For more details on the courses, please refer to the Course Catalog
| Code | Course Title | Credit | Learning Time | Division | Degree | Grade | Note | Language | Availability |
|---|---|---|---|---|---|---|---|---|---|
| PSE5001 | Photovoltaic Power Generation System | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | English | Yes |
| This lecture offers practical lessons in photovoltaic industry related issues such as photovoltaic policy, wafer growth, solar cell, photovoltaic module, power conditioning system, PV system design, PV system installation, PV component and system standard evaluation, economic evaluation of PV system, PV system applications, and examples of PV dissemination, new energy and renewable energy sources. Covering various topics on PV power generation, student will be exposed to the very specialized lectures in photovoltaic system. | |||||||||
| PSE5002 | Solar Cell Engineering | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | Korean | Yes |
| Almost all range of solar cell related topics are covered. After an introduction of basic optical phenomena, the lecture covers different aspect of the photovoltaic conversion efficiencies. Since energy conversion requires internal built-in potential to segregate photo-generated electron-hole pairs, various junction types are addressed such as MS, MIS, SIS, PN, PIN, homojunction, and heterojunction. Other practical issues are treated in terms of device fabrication, characterization, simulation, and future research trend. | |||||||||
| PSE5005 | Lab Experiment for PV Power Generation | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | - | No |
| Photovoltaic power generation system with a small laboratory scale system will be made in this lecture to practice PV componenet and system characterization for those who took lectures on Photovoltaic Power Generation System. Based on solar cell fabrication knowledge, students will carry out design and fabrication of power conditioning unit software as well as hardware including subjects like AC-DC inverter, DC-DC converter, DC-AC inverter, and AC-AC converter design and actual system implementation. | |||||||||
| PSE5006 | Lab Experiment for Solar Cell Fabrication | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | English | Yes |
| Solar cell fabrication process like surface texturing, emitter doping, surface passivation, antireflection coating, p-n junction isolation, solar cell metallization, metal contact firing heat treatment, current-voltage properties, spectral response, process monitoring method, solar cell module fabrication related circuit construction, matrix composition, lamination, and module evaluation method will be covered in this course work. Student will be equipped to manipulate balance of system for the photovoltaic power generation. | |||||||||
| PSE5007 | Solar Energy Industry Seminar | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | Korean | Yes |
| To tackle climate change crisis, many countries across the world have declared to achieve carbon-neutral. Accordingly, renewable energy deployment has been rapidly accelerated in recent years. In particular, solar energy harvesting becomes one of the most important industries. In this class, we will discuss the status and issues of solar energy industries with experts working in solar energy industry-related institutes. | |||||||||
| PSE5008 | Internship in Solar Energy Materials Industry | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | - | No |
| To tackle climate change crisis, many countries across the world have declared to achieve carbon-neutral. Accordingly, renewable energy deployment has been rapidly accelerated in recent years. In particular, solar energy harvesting becomes one of the most important industries. In this class, the student will gain work experience in solar energy materials industry. | |||||||||
| PSE5009 | Internship in Solar Energy Equipment Industry | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | - | No |
| To tackle climate change crisis, many countries across the world have declared to achieve carbon-neutral. Accordingly, renewable energy deployment has been rapidly accelerated in recent years. In particular, solar energy harvesting becomes one of the most important industries. In this class, the student will gain work experience in solar energy equipment ndustry. | |||||||||
| PSE5010 | Internship in Pphotovoltaic Module Industry | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | - | No |
| To tackle climate change crisis, many countries across the world have declared to achieve carbon-neutral. Accordingly, renewable energy deployment has been rapidly accelerated in recent years. In particular, solar energy harvesting becomes one of the most important industries. In this class, the student will gain work experience in photovoltaic module industry. | |||||||||
| PSE5011 | Internship in Smart Manufacturing Industry | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | - | No |
| Since the rapid development in artificial intelligence and machine learning technologies, smart manufacturing has become an essential technology for enhancement of product productivity in industries. In this class, the students will visit companies adopting the smart manufacturing technologies to gain related knowledge and work experience. | |||||||||
| PSE5012 | Introduction to Building Integrated PhotoVoltaics | 3 | 6 | Major | Master/Doctor | 1-4 | Photovoltaic System Engineering | - | No |
| Preliminary simulation is very useful in building PV because it is often exposed to various special conditions. As a practical curriculum for the building PV industry, students will learn how to use specialized software (PSpice, CAD/CAM, etc.) related to the building PV field and experience practical applications to cultivate their research and work skills. Also, the course covers a wide range of professional topics, from identifying major PV policies and wafer growth, which is the basic stage of the industry supply chain, to solar cells, PV modules, power conditioning devices, power system connection, PV system design, PV system installation, PV standardization and evaluation, PV system economic evaluation, PV application and dissemination cases. | |||||||||
| PSE5013 | Building Photovoltaic Module Reliability Test and Analysis | 3 | 6 | Major | Master/Doctor | Photovoltaic System Engineering | Korean | Yes | |
| The world has been evolving into an industrial ecosystem centered on sustainable renewable energy, such as solar power, for climate change, energy paradigm transition, and carbon neutrality. In particular, the importance of urban solar power generation, specifically through Building Integrated PhotoVoltaics (BIPV) systems, has significantly increased in order to solve the energy consumption limit of buildings and to realize energy self-sufficient zero energy buildings (ZEB). In this course, students will learn about reliability test method and pass/fail criteria of BIPV modules used in urban solar power generation systems. There are three reliability tests which are environmental, safety, and performance test will be covered | |||||||||
| PSE5014 | Renewable energy electrical system reliability analysis on Building | 3 | 6 | Major | Master/Doctor | Photovoltaic System Engineering | Korean | Yes | |
| The world has been evolving into an industrial ecosystem centered on sustainable renewable energy, such as solar power, for climate change, energy paradigm transition, and carbon neutrality. In particular, the importance of renewable energy system, specifically through Building Integrated PhotoVoltaics (BIPV) systems, has significantly increased in order to solve the energy consumption limit of buildings and to realize energy self-sufficient zero energy buildings (ZEB). In this course, students will learn about electrical system test method and pass/fail criteria based on building regulation for fire resistance, water ingress resistance, and wind pressure resistance. | |||||||||
| PSE5015 | Photovoltaics Simulation | 3 | 6 | Major | Master/Doctor | Photovoltaic System Engineering | - | No | |
| Preliminary simulation is very useful in building PV because it is often exposed to various special conditions. As a practical curriculum for the building PV industry, students will learn how to use specialized software (PSpice, CAD/CAM, etc.) related to the building PV field and experience practical applications to cultivate their research and work skills. Also, the course covers a wide range of professional topics, from identifying major PV policies and wafer growth, which is the basic stage of the industry supply chain, to solar cells, PV modules, power conditioning devices, power system connection, PV system design, PV system installation, PV standardization and evaluation, PV system economic evaluation, PV application and dissemination cases. | |||||||||
| PSE5016 | Building Integrated PhotoVoltaics(BIPV) Practical Working Internship 1 | 3 | 6 | Major | Master/Doctor | Photovoltaic System Engineering | - | No | |
| This is a hands-on training course in the field of building photovoltaics, providing students with the opportunity to apply the knowledge gained in BIPV-related coursework to actual industrial sites. Students will visit actual companies or institutions in the field of building-based photovoltaics to learn and practice BIPV-related research/process equipment and business processes. In particular, the course reflects the convergence of the fields of architecture and electricity, considering not only existing photovoltaic modules but also the specificity of building materials. The learning process is conducted with experts and the final evaluation is also conducted with the experts in the field. | |||||||||
| PSE5017 | Building Integrated PhotoVoltaics(BIPV) Practical Working Internship2 | 3 | 6 | Major | Master/Doctor | Photovoltaic System Engineering | - | No | |
| This is a advanced hands-on training course in the field of building photovoltaics, providing students with the opportunity to apply the knowledge gained in BIPV-related coursework to actual industrial sites. Students visit actual companies or institutions in the field of building-based photovoltaics to learn and practice BIPV-related research/process equipment and advanced business processes. In particular, the course reflects the convergence of the fields of architecture and electricity, considering not only existing photovoltaic modules but also the specificity of building materials. The learning process is conducted with experts and the final evaluation is also conducted with the experts in the field. | |||||||||