• University of Leeds Featured Masters Courses
  • Northumbria University Featured Masters Courses
  • University of Edinburgh Featured Masters Courses
  • University of Derby Online Learning Featured Masters Courses
  • Aberystwyth University Featured Masters Courses
  • Jacobs University Bremen gGmbH Featured Masters Courses
  • University of Bristol Featured Masters Courses

Postgrad LIVE! Study Fair

Birmingham | Bristol | Sheffield | Liverpool | Edinburgh

University of London International Programmes Featured Masters Courses
Cass Business School Featured Masters Courses
University of the West of England, Bristol Featured Masters Courses
Southampton Solent University Featured Masters Courses
Teesside University Featured Masters Courses
"industrial" AND "electro…×
0 miles

Masters Degrees (Industrial Electronics)

We have 217 Masters Degrees (Industrial Electronics)

  • "industrial" AND "electronics" ×
  • clear all
Showing 1 to 15 of 217
Order by 
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/

Read less
IN THIS 18-MONTH INTENSIVE PART-TIME PROGRAM YOU WILL GAIN. - Skills and know-how in the latest technologies in instrumentation, process control and industrial automation. Read more
IN THIS 18-MONTH INTENSIVE PART-TIME PROGRAM YOU WILL GAIN:

- Skills and know-how in the latest technologies in instrumentation, process control and industrial automation
- Guidance from industrial automation experts in the field
- Knowledge from the extensive experience of instructors, rather than from the clinical information gained from books and college
- Credibility as the local industrial automation expert in your firm
- Networking contacts in the industry
- Improved career prospects and income
- An Advanced Diploma of Industrial Automation

Next intake starts October 09, 2017. Applications now open; places are limited.

Contact us now to secure your place!

Payment is not required until around 2 to 4 weeks before the start of the program.

The EIT Advanced Diploma of of Industrial Automation is recognized worldwide and has been endorsed by the International Society of Automation (ISA). Please ask us about specific information on accreditation for your location.

OVERVIEW

Gain strong underpinning knowledge and expertise in Industrial Automation covering a wide range of skills ranging from instrumentation, automation and process control, industrial data communications, process plant layout, project and financial management and chemical engineering with a strong practical focus. Industrial Automation is an extremely fast moving area especially compared to the more traditional areas such as electrical and mechanical engineering. The field is diverse and dynamic and offers the opportunity for a well paid and enjoyable career. The aim of the course is to empower you with practical knowledge that will improve your productivity in the area and make you stand out as a leader in industrial automation amongst your peers.

*JOB OUTCOMES, INTERNATIONAL RECOGNITION AND PROFESSIONAL MEMBERSHIP:

A range of global opportunities awaits graduates of the Advanced Diploma of Industrial Automation. Pending full accreditation you may become a full member of Engineers Australia and your qualification will be recognized by Engineers Australia and (through the Dublin Accord) by leading professional associations and societies in Australia, Canada, Ireland, Korea, New Zealand, South Africa, United Kingdom and the United States. The Dublin Accord is an agreement for the international recognition of Engineering Technician qualifications.

For example, current enrolled students can apply for free student membership of Engineers Australia. After graduation, you can apply for membership to become an Engineering Associate, while graduates interested in UK recognition can apply for membership of the Institution of Engineering and Technology (IET) as a Technician Member of the Institution of Engineering and Technology.

This professional recognition greatly improves the global mobility of graduates, and offers you the opportunity of a truly international career.

You will be qualified to find employment as an Engineering Associate in public and private industry including transportation, manufacturing, process, construction, resource, energy and utilities industries. Engineering Associates often work in support of professional engineers or engineering technologists in a team environment. If you prefer to work in the field you may choose to find employment as a site supervisor, senior technician, engineering assistant, or similar.

PROGRAM STRUCTURE

The program is composed of 72 topics within 21 modules. These cover the following seven engineering threads to provide you with maximum practical coverage in the field of industrial automation:

- Instrumentation, Automation and Process Control
- Electrical Engineering
- Electronics
- Industrial Data Communications and Networking
- Mechanical Engineering
- Project Management
- Chemical Engineering

The modules will be completed in the following order:
1. Practical Instrumentation for Automation and Process Control
2. Practical Fundamentals of Chemical Engineering (for Non- Chemical Engineers)
3. Control Valve Sizing, Selection and Maintenance
4. Fundamentals of Process Plant Layout and Piping Design
5. Practical Process Control for Engineers and Technicians
6. Practical Tuning of Industrial Control Loops for Engineers and Technicians
7. Practical Distributed Control Systems (DCS)
8. Practical Programmable Logic Controllers (PLCs) for Automation and Process Control
9. Best Practice in Industrial Data Communications
10. Practical Advanced Process Control for Engineers and Technicians
11. Practical Boiler Control and Instrumentation for Engineers and Technicians
12. Practical Hazardous Areas for Engineers and Technicians
13. Practical Safety Instrumentation and Emergency Shutdown Systems for Process Industries Using IEC 6155 and IEC 61508
14. Practical HAZOPS (Hazard and Operability Studies) for Engineers and Technicians
15. Practical Shielding, EMC/EMI, Noise Reduction, Earthing and Circuit Board Layout of Electronic Systems
16. Practical Wireless Ethernet and TCP/ IP Networking
17. Practical Radio Telemetry Systems for Industry
18. Practical SCADA Systems for Industry
19. Motor Protection, Control and Maintenance Technologies
20. Practical Power Distribution for Engineers and Technicians
21. Practical Project Management for Electrical, Instrumentation and Mechanical Engineers and Technicians

COURSE FEES

EIT provides distance education to students located all around 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. We aim to give you a rapid response regarding course fees that are relevant to your individual circumstances.

We understand that cost is a major consideration before a student begins to study. For a rapid reply to your query regarding course fees and payment options, please contact a Course Advisor in your region via the below button and we will respond within two (2) business days.

Read less
The MSc in Compound Semiconductor Electronics has been designed to provide you with advanced level knowledge and skills in compound semiconductor engineering, fabrication and applications, and to develop related skills, enhancing your engineering competency and employability. Read more
The MSc in Compound Semiconductor Electronics has been designed to provide you with advanced level knowledge and skills in compound semiconductor engineering, fabrication and applications, and to develop related skills, enhancing your engineering competency and employability.

This programme is jointly delivered with the School of Physics and Astronomy and the Institute for Compound Semiconductors (ICS). The ICS is an exciting new development at the cutting edge of compound semiconductor technology. The Institute has been established in partnership with IQE plc, to capitalise on the existing expertise at Cardiff University and to move academic research to a point where it can be introduced reliably and quickly into the production environment. It is unique facility in the UK, and aims to create a global hub for compound semiconductor technology research, development and innovation.

As a student on this programme, you will have the opportunity to undertake a 3-month summer project which will be based either within the Institute for Compound Semiconductors, or in placement with one of our industrial partners. We have strong, long-established industrial links with companies such as National Instruments and Mesuro and are therefore able to offer a portfolio of theoretical, practical, fabrication and applications-centred projects in both academic and industrial placement environments.

Our flexible curriculum contains a robust set of required modules and a number of elective modules which include the latest results, innovations and techniques and are designed to incorporate the most effective teaching and learning techniques.

Upon graduation, you will have the training, skill-sets and hands-on experience you need to succeed in the dynamic and highly competitive fields of compound semiconductors and advanced communications systems. Given the University’s unique position at the forefront of compound semiconductor technology, you will have a distinct advantage when applying for PhD studentships or employment in industry.

Structure

The MSc in Compound Semiconductor Electronics is a two-stage programme delivered over three semesters (autumn, spring, and summer) for a total of 180 credits.

• Stage 1: Autumn/Spring terms (120 credits, taught)

You will undertake required modules totaling 70 credits, covering essential skills.

You will additionally have the choice of 50 credits of optional modules from a total of 100 credits, with each module covering specialist skills.

You must successfully complete the 120 credits of the taught component of the course before you will be permitted to progress to the research project component.

• Stage 2: Summer term (60 credits, dissertation/research project)

The summer semester consists of a single 60 credit research project module of 3 months’ duration. You will be required to produce a research dissertation to the required standard in order to complete this module. Students completing Stages 1 and 2 will qualify for the award of the MSc degree.

Core modules:

High Frequency Device Physics and Design
RF Circuits Design & CAD
RESEARCH STUDY
Management in Industry
Software Tools and Simulation
Compound Semiconductor Fabrication
Compound Semiconductors Research Project

Optional modules:

Commercialising Innovation
Fundamentals of Micro- and Nanotechnology
High Frequency Electronic Materials
HF and RF Engineering
Optoelectronics
Magnetism, Superconductivity and their Applications
Low Dimensional Semiconductor Devices
Quantum Theory of Solids
Compound Semiconductor Application Specific Photonic Integrated Circuits

Teaching

A wide range of teaching styles will be used to deliver the diverse material forming the curriculum.

Lectures can take a variety of forms depending on the subject material being taught. Generally, lectures are used to convey concepts, contextualise research activities in the School and to demonstrate key theoretical, conceptual and mathematical methods.

You will practice and develop critique, reflective, analytical and presentational skills by participating in diverse learning activities such as research group meetings, seminars and open group discussions. At all times you will be encouraged to reflect on what you have learned and how it can be combined with other techniques and concepts to tackle novel problems.

In the practical laboratory sessions, you will put the breadth of your knowledge and skills to use, whether that be using your coding skills to automate a laboratory experiment, designing components for a large piece of equipment or troubleshooting research hardware. The emphasis on the MSc in Compound Semiconductor Electronics is squarely on acquiring and demonstrating practical skills which will be of use in a research environment and hence highly sought-after by employers.

When working on your dissertation you will be allocated a supervisor from among our teaching staff. Dissertation topics are typically chosen from a range of project titles proposed by academic staff, usually in areas of current research interest, although students are encouraged to put forward their own project ideas. Projects may also come forward from potential employers and industrial partners who may be able to offer work-based placements for the duration of the project work.

Assessment

Multiple assessment methods are used in order to enhance learning and accurately reflect your performance on the course. In the required modules, a mixture of problem-based learning, in-lab assessment, written assignment, simulation exercises, written and oral examinations and group-based case study work will be used.

Feedback provided by your MSc Tutor, Module Leaders and for some modules, your fellow students will allow you to make incremental improvements to the development of your core skillset.

The methods used on the optional modules vary depending on the most appropriate assessment method for each module, but typically include written and/or practical assignments together with a written and/or oral examination.

Career prospects

An MSc in Compound Semiconductor Electronics will open up opportunities in the following areas:

• Technical, research, development and engineering positions in industrial compound semiconductors, silicon semiconductors and advanced communication systems;

• Theoretical, experimental and instrumentational doctoral research;

• Numerate, technical, research, development and engineering positions in related scientific fields;

• Physics, mathematics and general science education.

Cardiff University’s unique position at the forefront of compound semiconductor technology will provide you with the opportunity to develop experience and build contacts with a range of leading companies and organisations.

Placements

There will be a number of industrial placements each year for the summer research project module, which will either be hosted at the Institute for Compound Semiconductors or at the industrial partner’s facilities. The number and nature of these projects will vary from year to year and will be assigned based on performance in formal assessments.

Read less
This Masters in Electronics & Electrical Engineering is designed for both new graduates and more established engineers. It covers a broad spectrum of specialist topics with immediate application to industrial problems, from electrical supply through systems control to high-speed electronics. Read more

This Masters in Electronics & Electrical Engineering is designed for both new graduates and more established engineers. It covers a broad spectrum of specialist topics with immediate application to industrial problems, from electrical supply through systems control to high-speed electronics.

Why this programme

  • Electronics and Electrical Engineering at the University of Glasgow is consistently highly ranked recently achieving 1st in Scotland and 4th in the UK (Complete University Guide 2017). It was also ranked 1st in Scotland in the Guardian and Complete University Rankings 2018.
  • If you are an electronics and electrical engineering graduate wanting to improve your skills and knowledge; a graduate of another engineering discipline or physical science and you want to change field; looking for a well rounded postgraduate qualification in electronics and electrical engineering to enhance your career prospects, this programme is designed for you.
  • The MSc in Electronics and Electrical Engineering includes lectures on "Nanofabrication", "Micro- and Nanotechnology", "Optical Communications" and "Microwave and Millimetre Wave Circuit Design", "Analogue CMOS circuit design", VLSI Design and CAD", all research areas undertaken in the James Watt Nanofabrication Centre.
  • This programme has a September and January intake*.

         *For suitably qualified candidates.

Programme structure

Modes of delivery of the MSc in Electronics and Electrical Engineering include lectures, seminars and tutorials and allow students the opportunity to take part in lab, project and team work. 

You will undertake a project where you will apply your newly learned skills and show to future employers that you have been working on cutting-edge projects relevant to the industry.

Courses include (six normally chosen)

  • Bioelectronics
  • Computer communications
  • Control
  • Digital signal processing
  • Electrical energy systems
  • Energy conversion systems 
  • Micro- and nano-technology
  • Microwave electronic and optoelectronic devices
  • Microwave and millimetre wave circuit design
  • Optical communications
  • Power electronics and drives
  • Real-time embedded programming
  • VLSI design
  • MSc project.

Career prospects

Career opportunities include chip design, embedded system design, telecommunications, video systems, automation and control, aerospace, software development, development of PC peripherals and FPGA programming, defence, services for the heavy industries, for example electricity generation equipment and renewables plant, etc.



Read less
The control and conversion of electric power using solid-state techniques are now commonplace in both the domestic and industrial environments. Read more
The control and conversion of electric power using solid-state techniques are now commonplace in both the domestic and industrial environments. A knowledge and understanding of the diverse disciplines encompassed by Power Electronics: devices, converters, control theory and motor drive systems, is now essential to all power engineers. Power electronics, driven by the need for greater energy efficiency and more accurate control of a wide range of systems, is developing rapidly.

This course aims to provide specialist education in power electronics and drive techniques, covering key fundamental principles along with modern applications and current practices. It provides a specialist education in power electronics and drives techniques, covering key fundamental principles along with modern applications and current practices.

Students will develop:

the analytical and critical powers for the development of hardware and software required for power electronics and drives
the ability to plan and undertake an individual project
interpersonal, communication and professional skills
the ability to communicate ideas effectively in written reports
the technical skills to equip them for a leading career in power electronics or electrical machine drive systems
an understanding of how power electronics are applied within key industries such as aerospace and power supply

Following the successful completion of the taught modules, an individual research project is undertaken during the summer term.

Previous research projects on this course have included:

Development of a microprocessor controlled variable speed permanent magnet motor for an aerospace application
Experimental determination of induction motor torque-speed curves under variable speed
Evaluation of stray reactance in a current source rectifier for marine propulsion motor drives and wind power generators
Design, build and testing of a DSP-controlled switched reluctance motor for an automotive power assisted steering application

Scholarship information can be found at http://www.nottingham.ac.uk/graduateschool/funding/index.aspx

Read less
Electronics and information technology are vital for global industries to function, and career opportunities continue to increase in the sector. Read more
Electronics and information technology are vital for global industries to function, and career opportunities continue to increase in the sector. This course will develop your ability to manage new technologies and ensure high levels of product quality. It is ideal if you want a career in the electronics or IT industry, or if you already work in the engineering industry and want to enhance your potential.

With this flexible Masters programme, you can tailor your qualification to suit your individual needs and build on your existing studies and experience. The course includes a 15-week project, which you may conduct in industry* and could lead to job opportunities when you graduate. You will work on industrial case studies and be involved in ‘live’ mini-projects. If you study part-time and continue working in the electronics industry, you may be able to relate your major project to an aspect of your company’s work.

*Subject to a suitable placement being obtained by the student and an appropriate project being agreed between the company and the University.

See the website http://courses.southwales.ac.uk/courses/415-msc-electronics-and-information-technology

What you will study

Modules include Product Management and ICS, and a Major Project.

You will then select the rest of your study programme in discussion with the scheme manager. At least three of the modules selected must be from the area of electronics.

Learning and teaching methods

The course is delivered in three major blocks to offer an intensive but flexible learning pattern, with two start points each year – February and September. There are six taught modules and a 15-week major project. If you study part-time, you will complete three modules in year one and three in year two. Year three will consist of the Major Project.

Work Experience and Employment Prospects

On graduation from this course, there are many exciting engineering and management careers open to you. These range from design and development of the latest electronic products, to the application of information technology to support industrial applications.

Assessment methods

Typically, each module will be assessed through 50% coursework and 50% tests in class.

Facilities

In addition to providing dedicated Mac and PC labs, we have specialist facilities for the whole range of courses. We’ve recently opened a Calypto lab, which has software licences and support for the Catapult C toolset. This is used to develop advanced electronic products, such as the next generation of smart phones, more quickly and cost-effectively and to help engineers overcome design challenges in the increasingly complex world of board and chip design. The lab is sponsored by Calypto Design Systems Inc, a leader in electronic design automation. We are one of only four UK universities and 60 universities globally that have been granted permission to use the software, worth £1.9m.

The Faculty’s new Renesas Embedded Systems lab comprises 25 new high-end terminals running cuttingedge tools. The facility was designed in collaboration with Renesas, the world’s leading supplier of microcontrollers, whose sponsorship helps ensure that students are always working with the latest technologies and development tools.

Read less
The programme is co-organised by Vrije Universiteit Brussel (VUB) and Universite Libre de Bruxelles (ULB), offering students the possibility to obtain a double master's degree at the end of the programme. Read more

About the programme

The programme is co-organised by Vrije Universiteit Brussel (VUB) and Universite Libre de Bruxelles (ULB), offering students the possibility to obtain a double master's degree at the end of the programme. The first year of courses is taught at the ULB Engineering Campus in Brussels, while the second year is taught at VUB.

This Master offers:

- A broad scientific and profound practical knowledge of technology, with attention to the social, moral, juridical, economical and environmental aspects of their activities.
- A profound knowledge of electronic circuits and systems knowledge of telecommunications and computer-controlled systems.
- Basic knowledge of information theory, treatments of signals and images, multimedia and photonics.
- A profound knowledge of modeling, systemidentification, electric and electronic
measurements and industrial control.
- Basic knowledge of economics and management informatics and software
engineering.

Learning outcomes:

- The students are ready for an international career with English as working language.
- They are prepared to take responsibilties, can withstand stress, can act individually but can also function in a group.
- They are intellectually mobile and curious, they can act upon necessary evolutions, they are prepared for life-long learning, especially in their own field of specialization.
- Scientific knowledge in their own field
- The students already have some experience in conducting research and can consequently contribute to technological and/or scientific innovations.
- They have a profound and active knowledge of the theory and applications of electronics and information technology.

Student profile

Are you interested in electronics and information technology?
Are you looking for a balance between a rigorous scientific and technical formation and practical skills, with emphasis on independence, creativity and inventiveness?
Are you interested in specialising in electronics and information technology engineering while maintaining a broad-based education by balancing the specialisation with more general subjects?
Are you looking for an academic programme closely linked to scientific research?

Curriculum

Available on http://www.vub.ac.be/en/study/electronics-and-information-technology-engineering/programme

The standard track in the Master of Science in Electronics and Information Technology Engineering (120 ECTS) consists out of 5 modules:
1) Common compulsory courses (47 ECTS)
2) Compulsory/Elective courses in year 1 (13 ECTS)
3) One compulsory, masterspecific option package (1 set to accomplish out of 3 sets provided, 24 ECTS each)
4) Free elective courses and/or an internship (12 ECTS)
5) Master Thesis Electronics and IT-Engineering (24 ECTS)

Each of the modules should be succesfully completed to obtain the master degree. The student should respect the specified registration requirements. The educational board strongly suggests the student to follow the standard learning track. Only this model track can guarantee a timeschedule without overlaps of the compulsory course units.

Read less
What is the Master in Electronics and ICT Engineering Technology all about?. In this master's programme you learn to correctly assess the workings and impact of various electronic technologies. Read more

What is the Master in Electronics and ICT Engineering Technology all about?

In this master's programme you learn to correctly assess the workings and impact of various electronic technologies. You learn to design and implement existing analogue and digital electronic systems and leverage this knowledge to complex information and communication systems.

Intelligent Electronics option

Intelligent Electronics refers to the combination of hardware and software used to develop and implement so-called embedded systems (cell phones, MP3 players, digital cameras, etc.). You learn to take into consideration limitations in the areas of I/O possibilities, memory, speed and energy consumption.

Internet Computing option

Internet Computing follows the trend of a more broadly distributed approach to developing computer applications. The advantages to this are high reliability, scalability, high performance, easy maintenance, low cost price, etc. Examples of applications based on this approach include web-based and internet applications like search robots and voice-over IP, as well as e-commerce, enterprise resource management, and user applications in the area of info-/edu-/entertainment.

Add an in-company or project-based learning experience to your master's programme

You can augment your master's programme with the Postgraduate Programme Innovation and Entrepreneurship in Engineering. This programme is made up by a multifaceted learning experience in and with a company, with an innovative engineering challenge as the central assignment. It is carried out in a team setting, has a distinct international dimension, and usually requires a multidisciplinary approach. Entrepreneurs and students alike are encouraged to innovate, transfer knowledge and grow. It is a unique cross-fertilisation between company and classroom.

International Campus Group T

The Faculty of Engineering Technology maintains close ties with universities around the world. At Campus Group T, more than 20% of the engineering students are international students. They represent 65 different nationalities from all over the world. This international network extends not just to Europe, but also to China, Southeast Asia, India, Ethiopia and beyond.

Campus Group T is the only campus of the faculty who offers all the degree programmes in the business language par excellence: English. The language is ubiquitous both inside and outside the classroom. If you've mastered English, you feel right at home. And if you want to explore more of the world, you can do part of your training at a university outside Belgium as an exchange student.

Objectives

This master's programme brings students to the advanced level of knowledge and skills that is associated with scientific work in the broad sense, and more particularly to those areas of the engineering sciences that are related to electronics and IT/communications systems. This programme offers a broad academic training in the analysis, modelling and design of electronics and IT systems. The Electronics major focuses on the hardware of digital and analog systems. In the IT major, the emphasis is on computer systems, application software and communication networks.

Degree holders are able to apply the acquired scientific knowledge autonomously and in a broad social context. They possess the necessary organisational skills to hold executive positions.

Career paths

On completion of the programme, you will be an industrial engineer with a broad foundation of general skills and technical knowledge. At the same time, you will be familiar with the fascinating world of information processing, which plays a crucial role in many social sectors. Often, you will also play a key role in the development of a variety of digital media applications ranging from modern consumer products (positioning and navigation systems; smartphones; digital audio and video) to custom stand-alone or networked applications.



Read less
Please click here to view website www.itim.unige.it/mipet. Read more
Please click here to view website http://www.itim.unige.it/mipet

MIPET (Master in Industrial Plant Engineering and Technologies) is a One-year Degree Program organized in Genoa University and focusing on preparing new generations of top quality technical experts for Process Engineering, Industrial Plant Main Contractors, Power & Energy Industry, Iron & Steel Sector, Plant Equipment Suppliers as well as Construction Companies.

MIPET main aim it is to satisfy the expectation from Leading Industries in term of high technical skills and excellence capabilities in Industrial Plants and Engineering. The Master Program is directed by Polytechnic School - Faculty of Engineering in strong cooperation with leading industries and major companies operating in these industrial sectors; this approach guarantees the relevance and effectiveness of the initiative in the international scenario.

In fact this project is part of a large initiative devoted to develop excellence in Industrial Plant Engineering through the synergy between the expertise of Genoa University Engineering Faculty and Top Level Companies with long traditions that are leading this Area Nationally and Internationally in term of turnovers, size, processes and products complexity as well as know how and technical background and skills.
MIPET is devoted to create System and Process Engineers, Technical Coordinators operating effectively in Project Teams in Global Engineering and Construction. This Master provides deep technical skills in Industrial Plants as well as the capability to get the whole overview on the project and its technical aspects along the whole project phases: Offering, Engineering, Purchasing, Construction and Erection and Commissioning.

At the completion of the Master Program students develop transversal capabilities in all the critical areas (mechanics, high power, electronics , automation, computation, management, security and safety, materials, processes and components) combined with their specialization expertise in specific Plant Sectors (i.e. Power Equipment, Iron & Steel) as well as with the Company Internship Experiences.

More details can be found here: http://www.itim.unige.it/mipet

Read less
This new conversion masters programme builds on the strengths of the Queen Mary University School of Electronic Engineering and Computer Science. Read more
This new conversion masters programme builds on the strengths of the Queen Mary University School of Electronic Engineering and Computer Science. These strengths include world-leading research in: networks, antenna design and electromagnetics, computer vision and computer theory. This conversion masters programme features a common first semester of: analogue electronics, digital systems design (incorporating an on-line pre-sessional module in digital circuit design), control systems, embedded systems (incorporating C programming). In the second semester the electronic engineering stream features choices from: advanced control systems, critical systems, integrated circuit design, real-time DSP, while the electrical engineering stream features choices from: bioelectricity, microwave and millimeterwave communication systems, power electronics, and electrical power engineering. Both streams have a Project / industrial project during the 3rd (summer) semester.

Industrial Experience

The industrial placement currently takes place towards the end of the first year for a maximum of 12 months. It is the student’s responsibility to secure their placement, the school will offer guidance and support in finding and securing the placement but the onus is on the student to secure the job and arrange the details of the placement.

Currently if you are not able to secure a placement by the end of your second semester we will transfer you onto the 1 year FT taught programme without the Industrial Experience, this change would also be applied to any visa if you were here on a student visa.

The industrial placement consists of 8-12 months spent working with an appropriate employer in a role that relates directly to your field of study. The placement is currently undertaken between the taught component and the project. This will provide you with the opportunity to apply the key technical knowledge and skills that you have learnt in your taught modules, and will enable you to gain a better understanding of your own abilities, aptitudes, attitudes and employment potential. The module is only open to students enrolled on a programme of study with integrated placement.

If you do not secure a placement you will be transferred onto the 1 year FT programme.

Read less
The University Master's Degree in Industrial Engineering (MEI) qualifies graduates to work as industrial engineers. The programme is divided into 120 ECTS credits. Read more
The University Master's Degree in Industrial Engineering (MEI) qualifies graduates to work as industrial engineers. The programme is divided into 120 ECTS credits. Industrial engineering is a profession with a long tradition and considerable prestige in Spain. The ability of graduates to integrate technology and to design, maintain and manage industrial processes means that they are in high demand on the labour market.

Student Profile

This master's degree is a continuation of the degrees in the field of industrial engineering, specifically the bachelor's degrees in industrial technology engineering, electrical engineering, industrial electronics and automatic control, mechanical engineering, chemical engineering and textile engineering.

It is also designed for holders of diplomas in industrial engineering and other engineering qualifications.

The personal and academic characteristics that are considered appropriate for students who want to take this master's degree are the following:
-A technical education and a desire for a career in the field of industry.
-Knowledge of basic materials and industrial technologies.
-The ability to analyse and assess the social and environmental impact of technical solutions.

Career Opportunities

The University Master's Degree in Industrial Engineering enables for professional practice in Spain. Graduates can find work in the following areas:
-Self-employment
-Management of production plants
-Industrial organisation
-Maintenance management
-Resource management
-Research and development
-Teaching

Read less
The Master’s programme in Electronics Engineering focuses on the  design of integrated circuits and System-on-Chip in advanced semiconductor technologies. Read more

The Master’s programme in Electronics Engineering focuses on the  design of integrated circuits and System-on-Chip in advanced semiconductor technologies. This requires a broad spectrum of knowledge and skills across many fields within engineering and science.

The programme provides a competitive education in digital, analogue and radio-frequency (RF) integrated circuits (IC) and System-on-Chip (SoC) design, combined with in-depth knowledge in signal processing, application specific processors, embedded systems design, modern communications systems, and radio transceiver design.

Modern society depends on reliable and efficient electronics. Mobile phones, the Internet, computers and TVs are just a few examples that constantly improve in terms of functionality, performance and cost. In addition, a growing number of concepts and technologies significantly improve areas such as mobile and broadband communication, healthcare, automotive technology, robotics, energy systems management, entertainment, consumer electronics, public safety and security, industrial applications, and much more. This suggests that there will be vast industrial opportunities in the future, and a high demand for skilled engineers with the knowledge and skills required to lead the design of such complex integrated circuits and systems.

World-class research activities

The programme is organised by several strong divisions at the Department of Electrical Engineering and the Department of Computer and Information Science. These divisions, which include more than 60 researchers and 10 internationally recognised professors, have excellent teaching experience, world-class research activities that cover nearly the entire field of integrated electronic design, state-of-the-art laboratories and design environments, and close research collaboration with many companies worldwide.

Design-project courses with the latest software

The programme starts with courses in digital communication, digital integrated circuits, digital system design, analogue integrated circuits, and an introduction to radio electronics, providing a solid base for the continuation of the studies.

Later on, a large selection of courses enables students to choose between two major tracks:

  • System-on-Chip, with a focus on digital System-on-Chip design and embedded systems
  • Analogue/Digital and RF IC design, with a focus on the design of mixed analogue/digital and radio-frequency integrated circuits.

The programme offers several large design-project courses, giving excellent opportunities for students to improve their design skills by using the state-of-the-art circuit and system design environments and the CAD tools used in industry today. For instance, students who take the course VLSI Design will design real chips using standard CMOS technology that will be sent for fabrication, measured and evaluated in a follow-up course. Only a few universities in the world have the know-how and capability to provide such courses.



Read less
The MSc in Electronics with Robotic and Control Systems aims to produce postgraduates with a strong practical skill base that will enable them to model, analyse, design and prototype smart robotic sub-systems. Read more
The MSc in Electronics with Robotic and Control Systems aims to produce postgraduates with a strong practical skill base that will enable them to model, analyse, design and prototype smart robotic sub-systems. Specialist knowledge and practical skillsets will be taught, extensively developed and practiced in the areas of control systems and the analysis, categorisation and design of robotic systems that facilitate movement with multiple degrees of freedom. The knowledge and skillsets taught are key enabling skillsets used to implement devices for applications such as security drones, warehouse robots, medical robots and more humanoid like robots. It is intended that the course will re-focus and enhance existing knowledge in the areas of software engineering, electronic engineering and real-time embedded systems to enable the student to participate in the fast expanding and exciting sector of industrial and consumer robotic systems.

Course structure

Each MSc course consists of three learning modules (40 credits each) plus an individual project (60 credits). Each learning module consists of a short course of lectures and initial hands-on experience. This is followed by a period of independent study supported by a series of tutorials. During this time you complete an Independent Learning Package (ILP). The ILP is matched to the learning outcomes of the module. It can be either a large project or a series of small tasks depending on the needs of each module. Credits for each module are awarded following the submission of a completed ILP and its successful defence in a viva voce examination. This form of assessment develops your communication and personal skills and is highly relevant to the workplace. Overall, each learning module comprises approximately 400 hours of study.

The project counts for one third of the course and involves undertaking a substantial research or product development project. For part-time students, this can be linked to their employment. It is undertaken in two phases. In the first part, the project subject area is researched and a workplan developed. The second part involves the main research and development activity. In all, the project requires approximately 600 hours of work.

Further flexibility is provided within the structure of the courses in that you can study related topic areas by taking modules from other courses as options (pre-requisite knowledge and skills permitting).

Prior to starting your course, you are sent a Course Information and Preparation Pack which provides information to give you a flying start.

MSc Electronics Suite of Courses

The MSc in Electronics has four distinct pathways:
-Robotic and Control Systems
-Embedded Systems
-System-on-Chip Technologies
-Medical Instrumentation

The subject areas covered within the four pathways of the electronic suite of MSc courses offer students an excellent launch pad which will enable the successful graduate to enter into these ever expanding, fast growing and dominant areas. With ever increasing demands from consumers such as portability, increased battery life and greater functionality combined with reductions in cost and shrinking scales of technologies, modern electronic systems are finding ever more application areas.

A vastly expanding application base for electronic systems has led to an explosion in the use of embedded system technologies. Part of this expansion has been led by the introduction of new medical devices and robotic devices entering the main stream consumer market. Industry has also fed the increase in demand particularly within the medical electronics area with the need of more sophisticated user interfaces, demands to reduce equipment costs, demands for greater accessibility of equipment and a demand for ever greater portability of equipment.

The technical tasks undertaken in ILPs, along with the required major project, thoroughly exercise the concepts covered in the course modules and give scope for originality and industry-relevant study. Team-working activities encouraged within modules, along with the all-oral individual examination regimen employed in this Electronics MSc Suite, have proven solidly beneficial in refining the communication and employability-enhancing skills that are strongly valued by industry.

Read less
Our MSc in Electronic Engineering offers content that is different to many other similarly-titled courses. It equips you with a skill set that is in demand by industry worldwide, allowing you to maximise your employability by taking a course that is broad in scope but challenging in detail. Read more

About the course

Our MSc in Electronic Engineering offers content that is different to many other similarly-titled courses. It equips you with a skill set that is in demand by industry worldwide, allowing you to maximise your employability by taking a course that is broad in scope but challenging in detail.

Electronic Engineering provides a broad master’s-level study of some of the most important aspects of electronic engineering today. It builds on your undergraduate knowledge of core aspects of electronics, supported by a module in Engineering Business Environment and Energy Policies, which provides you with an understanding of the context of engineering in the early 21st Century.

The course embraces a number of themes in areas identified as being generally under-represented in many other courses, such as power electronics and electromagnetic compatibility, providing you with as wide a range of employment opportunities as possible – whether this is in industry or continuing in research at university.

The course has achieved accreditation by the Institution of Engineering and Technology (IET) to CEng level for the full five year period.

Reasons to study

• Accredited by the Institution of Engineering and Technology (IET) to CEng level
offering a streamlined route to professional registration

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

• Graduate employability
Our graduates have gone on to work in a variety of specialist roles in diverse industries, including; embedded systems, electronic design and biomedical monitoring

• Access to superb professional facilities
such as general electronics and assembly, digital electronics and microprocessor engineering, power electronics, control systems and communications engineering

• Study a wide range of specialist modules
course content is regularly reviewed and modules have been specifically developed to address skills gaps in the industry

• Academic and research expertise
benefit from teaching by experienced academic and research-based staff, including those from DMU’s dedicated Centre for Electronic and Communications Engineering, who are actively involved in international leadership roles in the sector.Programme

Course Structure

First semester (September to January)

• Digital Signal Processing
• Physics of Semiconductor Devices
• Engineering Business Environment and Energy Policies
• Control and Instrumentation

Second semester (February to May)

• Embedded Systems
• Research Methods
• Electromagnetic Compatibility and Signal Integrity
• Power Electronics

Third semester (June to September)

This is a major research-based individual project

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

Modules are delivered through a mixture of lectures, tutorials and laboratories. The methodology ensures a good balance between theory and practice so that real engineering problems are better understood, using strong theoretical and analytical knowledge translated into practical skills.

Contact and learning hours

You will normally attend 4 hours of timetabled taught sessions each week for each module undertaken during term time, for full time study this would be 16 hours per week during term time. You are expected to undertake around 212 further hours of independent study per 30 credit modules. Alternate study modes and entry points may change the timetabled session available, please contact us for details.

Industry Accreditation

he course is fully accredited by the Institution of Engineering and Technology (IET) which is one of the world’s leading professional societies for the engineering and technology community, with more than 150,000 members in 127 countries.

IET accreditation recognises the high standard of the course and confirms the relevance of its content. In order to achieve IET accreditation the course has had to reach a certain standard in areas such as the course structure, staffing, resourcing, quality assurance, student support and technical depth.

The benefits of an IET accredited course include increased opportunities, being looked on favourably by employers and completing the first step in your journey to achieving professional Chartered Engineer (CEng) status which can be applied for following a period of suitable industrial experience after graduation.

This degree has been accredited by IET under licence from the UK regulator, the Engineering Council. Accreditation is a mark of assurance that the degree meets the standards set by the Engineering Council in the UK Standard for Professional Engineering Competence (UK-SPEC). An accredited degree will provide you with some or all of the underpinning knowledge, understanding and skills for eventual registration as an Incorporated (IEng) or Chartered Engineer (CEng). Some employers recruit preferentially from accredited degrees, and an accredited degree is likely to be recognised by other countries that are signatories to international accords.

Facilities

You will have flexible access to our laboratories and workshops which include: electrical and electronic experimental facilities in general electronics and assembly, digital electronics and microprocessor engineering, power electronics, control systems and communications engineering. Each area is equipped with the latest experimental equipment appropriate to the corresponding areas of study and research. An additional CAD design suite provides access to computing facilities with specialist electronics CAD tools including OrCAD and PSpice. A specialised area incorporating a spacious radio frequency reverberation chamber and Faraday cage allows for experimentation in radio frequency engineering and electromagnetics, while our digital design suite is equipped with the latest 8 and 32-bit embedded microprocessor platforms together with high-speed programmable logic development environments. Power generation and conversion, industrial process control and embedded drives are provided while our communications laboratory is additionally equipped for RF engineering.

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

Read less
This programme develops mathematical modelling skills and provides mathematical techniques required by industry. The period October to June is devoted to lectures, tutorials and practical sessions comprising the core modules. Read more
This programme develops mathematical modelling skills and provides mathematical techniques required by industry.

The period October to June is devoted to lectures, tutorials and practical sessions comprising the core modules.

This is followed by a period of about 14 weeks devoted to an individual project either in an industrial or engineering company or at the University.

Core study areas include mathematical modelling, regular and chaotic dynamics, programming and numerical methods, advanced reliability, availability and maintainability, elements of partial differential equations, static and dynamic optimisation and fluid mechanics.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/mathematics/industrial-maths-modelling/

Programme modules

Compulsory Modules:
Semester 1
- Mathematical Modelling I
- Regular and Chaotic Dynamics
- Programming and Numerical Methods
- Advanced Reliability, Availability and Maintainability

Semester 2
- Mathematical Modelling II
- Elements of Partial Differential Equations
- Static and Dynamic Optimisation
- Fluid Mechanics

Assessment

A combination of written examinations, reports, individual and group projects, and verbal presentations.

Careers and further Study

Graduate employment over a wide range of industries encompassing aerospace, automotive electronics, and computer interests as well as software houses, insurance companies, and research establishments and institutions.

Scholarships and sponsorships

A limited number of scholarships are available for this programme as well as the loyalty bonus scheme which reduces fees for Loughborough graduates.

Why choose mathematics at Loughborough?

Mathematics at Loughborough has a long history of innovation in teaching, and we have a firm research base with strengths in both pure and applied mathematics as well as mathematics education.

The Department comprises more than 34 academic staff, whose work is complemented and underpinned by senior visiting academics, research associates and a large support team.

The programmes on offer reflect our acknowledged strengths in pure and applied research in mathematics, and in some cases represent established collaborative training ventures with industrial partners.

- Mathematics Education Centre (MEC)
The Mathematics Education Centre (MEC) at Loughborough University is an internationally renowned centre of research, teaching, learning and support. It is a key player in many high-profile national initiatives.
With a growing number of academic staff and research students, the MEC provides a vibrant, supportive community with a wealth of experience upon which to draw.
We encourage inquiries from students who are interested in engaging in research into aspects of learning and teaching mathematics at Masters, PhD and Post Doc levels. Career prospects With 100% of our graduates in employment and/or further study six months after graduating, career prospects are excellent. Graduates go on to work with companies such as BAE Systems, Citigroup, Experian, GE Aviation, Mercedes Benz, Nuclear Labs USA and PwC.

- Career prospects
With 100% of our graduates in employment and/or further study six months after graduating, career prospects are excellent. Graduates
go on to work with companies such as BAE Systems, Citigroup, Experian, GE Aviation, Mercedes Benz, Nuclear Labs USA and PwC.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/mathematics/industrial-maths-modelling/

Read less

Show 10 15 30 per page



Cookie Policy    X