Edwards Tel. 01244 512314 to discuss the project further. For general enquiries contact Postgraduate Research Admissions, University of Chester at

Closing date: 31st January 2018



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Instrumentation and control engineers are highly sought after in a range of industries, including oil and gas, petrochemicals, chemical engineering, manufacturing, research, transport and infrastructure. Read more

Instrumentation and control engineers are highly sought after in a range of industries, including oil and gas, petrochemicals, chemical engineering, manufacturing, research, transport and infrastructure.

Course details

This programme will help you develop your knowledge and skills in instrumentation, electronics and control engineering, and it will help you develop the ability to synthesise information from a variety of sources and make effective decisions on complex instrumentation and control engineering problems.

What you study

For the Postgraduate Diploma (PgDip) award you must successfully complete 120 credits of taught modules. For an MSc award you must successfully complete 120 credits of taught modules and a 60-credit master's research project.

Examples of past MSc research projects:

  • effects of particle size on gas-solid flow measurement using dynamic electrostatic meters
  • an investigation of self-turning and predictive control with MATLAB
  • modelling and control of hot air blow rig PT326
  • wireless controlled car with data acquisition
  • BCD to 6-3-1-1 code converter design using VHDL
  • comparative evaluation of turning techniques for MPC
  • digital traffic signal controller design
  • proteus control board test site
  • design of temperature measurement system
  • control system design for stepping motor.

Course structure

Core modules

  • Digital Control and Implementation
  • Hydrocarbon Production Engineering
  • Identification and Model Predictive Control
  • Project Management and Enterprise
  • Research and Study Skills
  • Robust Control Systems
  • Signal Conditioning and Data Processing

MSc only

  • Major Project

Modules offered may vary.

Teaching

How you learn

You learn through lectures, tutorials and practical sessions. Lectures provide the theoretical underpinning while practical sessions give you the opportunity to put theory into practice, applying your knowledge to specific problems. 

Tutorials and seminars provide a context for interactive learning and allow you to explore relevant topics in depth. In addition to the taught sessions, you undertake a substantive MSc research project.

How you are assessed

Assessment varies from module to module. The assessment methodology could include in-course assignments, design exercises, technical reports, presentations or formal examinations. For your MSc project you prepare a dissertation.

Employability

An instrumentation and control engineer may be involved in designing, developing, installing, managing and maintaining equipment which is used to monitor and control engineering systems, machinery and processes. Graduates can expect to be employed in a wide range of sectors, including industries involved with oil and gas, petrochemicals, chemical engineering, manufacturing, research, transport and infrastructure.



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Our Masters in Electrical and Electronic Engineering is an advanced course designed for engineering graduates to enhance their skills in this area of high technology. Read more
Our Masters in Electrical and Electronic Engineering is an advanced course designed for engineering graduates to enhance their skills in this area of high technology. The ever increasing pace of developments in all areas of electrical and electronic engineering, (and in particular in the systems that are related to energy and the environment), requires engineers with a thorough understanding of operation principles and design methods for various modern electrical and electronic systems. As a graduate you'll be able to not only respond to the latest changes but also to look ahead and help in shaping future developments.

The unique features of this course are that the traditional electrical and electronic engineering subjects are supported by the more modern topics of computer control and machine learning techniques, which are at the forefront of modern electrical and electronic systems in the industry today. This course offers an integrated systems approach to engineering, incorporating modules in advanced power electronics and renewable energy systems, advanced instrumentation and control with signal processing, real-time systems and machine learning techniques.

There is an increasing demand for skilled engineers who are able to design and maintain electrical and electronic systems that are at the forefront of current technologies. These positions cover many industries, hence graduates from this course can expect significantly enhanced job prospects in electrical, electronic as well as systems engineering.

Modules

Digital signal processing
Pattern recognition and machine learning
Advanced Instrumentation and Design
Advanced power electronics and renewable energy systems
Technology evaluation and commercialization
Technical, research and professional skills
MSc engineering project

Professional links

The School has a strong culture of research and extensive research links with industry through consultancy works and Knowledge Transfer Partnerships (KTPs). Teaching content on our courses is closely related to the latest research work.

This course is accredited by the IET as meeting the further learning requirements for CEng registration. The IET is one of the world’s largest engineering institutions with over 167,000 members in 127 countries.

Employability

The acquired skills in computer control and AI techniques offer additional scope for jobs in the design of decision support systems that cross traditional boundaries between engineering and other disciplines. (i.e. medical, finance). Successful graduates will enjoy exciting career opportunities from a wide range of industries, such as electrical energy supply and control, electronics and instrumentation products and services, intelligent systems and automation to include: automotive, aerospace, electrical and electronic consumer products, telecommunications. The students can also pursue PhD studies after completing the course.

Engineering management skills

Engineering employers have expressed their need for engineers with a solid grasp of the business requirements that underpin real engineering projects. Our course incorporates a management-related module focused on entrepreneurship and project management. This management module develops our graduates' commercial awareness and ensures that they have the skill-set valued by industry employers.

LSBU Employability Services

LSBU is committed to supporting you develop your employability and succeed in getting a job after you have graduated. Your qualification will certainly help, but in a competitive market you also need to work on your employability, and on your career search. Our Employability Service will support you in developing your skills, finding a job, interview techniques, work experience or an internship, and will help you assess what you need to do to get the job you want at the end of your course. LSBU offers a comprehensive Employability Service, with a range of initiatives to complement your studies, including:

• Direct engagement from employers who come in to interview and talk to students
• Job Shop and on-campus recruitment agencies to help your job search
• Mentoring and work shadowing schemes.

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This Masters' programme extends the technical knowledge acquired on an undergraduate programme in electrical and electronic engineering. Read more
This Masters' programme extends the technical knowledge acquired on an undergraduate programme in electrical and electronic engineering. This MSc covers a wide range of topics and the programme provides a broad subject-specific curriculum with specialism pursued through a major project. Many of the projects reflect the key research interests of the Faculty, such as embedded systems, electronic manufacturing and control and instrumentation. There is the opportunity for projects to be derived from our industrial links, and a number are proposed by students, reflecting their own 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 electrical and electronic engineering at the professional engineer level

- To enhance specialist knowledge in the area of electrical and electronic 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 the industrial applications and requirements

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

- To develop a comprehensive knowledge of leading-edge ICT tools and techniques

- To provide the ability to progress to the next level of study.

Visit the website http://www2.gre.ac.uk/study/courses/pg/electr/elelec

Engineering - Electrical and Electronic

The Department of Electronic, Electrical & Computer Engineering has a focus on innovation, analysis and development within a wide range of advanced engineering technologies. Students develop an understanding of both hardware and software, enabling them to design electronic and electrical systems capable of meeting the exacting demands of a diverse range of applications.

What you'll study

Research Methodology (15 credits)
Internet Electronics (15 credits)
Real-Time Embedded Systems (15 credits)
Mixed Signal Electronics (15 credits)
Design of Embedded System (15 credits)
Design of Electronic System (15 credits)
Strategy and Management (15 credits)
Multiple Technology Integration (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.

Assessment

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

Career options

Graduates from this programme can pursue careers as electrical and electronic engineers in sectors ranging from communications to control and instrumentation in the process industries.

Find out about the teaching and learning outcomes here - http://www2.gre.ac.uk/__data/assets/pdf_file/0009/643914/MSc-Electrical-and-Electronic-Engineering.pdf

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

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With an ever growing demand for skilled electronic engineers, our course will equip you with the skills and expertise you’ll need to meet the challenges of a constantly changing industrial world. Read more
With an ever growing demand for skilled electronic engineers, our course will equip you with the skills and expertise you’ll need to meet the challenges of a constantly changing industrial world.

Your course will have a new home in Compass House, which will extend our campus along East Road. You’ll have the latest technology at your fingertips and be able to collaborate with other students on innovative projects to hone your skills.

See the website http://www.anglia.ac.uk/study/postgraduate/electronic-and-electrical-engineering

Our course covers a number of contemporary topics, including power electronics, signal processing, renewable systems, holistic modeling of electronic systems and image processing. Building on your previous experience, and with developed practical skills, you’ll leave with the expert knowledge and understanding to practice safely and effectively in a wide range of environments.

Cambridge is home to the Silicon Fen, Europe’s largest high-technology commercial research and development centre. We have excellent, established links with many employers in the sector including:

- ARM Ltd
- British Computer Society
- Cambridge Network
- Cambridge Silicon Radio
- E2V
- Ford Motor Company
- Selex Sensors and Airborne Systems
- South East Essex PCT

Our specially equipped laboratories provide you with the essential tools you need in the field of industrial electronics and microelectronics. Among other features they are equipped with wind and solar energy systems, development boards with FPGA circuits and power electronics modules. You’ll also have access to our CAD laboratories with the very latest software.

This programme is CEng accredited and fulfils the educational requirements for registration as a Chartered Engineer when presented with a CEng accredited Bachelors programme.

See the website http://www.anglia.ac.uk/study/postgraduate/electronic-and-electrical-engineering

Our course is designed to address the challenges of the modern industrial world. It focuses on power electronics, renewable systems, signal processing, holistic modelling of electronic systems and image processing. The main aims of the course are to:
• Meet a local, national and international demand for skilled electronic and electrical engineers.
• Provide an opportunity for students to gain in-depth relevant specialist knowledge in electronics systems design.
• Synthesise formal solutions through the application of specialist knowledge to design and create innovative electronic and electrical circuits.
• Perform and develop objective and critical analysis skills necessary to synthesis effective solutions when presented with a set of specifications.
• Equip you with the appropriate depth in understanding of electronic engineering development tools and techniques.

Upon completion of the course you will be able to:
• Exercise an in-depth understanding of the design mechanisms which can be used to create electronic and electrical designs and critically evaluate their effectiveness.
• Demonstrate an ability to deal with complex and interdependent design issues both systematically and creatively in a sustainability context.
• Analyse and devise strategies to design, evaluate and optimise microelectronics based systems.
• Critically evaluate the tools and techniques required to create microelectronics circuits which satisfy specifications.
• Analyse current research and technical problems within the discipline for further reflection for evaluation and critique.
• Recognise your obligations to function in a professional, moral and ethical way.
• Synthesise original circuit design from a knowledge of current tools, methodologies and strategies.
• Critically survey current and recent practice in the field of electronic and electrical engineering, in a sustainability context, in order to identify examples of best practice and to propose new hypotheses.
• Develop the ability to act autonomously to plan and manage a project through its life cycle, and to reflect on the outcomes.
• Define the goals, parameters and methodology of a research and development activity.

Careers

The possibilities that are open to you range from design or systems engineering, to medical electronics, environmental monitoring, sound technology biophysics or microelectronics. Across industry, whether it’s in process control, construction and building or services, teaching and beyond, there’ll be opportunities to find your own specialist niche.

Core modules

Sustainable Technologies
DSP Applications and ARM® Technology
Digital Systems Design with VHDL and FPGAs
Power Conversion Systems
Remote Sensing and the Internet of Things
Research Methods
Major Project

Assessment

You’ll be assessed through exams and written assignments based on case studies and scenarios.

Facilities

Our Department has specialist laboratories for electronics and microelectronics, equipped with wind and solar energy systems, power electronics modules, development boards with FPGA circuits and more. Our laboratories are designed, maintained, and operated by an in-house team of technical experts. Students also benefit from access to a wide range of central computing and media facilities.

We also operate modern electronic Computer Aided Design labs loaded with the latest software that includes Integrated Synthesis Environment Design Suite, Matlab, Simulink and other relevant software.

Your faculty

The Faculty of Science & Technology is one of the largest of five faculties at Anglia Ruskin University. Whether you choose to study with us full- or part-time, on campus or at a distance, there’s an option whatever your level – from a foundation degree, to a BSc, MSc, PhD or professional doctorate.

Whichever course you pick, you’ll gain the theory and practical skills needed to progress with confidence. Join us and you could find yourself learning in the very latest laboratories or on field trips or work placements with well-known and respected companies. You may even have the opportunity to study abroad.

Everything we do in the faculty has a singular purpose: to provide a world-class environment to create, share and advance knowledge in science and technology fields. This is key to all of our futures.

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This course covers all the major disciplines in automation and control. It includes in-depth study of advanced control systems, industrial automation technologies, systems integration, distributed control systems and field bus protocols. Read more
This course covers all the major disciplines in automation and control. It includes in-depth study of advanced control systems, industrial automation technologies, systems integration, distributed control systems and field bus protocols.

The Automation and Control MSc equips engineering graduates with the theory and practical experience to begin a career as a design or development engineer in control and automated systems. It also develops skills in research and knowledge acquisition, which provides the foundation for further study.

You study modern and classic control systems and industrial automation technologies. The course also provides the latest information on systems integration using field buses and distributed control systems. You use industry standard test and measurement equipment and also experimental hardware and software packages relevant to the field of automation and control.

The course comprises a mixture of lectures, tutorials, coursework and practical laboratory classes. Innovative educational techniques equip you with practical design skills and research methodologies. A specialist topic of your choice is developed through an in-depth research project. You will engage with experts with world-wide reputations for high quality research in the field of Electrical Engineering and Control.

The course is delivered by the School of Electrical and Electronic Engineering. Find out from our staff and previous students about the benefits of studying Electrical and Electronic Engineering at Newcastle.

Delivery

You take modules to a total value of 180 credits over three semesters. Taught modules, worth 120 credits, take place during the first and second semesters with exams held in January and May/June. An individual project, worth 60 credits, is undertaken over semesters two and three.

Background reading and design work take place during the second semester. The majority of experimental work and preparation of your dissertation takes place during semester three.

Teaching is delivered in modern lecture theatres equipped with audio visual equipment. Blackboard, a web based Virtual Learning Environment (VLE), supports your taught modules. Practical sessions take place in small groups in world-class laboratories with extensive computing facilities.

Accreditation

The course is accredited by the Institution of Engineering and Technology (IET) and Engineering Council, and therefore provides a good foundation for professional registration.

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On this course you gain the knowledge the skills you need to work as an engineer, building on your existing degree in science or technology. Read more

On this course you gain the knowledge the skills you need to work as an engineer, building on your existing degree in science or technology.

A rewarding career

Engineers apply scientific and technological principles to solve problems in a creative way. It’s a well-paid and rewarding career that is constantly changing with new developments in technology. And with a shortage of electrical and electronic engineers in the UK, your skills will be in demand.

Electrical engineers are at the forefront of many innovations in the way we live and work today. They design, produce and install systems which power and control a range of products and digital communications.

What you study

You can follow your interests to create the right programme of study for you. Initially, you take two modules in engineering principles. Then, with guidance from your course leader, you select from a range of technical modules covering topics including electrical and control engineering and electronic systems.

In addition to your technical modules, you also take an engineering management subject and participate in a multidisciplinary product development project with MSc students from a range of engineering specialisms. You develop an understanding of how engineering projects work and how they relate to the commercial world, as well as becoming part of our engineering community and learning to think like an engineer.

One third of your study will be an individual project and dissertation. You specialise in a technical area of your interest and carry out your own in-depth investigation into a particular problem. Where possible, this will be an industry-related problem.

Expertise

Many of our academic staff are actively involved in research. Examples of recent projects include • developing equipment to monitor the bone mineral density of young children for Sheffield Children's Hospital • developing palm-sized robots to enable firefighters to safely enter and negotiate hazards in burning buildings.

Course structure

Core modules

  • engineering principles
  • electrical and electronic engineering
  • international product development (group project)

Plus one of either

  • project and quality management

or

  • global supply chain and manufacturing strategy.

Options

Your remaining four modules are themed in the following subjects.

You can choose to specialise in one theme or a mix of both:

Electrical and Control Engineering

• electrical energy systems • efficient machines and electromagnetic applications • control of linear systems • industrial automation

Electronic Systems

• digital electronic systems design • mixed signal design • digital signal processing • microprocessor engineering

Assessment

Assessments will be a mix of coursework and exam, depending on the specific module studied.

Employability

You can work in areas such as • global telecommunications • consumer electronics • computer electronics • aerospace • automotive • railway • robotics • general manufacturing • water, gas and electricity supply.

You can specialise in the design of • computers • mobile phones • media streamers • satellite dishes • instrumentation and control systems • aeroplanes • military equipment • cars • electrical energy systems.

Our graduates have developed careers with companies including • BBC • Tata Steel • Emhart Glass • Sony Mobile Communications • Honeywell Control Systems • Motorola • Rolls-Royce • First ScotRail • Siemens • Vodafone.



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We worked with industry professionals to develop an MSc Applied Instrument and Control programme that is accredited by the Institute of Measurement and Control (InstMC). Read more

We worked with industry professionals to develop an MSc Applied Instrument and Control programme that is accredited by the Institute of Measurement and Control (InstMC). It covers both the latest developments in the field and the industry knowledge we've gained through years of experience.

You'll acquire a specialised skillset and expertise that's highly desirable to employers, making you a competitive candidate for rewarding careers in many industries, with oil and gas pathways available. The programme draws on relevant case studies with real-world implications, so you'll gain practical knowledge that you can apply on the job from day one.

The programme also fulfils the Engineering Council's further learning requirements for registration as a Chartered Engineer.

  • Gain a solid foundation in measurement science and control theory
  • Practise data acquisition and instrument networking
  • Study analysis of systems for condition monitoring
  • Investigate fault detection and control system design
  • Complete a hands-on project in the industry for experiential learning

At GCU, you'll find a welcoming community of people like yourself - hardworking, career-focused individuals with the vision and discipline to pursue meaningful work. We'll help you develop the tools to be successful, in your career and in your life.

We hope you'll use those tools to make a positive impact on your community and contribute to the common good through everything you do.

Oil and Gas stream

From shifting economics and environmental policies to the evolving mix of global energy, we understand the growing range of factors that influence change in the oil and gas industries. That's why we draw on our close relationship with industry and cutting-edge research for this suite of pathways within our master's programmes - giving you the academic foundation, practical skills and ethical framework you need to lead and innovate in a complex and ever-transforming field; from operating principles to implementation. You'll understand the importance of efficient and reliable measurement and control, and learn a range of approaches to help you identify and solve complex problems.

What you will study

The curriculum has been developed in consultation with industry and can be broadly grouped in three areas: the introduction of new facts and concepts in measurement and control; the application of facts and concepts to real measurement problems and systems; and subjects which are of general importance to the professional engineer, for example safety and safety management and management ethics and project planning.

A specialist oil and gas industry instrumentation pathway is also available. Oil and gas industries are widely affected by a growing range of factors, including shifting global economics, an evolving global energy mix and environmental issues. The oil and gas industry instrumentation professional must be equipped to understand the principles and implementation of instrumentation, the importance of efficient and reliable measurement and control systems and have a suitably wide perspective of the subject area so that a number of different approaches to a problem can be identified.

Students complete eight taught modules - four in trimester A and four in trimester B; and a Masters project in trimester C.The MSc project will be carried out at the student's workplace; this can be in an area relevant to the company's production/maintenance function, thus providing maximum benefit to both the company and the individual.

Accreditation

The programme is accredited by the Institute of Measurement and Control (InstMC) as meeting the Engineering Council’s further learning requirements for registration as a Chartered Engineer.

Graduate prospects

The MSc Applied Instrumentation and Control offers graduates a highly focused skillset that's valuable to an extremely wide range of industries - any business that benefits from the measurement of process variables and environmental factors. For instance, chemicals, pharmaceuticals, optics and optoelectronics, medical instrumentation and more.

Across these industries, you might focus on computer-controlled instrumentation systems, process instrumentation, technical management and sales, process control and automation, sensor development and manufacturing, instrument networking, industrial development or test and measurement systems.

You might also pursue a career with a company that designs and manufactures measurement systems.



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