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Masters Degrees (Integrated Circuit)

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An MSc-level conversion programme for those with first degrees in numerate disciplines (e.g. Maths, Physics, others with some mathematics to pre-university level should enquire). Read more
An MSc-level conversion programme for those with first degrees in numerate disciplines (e.g. Maths, Physics, others with some mathematics to pre-university level should enquire). The programme targets producing engineers with knowledge and skills required for designing the integrated circuits which lie at the core of the vast array of consumer electronics of today’s world. The demand for people to fill such roles is extremely high, in companies (small and large) covering the range of electronics and ICT products, and integrated circuit design companies that supply them.

Integrated circuits have been powering the information revolution for over 50 years. Continuous innovation has resulted in greater processing power, memory and new devices. This, together with ever reducing manufacturing costs and reliability, has enabled the mass production of integrated circuits for consumer products that are more powerful han the supercomputers of the 1980s. While the fabrication technology advances, there is an increasing need for innovative design which can harness the power of these circuits, while taking into account constraints such as requirements for energy efficiency.

Visit the website https://www.kent.ac.uk/courses/postgraduate/1224/integrated-circuit-design-engineering

About the School of Engineering and Digital Arts

The School of Engineering and Digital Arts successfully combines modern engineering and technology with the exciting field of digital media.

Established over 40 years ago, the School has developed a top-quality teaching and research base, receiving excellent ratings in both research and teaching assessments.

The School undertakes high-quality research that has had significant national and international impact, and our spread of expertise allows us to respond rapidly to new developments. Our 30 academic staff and over 130 postgraduate students and research staff provide an ideal focus to effectively support a high level of research activity. There is a thriving student population studying for postgraduate degrees in a friendly and supportive teaching and research environment.

We have research funding from the Research Councils UK, European research programmes, a number of industrial and commercial companies and government agencies including the Ministry of Defence. Our Electronic Systems Design Centre and Digital Media Hub provide training and consultancy for a wide range of companies. Many of our research projects are collaborative, and we have well-developed links with institutions worldwide.

Course structure

Modules
The following modules are indicative of those offered on this programme. This list is based on the current curriculum and may change year to year in response to new curriculum developments and innovation. Most programmes will require you to study a combination of compulsory and optional modules. You may also have the option to take modules from other programmes so that you may customise your programme and explore other subject areas that interest you.

EL893 - Reconfigurable Architectures (15 credits)
EL894 - Digital Integrated Circuit Design (15 credits)
EL896 - Computer and Microcontroller Architectures (15 credits)
EL897 - Analogue Integrated Circuit Design (15 credits)
EL898 - Electronic Design Automation for IC Design (15 credits)
EL849 - Research Methods & Project Design (30 credits)
EL871 - Digital Signal Processing (DSP) (15 credits)
EL827 - Signal & Communication Theory II (15 credits)
EL890 - MSc Project (60 credits)

Careers

The programme targets producing engineers with the knowledge and skills required for working in the communications industry on programmable hardware, in particular. There is a high demand for people to fill such roles in communications and test & measure equipment vendors, and in many smaller companies developing devices for the internet of things.

Kent has an excellent record for postgraduate employment: over 94% of our postgraduate students who graduated in 2013 found a job or further study opportunity within six months.

We have developed our programmes with a number of industrial organisations, which means that successful students are in a strong position to build a long-term career in this important discipline. You develop the skills and capabilities that employers are looking for, including problem solving, independent thought, report-writing, time management, leadership skills, team-working and good communication.

Building on Kent’s success as the region’s leading institution for student employability, we offer many opportunities for you to gain worthwhile experience and develop the specific skills and aptitudes that employers value.

Find out how to apply here - https://www.kent.ac.uk/courses/postgraduate/apply/

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This MSc course provides integrated circuit (IC) designers with in-depth knowledge of analogue, mixed signal and digital circuits and also experience with both the practical issues of device-level design and system-level performance requirements. Read more
This MSc course provides integrated circuit (IC) designers with in-depth knowledge of analogue, mixed signal and digital circuits and also experience with both the practical issues of device-level design and system-level performance requirements.

A key feature is the course’s balanced approach to both analogue and digital IC design, and its in-depth treatment of high frequency and low power circuits.

Issues related to design for test and CAD algorithms and design automation will be covered, as well as robust design methods, which allow relaxation of performance requirements, yield enhancement and exploitation of state-of-the-art process technology.

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Electrical and Electronic Engineering is characterised by the need for continuing education and training. Today, most Electrical and Electronic Engineers require more than is delivered in a conventional four-year undergraduate programme. Read more
Electrical and Electronic Engineering is characterised by the need for continuing education and training. Today, most Electrical and Electronic Engineers require more than is delivered in a conventional four-year undergraduate programme. The aim of the MEngSc (Electrical and Electronic Engineering) programme is to provide advanced coursework with options for a research element or industrial element, and additional professional development coursework. Students choose from a range of courses in Analogue, Mixed Signal, and RF Integrated Circuit Design, VLSI Architectures, Intelligent Sensors and Wireless Sensor Networks, Wireless Communications, Robotics and Mechatronics, Advanced Power Electronics and Electric Drives, Optoelectronics, Adaptive Signal Processing and Advanced Control. A range of electives for the coursework-only stream includes modules in Computer Architecture, Biomedical Design, Microsystems, Nanoelectronics, Innovation, Commercialisation, and Entrepreneurship

Visit the website: http://www.ucc.ie/en/ckr47/

Course Details

The MEngSc (EEE) has three Streams which include coursework only, coursework with a research project, or coursework with an industrial placement. Students following Stream 1 take course modules to the value of 60 credits and carry out a Minor Research Project to the value of 30 credits. Students following Stream 2 take course modules to the value of 60 credits and carry out an Industrial Placement to the value of 30 credits. Students following Stream 3 take course modules to the value of 90 credits, up to 20 credits of which can be in topics such as business, law, and innovation.

Format

In all Streams, students take five core modules from the following range of courses: Advanced Analogue and Mixed Signal Integrated Circuit Design, Advanced RF Integrated Circuit Design, Advanced VLSI Architectures, Intelligent Sensors and Wireless Sensor Networks, Wireless Communications, Robotics and Mechatronics, Advanced Power Electronics and Electric Drives, Optoelectronics, and Adaptive Signal Processing and Advanced Control. In addition, students following Stream 1 (Research Project) and Stream 2 (Industry Placement) carry out a Research Report. Following successful completion of the coursework and Research Report, students in Streams 1 and 2 carry out a research project or industry placement over the summer months.

Students who choose the coursework-only option, Stream 3, take additional courses in lieu of the project or placement. These can be chosen from a range of electives that includes modules in Computer Architecture, Biomedical Design, Microsystems, Nanoelectronics, Innovation, Commercialisation, and Entrepreneurship.

Assessment

Part I consists of coursework modules and mini-project to the value of 60 credits. These are assessed using a combination of written examinations and continuous assessment. Successful completion of the initial tranche of coursework modules qualifies the student to progress to Part II, the research project, industrial placement, or additional coursework to the value of 30 credits in the cases of Streams 1, 2, and 3, respectively.

Placement and Study Abroad Information

For students following Streams 1 and 2, research projects and industrial placements are normally in Ireland. Where the opportunity arises, a research project or work placement may be carried out outside Ireland.

Careers

MEngSc (Electrical and Electronic Engineering) graduates will have a competitive advantage in the jobs market by virtue of having completed advanced coursework in Electrical and Electronic Engineering and, in the case of Streams 1 and 2, having completed a significant research project or work placement.

How to apply: http://www.ucc.ie/en/study/postgrad/how/

Funding and Scholarships

Information regarding funding and available scholarships can be found here: https://www.ucc.ie/en/cblgradschool/current/fundingandfinance/fundingscholarships/

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The field of microelectronics systems design embodies many of the key skills relating to integrated circuit design and electronic systems engineering. Read more

Course Summary

The field of microelectronics systems design embodies many of the key skills relating to integrated circuit design and electronic systems engineering. This cutting-edge programme examines aspects of system integration and discrete device properties, and is an excellent platform for further research in the Nano group and the Electronics and Electrical Engineering group.

Modules

Semester one: Digital Integrated Circuit Design; Digital System Design; Nanoelectronic Devices; VLSI Systems Design

Semester two: VLSI Design Project; Analogue and Mixed Signal CMOS Design; Automated Software Verification; Nanofabrication and Microscopy; Advanced Wireless Communication Networks and Systems; Medical Electrical and Electronic Technologies; Cryptography; Digital Systems Synthesis; Embedded Processors

Visit our website for further information...



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Bristol, and the surrounding area, hosts a thriving and world-leading semiconductor design industry. Read more
Bristol, and the surrounding area, hosts a thriving and world-leading semiconductor design industry. The Microelectronics group at the University of Bristol has many collaborative links with multinational companies in the microelectronics industry that have identified a shortfall in graduates with the necessary qualifications and professional skills to work in the sector. This programme has been designed to meet this need.

A range of taught subjects cover core topics such as advanced architectures and system design using FPGA and DSP platforms, before progressing into more specialised areas such as digital and analogue ASIC design, integrated sensors and actuators and mixed-signal design. Changes are made periodically to reflect important emerging disciplines, such as electronics for internet of things, bio-medical applications and neuromorphic computing.

The programme offers you the opportunity to learn from experts in micro- and nanoelectronics and computer science, to allow you to start working straight after your degree or continue your studies via a PhD. Special emphasis is put on providing you with a range of contemporary design skills to supplement theoretical knowledge. Lectures are accompanied by lab exercises in state-of-the-art industrial EDA software to give you experience of a professional environment.

Programme structure

The course consists of 120 credits of taught units and an individual research project worth 60 credits. The following core subjects, each worth 10 credit points (100 learning hours), are taken over autumn and spring:
-Design Verification
-Analogue Integrated Circuit Design
-Integrated Circuit Electronics
-Digital Filters and Spectral Analysis (M)
-Advanced DSP & FPGA Implementation
-VLSI Design M
-Embedded and Real-Time Systems
-Wireless Networking and Sensing in e-Healthcare

Additionally students are able to choose any two out of the following four 10-credit units (some combinations may not be possible due to timetabling constraints).

-Device Interconnect - Principles and Practice
-Advanced Computer Architecture
-Sustainability, Technology and Business
-Computational Neuroscience
-Bio Sensors

In the spring term, students also take Engineering Research Skills, a 20-credit unit designed to introduce the fundamental skills necessary to carry out the MSc project.

After completing the taught units satisfactorily, all students undertake a final project which involves researching, planning and implementing a major piece of work relating to microelectronics systems design. The project must have a significant scientific or technical component and may involve on-site collaboration with an industrial partner. The thesis is normally submitted by the end of September.

The programme structure is under continual discussion with the National Microelectronics Institute and our industrial advisory board in order that it remains at the cutting edge of the semiconductor industry. It is therefore subject to small changes on an ongoing basis to generally improve the programme and recognise important emerging disciplines.

Careers

This course gives graduating students the background to go on to a career in a variety of disciplines in the IT sector, due to the core and specialist units that cover key foundational concepts as well as advanced topics related to hardware design, programming and embedded systems and system-level integration.

Typical careers are in soft fabrication facilities and design houses in the semiconductor industry, electronic-design automation tool vendors, embedded systems specialists and software houses. The course also covers concepts and technologies related to emerging paradigms such as neuromorphic computing and the Internet of Things and prepares you for a career in academic research.

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This MSc programme will develop your knowledge and skills to an advanced level in key aspects of telecommunications and wireless systems. Read more
This MSc programme will develop your knowledge and skills to an advanced level in key aspects of telecommunications and wireless systems.

The course content is updated annually to maintain industry relevance and to reflect the latest developments in the industry.

This programme can be studied full- or parttime. The first two sections consist of lectures, laboratory classes and seminars, with a final section devoted to an individually supervised project.

You will study the following core (compulsory) topics during the MSc:

- Wireless systems and designs
- Communication networks and security
- Research skills and management
- Signal processing
- Cellular radio communications systems related topics.

In addition you can choose from the following options to take account of your interests:

- Optical fibre systems
- Radio propagation and antennas
- Communication signal processing
- Neural networks
- Integrated circuit design.

Part-time study is in co-operation with the students’ employers. Please contact the Programme Director before applying.

Projects

Your project work will earn you 75 credits towards your MSc degree. This includes 15 credits allocated to course work relating to report-writing skills. The project's examined by dissertation.

In your work you'll need to demonstrate an in-depth understanding of your topic, mastery of research techniques, and the ability to analyse assembled data and assess outcomes.

Why Electrical Engineering and Electronics?

World-class facilities, including top industry standard laboratories

We have specialist facilities for processing semiconductor devices, optical imaging spectroscopy and sensing, technological plasmas, equipment for testing switch gear, specialist robot laboratories, clean room laboratories, e-automation, RF Engineering, bio-nano engineering labs and excellent mechanical and electrical workshops.

A leading centre for electrical and electronic engineering expertise

We are closely involved with over 50 prominent companies and research organisations worldwide, many of which not only fund and collaborate with us but also make a vital contribution to developing our students.

Career prospects

Our postgraduate students get to be a part of the cutting edge research projects being undertaken by our academic staff.

Here are some of the areas these projects cover:-

Molecular and semiconductor integrated circuit electronics
Technological plasmas
Communications
Digital signal processing
Optoelectronics
Nanotechnology
Robotics
Free electron lasers
Power electronics
Energy efficient systems
E-Automation
Intelligence engineering.

You'll get plenty of industry exposure too. Our industrial partners include ARM Holdings Plc, a top 200 UK company that specialises in microprocessor design and development.

As a result our postgraduates have an impressive record of securing employment after graduation in a wide range of careers not limited to engineering.

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

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

Program outcomes

After completing the program, students will be able to:

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

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

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

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

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

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

Plan of study

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

Microelectronics

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

Microlithography

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

Manufacturing

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

Internship

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

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

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

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This programme is suitable for recent graduates and engineers with experience of microelectronics who have good mathematical ability. Read more
This programme is suitable for recent graduates and engineers with experience of microelectronics who have good mathematical ability. It provides a thorough knowledge of the principles and techniques of this exciting field and has been developed in consultation with industry advisors to ensure it is relevant to today’s workplace.

Modules are block taught so can also be studied separately by working engineers as continuous professional development either to enhance their knowledge in particular subject fields or to widen their portfolio.

Core study areas include ASIC engineering, sensors and actuators, technology and verification of VLSI systems, embedded software development and an individual project.

Optional study areas include communication networks, information theory and coding, solar power, wind power, systems architecture, advanced FPGAs, DSP for software radio, advanced photovoltaics, mobile network technologies and advanced applications.

See the website http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/electronic-electrical-engineering/

Programme modules

Compulsory Modules:
• ASIC Engineering
• Sensors and Actuators for Control
• Embedded Software Development
• Individual Project

Optional Modules (Choose five):
• Communication Networks
• Fundamentals of Digital Signal Processing
• Solar Power 1
• Wind Power 1
• Communications Channels
• DSP for Software Radio
• Imagineering
• Mobile Networks
• Advanced FPGAs
• Engineering Applications
• Systems Modelling for Control Engineering – new for 2015
• Radio Frequency and Microwave Integrated Circuit Design – new for 2015

Block-taught, individual modules are also highly suitable as CPD for professional engineers needing to fill a skills gap.

How you will learn

Compulsory modules provide a comprehensive understanding of modern microelectronics, embedded electronic systems, emerging technologies and their uses while the individual research project offers the chance to pursue a specialism in-depth. You’ll have access to advanced research knowledge and state of the art laboratories using industry standard software (Altera, Cadence, Mentor, Xilinx) so that you are prepared to enter a wide range of industry sectors on graduation.

- Assessment
Examinations are held in January and May, with coursework and group work assessments throughout the programme. The high practical content of this course is reflected in the inclusion of laboratory assessments and practical examinations. The individual research project is assessed by written report and viva voce in September.

Facilities

You’ll have access to laboratories, industry standard software (Altera, Cadence, Mentor Graphics, Xilinx) and hardware including equipment provided by Texas Instruments.

Careers and further study

Consultation with industry to craft the syllabus ensures that you’ll have an advantage in the job market. The in-depth knowledge acquired can be applied wherever embedded electronic systems are found including mobile phones (4/5G), acoustics, defence, medical instrumentation, radio and satellite communication and networked systems, control engineering, instrumentation, signal processing and telecommunications engineering.

Scholarships and bursaries

Scholarships and bursaries are available each year for UK/EU and international students who meet the criteria for award.

Why choose electronic, electrical and systems engineering at Loughborough?

We develop and nurture the world’s top engineering talent to meet the challenges of an increasingly complex world. All of our Masters programmes are accredited by one or more of the following professional bodies: the IET, IMechE, InstMC, Royal Aeronautical Society and the Energy Institute.

We carefully integrate our research and education programmes in order to support the technical and commercial needs of society and to extend the boundaries of current knowledge.

Consequently, our graduates are highly sought after by industry and commerce worldwide, and our programmes are consistently ranked as excellent in student surveys, including the National Student Survey, and independent assessments.

- Facilities
Our facilities are flexible and serve to enable our research and teaching as well as modest preproduction testing for industry.
Our extensive laboratories allow you the opportunity to gain crucial practical skills and experience in some of the latest electrical and electronic experimental facilities and using industry standard software.

- Research
We are passionate about our research and continually strive to strengthen and stimulate our portfolio. We have traditionally built our expertise around the themes of communications, energy and systems, critical areas where technology and engineering impact on modern life.

- Career prospects
90% of our graduates were in employment and/or further study six months after graduating. They go on to work with companies such as Accenture, BAE Systems, E.ON, ESB International, Hewlett Packard, Mitsubishi, Renewable Energy Systems Ltd, Rolls Royce and Siemens AG.

Find out how to apply here http://www.lboro.ac.uk/study/postgraduate/programmes/departments/eese/electronic-electrical-engineering/

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Systems in mobile telephones, computers, cars and aircraft are shrinking, with many parts implemented as a single integrated circuit. Read more

Course Summary

Systems in mobile telephones, computers, cars and aircraft are shrinking, with many parts implemented as a single integrated circuit. This course prepares you for the rapidly changing skills required to support this. The focus is on system-on-chip design techniques and extensive practical use of cutting-edge and industry-standard methods. You will be taken through the system-on-chip design process, from concept to implementation.

Modules

Semester one: System-on-Chip Electronic Design Automation; Nanoelectronic Devices; Digital System Design; System-on-Chip Design Techniques

Semester two: SOC Design Project; Automated Software Verification; Analogue and Mixed Signal CMOS Design; Advanced Wireless Communication Networks and Systems; Medical Electrical and Electronic Technologies; Cryptography; Digital Systems Synthesis; Embedded Processors

Visit our website for further information...



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The program covers key areas of professional electronics eningeering systems design, delivery and management, including. - Very Large Scale Integration Algorithms and Systems. Read more

Overview

The program covers key areas of professional electronics eningeering systems design, delivery and management, including:
- Very Large Scale Integration Algorithms and Systems
- High Performance Integrated Circuit Design
- Reconfigured Electronics
- Telecommunications Performance Analysis
- Hetrogeneous Networks, Theory and Practice

See the website http://courses.mq.edu.au/international/postgraduate/master/master-of-engineering

Key benefits

Core skillset capabilities in Engineering obtained in prior studies are enhanced and extended in this robust practical masters degree program.

The currculum takes core competencies in electronics systems design and delivery to a new level, focussing on applied capabilities for project management, systems design and network performance measurement.

Suitable for

This degree is suitable for aspiring professional engineering careers in the high-technology, precision manufacturing, telecommunications, government and academic sectors. Through this program, Macquarie Engineers will be prepared for work in research, manufacturing, product development and production, and in operations roles such as sales, marketing, technology management and support.

Recognition of prior learning

Course Duration
- 2 year program
Bachelor degree in a relevant discipline.

- 1.5 year program
Bachelor degree in a relevant discipline with a relevant major and work experience in a relevant area or portfolio of experience in a relevant area.

- 1 year program
4 year Bachelor degree in a relevant discipline with a relevant major.

- Relevant disciplines
Computing, computer science, engineering, IT, science, technology, electronics or electrical engineering.

- Relevant areas
Engineer.

English language requirements

IELTS of 6.5 overall with minimum 6.0 in each band, or equivalent

All applicants for undergraduate or postgraduate coursework studies at Macquarie University are required to provide evidence of proficiency in English.
For more information see English Language Requirements. http://mq.edu.au/study/international/how_to_apply/english_language_requirements/

You may satisfy the English language requirements if you have completed:
- senior secondary studies equivalent to the NSW HSC
- one year of Australian or comparable tertiary study in a country of qualification

Careers

- Career Opportunities
We have working parnerships with many of the global high-tech comanies neighbouring our campus, which offer valuable internships and work placements for students in this program.

See the website http://courses.mq.edu.au/international/postgraduate/master/master-of-engineering

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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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On this well-established MSc programme you willdevelop advanced knowledge and skills in key aspects of telecommunications and wireless systems. Read more
On this well-established MSc programme you willdevelop advanced knowledge and skills in key aspects of telecommunications and wireless systems.

The course content is updated annually to maintain industry relevance and to reflect the latest developments in the industry.

We cover the following core (compulsory) topics during the MSc:

- Embedded computer systems
- Digital system design
- IC design
- Microprocess systems
- Research skills and project management.

Part-time study is in co-operation with the students’ employers. Please contact the Programme Director before applying.

Projects

Your project work will earn you 60 credits towards your MSc degree. The project's examined by oral presentation and dissertation.

In your work you'll need to demonstrate an in-depth understanding of your topic, mastery of research techniques, and the ability to analyse assembled data and assess outcomes.

Why Electrical Engineering and Electronics?

World-class facilities, including top industry standard laboratories

We have specialist facilities for processing semiconductor devices, optical imaging spectroscopy and sensing, technological plasmas, equipment for testing switch gear, specialist robot laboratories, clean room laboratories, e-automation, RF Engineering, bio-nano engineering labs and excellent mechanical and electrical workshops.

A leading centre for electrical and electronic engineering expertise

We are closely involved with over 50 prominent companies and research organisations worldwide, many of which not only fund and collaborate with us but also make a vital contribution to developing our students.

Career prospects

Our postgraduate students get to be a part of the cutting edge research projects being undertaken by our academic staff.

Here are some of the areas these projects cover:-

Molecular and semiconductor integrated circuit electronics
Technological plasmas
Communications
Digital signal processing
Optoelectronics
Nanotechnology
Robotics
Free electron lasers
Power electronics
Energy efficient systems
E-Automation
Intelligence engineering.

You'll get plenty of industry exposure too. Our industrial partners include ARM Holdings Plc, a top 200 UK company that specialises in microprocessor design and development.

As a result our postgraduates have an impressive record of securing employment after graduation in a wide range of careers not limited to engineering.

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This programme will not have a 2016 intake as the content is being extensively improved. The programme aims to offer a rational, flexibly structured. Read more

NOTE

This programme will not have a 2016 intake as the content is being extensively improved.

OVERVIEW

The programme aims to offer a rational, flexibly structured
and coherent postgraduate study in Automatic Control. While
providing advanced general knowledge in Electronic Engineering, the programme is specifically focussed on nonlinear control principles, measurement instrumentation, simulations and implementation of feedback control.
The programme is designed to provide specific skills for individuals who wish to become a control engineer in manufacturing or research and development in industry sectors, or to pursue a PhD in control engineering.

With a track record of 20 years, the research group Control & Intelligent Control Systems Engineering at the University of Hull has an international reputation for its initiatives in the field of fault diagnostics of dynamic systems. This expertise along with its staff’s teaching experience in control engineering supports the masters programme.

OBJECTIVES

The course will provide students with:
• advanced knowledge of control principles including
multivariable feedback control and nonlinear control
systems,
• essential knowledge of control systems configuration,
algorithm design and evaluation,
• a general knowledge of advanced computer simulation
and measurement instrumentation,
• skills in the software and hardware implementation of
control the latest computer modelling and simulation
techniques,
• research experience in control applications in the
engineering field,
• experience of undertaking a significant relevant
research project

SUBJECTS COVERED

• Multivariable feedback control
• Robotic manipulator control
• Machine vision
• Applied Optoelectronics
• Time Signal Processing and Integrated Circuit Design
• Low Power/Voltage Design and VHDL
• Advanced Digital Systems Design
• Microwave Devices, Techniques and Measurements
• Communication Systems
• Intellectual property rights
• Research skills and project planning

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This programme will not have a 2016 intake as the content is being extensively improved. Microcontrollers are being designed into more and more products e.g. Read more

NOTE

This programme will not have a 2016 intake as the content is being extensively improved.

Overview

Microcontrollers are being designed into more and more products e.g. motor cars, washing machines, mobile phones etc. The fast growing and challenging area of embedded systems requires engineers with hardware and software design capabilities for use in this variety of situations. This advanced programme of study offers a natural progression route for graduates in electrical and electronic engineering, physics, computer science, or related disciplines, and is structured to provide the student with the necessary skills for embedded systems development.

Aims and Objectives

To provide knowledge of electronic systems design based around microcontrollers
To provide the ability to manage new technologies and integrate them into system design
To satisfy the growing demand for engineers with embedded systems experience
To facilitate professional development of the student that will lead to a successful professional career

Distinctive features

MSc in Embedded Systems is for students who wish to study a programme to engage them in system development and design focussing on microcontrollers, both hardware and software. It will provide advanced knowledge in areas essential for this type of design and development, whilst also providing learning in areas closely associated to embedded systems such as control and communications.

Modular structure

The course conforms to the standard University of Hull structure, consisting of two taught semesters (the Diploma stage) followed by a substantial individual project. Core modules are compulsory; choice of optional modules is based on student preferences.

Core:

Advanced Digital Systems Design (Semester 1)
Product Planning and Design Exercise (Semester 1)
Complex Circuits and Systems (Semester 2)
Advanced Discreet Time Signal Processing and Integrated Circuit Design (Semesters 1 and 2)
Dissertation project

Options:

Mobile Radio
Propagation and Antennas
Advanced Control
Radio Frequency and Microwave Devices
Techniques and Measurements
Machine Vision

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There is a significant demand in Engineers trained beyond the Bachelor level. MSc in Electronic Engineering provides a rational, flexibly structured and coherent postgraduate study. Read more

Overview

There is a significant demand in Engineers trained beyond the Bachelor level. MSc in Electronic Engineering provides a rational, flexibly structured and coherent postgraduate study. The students will achieve a profound knowledge base in a wide area of Electronic Engineering. In additions, they will develop wider skills in IT, communication, problem solving, team working and time/task management. As a result, the programme will provide a springboard to a successful career to the mutual benefit of the individual, the economy and society.

Aims and Objectives

To satisfy demand in Engineers trained beyond the Bachelor level;
To provide sound general knowledge in advanced Electronic Engineering;
To present an intellectual challenge to the students
To facilitate professional development of the student that will lead to a successful professional career.

Distinctive features

MSc in Electronic Engineering is for students who wish to study a generic programme which is not biased towards a specialization. It will provide advanced knowledge in a broad range of Electronic Engineering without being focussed on a particular area. The programme is very flexible with a large range of choice options to accommodate candidates’ preferences. The candidates will gain both subject-specific and more generic skills. The programme combines academic depth with current industrial practice in the context of real engineering applications.

Modular structure

The course conforms to the standard University of Hull structure, consisting of two taught semesters (the Diploma stage) followed by a substantial individual project. Core modules are compulsory; choice of optional modules is based on student preferences.

Core:

Product Planning and Design Exercise (Semester 1)
Complex Circuits and Systems (Semester 2)
Dissertation project

Options:

Advanced Digital Systems Design
Advanced Discreet Time Signal Processing and Integrated Circuit Design
Applied Optoelectronics
Advanced Control
Control and Robotics
Machine Vision
Communication Systems
Mobile Radio
Propagation and Antennas
Radio Frequency and Microwave Devices
Techniques and Measurements

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