Masters Degree in Engineering in Europe

See Masters Programs in Engineering in Europe 2017

Engineering

In order to successfully obtain a Masters qualification, you will need to obtain a number of credits by passing individual modules. Most taught Masters will have a number of core modules which you must take and pass in order to obtain the qualification. The assessment of research Masters is almost always entirely by a single dissertation module or project.

Improvements made to manmade things such as tools, structures and machines are largely due to the efforts of people in the field of engineering. These people combine creativity with mathematics and worldly knowledge, resulting in innovation.

 

Europe is the sixth largest continent and includes 47 countries and assorted dependencies, islands and territories. It is bordered by the Mediterranean Sea to the south, Asia to the east, and the Atlantic Ocean to the West.

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Master Control Systems Engineering

HAN University of Applied Sciences
Campus Full time Part time 16 - 18 months September 2017 Netherlands Arnhem + 1 more

HAN's Masters course in Control Systems Engineering provides you with cutting-edge knowledge and techniques that can be directly used in an industrial [+]

Masters in Engineering in Europe 2017. Applying knowledge to the industrial environment HAN's Masters course in Control Systems Engineering provides you with cutting-edge knowledge and techniques that can be directly used in an industrial environment. Complex processes require advanced control systems. This Masters course focuses on advanced regulating systems used in industry, such as optimal and model predictive control devices and multi-variable non-linear control devices. You also learn about the latest methods of statistical analysis. Upon graduation you will be ready for a specialised career in systems engineering. Cooperation with companies and other universities Associated large industries and specialised companies all acknowledge the constant need for control systems engineers with a Masters qualification. This is reflected in the support given by companies like DNV GL (KEMA), Shell, IPCOS, OMRON, SKF and Tatasteel, who share their knowledge by providing trainers and facilitate many of our major projects and excursions. HAN also cooperates with other institutes and universities, such as Delft University of Technology, Wageningen University, Eindhoven University of Technology and Artemis/Edulab. As a result, teaching and laboratory facilities can be shared and students can benefit from guest lecturers. This also enables the level and content of the course to be continuously monitored. The course is recognised and supported by the Royal Institute of Engineers in the Netherlands. International focus This course is unique in the Netherlands in that it focuses on the translation of skills and knowledge taught at university to the real world. Many of our graduation projects are carried out in association with multinational companies and the course itself has a truly international focus with students from all over the world. Master of Engineering in Control Systems Students completing the course with a graduation project (thesis) will be awarded the title Master of Science which is acknowledged worldwide. Completion of the course curriculum (without thesis) will entitle you to a postgraduate certificate. Full-time or part-time course taught in English The Masters course in Control Systems Engineering is taught entirely in English. You can combine your work and studies by choosing the part-time option. If you opt for studying full-time in the Netherlands, we will help you find a work placement position. Entry Requirements Applicants for this course need a Bachelors degree in Engineering or a related technical discipline, with a GPA of 2.8 or higher based on a 4.0 scale. Sufficient level of English As well as having a Bachelors degree, you will also need to be proficient in English. You will need one of the following: - TOEFL score of 550 or more - IELTS score of 6.0 or more - Cambridge Certificate in Advanced English - Cambridge Certificate of Proficiency in English Mathematics If you have doubts about whether you possess the required level of mathematics, you can work on some extra mathematics modules at home before the course starts. Exemptions If you can demonstrate that you have already covered certain units in the curriculum, you may receive exemption from some of the taught components of the course. All candidates with sufficient academic or field experience may indicate this in their application. [-]

Master Advanced Manufacturing Processes for Aeronautical Structures (AMPAS)

Ecole Des Mines D’Albi-Carmaux | EMAC
Campus Full time 1 year September 2017 France Albi

The Advanced Master course AMPAS, is designed by Mines Albi and ISAE with the support of aeronautical industry partners. [+]

Master Advanced Manufacturing Processes for Aeronautical Structures (AMPAS) A booming industry After a short recession period, the Aeronautical industry market is facing a rapid and continuous increase worldwide as shown by the record breaking contracts recently signed by both Airbus and Boeing. These two industry leaders forecast an increase of close to 5% in activity over the next years and estimations indicate that the annual increase of large commercial airplanes will induce a doubling of the number of aircraft by 2030. Nearly sixty percent of the turnover is subcontracted all over the world and concerns mostly production and manufacturing activities. As a consequence most aeronautical subcontracting companies will have to increase their production rates but also to keep up to date with technological changes; moving from metallic processes toward composite materials processes. Moreover the aircraft manufacturers have changed their supply chain structure in the last years, and subcontractors are now required to manage more complex parts and to take over, on their own, the qualification processes. At the heart of Europes Aerospace Valley The Midi-Pyrénées is home to the global headquarters of Airbus and over 600 subcontracting businesses, employing more than 60,000 employees. The French space agency (CNES), as well as Thales and EADS Astrium are also present in the area along with their lot of subcontractors. The Ecole des Mines d’Albi and Institut Supérieur de l’Aéronautique et de l’Espace (ISAE), have both a proven track record of leading research and working alongside industrial partners in the aeronautics industry. This master program is accredited by the French “Conference des Grandes Ecoles” A formation tailored to the need of the industry The Advanced Master course AMPAS, is designed by Mines Albi and ISAE with the support of aeronautical industry partners. It will give a specialization to master level students allowing them to take over high level responsibilities in airframe structure manufacturing plants. It is especially well suited to students who have followed general studies in mechanical engineering, material science or equivalent and who would like to gain a major chance to be recruited by aeronautical industry. To reach this goal, AMPAS master students will develop: general knowledge of flight dynamics constrains and airframe design knowledge and understanding of the airframe materials and processes and their qualification constrains knowledge, understanding and practice of the prevalent processes for structural applications with either metallic or fiber reinforced thermoset composites materials ability to use state of the art simulation tools for definition and optimization of metallic sheet forming and RTM/infusion process knowledge of the aeronautical supply chain structure and their communication rules understanding of the aeronautic dedicated quality and management requirements knowledge and practice of lean manufacturing tools ability to undertake manufacturing projects in an international team environment ability to communicate with written reports and by oral presentation Lecturers Professoral staff form Ecole des Mines Albi and ISAE (Institut Supérieur de l'Aeronautique) and more generally from University of Toulouse Experts form Aeronautical Insdustry, especially from AIRBUS and supply chain Experts from certification, quality, supply chain organization and management Requirements Applicants must have a Master degree, or an equivalent degree in science or engineering, or a bachelor degree with 3 years of professional experience at least. English Language Requirements IELTS band: 6 TOEFL paper-based test score : 550 TOEFL iBT® test: 79 Contents A balance of theoretical learning and practical experience: The course consists of 75 credits mixing academic teaching and professional experience. First semester: academic term of 450h and 45 credits, provided by permanent professors of Mines Albi and ISAE and expert practitioners from aerospace industry to bring current knowledge and experience. The teaching, balancing academic lessons with more applied practice. Second semester: Professional thesis in the aeronautical industry or in an academic research lab in collaboration with aeronautical industrial partners, in France or abroad. The duration is from 5 to 6 months and corresponds to 30 credits. Students are supervised by a tutor from the host organization and from Mines Albi or ISAE. Thesis is concluded by the preparation of a final report and an oral dissertation in front of a jury. Syllabus The academic course consists of 450 hours of taught modules aiming to provide a deep knowledge of the three main material families used in airframe structures (i.e. aluminum, titanium and long fiber reinforced polymer composites) as well as their related forming routes relevant to aeronautical industries. It is also devoted to gain knowledge in aircraft architecture, on aeronautical supply chain specificities, lean manufacturing and quality management required to be able to take over technical and organizational responsibilities in industry. A team project (100 hours) will demonstrate the ability to address an aeronautical part processing problem following the theoretical and professional skills. In more details: 1. Aircraft, material and process basic scientific knowledge Aircraft General Knowledge Flight Dynamic Structure and Airframe Design Aeronautical materials and processes Aluminium and titanium alloys Epoxy and thermoplastic composites Assembly processes Material and processes qualification NDT and shape control techniques NDT for metallic and composite materials Optical techniques for assembly aid Computer Aided Design 2. Composite structure forming and machining Processes Physical phenomena description and modeling related to epoxy based manufacturing Raw material and composite quality control LCM/RTM processes Autoclave Vacuum Bagging (monolithic - sandwich) processes Composite material trimming, drilling and assembly RTM/Infusion Simulation 3. Metallic structure forming and machining processes Material behaviour and mechanical model Cold and hot sheet forming processes Surface treatments Metallic material machining Sheet forming simulation 4. Industrial Organization and Management Supply chain structure and organization Materials management and Lean manufacturing Supply chain improvement and collaborative processes Quality management and tools 5. Integrated Team Project 6. Internship and Professional Thesis (2nd semester) [-]

Master of Engineering in Real Time, Steering and Supervision

Centrale Nantes
Campus Full time 2 years September 2017 France Nantes

The Master offers two speciality tracks: Real Time embedded systems - embedded computer science and Simulation & Supervision [+]

This Master is internationally recognized and accredited by the French Ministry of Higher Education.

Language of teaching

Courses fully taught in English during the two years.

TRACK: REAL TIME EMBEDDED SYSTEMS - EMBEDDED COMPUTER SCIENCE

The objective of this track is to present the techniques currently used for the design and the verification of embedded systems, and more especially real-time embedded systems. The track relies on several courses covering various topics: the design of real-time systems and the architecture of a real-time operating systems (OSEK/VDX standard is used); the real-time scheduling policies and the associated implementation; tools for the modeling and verification of real-time systems: Petri networks, finite state automata and time automata. ... [-]


Master's Programme in Engineering Mathematics

Mälardalen University
Campus Full time 2 years August 2017 Sweden Eskilstuna

The programme will provide you with broad and deep mathematical knowledge about Mathematics and its applications – knowledge which is highly attractive on the labour market in the industrial and public sectors as well as in society in general. Tomorrow’s technology depends on mathematical methods and calculations and your education in Engineering Mathematics will give you the knowledge and skills you need to actively develop new technology, build a sustainable society and/or run your own successful business. [+]

The programme will provide you with broad and deep mathematical knowledge about Mathematics and its applications – knowledge which is highly attractive on the labour market in the industrial and public sectors as well as in society in general. Tomorrow’s technology depends on mathematical methods and calculations and your education in Engineering Mathematics will give you the knowledge and skills you need to actively develop new technology, build a sustainable society and/or run your own successful business. The Programme The Master’s Programme in Engineering Mathematics prepares you for developing tomorrow’s technologies. You will learn to master mathematical methods and applications in statistics, information technology, computer science, energy and environmental technology, robotics and automatic control technology, optimisation and financial mathematics. The programme’s course offerings are carefully planned yet flexible, and give you both good theoretical knowledge and a well-developed understanding of engineering methods and practices. You will also be able to deepen your knowledge within one or more areas of your choice. Among other options, two project courses are included in the programme, where you can come in direct contact with development and research, maybe in cooperation with a company. Technical and mathematical skills are becoming more and more important in modern research and development, whether it is within typical engineering fields like information technology, communication technology, robotics and medical technology, or other fields such as finance or the health sciences. Employment and Future Prospects After completing the programme, you may have the opportunity to continue as a research student at Mälardalen University or another university in Sweden or abroad. Alternatively, your professional life after completing the programme can, for example, focus on research and development in your own business or at a Swedish or multinational company that uses mathematical or statistical methods, computations and algorithms in their technological solutions. University degree The degree programme is so designed that the studies will lead towards fulfilment of the requirements for the following degree(s): Master of Science (60 credits) in Mathematics/Applied Mathematics Master of Science (120 credits) in Mathematics/Applied Mathematics [-]

International Master In Foundations And Retaining Structures

Zigurat E-Learning | Escuela de Ingenieria y Arquitectura
Online Part time 1 year October 2017 Spain Spain Online

The International Master in Foundations and Retaining Structures proposes, from a practical perspective and hand of reference professionals in the sector, how to deal with the design and calculation of foundations and containment of land from two tours: European and American. [+]

Masters in Engineering in Europe 2017. The International Master in Foundations and Retaining Structures proposes, from a practical perspective and hand of reference professionals in the sector, how to deal with the design and calculation of foundations and containment of land from two tours: European and American. NEW MODULE! earthquake resistant design of foundations and retaining structures The new module allows the participant to understand not only the structural geotechnical aspect of the foundation but also consider the effect of the seismic action on the ground. Why study the Master in Foundations? The International Master in Foundations and Retaining Structures, will enable you to meet the design and calculation of foundations and containment of land from a practical methodology and the hand of the best professionals. The program includes Spanish and American regulations. You will learn working in 10 real projects. VIDEODIÁLOGO GEOTECNIA AND FOUNDATIONS The micropile is a technique that has universal application to be a versatile method to address a lot of problems. America has led the rehabilitation of structures and contracimentación technique approach. [-]

Integrated Master's in Engineering and Management of Information System - Post Labor

University of Minho - School of Engineering
Campus Full time 10 semesters September 2017 Portugal Guimarães

This course provides the technical and scientific capacity to access the courses of the second cycle (Master). [+]

Academic degree: Bachelor (Bologna 1st cycle degree), Master's degree ECTS: 300 Duration: 10 curricular semesters Regime: After Working Hours Place: Azurém Campus, Guimarães Main Scientific area: Information Systems and Technologies INTEGRATED MASTER’S | 5 YEARS NORMAL + POST - LABOUR The role of these engineers is to use the information technologies and its applications for organizations. The main actions of these professionals include organizational interventions related to the adoption of IT management technologies and organizational information systems, engineering work and organizational processes and managing organizational knowledge. Graduates also have technology translation skills that allow them to also engage themselves in building applications or establishing the organization's IT infrastructure. They will also be able to work in any organization, regardless of size or sector of the economy and in management and consulting firms [-]

Master in Quantum Physics for Advanced Materials Engineering

National University of Science and Technology MISiS
Campus Full time 2 years October 2017 Russia Moscow

Master's program "Quantum Physics for Advanced Materials Engineering" is devoted to the study of new physical phenomena in nanostructured materials and quantum devices created or discovered during the last 20-30 years of research for components for quantum electronics. [+]

Masters in Engineering in Europe 2017. The Master's program Quantum Physics for Advanced Materials Engineering is devoted to the study of new physical phenomena discovered in nanostructured materials and quantum devices created last 20-30 years in the search for components for quantum electronics. At the same time the program addresses the basic physical principles of electronic systems and devices of quantum electronics, as well as some important manufacturing techniques and measurements of physical and chemical characteristics of quantum-sized structures and materials. The program is designed for students trained in the amount of university courses in general physics and introduction to theoretical physics for a Bachelors, which includes the courses: theoretical mechanics and the theory of elasticity,electrodynamics, quantum mechanics and statistical physics. The program does not involve a starting special training of students in the condensed matter physics,, because it includes basic courses in: 1) modern quantum physics of solids, 2) electronic theory of metals, 3) technology and materials of quantum electronics, 4) spectroscopic methods of materials characterization. The medium of instruction for this program is English. The urgency and necessity A distinctive feature of this Master’s program is to focus on the study of new physical phenomena in quantum-sized materials and devices, all of which are overlooked in traditional courses of solid state physics. These objects of study appeared in the last 20-30 years due to development of tools and methods of measurement and conversion of properties of materials in the nanometer range of distances. Although the physical phenomena and processes observed in the new materials and nanostructures are described in the framework of well-established fundamental concepts of quantum and classical physics, they could not become an object of study of traditional training courses on condensed matter physics, which were created in the middle of the twentieth century, simply because most of these facilities and adequate measurement tools for their research were not yet developed. The circle of new physical phenomena studied in special courses of this master's program includes the effects of size quantization in low-dimensional structures, in particular: the quantum Hall effect, quantum charge fluctuations, Coulomb blockade and Landauer quantum conductance of the contacts of atomic size, the Wigner-Dyson statistics of electronic energy levels in the nanoclusters, the Rabi oscillations in two-level systems, the spectra of quantum dots, wells and wires in a magnetic field, phonons in fractal structures, Einstein modes in thermoelectric semiconductor materials with complex crystal cell, etc. Developing skills This master's program enables students to orient themselves in the modern scientific and applied research and development of quantum-sized materials and devices through the acquisition of skills in both theoretical calculations in the field of quantum physics of nanosystems as well as experimental measurements using modern equipment in the field of electron and scanning probe microscopy and spectroscopy. Basic Courses 1) Modern quantum physics of solids (1 st semester) introduces into: different aspects of modern solid state physics, including phenomena in the objects of atomic size, including those considered in the following topics: quantum Hall effect, graphene and carbon nanotubes, Landauer quantum conductance of atomic size contacts, quantum magnets (spin chains), magnetism of frustrated systems, magnetic semiconductors, including silicon doped with manganese, colossal magnetoresistance, quantum phase transitions, the low-energy excitations in disordered media and fractal structures, granular conductors, metals with heavy fermions, the Kondo semiconductors, quasicrystals and structurally complex alloys; 2) Electron theory of metals (1 st semester) introduces into: basic methods and results of the electron theory of metals, that are in the focus of the current research of quantum properties of solids and use the concept of Landau quasi-particles and Fermi-liquid theory to describe the properties of normal metals; description of phenomena in superconductors, based on the concept of spontaneous symmetry breaking and Bose-condensation of Cooper pairs in the framework of the theory of Bardeen, Cooper and Schrieffer, with application of the equations of the Ginzburg and Landau; foundations of the Green's functions technique and its applications for prediction and interpretation of experiments involving the scattering of photons, neutrons, muons and measuring the current-voltage characteristics of the tunneling microcontacts; 3) Technologies and Materials of Quantum Electronics (2 nd semester) introduces into: physical properties of basic semiconductor materials and methods of nanotechnology in relation to the creation of the base elements of nanoelectronics, optoelectronics, quantum devices, in particular, including the study of changes in the electrical and optical properties of bulk materials when they are produced in the form of low-dimensional structures (quantum wells, wires and dots) due to the effects of quantum-size effect; with the emphasis on C, Si, solid solutions GeXSi1 -X , compounds and solid solutions А2В6 and A3B5; also considered are basic technologies of manufacturing of quantum-sized structures: liquid phase epitaxy, molecular beam epitaxy, vapor phase epitaxy of organometallic compounds, nanolithography, self-organization of quantum wires and dots; outline of the use of low-dimensional structures in the devices of micro-and nanoelectronics; also considered are emitting diodes and lasers for the infrared, visible and ultraviolet spectral regions, photodetectors and transistors; 4) Spectroscopic methods for analysis of materials (1 st semester) introduces into: the fundamentals of modern spectroscopic methods of analysis of materials, such as Auger electron spectroscopy (AES), X-ray photoelectron spectroscopy (XRF), secondary ion mass spectrometry (SIMS), transmission electron microscopy (TEM), scanning ion microscopy (SIM), i.e. methods that allow us to investigate elemental, chemical composition, atomic structure, structural perfection of the surfaces of solids, surface layers, interphase boundaries and nanostructures. Special Courses familiarize students with basic modern areas of theoretical physics research in nanosystems, in including low-dimensional systems. 1) Quantum electronic properties of nanosystems (3rd semester) introduces into: theory of electronic quantum phenomena in nanosystems: random Hamiltonian matrices of Wigner-Dyson and thermodynamics of nanoclusters, Peierls transitions in quasi one-dimensional conductors, transitions of Ising and Berezinskii Kosterlitz-Thouless in two-dimensional lattice systems, the theory of spin fluctuations in one-dimensional Ising chain, the theory of Landauer quantum conductance of quantum point contact; 2) Physics of liquid-crystal membranes (3rd semester) introduces into: physics of liquid crystals and its applications to the theory of lipid membranes, in particular, into fundamentals of elasticity of liquid crystals adapted to describe bilayer membranes, thermodynamics and kinetics of phase transitions in multicomponent systems, Gibbs phase diagrams and various two-dimensional lattice models; basic theory of wetting, adapted to biomembranes, mechanisms of protein-lipid interactions and conditions of formation of macroscopic wetting films, the dependence of the rate of cellular processes on the energy of forming membrane structures using exo-and endocytosis as example; 3) Physics of Low-Dimensional Systems (2 nd semester) introduces into: low-dimensional systems - quasi-two-dimensional quantum wells, one-dimensional quantum wires and quasi zero-dimensional quantum dots, in particular, with the quantum-mechanical phenomena in such systems and the influence of external electric and magnetic fields, methods of computer modeling and calculations from first principles of parameters of the low-dimensional systems: resonant frequencies, the energy spectra and wave functions of electronic and excitonic systems with carriers incoupled quantum wells and coupled quantum dots; evolution of the spectrum and restructuring of the spin states of molecules consisting of horizontally and vertically coupled quantum dots; 4) Experimental Methods in the physics of low-dimensional systems (2-nd semester) introduces into: methods of experimental studies of transport and magnetic properties of solids, including: galvanomagnetic effects (magnetoresistance, Hall effect, de Haas-van Alphen effect, Shubnikov - de Haas effect), electrodynamics of metals, nuclear magnetic resonance, nuclear gamma resonance; equipment and experimental techniques of measurement of weak signals in the presence of noise, resistance measurement, thermometery, application of high magnetic fields; methods of choice of appropriate measurement technology for research, experimental design, design scheme of the experimental setup, processing and interpretation of the results of the experiment, the course also teaches methods of analysis of surfaces of solids, including: classification of methods of analysis of materials surface, ion-beam probe (inverse Rutherford scattering, channeling, mass spectroscopy of secondary ions), electron-beam probe (characteristic loss spectroscopy, secondary electron emission, Auger spectroscopy), electromagnetic radiation probe, tunneling microscopy; 5) Phase diagrams of multicomponent systems (3rd semester) introduces into: analysis of phase diagrams of multicomponent systems, including applied to real materials and processes based on software packet calculation methods “Thermo-Calc”, as well as the original techniques focused on the use of widespread program EXCEL; methods of solution of the following tasks: analysis of phase composition of multicomponent materials at different temperatures; graphical estimate and calculation of the liquidus, solidus, and other critical temperatures of phase transformations; construction of insulated and polythermal cuts of triple, quadruple and five fingers systems using both graphical and computational methods; calculation of the mass and volume fractions of phases in multicomponent systems, a critical analysis of information on phase diagrams and finding errors in the prediction of phase equilibria in unexplored multicomponent systems. 6) Electronic properties of quantum confined semiconductor heterostructures (2–nd semester) introduces into: physics of low dimensional quantum confined heterostructures, that are the structures where the carrier motion is restricted in one or more directions at the distances of the order of de Broglie wavelength; electron transport and optical transitions in low dimensional electronic systems, and the difference between the electronic properties of low dimensional structures and those of bulk semiconductors; applications of quantum dots and wells in photovoltaics and laser techniques. 7) Introduction to path integral methods in condensed matter physics (2–nd semester)motivation and contents: The idea of the course is to get students acquainted with path integral approach to problems of contemporary condensed matter physics. The aim is to give students firm command of this approach via carefully selected examples and problems. The course contains mathematical digression into complex calculus, the basics of second quantization, field quantization, path integral description of quantum statistical mechanics, finite temperature perturbation theory, theory of linear response, basics of renormalization group analysis and effective field theory. The final project consists of the theoretical description of single electron transistor via effective Ambegaokar-Eckern-Schoen action. Courses in experimental research methods help students to get an idea of materials for prospective elementary base of quantum electronics, as well as on the possibilities of measurement methods: 1) spectroscopy, 2) tunneling microscopy, 3) scanning ion microscopy, 4) the accuracy, sensitivity, locality, and applicability of different measurement methods for the study of nanomaterials. Focus of lecture courses are new materials and modern quantum devices. List of new materials studied in the course of the program includes: 1) graphene and carbon nanotubes 2) quantum magnets - atomic spin chain 3) magnetic semiconductors - silicon doped with manganese; 4) semiconductor materials based on solid solutions of germanium in silicon 5) disordered media and fractal structures – aerogels, granular conductors, 6) heavy fermionic metals, the Kondo semiconductors, 7) quasicrystals and structurally complex thermionic materials based on bismuth telluride. Studied electronic devices and appliances include: 1) tunnel contact of atomic size, 2) magnetic switches on the basis of manganites with colossal magnetoresistance 3) Josephson junctions 4) emitting diodes and lasers for the infrared, visible and ultraviolet, photodetectors, transistors. Studied manufacturing technologies of quantum-sized materials: 1) liquid-phase epitaxy, 2) molecular-beam epitaxy, 3) vapor-phase epitaxy from organometallic compounds, 4) nanolithography, 5) self-organization of quantum wires and dots. Admission Admission to International Master’s Programs at MISiS is open to both Russian and international students. Given that all classes will be conducted in English, we recommend that nonnative speakers of English achieve a TOEFL score of at least 525 (paper based) or 200 (computer based) prior to admission. To apply for a two-year Master’s program at MISiS, the applicant must hold a Bachelor’s degree in a related field. Upon the completion of the program of study at MISiS, the applicant will receive a Russian State diploma and a European Diploma Supplement. Admission Deadline The deadline to submit the application for Fall 2016 is 15 March 2016. [-]

Engineering Degree - taught in FRENCH

ECAM Lyon
Campus Full time 1 - 3 years September 2017 France Lyon

This program is taught in FRENCH. ECAM Lyon provides a multi-disciplinary Engineering programme which combines broad training in science and inter-personal skills. [+]

This program is taught in FRENCH Read the official French description and apply here: ECAM Lyon : Diplôme d'Ingénieur Généraliste [-]

Masters in Textile Materials Engineering - IN FRENCH

ITECH Lyon
Campus Full time 3 years September 2017 France Lyon

ITECH textile manufacturing engineers cover the many upstream industries involved in the making of textile materials, as well as the different application sectors: medical, building and civil engineering, sport equipment, automotive, aeronautical, furnishing and... clothing. [+]

Masters in Engineering in Europe 2017. ITECH textile manufacturing engineers cover the many upstream industries involved in the making of textile materials, as well as the different application sectors: medical, building and civil engineering, sport equipment, automotive, aeronautical, furnishing and... clothing. He/she follows the development of the products, from management to the organisation of production. Admission for Students outside France 1st year admission: Graduate studies in chemistry (Bachelor’s degree or equivalent , 180 ECTS) A satisfying level in French: B2 CERF + interview with ITECH 2nd year admission: 1 year of postgraduate studies completed (M1 or equivalent, 240 ECTS) How to apply? Visit and register at inscription.itech.fr (for EU students) Or Apply through Campus France site (CEF procedures)for non-EU students For countries which do not have CEF procedures with France, you must do an Application for Preliminary Admission (DAP) to the cultural service of the French embassy in your country of residence. Tuition fees Tuition fees for the French Section are 6 500€/year. Hands on training ITECH is adamant in supplying students with a strong professional experience. On top of a multidisciplinary teaching, the institute adds a 10 month minimum of mandatory internships in companies for the regular status students. End of 1st year: International experience - minimum 6 weeks This international experience is prepared in advance in terms of an intercultural approach and the expectations regarding the content of the report are fully defined. This is an individual review of each student’s experience and acts as a basis for reflection during the intercultural lessons the following term. End of 2nd year: Engineering placement - minimum 8 weeks Practical application with privileged trainee status allows students to come face to face with the realities of corporate life and become acquainted with companies’ material, economic and human requirements. End of 3rd year: Final year project - maximum 6 months This is a project generally entrusted to young engineers. Students demonstrate that they are capable of acting autonomously and tackling complex subjects in situations that can, at times, prove complex. The project involves a minimum 5-month placement with a company or laboratory either in France or abroad. The Region Lyon is located in the south-east of France, on the confluence of the Rhône and the Saône Rivers. It stands on a geographical crossroads, to the North of the natural corridor of the Rhône valley (which stretches from Lyon to Marseille). With the Lyon-Saint Exupéry international airport and three TGV high-speed train stations, Lyon is connected to all major European cities and the world! Lyon is only 2 hours by TGV to Paris and 1hr40 to Marseille and the Mediterranean. If it's mountains you prefer, the Alps are a mere 90 minutes away by car, the Massif Central only 30 minutes away. Historically, Lyon is an industrial city and therefore houses many petrochemical industries along the Saône and Rhône Rivers, in the so-called ‘chemistry corridor’. Lyon is also the city with the second largest number of students in France, with three universities and many engineering schools. In terms of its population, it’s the 3rd biggest city in France, with over 470,000 inhabitants, and the second largest agglomeration after Paris (2 million inhabitants). [-]

Master in Wireless Communications Engineering

University of Oulu
Campus Full time 2 years September 2017 Finland Oulu

30 years of groundbreaking research and cooperation with the global telecommunication and electronics companies like Nokia has been the foundation for the programme development at the Department of Communications Engineering (DCE) and Centre for Wireless Communications (CWC). DCE & CWC research unit being in charge of conducting WCE programme consist of ca 130 academics, of which roughly 50% are foreigns coming from ca 20 countries from all main continents. [+]

Master in Wireless Communications Engineering WCE - Wirelessly Yours! 30 years of groundbreaking research and cooperation with the global telecommunication and electronics companies like Nokia has been the foundation for the programme development at the Department of Communications Engineering (DCE) and Centre for Wireless Communications (CWC). DCE & CWC research unit being in charge of conducting WCE programme consist of ca 130 academics, of which roughly 50% are foreigns coming from ca 20 countries from all main continents. Study WCE will help you reach your goals! The programme consists of cutting-edge knowledge and latest developments in the essential areas and topics of wireless communications systems and networks. It will give you relevant skills and core knowledge of the latest methods, tools and technologies combined with time-tested issues such as information theory, advanced wireless communication systems, communication networks, stochastical and digital signal processing, antennas, radio channels, radio engineering, electronics design, and computer engineering. You will possess the essential knowledge on the design of wireless communications networks at the system level. Graduate WCE will give you the professional edge! As a graduate of WCE you will get foundational background in a growing, dynamic field of wireless communications including networking, systems and technologies. The skills gained in the Master’s Degree Programme offer a solid academic training that answers to the demands of wireless communications industry globally. Work WCE will advance your career! You may get the possibility to move forward even during your studies. Centre for Wireless Communications, CWC, provides a number of jobs as a trainee or a master's thesis student, with the possibility to continue as a doctoral student at CWC doctoral study programme at the University of Oulu Graduate School (UniOGS), and even as a post doctoral researcher at CWC. Typically 10-12 master's degree holders from CWC receive Ph.D. degree every year. Programme Outline Studies of wireless communications engineering consist of basic and advanced modules that are obligatory. Besides that a WCE student can choose elective courses from the optional module consisting of 24 courses from the areas of of electrical and computer engineering, as well as Finnish language studies. In addition, obligatory advanced practical training and written Master’s thesis are mandatory parts of WCE studies. Details of course structure are defined as follows: Basic Module (subject studies) Basic module gives all the basic knowledge on digital communications engineering. It contains the sufficient background in information theory, coding, optimization, as well as in wireless systems, communications networks, and radio engineering. After completing this preparation module, the student is, for example, able to design modern wireless communications systems and networks design future mobile communications systems, including network exchanges, base stations and mobile handsets design air-interface modules in detail at a physical algorithm level of OSI model design transceiver’s radio frequency electronics and digital signal processing parts perform system simulations at radio frequency, communication link, and network levels Advanced module (advanced studies) Advanced module on wireless communications engineering extends the skills learned in the basic module. It gives more information on communications networks, radio channels, design of radio systems, and antennas. After completing advanced module, the student is even more capable, for example, in designing modern wideband wireless communications systems (e.g., spread spectrum, CDMA, OFDM, UWB, MIMO, cognitive radios, etc.) designing radio networks and protocols DSP design of transceiver algorithms RF system design and radio link budget analysis of an air-interface designing intelligent antennas for base stations and handsets Optional Module (elective studies) Optional module is constructed from a list of optional courses by a student's choice. Depending on student’s choice, this optional module makes it possible to widen student’s expertise into the fields of practical analog and digital electronics design, RF components, mobile and social computing, signal processors, video and biomedical signal processing, machine vision, and several traditional computer science and engineering courses lectured in English. In addition it is possible to take Finnish language courses as elective studies, since they will help student to integrate into the Finnish society during studies and after graduation. Advanced practical training (internship) WCE programme also include an obligatory training period of 2 months, which is typically performed in electronics, communications, or network operator companies. It is also possible to do it in a research group at the university, or at some other research units. It is recommended to perform the training period during the summer time after the first study year. Every student is responsible for finding the employer for the training period by him/herself. In the case a student is not able to find training position in electronics industry, WCE programme will help to find training opportunity in a research group at the university. Department of Communications Engineering & Centre for Wireless Communications offers every year training and master's thesis grants for all of our WCE students. It is also possible to employ student’s prior work experience obtained after B.Sc. degree, in order to fulfil advanced practical training requirement of WCE programme. Programme Admissions General Academic Eligibility Requirements are the same for all of the UO Master's programmes. However, there are programme specific ways to show English language proficiency. See details from the Language Requirements page. There are also country-specific requirements of application documents. Please, read them carefully before submitting an application. Programme Specific Academic Requirements 1. B.Sc. Degree requirements Applicants who have obtained a university level Bachelor's degree or higher in one of the following degree programmes: Communication engineering Electrical engineering Computer engineering are eligible. The Bachelor’s degree should be equivalent to 180 ECTS corresponding at least three years of full-time study. Bachelor’s degree must have been granted by an academic, higher education institute, which enables the applicant to apply for higher university degree (master) studies in his/her home country. Other degrees are not eligible. Students who are on their last term/semester of Bachelor’s studies can apply to study for a Master’s degree. Applicants with good academic records can be offered a conditional study placement. Students are asked to state the expected date of graduation on the application form and provide the transcript of records with the other application documents. In the case that the applicant is accepted for study, the applicant has to submit officially certified copies of his/her Bachelor’s degree certificate and the final transcript of records by the deadlines. 2. Prior Studies The tight 2-year time-frame of the WCE programme does not give room for students to patch up their knowledge. Hence, the applicants for the programme are expected to possess sufficient basic knowledge from the areas of mathematics, probability theory and stochastic processes, signal theory, telecommunications theory, modulation methods, network theory, analog and digital electronics, radio engineering, electromagnetic wave theory, radio channels, signal processing, computer engineering, and programming skills. 3. Grade Limits In addition to the abovementioned general eligibility requirements, the applicants must posses good, very good or excellent grades in mathematical sciences, and the overall grade of the Bachelor's degree (Cumulative Grade Point Average, CGPA) in engineering should be good, very good or excellent. Comparisons between GPA for different education systems can be found from here (see also the web-links on that page). 4. Intake Restrictions The annual target intake of the WCE programme for admission period is 20 students. Also Finnish students having a university level B.Sc. and fulfilling the above criteria are eligible to the programme. A class may not be started, if the number of accepted students is less than 10. 5. Publication of the Results All selected applicants will be informed of their results with e-mail at the turn of April to May 2016. E-mail will also be send for those students who are not selected. The results of the official selection will also be placed on the UO IMP web page. Please note that any information given on this website document that is erroneous or changed at a later date cannot be accepted as grounds for an appeal. 6. Application Procedure and Documents Required Details of application procedure can be found from here. After completing and submitting the online application, it needs to be printed, signed and sent together with the necessary attachments to the address: University Admissions Finland, Unioninkatu 40 C, FI-00170 Helsinki, Finland. Recommendation letters and Curriculumn Vitae (CV) must also be sent along your printed and signed application to University Admissions Finland. 7. WCE Programme Specific Documents/Requirements When filling in your online application you have to fill the following information into the application form: A. Abstract of your Bachelor's Thesis (max. 3000 characters) Please fill into your application the Abstract of your Bachelor's thesis if a thesis is an obligatory part of your B.Sc. degree (in English, max 3 000 characters). If your B.Sc. degree does not include an obligatory written Bachelor’s thesis indicate it clearly by typing “My B.Sc. degree does not include a written B.Sc. thesis work”. If you are currently doing your thesis work (i.e., if you are on your last term/semester of your Bachelor’s studies) but it is not yet completed, write a draft abstract describing thesis contents. B. Motivation Letter (max. 7000 characters) Describe briefly (max. 7000 characters) your motivation for applying to study in Master's Degree Programme in Wireless Communication Engineering. Your letter should entail the following: why you wish to study at the University of Oulu, reasons why you have chosen this particular degree programme, how your previous studies and work experience support studying in this programme, how you will finance your studies, describe all working experience you have in engineering before and after obtaining B.Sc. degree, how your possible studies at the University of Oulu would improve your future career and/or study objectives, and what are your plans after obtaining Master’s degree. Please note that all application documents must be sent to the University Admissions Finland address in Helsinki, nor to the University of Oulu. In addition to the standard document requirements, educational documents from certain countries must be submitted in a certain country-specific way. By using your My UAF account you can check if your degree-awarding country has any specific requirements for the way the documents have to be submitted. Selection Process and Detailed Selection Criteria The applicants for the programme are expected to possess sufficient basic knowledge from the areas of mathematics, probability theory and stochastic processes, signal theory, telecommunications theory, modulation methods, network theory, analog and digital electronics, radio engineering, electromagnetic wave theory, radio channels, signal processing, computer engineering, and programming skills. The applicants are ranked based on their previous studies on those areas, as well as study grades like Cumulative Grade Point Average (CGPA), motivation, CV, recommendation letters, and work experience. A student selection sheet with points scale is used to rank applicants transpanently. Reviewers of applicants will decide whether applicant possess sufficient prior knowledge or not. Reviewers will also judge whether applicant's overall grade of the Bachelor's degree and CGPA will fall into the classes of good, very good and excellent or not. Student Selection Student selection is based on submitted B.Sc. documentation, recommendation and motivation letters, work experience, etc. WCE programme does not arrange interview of applicants. The results of the selection will be published on the University of Oulu IMP selection web page at the turn of April to May. University of Oulu International Master’s Scholarship Scheme 2017-2018 Connected with the renewal of university strategy, the increased importance of internationalization and the introduction of tuition fees for non-EU/EEA citizens, the University of Oulu has assigned a significant amount of money for tuition scholarships for 2017 entry. The scholarships will be granted in the form of a tuition fee waiver. The tuition fee waiver awarded covers 100 % of the full tuition fee. Applicants can apply for the tuition scholarship as part of the admissions process. University of Oulu Scholarship Scheme in more detail The University of Oulu International Master’s Scholarship Scheme (IM Scholarship) provides scholarships to academically talented international students. The scholarship is aimed at students studying for a Master’s degree in the University of Oulu two-year International Master’s programmes. The scholarship covers the full international tuition fee. University of Oulu IM Scholarships do not cover living costs. In order to retain the scholarship in the following year of study, a student must have completed 55 ECTS by the end of the previous academic year. If a student does not achieve this requirement during the first year of studies, they will be liable to pay the full international tuition fee for the second year if they wish to complete their Master’s degree programme. An exception to this rule can be made if a student has been granted approved leave from studies (e.g. due to serious illness). Eligibility Requirements to Apply for International Master’s Scholarship Applicants are eligible to apply for a University of Oulu IM Scholarship 2017-18, if they are: Non-EU/EEA* citizens who do not have a permanent residence permit in Finland. (Applicants not eligible for the International Master’s Scholarship are: 1) non-EU/EEA citizens who have a permanent residence permit in Finland, 2) EU/EEA citizens or comparable persons, 3) University of Oulu students who have been accepted to study BEFORE the academic year 2017-18.) Eligible to apply for a Master’s degree programme at the University of Oulu for academic year 2017 – 18. The applicant has obtained their first academic degree (Bachelor’s or equivalent) from a recognised institution of higher education. The applicant proves a high level of proficiency in English language. Approved methods of demonstrating language proficiency. Applicants who are in their last term/semester of studies for their first academic degree during the application period, can apply for the scholarship. Applicants who receive a conditional offer of study placement for a Master’s programme will receive a conditional scholarship offer. The scholarship application will be processed in the selection procedure only if the applicant meets the admissions criteria. *European Union / European Economic Area member states are: Austria, Belgium, Bulgaria, Cyprus, Czech, Estonia, Finland, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Liechtenstein Republic, Denmark, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, and United Kingdom. With the EU legislation, Switzerland is also comparable for EU member states. The nature of residence permit is indicated in the residence permit with a letter. A permanent residence permit bears the letter P or A and an EC residence permit for third-country nationals with long-term EC resident status bears the letters P-EY. Application for International Master’s Scholarship 2017-18 There is no separate application system for the International Master’s Scholarship. All applicants for University of Oulu Master’s degree programmes need to complete the Student Application Form. Those applicants who are applying for the University of Oulu International Master’s Scholarship have to additionally complete the “Application for Scholarship,” section which can be found at the end of the Student Application Form. The International Master’s Scholarship application section cannot be completed and/or submitted without the Student Application Form. The application period for the University of Oulu Master’s degree programmes and International Master’s Scholarships is 15.12.2016-25.1.2017 Selection criteria for University of Oulu IM Scholarship 2017-2018 Admissions and scholarships decisions will be taken at the same time. Those students successful in obtaining an International Master’s Scholarship will be notified at the same time as their offer of admission to their International Master’s programme is confirmed. The selection criteria for the University of Oulu IM Scholarship are based on previous academic performance and academic potential. For questions concerning the University of Oulu IM Scholarship, please contact admissions.officer(a)oulu.fi [-]

European Master in Renewable Energy

Hanze University of Applied Sciences - Groningen, the Netherlands
Campus Full time 3 semesters September 2017 Netherlands Groningen

The European Master in Renewable Energy is a programme offered at the School of Engineering of Hanze UAS in cooperation with EUREC, aimed at training post-graduate students to fill the gap between growing industry demand for specialised renewable energy expertise and the skills currently available on the job market. [+]

Masters in Engineering in Europe 2017. European Master in Renewable Energy: www.hanzegroningen.eu/mre * Tuition fees: EU/EEA: € 2,006 (per year)/ NON-EU/EEA: € 11,500 (full tuition fee). However, an EU student already holding a Dutch master's degree will pay €7,300, for the full programme. ​​​​Within the rapidly expanding European renewable energy industry, an urgent demand exists for more post-graduate trained staff specialised in renewable energy technology. Together with leading European Universities, EUREC has developed the European Master in Renewable Energy. Hanze University of Applied Sciences, Groningen (Hanze UAS), became member of the EUREC consortium and started this master programme in September 2012. Order our brochure now, or sign up for the open day.​ The aim of the European Master in Renewable Energy is to train post-graduate students to fill the gap between the growing industry demand for specialised renewable energy expertise and the skills currently available on the job market. By structuring the course in three sections, students are guaranteed to spend time in at least two different EU countries and make contact with a wide range of European universities and companies involved in the renewable energy sector. The participating universities are all well-established in training and research and recognised internationally for their work in the field of renewable energy technology. ​ Programme overview Core The first semester the student will acquire a solid foundation in key renewable energy technologies and the socio-economic issues related to these. For the core the student can choose one of the following universities: Hanze University of Applied Sciences, Groningen, the Netherlands (English) Ecole des Mines de Paris, France (French) Zaragoza University, Spain (Spanish) Loughborough University, UK (English) Oldenburg Un iversity, Germany (English) Semester 2 - Specialisation The second semester will give students the opportunity to specialise in a chosen technology. The specialisations are taught in English. For the specialisation there are the following options: Sustainable Fuel Systems for Mobility Photovoltaics Wind Energy Grid Integration Solar Thermal Ocean Energy Thesis In the third semester each student will conduct a 6 month research project in a company or a research centre. This is done under supervision of a professor of the core, a professor of the specialisation and a supervisor from the project provider. For your final thesis placement it is possible to apply for an Erasmus placement grant. For general information about the Erasmus LLL programme, you can read this page. The participating universities are all well-established in training and research as well as being recognised at an international level for their work in the field of renewable energy technology. [-]

Master in Mechanical Engineering

Czech Technical University in Prague
Campus Full time 2 years October 2017 Czech Republic Prague

The Faculty is authorized by the Ministry of Education, Youth and Sports of the Czech Republic to offer university education. The Faculty is also recognised by FEANI (European Federation of National Engineering Associations). [+]

Field of Study - Environmental Engineering - Power Engineering - Applied Mechanics - Instrumentation and Control Engineering - Transportation, Aerospace and Handling Technology - Mechatronics - Process Engineering - Production Machines and Equipment - Enterprise Management and Economics - Biomechanics and Medical Instruments - Production and Materials Engineering - Mathematical Modelling in Engineering Entrance Exams NON Entrance Requeirements - fully completed application form - English language certificate Level of English - TOEFL IB T 65/TOEFL CBT 185 - B2, FCE, IELTS 5.5 Scholarship not for the first year students [-]

International Master in Energy Technology

Peter the Great St. Petersburg Polytechnic University
Campus Full time 2 years September 2017 Russia St. Petersburg

The purpose of the Master of Science in Energy Technology degree programme is to prepare highly qualified professionals capable to solve complex engineering and management tasks in the world energy industry. [+]

International Master Degree Programme: Energy Technology

The 5 best reasons to participate in the program

1. The Master’s Degree Programme in Energy Technology includes a wide array of energy studies aimed to fundamental preparation and practical training.

2. The programme is conducted with the participation of key professors of St. Petersburg State Polytechnical University and other leading Russian and foreign universities.

3. The programme contributes to joint study of Russian students with foreign students, the opportunity to participate together in academic and extracurricular activities of SPbSPU.

4. The programme offers a unique opportunity to undertake an internship in leading Russian energy companies and a semester abroad at foreign partner University.... [-]


Master Programme in Spatial Engineering

ESTACA
Campus Full time 5 years September 2017 France Paris

The French and European space programmes are economically and strategically important for the future: the development of access to space, with applications such as Earth observation or telecommunications, activities related to research in a zero-gravity environment, the presence of man in space, the continuation of development of the large families of satellites such as Spot, development of mini and micro-satellites, preparation of various interplanetary probes and the missions to Mars, all of these are subjects that are currently being developed. Becoming an engineer in the space sector means working on the construction of launchers, spacecraft (satellites, probes, shuttles, orbital stations) and thrusters, and also taking part in the launch and operation of satellites. [+]

The French and European space programmes are economically and strategically important for the future: the development of access to space, with applications such as Earth observation or telecommunications, activities related to research in a zero-gravity environment, the presence of man in space, the continuation of development of the large families of satellites such as Spot, development of mini and micro-satellites, preparation of various interplanetary probes and the missions to Mars, all of these are subjects that are currently being developed. Becoming an engineer in the space sector means working on the construction of launchers, spacecraft (satellites, probes, shuttles, orbital stations) and thrusters, and also taking part in the launch and operation of satellites. SPECIALISED TRAINING AND PRIVILEGED CONTACT WITH COMPANIES more than 400 hours of courses are provided by engineers from CNES, EADS, ONERA, ArianeSpace, the SAFRAN Group, etc. at least 4 implementation projects are performed during the curriculum, for example: launcher architecture design office; calculation of the performance of the force provided by different propellants; dimensioning satellites for particular missions; programme for launch into orbit 12 months of work-experience courses obligatory: Discovering the company course in 1st year at EADS Astrium: management of documentation and nomenclature; Engineer's work-experience course in 4th year" at CNES: research into the characteristics of Martian soil from information collected during a mission to Mars; End-of-studies work-experience course in 5th year at EADS Space Transportation (Astrium): research into new architectures for navigation systems for development of the control of launchers. visits to sites and conferences: CNES at Toulouse, SAFRAN at Vernon (rocket engines), etc. AN ASSOCIATION FOR EXPRESSING YOUR INTERESTS The rocket club: ESO (ESTACA Space Odyssey) designs, builds and launches experimental rockets, mini-rockets and stratospheric balloons with the logistical and methodological support of the "Planète Sciences" Association. These launches take place during campaigns performed at the initiative of the national centre for space studies (CNES). [-]

Master in Biotechnological Engineering

Polytechnic Institute Of Bragança
Campus Full time 2 years October 2017 Portugal Bragança

This programme will allow the intervention in areas which link the primary and secondary sectors, providing new accomplishments namely in the field of microbial technology and plant biotechnology. [+]

Masters in Engineering in Europe 2017. Master in Biotechnological Engineering This master programme main goal is to provide technological training with a rather strong professional approach. This will allow the intervention in areas which link the primary and secondary sectors, providing new accomplishments namely in the field of microbial technology and plant biotechnology. This study cycle is lectured in cooperation with CIMO (The Mountain Research Centre), a Research & Development unit of the Portuguese Science and Technology Foundation (FCT). Profile of the programme The profile of the programme is organized into two major areas of specialization, microbial biotechnology (Microbial Physiology and Genetics; Microbial Associations and Biofertilizers, Biomass and Bioenergy; Industrial Microbiology) and agricultural biotechnology (Microbial Associations and Biofertilizers, Genetically Modified Organisms; Biomass and bioenergy Production; Molecular Diagnostic Methods; Biopesticides and Biocontrol; Biofactories, Bioproducts and Innovation). A set of courses is the interface between the two areas (Biomass and Bioenergy; Biocatalysts Technology, Engineering of Biotechnological Processes), giving the necessary engineering component to this curriculum. Finally, the disciplines that provide the foundations of statistics and experimental design (Multivariate Analysis and Experimental Design), and safety and regulation in the biotechnology industry (Safety and Regulation in Biotechnology) complete the plan of studies. Biology and biochemistry Key learning outcomes The degree of "mestre" (master) in Biotechnological Engineering, is awarded to those students that demonstrate, in this field, the ability to: develop and enhance the knowledge obtained in the first cycle, in order to develop and apply that knowledge to original situations often in the context of research; apply their knowledge and understanding and problem solving capacities to new and unfamiliar situations in wide multidisciplinary situations, although related to their area of studies; integrate knowledge, deal with complex matters, develop solutions or put forward opinions on situations of limited or incomplete information, including reflecting upon the implications and ethical and social responsibilities that result from both those solutions and opinions or indeed that condition them; communicate their conclusions and the knowledge and reasoning that underlay them, both to experts and non-experts, clearly and unambiguously; develop competences that will enable them to benefit from self-oriented or autonomous lifelong learning. To complete the qualification, the student is required to pass all compulsory course units of the study plan. Occupational profiles of graduates The degree of "mestre" (master) in Biotechnological Engineering belongs to the education and training area of Technologies. Graduates are specialized to develop a professional activity within the agrarian and industrial sectors of production associated with biotechnology; act at the level of new plant/animal production technologies and screening and diagnosis of plant/animal health; intervene in areas of connection between the primary and secondary sectors, bringing new skills to the two productive sectors; undertake business activities to bring the added value of the products obtained. [-]