Master's in Technology in Czech Republic

Find Masters Programs in Technology in Czech Republic 2017

Technology

A masters is earned after students complete an undergraduate degree program. To obtain a masters, you usually need to complete 12 to 18 college courses that often involve completing comprehensive tests and/or a thesis.

One of the greatest aspects of technology is that when it is embedded in machines and devices, most of the time the individual operating the machine or device does not need to understand the specifics of how the technology works. For example, someone using a computer does not need to understand the mechanics of the hard drive to benefit from using it.

Czech Republic has a well-established and research based university education. This has made learning ini Prague one of the respected curriculum's in Europe since it cultivates the spirit of creativity and innovation among students.

Top Master Programs in Technology in Czech Republic 2017

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Master in Modern Metallurgical Technologies

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

The Master's Study Branch Modern Metallurgical Technology is designed as a modern study branch aimed at training professionals for current and highly sophisticated metallurgical technologies, covering in detail the issues of theory and technology of production, casting and processing of iron and steel or their forming, including the forming of non-ferrous metals and/or foundry of alloys based on both iron and non-ferrous metals. [+]

Best Masters in Technology in Czech Republic 2017. Study Branch Metallurgical Engineering Branch Profile The Master's Study Branch Modern Metallurgical Technology is designed as a modern study branch aimed at training professionals for current and highly sophisticated metallurgical technologies, covering in detail the issues of theory and technology of production, casting and processing of iron and steel or their forming, including the forming of non-ferrous metals and/or foundry of alloys based on both iron and non-ferrous metals. In addition to these specialization areas, all graduates receive knowledge from the field of technical materials, industrial furnaces, preparation of non-ferrous metals and alloys, methods of planning and quality enhancement as well as managerial economics. Theoretical knowledge is complemented with a number of additional laboratory and computing practical exercises, in which the current laboratory technology is applied, and which address tasks related to metallurgical processes and their modelling. Theses are mainly focused on the selected study branches, or also partially extend to related study branches, such as Thermal Engineering and Ceramic Materials, or Materials Engineering. The study branch has a unique position in the structure of study fields at Czech universities. Key Learning Outcomes Knowledge Graduates can characterize advanced and contemporary technologies of iron and steel production, foundry technology and forming technology of ferrous and non-ferrous metals. They have a good command of the technological principles of the iron and steel production, foundry technology and technology of materials forming. Based on their professional specialization, consisting of an appropriate choice of study courses, graduates are able to demonstrate a more profound knowledge of the theoretical principles related to technology of iron or steel production, foundry and materials forming technologies of foundry or modelling of forming processes. Graduates are able to use methods of statistical analysis and data processing. They can also use advanced modelling methods of steel production technology or foundry technology, or modelling of forming processes at the advanced level. Graduates can demonstrate basic knowledge of technical materials, production of non-ferrous metals, thermal processes in industrial furnaces, methods of planning and quality enhancement, and managerial economics. Skills Based on the selected study specialization, graduates are able to independently solve tasks in the field of current technologies of iron and steel production, foundry, or forming of materials. They are able, to a greater extent, to apply advanced methods of theoretical and experimental research for the technologies of iron and steel production, foundry or forming of materials. Graduates are able to apply the methods of statistical analysis, advanced numerical modelling methods, as well as basic principles of managerial economics to solve individual tasks. General Competencies Graduates have developed soft skills on a sufficient level. They have a good command of at least one foreign language at the B1-B2 level of the Common European Framework of Reference (CEFR), and are prepared for teamwork. Occupational Profiles of Graduates The Master's Study Branch Modern Metallurgical Technology is designed as a modern study branch aimed at training professionals for current and highly sophisticated metallurgical technologies, covering in detail the issues of theory and technology of production, casting and processing of iron and steel or their forming, including the forming of non-ferrous metals and/or foundry of alloys based on both iron and non-ferrous metals. Theoretical knowledge is complemented with a number of additional laboratory and computing practical exercises, in which the current laboratory technology is applied, and which address tasks related to metallurgical processes and their modelling. The study branch has a unique position in the structure of study fields at Czech universities. Admission Requirements Determined by Dean, may include entrance examination, other formal documents. Graduation Requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits List of courses is available at the detailed branch description page 30 ECTS credit per semester. [-]

Master in Automation and Computing in Industrial Technologies

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

The Branch is focused to the exploitation of computers and automation of technological processes above all in the metallurgical industry by application of knowledge in the field of theory of automated control, integrated computer systems, modern methods of control with exploitation of artificial intelligence and applied informatics and control of technological aggregates and processes. [+]

Study Branch Economics and Management of Industrial Systems Branch Profile The Branch is focused to the exploitation of computers and automation of technological processes above all in the metallurgical industry by application of knowledge in the field of theory of automated control, integrated computer systems, modern methods of control with exploitation of artificial intelligence and applied informatics and control of technological aggregates and processes. Key Learning Outcomes Knowledge advanced scientific methods of modelling, simulation and optimal control of dynamic systems, modern tools and techniques for designing and implementation of complex control systems based on programmable logic controllers, programming of information systems and modern control methods, detailed knowledge of industrial technologies, especially in the field of metallurgy and related technologies. Skills independent control of production and technological processes, particularly in the metallurgical enterprises ability of creative synthesis of gained technological knowledge in the field of metallurgy, knowledge of control methods and implementation of control and information systems, ability of independent analysis, design and implementation of control systems for technological processes especially in metallurgical industry field by means of application of modern computing, measurement and automation tools. General Competencies General competences within the scope defined by the national descriptors of the Czech qualifications framework with an emphasis on communication skills, management and organizational skills, ability to communicate in at least one foreign language, etc. Occupational Profiles of Graduates This unique engineering field of study follows on the bachelor’s study program and expands and deepens knowledge and practical abilities in the automation and informatics areas in industrial technologies. The teaching process is focused on application of modern technology from the artificial intelligence field, programed logic control and robotic systems in real industrial environment. The teaching process are conducted in modern laboratories, equipped with models of technological devices with computer support and with virtual reality elements. The students can gather scholarship by working on research projects under the department and its partner’s supervision. These projects can significantly enhance student’s experience in given area. Graduates are very desired and can work as an experienced techno-analytic workers. Admission Requirements Determined by Dean, may include entrance examination, other formal documents. Graduation Requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits List of courses is available at the detailed branch description page 30 ECTS credit per semester. [-]

Master in Applied Electronics

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

Students specialize in either Commercial or Industrial Electronics complimenting a basic study of electrical engineering. There is a particular emphasis placed on a highly efficient education in order to teach students to think creatively and apply new knowledge in the creation of new technical pieces of work. [+]

Best Masters in Technology in Czech Republic 2017. Faculty of Electrical Engineering and Computer Science Study Branch Applied Electronics Branch Profile Students specialize in either Commercial or Industrial Electronics complimenting a basic study of electrical engineering. There is a particular emphasis placed on a highly efficient education in order to teach students to think creatively and apply new knowledge in the creation of new technical pieces of work. The instruction is focused on the practical, and facilitates development of distinctive diploma theses. Key Learning Outcomes - Knowledge Graduates have a broad and deep knowledge in the technical fields of this branch, which corresponds to the current state of the art. They understand the state-of-the-art theories, concepts and methods of the branch. They are able to apply knowledge from related branches in their own branch. Students of Applied Electronics acquires the necessary knowledge of mathematics, theory of electrical circuits, information technology, and special knowledge in the following technical fields: Applied Electronics Analogue and Digital Electronic Circuits Microprocessor Technology Semiconductor Power Systems Electric Regulated Drives Optoelectronics Measurement Technology Audiovisual Technology Construction of Electronic Devices - Skills Using their expert knowledge, a graduate is able to independently define and creatively deal with practical or theoretical problems within the branch. They can solve complex problems independently and creatively, using selected theories, concepts and methods of the branch, and apply some of the advanced research procedures of the branch to obtain new, original information. - General competencies: A graduate is able to make independent and responsible decisions in new or changing contexts of the individual technical fields of the branch, considering the broader social consequences of the decisions. Further, they are able to determine assignments of professional activities from available sources, they can coordinate them and bear responsibility for the results. They can convincingly communicate their own expert opinions to professionals and the public, use their professional knowledge, expert skills and general qualifications in at least one foreign language. Using the theoretical findings of the branch, they can plan, support and manage the acquisition of further professional knowledge, skills and qualifications of other team members. Occupational Profiles of Graduates Graduates will find employment at designing institutes, in R&D departments, developing electronic applications in the field of control technology, semiconductor power systems, electric regulated drives, measurement technology, audiovisual technology, as managers, designers of electronic devices, researchers and developers, etc. They can work at companies with electrotechnical production, in the management of technological processes at production organizations, or in maintenance and repair operations. Admission Requirements Determined by Dean, may include entrance examination, specific courses taken during bachelor studies, other formal documents. Graduation requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits 30 ECTS credits per semester. [-]

Master in Mobile Technology

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

Graduates gain experience in the field of information and communication technologies with a focus on the mobile networks. They can design, operate, modify and optimize mobile wireless networks, develop, and optimize applications for mobile devices, and have knowledge of mobile networks, radio technology and software designing of applications for mobile devices. [+]

Faculty of Electrical Engineering and Computer Science Study Branch Mobile Technology Branch Profile Graduates gain experience in the field of information and communication technologies with a focus on the mobile networks. They can design, operate, modify and optimize mobile wireless networks, develop, and optimize applications for mobile devices, and have knowledge of mobile networks, radio technology and software designing of applications for mobile devices. Practical laboratory training is carried out in coordination and cooperation with experts of leading telecommunications companies which focus on providing mobile services such as T-Mobile and O2. Study also focuses on business needs and its incorporation in the design of appropriate mobile applications, both in the sphere of labor-service and areas of administration and management. Graduates have the potential to control the technical tasks related to the operation of mobile networks, and the design and implementation of customized solutions. Graduates are in strong demand as mobile network engineers and developers of software for mobile devices. Key Learning Outcomes - Knowledge A graduate has a deeper and broader command of theoretical disciplines such as mathematics, with an enhanced ability to perform analyses. Study covers more complex, theoretically demanding or less frequently practical areas of information and telecommunication technology, e.g. processing and analysis of data of various kinds. The graduate is able to evaluate the above mentioned areas and understands the basic scientific methods applied here. - Skills The graduates can design large scale projects (e.g. software products in the environment of mobile networks) and implement them as members or leaders of teams. They are able to choose the suitable procedure and technology for the solution. In non-standard situations they can effectively modify the commonly used procedures. They can compare and evaluate various procedures, and defend suggested solutions in professional discussions. - General competencies: Graduates develop communication skills towards problem solving, e.g. with other team members or customers when specifying the tasks and delivering results. They can manage a problem-solving team, define targets, determine strategies, choose alternative solutions, present and defend their opinions and chosen solutions, study technical literature, bear responsibility for their decisions and the work of the team, educate and themselves in the given branch as well as communicate with experts of the branch in a foreign language, especially English. Occupational Profiles of Graduates The graduates can find employment both as operating and managerial workers in construction and maintenance of software systems in mobile networks as well as in the creation and administration of telecommunication and mobile networks. Admission Requirements Determined by Dean, may include entrance examination, specific courses taken during bachelor studies, other formal documents. Graduation requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits 30 ECTS credit per semester. [-]

Master in Nanotechnology

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

The Master‘s Study Branch of Nanotechnology is the second level of nanotechnology study following upon Bachelor’s study. [+]

Best Masters in Technology in Czech Republic 2017. Branch Profile The Master‘s Study Branch of Nanotechnology is the second level of nanotechnology study following upon Bachelor’s study. The study programme contains more advanced methods of the structural and properties’ study of nanomaterials, theoretical and experimental approaches. During the first year of study students may choose one of two orientations - physical or chemical. Both orientations have common fundamental theoretical and experimental subjects including modelling and computer design of nanomaterials. Key Learning Outcomes KNOWLEDGE The aim of the master‘s study of Nanotechnology is to provide advanced education of characterization and properties of nanomaterials. Students extend their knowledge of mathematics, physics and chemistry in specialized subjects as electron microscopy, magnetic and optic properties of nanomaterials. The programme includes study of the relationship between properties of nanomaterials and their structures and utility as well. Graduates will have gained detailed knowledge about modern methods of structure study (for example electron microscopy, atomic force microscopy etc.). SKILLS The graduates of Nanotechnology master‘s study can use specialized knowledge to solve practical problems. They can use advanced research methods in nanotechnology that allow them to obtain new information based on practice and theory. GENERAL COMPETENCIES Graduates are able to independently make responsible decisions to solve individual parts of a problem. They know how to solve practical problems with characterization and preparation of nanomaterials, can formulate the results of experiments and opinions of a research team in a report. They understand specialized literature and databases and can make use of this knowledge. Graduates are also able to present their knowledge and experience in a foreign language. Graduates have the learning skills to allow them to continue to study in a manner that may be largely self-directed or autonomous. Occupational Profiles of Graduates The two-year study program includes advanced methods of assessment of structure and characteristics of nanomaterials, both theoretical and experimental. Theoretical subjects include the study of the electron structure, optical and magnetic characteristics and deal with the relationship of the nanomaterial characteristics and their functionality. Molecular modelling and computer design of nanomaterials is also a part of the programme. Furthermore, the programme includes advanced experimental methods of the structure and characteristics of the nanomaterials assessment (e.g. various types of microscopy, spectroscopic methods etc.) with sufficient ratio of the laboratory work in the laboratories equipped with modern apparatus. During studies, a student chooses one of two specializations (physical, chemical), differing in the way of manufacturing and characterization of the nanomaterial attributes. Admission Requirements Determined by Dean, may include entrance examination, other formal documents. Graduation Requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits List of courses is available at the detailed branch description page 30 ECTS credit per semester. [-]

Master in Computer Science and Technology

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

The Master’s course of Computer Science and Technology provides the students with an education designed to help them find employment mainly in the field of creation and administration of various extensive and complex software products, in the creation and administration of computational systems and computer networks, in the production of computers and their components, and finally, among others, in the fields of business and education. [+]

Faculty of Electrical Engineering and Computer Science Study Branch Computer Science and Technology Branch Profile The Master’s course of Computer Science and Technology provides the students with an education designed to help them find employment mainly in the field of creation and administration of various extensive and complex software products, in the creation and administration of computational systems and computer networks, in the production of computers and their components, and finally, among others, in the fields of business and education. Apart from the knowledge ensuring very good chances of employment in practice, the students are educated in relevant theoretical areas as well, which enables them to find employment in R&D as well as to continue their studies in the doctoral programme. Key Learning Outcomes - Knowledge In comparison with the Bachelor’s level, the Master’s knowledge of the preparation theoretical disciplines (e.g. mathematics, discrete mathematics, and theoretical informatics, logics) are deeper and broader. Moreover, the graduate is able to perform analyses. Also, there are more complex, theoretically demanding, or less frequent areas of informatics, such as the processing and analysis of data of various kinds, including multimedia data and very extensive data, systems implementing artificial intelligence, cognitive robots, systems of machine perception and recognition, computer modelling of various systems, designing of special (e.g. very powerful) computational systems. In the above mentioned areas, the graduate is capable of evaluation, and he/she also understands the elementary scientific methods used here. - Skills The graduates can design pieces of work of a large extent (e.g. software products, computation systems) as well as theoretically and technologically demanding pieces of work and can implement them as members or leaders of teams. They are able to choose the suitable procedure and technology for the solution. In non-standard situations they can modify the commonly used procedures appropriately. They can compare and evaluate various procedures. They can defend suggested solutions in a professional discussion. As a team member, the graduate can independently perform very demanding partial tasks. He/she can administer extensive and complex systems. The graduate can draw up extensive texts presenting complex ideas. - General competencies: When dealing with problems, the graduates can communicate with people, e.g. with other team members or with customers when specifying the tasks and handing over products. They can manage a problem-solving team, define the targets, determine strategies, choose alternative solutions, present and defend their opinions and chosen solutions, study technical literature, bear responsibility for their decisions and the work of the team, and educate themselves in the given branch as well as communicate with experts of the branch in a foreign language, especially English. Occupational Profiles of Graduates The graduates can find employment both as operating and managerial workers in various areas, such as in the creation and administration of various extensive and demanding software products, in creation and administration of extensive computational systems, in creation and administration of extensive computer networks, and in creation of software products for theoretically demanding computational procedures as well as in research, development, consulting and teaching activity within the branch. Admission Requirements Determined by Dean, may include entrance examination, specific courses taken during bachelor studies, other formal documents. Graduation requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits 30 ECTS credit per semester. [-]

Master in Control and Information Systems

Technical University of Ostrava
Campus Full time 2 years September 2017 Czech Republic Ostrava

The aim of the course is to cultivate engineers as specialists in the fields of automation, control systems, measurement, and sensors using cutting edge laboratories and expert instruction. The priority of the Branch is to teach students to approach technical problem solving creatively, and to deal with assignments in the field of measurement and control engineering independently and systematically – i.e. to acquire all skills that are necessary for work as an engineer. [+]

Best Masters in Technology in Czech Republic 2017. Faculty of Electrical Engineering and Computer Science Study Branch Control and Information Systems Branch Profile The aim of the course is to cultivate engineers as specialists in the fields of automation, control systems, measurement, and sensors using cutting edge laboratories and expert instruction. The priority of the Branch is to teach students to approach technical problem solving creatively, and to deal with assignments in the field of measurement and control engineering independently and systematically – i.e. to acquire all skills that are necessary for work as an engineer. Key Learning Outcomes - Knowledge The graduates have detailed knowledge in the technical areas they acquaint themselves with over the course of their studies. The students can focus in the following specializations: - Information Systems in Controls. - Automation and Information Systems in Industry. - Virtual Instrumentation. - Measurement and Control Technology in Medicine. - Skills You will become an expert in an up-and-coming branch of engineering. We will teach you how to measure, evaluate and manage the world around you using a computer. Our cutting-edge laboratories are not only used for teaching but also for the students to deal with technical problems of both science and practice. The students will learn to present their achievements in practical, project-oriented instruction. Within the projects they are encouraged to work as a team, which is what employers often require. - General competencies: The branch of Control and Information Systems is multidisciplinary and pervades a whole range of human activities. Our graduates find employment easily and are much sought after on the labour market. The students can continue their studies in Doctoral programmes. During the course of study, the students can participate in the projects drawn up for cooperating commercial firms. We will teach you to think up and implement a project and to sell the results of your work. Occupational Profiles of Graduates The graduates are primarily prepared to work in the sphere of control and information systems, particularly in the design and implementation of hardware and software for measurement and control equipment, in the planning, designing and preparation of software for control and information systems at companies engaged in the design and supply of electrical engineering and automation technology, and with the manufacturers of equipment complexes, machines, devices and transport equipment. The graduates can also find employment outside these industries, e.g. in the sphere of biomedicine or information technology. Admission Requirements Determined by Dean, may include entrance examination, specific courses taken during bachelor studies, other formal documents. Graduation requirement 120 ECTS Credits, Final state examination, Diploma thesis Course Structure Diagram with ECTS Credits 30 ECTS credit per semester. [-]

Master in Intelligent Buildings

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

Intelligent Buildings [+]

Field of Study Intelligent Buildings 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 [-]