• UEE690 Master’s Research [석사논문연구]

    This course is related with the students graduate thesis and dissertation. As such, students should be actively working in a laboratory setting and gaining experience through hands-on experimentation.

  • UEE890 Doctoral Research [박사논문연구]

    This course is related with the students graduate thesis and dissertation. As such, students should be actively working in a laboratory setting and gaining experience through hands-on experimentation.

  • ENV505 Wastewater Microbiology [폐수미생물학]

    The goal of this course is to gain a fundamental understanding of microorganisms and their roles in wastewater environments.

  • ENV604 Aquatic Chemistry [수질화학]

    Basic concepts and chemical principles of water chemistry will be introduced, emphasizing the application of the principles to solve the specific chemical problems in aqueous environment, pollution control and purification technology.

  • ENV607 Environmental Justice and Ethics [환경 정의와 윤리]

    This course covers two major areas: (1) various surface chemistry areas including hydrous oxide-water interface, electric double layer theory, adsorption mechanisms, and particle-particle interaction, (2) colloid hydrodynamics including basic motion equations, motion of single and two interacting colloids in water.

  • ENV608 Bioprocess Modeling and Control [생물공정모델링 및 공정제어]

    This course aims to provide students with fundamental knowledge of bioprocess operation and control with particular emphasis on environmental treatment systems. Different biokinetic models and their applications in process control are discussed.

  • ENV703 Introduction to Advanced Oxidation Technology [고도산화기술개론]

    This course provides basic concepts and principles of advanced oxidation technologies for environmental remediation which include ozonation, Fenton systems and photocatalytic processes.

  • ENV706 Introduction to Membrane Technology to Water/Wastewater Treatment [수처리/폐수처리 분리막 개론]

    Fundamental principles of membrane technology with focus on microfiltration, ultrafiltration, nanofiltration and reverse osmosis. Emphasis is on polymer chemistry, synthesis, modification, characterization and degradation of membranes and then application of the membranes to solve problems in aquatic systems.

  • ENV707 Environmental Biotechnology [환경생명공학기술]

    This course introduces applications of biotechnologies and molecular techniques today in environmental engineering with particular emphasis on biological pollutant removal processes.

  • ENV802~804 Special Topics for Environmental Engineers I~III [환경문제특수해석 I~III]

    In this class we will examine the causes of environmental pollution in the spheres of water, atmosphere, waste, noise and vibration; focus on the effect and prevention counterplan and a comprehensive management plan for prevention of environmental pollution.

  • ENV808 Special Topics in Environmental Science and Engineering [환경과학공학 특론]

    This course covers interdisciplinary topics on environmental science and engineering including environmental pollution and control, environmental analysis, climate change, and earth science.

  • EES502 Introduction to environmental analysis [환경분석개론]

    This course introduces sampling, pretreatment, and instrumental analysis for organic pollutants and heavy metals. The main contents are transport of pollutants, water analysis (major and trace constituents), analysis of solids and waste, atmospheric analysis (gases and particulates), and ultra-trace analysis.

  • EES503 Advanced Atmospheric Dynamics I [고급대기역학 I]

    The course covers fundamentals of geophysical fluid dynamics, which consists of five small topics. We first provide a brief introduction to fluid dynamics and the basic equations of motion. Then, the effects of stratification and rotation is introduced to discuss fundamental topics such as the primitive equations and the Boussinesq equations. Also, we introduce the shallow water equations that forms the simplest expression of many of the principles of geophysical fluid dynamics. We then discuss vorticity and potential vorticity. Finally, we derive simplified equation sets for large-scale flows, e.g. the quasi-geostrophic equations.

  • EES504 Mass Spectrometry [질량분석학]

    This course will introduce the principle and types of mass spectrometry, which has been widely used for trace-level analysis of organic pollutants. The interpretation of mass spectrum and applications for dioxin analysis will be also introduced.

  • EES505 Tropical Meteorology [열대기상학]

    Atmospheric motion in the tropics is distinguished from that in extratropics in physical and dynamical aspects.  The content includes the observed characteristics of tropical atmosphere, characteristics of tropical dynamics, tropical waves, and thermodynamic aspects of tropical atmosphere. The lecture is followed by tropical phenomena of El Nino-Southern Oscillation, Intraseasonal Oscillation, Monsoon, and Tropical Cyclone. This course is intended for early graduate or undergraduate students.

  • EES590 Seminar [세미나]

    The purpose of this course is to extend knowledge to the state-of-the-art R&D in real scientific fields and to get indirect experience by contacting experts in various fields. Students and professors can exchange their own ideas and information to reach creative and fine-tuned achievements through the Seminars

    EES601 Atmospheric Physics [대기물리]

    Atmospheric physics is applied to study the details of weather and climate, which includes the processes of radiation, cloud physics, convection, and turbulence. Moreover, understanding of the interaction between aerosol and cloud microphysics is gaining its importance recently for its uncertain role in the global warming. The course will cover these processes and their theoretical backgrounds based upon physics.

  • EES602 Gas Hydrates and Climate Change [가스 하이드레이트와 기후변화]

    This course presents the basic understanding and concepts of gas hydrates and their impacts on climate change. This course also covers exploration and production of natural gas hydrates, gas hydrate-based carbon dioxide capture and storage methods, and other novel technologies relating to gas hydrates.

  • EES603 Advanced Atmospheric Dynamics II [고급대기역학 II]

    The course is composed of two main topics: i) instabilities and wave-mean flow interaction, ii) large-scale atmospheric circulation. In the first half, we cover barotropic and baroclinic instability and how the waves and instabilities affect the mean flow in which they propagate. In the second half, we are mostly concerned with the dynamics of the Hadley and Ferrel Cells and mid-latitude circulation.

  • EES604 Analysis and Monitoring of Organic Pollutants [유기오염물질 분석 및 모니터링]

    This course will focus on multimedia sampling, extraction, cleanup and instrumental analysis for environmental monitoring of organic pollutants.

  • EES605 Air Pollution Management [대기오염관리]

    This course presents information about the general topic of air pollution and its control, and also covers the design procedures of various air pollution control.

  • EES611 Climate-Environment Modeling [기후환경 모델링]

    The global climate model has been extensively used for medium-range weather forecasts, seasonal prediction, global atmospheric and oceanic reanalyses, and climate change predictions due to the increased greenhouse gases. This course introduces state-of-the-art modeling technologies that construct the model, including numerical approximations for the dynamical part, and the representations of physical parts related with sub-grid scale radiation, condensation, boundary-layer turbulence, and the treatments of land surface. The students will experiment and produce the actual simulation outputs by testing the community model opened in public.

  • EES651 Remote Sensing of the Environment [환경원격탐사]

    This course investigates diverse applications of remote sensing as well as advanced digital image processing techniques for each application. This course covers understanding of various remote sensing systems (e.g. hyperspectral, LiDAR), their applications (e.g. vegetation, water) and advanced digital image processing techniques (e.g. object-based, texture-based, machine learning). Several interactive digital image processing systems (e.g., ENVI, ERDAS IMAGINE, ArcGIS, and/or MATLAB) are used by the students to analyze satellite and airborne-acquired remotely sensed image data.

  • EES652 Machine Learning for Remote Sensing Applications [원격탐사활용을 위한 인공지능]

    This is an introductory to intermediate level course to artificial intelligence focusing on machine learning, targeted toward graduate students with background remote sensing. The goal of this course is very practical, providing hands-on knowledge about basic and some recent artificial intelligence models such that you can use the models to solve real-world problems, especially focusing on remote sensing. The course consists of a series of lectures and labs. Students may need to conduct individual or group projects depending on class size and students’ background.

  • EES653 Atmospheric Radiation [대기복사론]

    This course introduces the overall theory of radiative transfer in the Earth’s surface and atmosphere. Also, this course aims to understand the remote sensing techniques with respect to the observed wavelength by understanding the principle of radiative transfer model. After understanding the radiative theory, the students practice the radiative transfer model simulations for their own research purposes.

  • EES680~682 Special Topics in Earth and Environmental Sciences I~III [지구환경과학 특강 I~III]

    We study the current hot topics in Earth and Environmental Sciences.

  • EES803 Current Topics in Carbon Dioxide Capture and Storage [이산화탄소 회수 및 저장 특론]

    This course is intended to introduce recent technologies on carbon dioxide capture and storage developed and being developed for mitigating global warming.

  • UIE501 Continuum Mechanics of Solids [고체연속체역학]

    This course is concerned with idealization of continuous materials that can be a solid or a fluid. In lectures, we deal with tensor expression, definition of stress and strain in 3 dimensional space, and developing constitutive equations.

  • UIE502 Structural Dynamics [구조동역학]

    The dynamic response of structures and structural components to transient loads and ground excitations is discussed for single and multi degree-of-freedom systems, including discussions for response spectrum concepts, simple inelastic structural systems, systems with distributed mass and flexibility, and fundamentals of experimental structural dynamics.

  • UIE503 Earthquake Resistant Design [내진설계론]

    The course topics include the behavior, design, and assessment of indeterminate reinforced concrete and steel structures subjected to gravity, wind, seismic, and blast loads. Primary emphasis will be given to the introduction of available design methods for two-way slab systems, and the earthquake-resistant design of beam-column frames, slab-column frames, and shear walls.

  • UIE504 Low Carbon Concrete [저탄소 콘크리트 공학]

    Portland cement concrete is highly economical and versatile construction building material; however, manufacture of portland cement is responsible for at least 5~8% of total worldwide man-made CO2 emission because one ton of portland cement production generates 0.9 ton of CO2. Development of new alternative binder with extremely low carbon emission to replace the portland cement in concrete production has been an urgent goal in academia and industries to build up sustainable future urban society. This course presents the state-of-art technology and research methodologies in the low carbon concrete.

  • UIE505 Research Methods for Urban Studies [도시연구방법론]

    Quantitative analysis of data used in urban planning research. Particular emphasis on Inferential statistics through multinomial regressions, forecasting, categorical data analysis, and spatial data analysis.

  • UIE507 Finite Element Methods [유한요소법]

    The topics of this course include the theory and application of finite element methods stiffness matrices for triangular, quadrilateral, and isoparametric elements two- and three-dimensional elements; algorithms necessary for the assembly and solution; direct stress and plate bending problems for static, nonlinear buckling and dynamic load conditions; and displacement, hybrid, and mixed formulations.

  • UIE509 Urban Design Workshop [도시설계워크샵]

    Examines urban design theory and principles, and evaluates the built environment in a studio-based setting. Working in teams, students become immersed in real work examples and propose design interventions for specific places, including socially diverse neighborhoods in small cities and major metropolitan urban centers.

  • UIE510 Advanced Engineering Mathematics [고급공학수학]

    This course covers the basics of graduate-level applied mathematics for students majoring in engineering. Topics include complex variables, integral transformations, and partial differential equations.

  • UIE511 Mechanics of Composites and Fiber Reinforced Cement Composites [복합재료 역학 및 섬유보강 시멘트 복합재료]

    This course is devoted to the mechanics of anisotropic solids with applications to composite materials for civil engineering applications. One half of the course focuses the study of composite materials structures based on three-dimensional elasticity analysis. Another part is concerned with the mechanics of fiber reinforced brittle matrices and the implications for cement-based system.

  • UIE602 Crack Analysis in Concrete [콘크리트 균열해석]

    Concrete structures are full of cracks. Their failure involves stable growth of large cracking zones and the formation of large fractures before the maximum load is reached. This course reviews the mechanism and analytical techniques for the cracking, which includes fracture mechanics of concrete and nonlinear mechanics of reinforced concrete.

  • UIE603 Time-Dependent Properties of Concrete [콘크리트 시간의존적 특성]

    Creep refers to long-term deformation, usually for several years in the case of concrete, when a material is under constant load. Even within short time, large amount of creep is observed at early age of concrete, which sometimes causes a problem on the construction of high-rise buildings and piers. In the period, shrinkage is accompanied and affects the dimensional stability of early-age concrete. Thermal deformation due to heat and its transfer of hydration is also an important time-dependent property to be considered for the safety and serviceability of concrete structures.

  • UIE702 Nonlinear Finite Element Analysis [비선형 유한요소해석]

    This course provides a comprehensive description of nonlinear finite element analysis for solid mechanics. It aimed to understand various approaches and difficulties inherent in nonlinear analysis as follows: Lagrangian and arbitrary Lagrangian-Eulerian formulation, explicit or implicit time integration methods, and handling nonlinear constitutive laws and structural stability.

  • UIE704 Concrete Micro-characterization [콘크리트 미세구조분석]

    This course covers two promising structural concretes: fiber reinforced concrete (FRC) and geo-polymer concrete. This course discusses various topics on these two materials from practical view for commercial use to in-depth research topics. All students are required to perform experimental research on these two materials using the following materials characterization techniques: X-ray diffractioin and Scanning Electron Microscope (SEM) and to turn in the research term-papers at the end of quarter.

  • UIE706 Urban Regeneration [도시재생]

    Analyzes how economic, social, physical conditions of central cities can be improved through large-scale urban-planning efforts Understand the process of neighborhood revitalization and the main planning issues for the process.

  • UIE707 Theory of Planning [계획이론]

    The logic of planning as a professional activity and Construction of methodologies for evaluating various theories of planning. Critical overview of current process theories leading students to develop a personal philosophy applicable to their work as planners.

  • UIE708 Planning for Housing [도시주택론]

     The role of housing in urban planning supply and demand of the housing market and analysis of public policies for housing as they affect special consumer groups (the poor, the elderly, and the minorities).

  • UIE802 Rheology of Concrete [콘크리트 레올로지]

    Concrete experience solidification from fluid. Its rheological properties before setting of concrete are critical for casting and construction of concrete structures. This course reviews fundamentals of fluid mechanics and rheology of unset concrete.

  • UIE804 Urban Modeling and Simulation [도시 시뮬레이션]

    Urban modeling and simulation is an essential analytic technique for scenario planning. This course addresses two popular urban modeling and simulation techniques: space syntax and agent-based simulation model. After successfully completing this course, the students will be able to understand the modeling process and apply the techniques to analyze urban planning and design issues.

  • UIE810~812 Special Topics in Urban Infrastructure Engineering I~III [도시기반시설공학특론 I~III]

    This course introduces new research topics in urban infrastructure engineering.

  • UIE590 Seminars [세미나]

    The purpose of this course is to extend knowledge to the state-of-the-art R&D in real scientific fields; and to get indirect experience by contacting experts in various fields. Students and professors can exchange their own ideas and information to reach creative and fine-tuned achievements through the Seminars.

  • DME502 Structural Reliability [구조신뢰성]

    The aim of this course is to offer a comprehensive review of reliability analysis methods and their applications to civil and structural engineering problems. In this course, students will learn several probabilistic approaches for structural reliability assessment including first- and second-order reliability methods, system reliability methods and sampling-based methods. As a final project, each student will be asked to model his/her own structural reliability problem and to solve it using one of the reliability analysis methods covered in this course.

  • DME503 Disaster Response and Recovery [재난대응 및 복구]

    This course examines the theory and practice of response and recovery,  including response variance and effectiveness. This course provides knowledge on immediate and long-term aspects of management of the post-impact phase of a disaster. The aim is to generate understanding of specific actions that should be taken during the post-impact stage of a disaster to facilitate its effective management.

  • DME505 Disaster Mitigation and Preparedness [재난완화 및 대비]

    This course discuss the variety of actions taken by individuals, households, businesses, communities, and governments to both prepare for the impact of disasters and offer realistic strategies to mitigate the adverse consequences of disasters. This course will explore hazard mitigation and preparedness procedures, programs, and planning through case studies.

  • DME506 Numerical Weather Prediction [수치 예보]

    This course introduces the basics concept of numerical modeling for weather prediction and provides student with the relevant numerical methods (e.g., grid and spectral methods). In addition, students study how to apply numerical methods to practical researches such as weather forecast.

  • DME507 Climate and Air Pollution: Integrated Approach [기후와 대기환경: 통합적 접근]

    This course focuses on the inter-impact between climate and air pollution. Especially, students will study the impact of the air pollution on climate adaptation and mitigation through co-benefit and trade-off effect.

  • DME508 Introduction to Safety Design [안전디자인 개론]

    Safe city design is based on four lines of specialized branches: 1)traffic safety-Traffic calming is a measure to slow down traffic flows, 2)fire prevention-to establish evacuation routes and to make people and fire fighters move faster, 3)crime prevention-surveillance and access control, 4)Disaster prevention & mitigation. The four lines of design philosophy have contradictory characteristics. This course will provide the basic knowledge of traffic safety, fire prevention, crime prevention, and disaster prevention & mitigation. Finally, this course will find a “Comprehensive Safety Design Model” that are creative and harmonious design principle.

  • DME509 Geotechnical Earthquake Engineering [지반지진공학]

    This course introduces fundamental concepts of earthquake engineering related to geotechnical problems, principles of earthquake, wave propagation, dynamic soil properties, liquefaction and seismic design of various geotechnical structures. This course begins with an introduction to seismology and tectonics, and continues with discussion on deterministic and probabilistic seismic hazard analyses, as well as site response analysis. In addition, the responses of various geotechnical structures such as foundations, retaining structures, and slopes subject to earthquake loading are discussed.

  • DME601 Disaster Planning and Policy [재난계획 및 정책]

    This course provides knowledge to appreciate the need for integrating disaster risk reduction aspects in development policy, planning and implementation. The purpose is to equip students with the skills to identify the linkages between disasters and development, and understand the formulation and application of appropriate development planning policies integrating disaster risk reduction. This course includes reviews and critiques actual plans and engages students in components of effective disaster planning within and across various jurisdictions.

  • DME602 Earthquake Engineering [지진공학]

    The first part of this course will focus on hazard analysis with emphasis on earthquake. The concepts necessary to understand, classify, and analyze an earthquake. The following concepts will be presented: the nature, power, and source of an earthquake, the wave propagation theory from the source to the site of interest, the characterization of a ground motion through different intensity measures, Probabilistic Seismic Hazard Analysis (PSHA). The second part of this course will involve earthquake design. The calculation of the demand and capacity of a structure subject to earthquake load will be studied. The common foundations at the base of each seismic design code will be explained. The different analyses available to assess the structural response of a structure will be explained: response spectrum method, pushover analysis, non-linear time history analysis.

  • DME604 Reliability of Infrastructure Systems [사회기반시설시스템의 신뢰성]

    This course will present the different methods used to estimate: the vulnerability of individual components and the reliability of entire civil infrastructures systems including distributed systems and complex systems. Examples of distributed systems are highway networks, power grids, water distribution systems. Examples of complex systems are nuclear power plants, dams, and chemical plants. Special consideration will be given to event tree analysis and fault tree analysis for complex systems, and Monte Carlo simulation for distributed systems.

  • DME701 Disaster Theory and Practice [재난이론과 응용]

    This course reviews the theoretical assumptions and foundation of disaster management from the interpersonal, small group, organization and societal levels.

  • DME702 Advanced Numerical Modeling for Weather [고급기상수치모델링]

    This course provides students with advanced techniques of the atmospheric numerical modeling such as objective analysis, data assimilation, physics parameterizations and boundary condition improvement.

  • DME703 Random Vibrations [불규칙진동론]

    This course introduces probabilistic methods and applications to describe structural behavior under stochastic dynamic loads. Both time and frequency domain analyses to extract meaningful information from random signals are discussed. Theoretical and computer-aided approaches for data processing and analysis are covered.

  • DME705 Micro-meteorology and Environment [환경미기상학]

    The objective of this course is to understands the physical and dynamical characteristics of the atmospheric planetary boundary layer and the structure of local air circulation near the earth surface. Also students will learn how to apply the micro-meteorological knowledge onto the atmospheric environment problems.

  • DME801~802 Special Topics in Disaster Management Engineering I~III [재난관리공학특론 I~III]

    This course introduces new research topics in disaster management engineering

  • CSA511/AHS111 Understanding Arts [예술의 이해]

    This course introduces students to the use of arts and design to develop fresh approaches to creating new content in the arts, humanities, and technologies. Students explore diverse themes and topics in the contemporary arts, digital humanities, and product prototyping to create novel media objects or compositions through teamwork. Readings include a selection of classic and contemporary critical cultural texts from the arts and design.

  • CSA521 Scientific Methodology [과학기술방법론]

    This course is on both scientific knowledge and artistic abstract, and also on the filosopia of convergence of science and arts. It encompasses fundamental observation procedures of nature, more detailed methodologies for knowledges and abstract, and underlying philosophy of the methods taken in this issue.

  • CSA561/AHS161: Introduction to Philosophy [철학 개론]

    In this course we shall examine various philosophical views at the preliminary level. The aim of the course is to provide the students with a general introduction to seminal questions in philosophy, to lead them to engage in deep thinking and reflections on important matters in life, and to enable them to make their own arguments on a given issue in a critical and reasonable fashion.

  • CSA590 Convergence of Science and Arts Seminars I [과학예술융합 세미나 I]

    The purpose of this course is to extend knowledge to the state-of-the-art R&D activities integrating science and arts in various fields. Students will be encouraged to share their ideas and thoughts to cultivate their ability of creative thinking.

  • CSA591 Convergence of Science and Arts Seminars II [과학예술융합 세미나 II]

    The purpose of this course is to extend knowledge to the state-of-the-art R&D activities integrating science and arts in various fields. Students will be encouraged to share their ideas and thoughts to cultivate their ability of creative thinking.

  • CSA710/AHS310 Topics in Arts [예술 특강 (with Subtitle)]

    This course focuses on a special topic in the field of arts. The particular contents of this course will be chosen by the instructor each semester when it is offered.

  • CSA760/AHS360 Topics in Philosophy [철학특강 (with Subtitle)]

    This course focuses on a special topic in the field of philosophy. The particular contents of this course will be chosen by the instructor each semester when it is offered.

  • CSA711~20 Special Topics in Science and Arts I~X  [과학예술특론 I~X]

    It is the project based class which is designed to tell students into contributing to necessary activities to solve existing problems of community where we live. Students are asked to design the methodologies of classes to work on project(s), from strategic plannings to working realities. Students may solve the problem which they also select in scientific, artistic, or multidisciplinary ways. Classes are to be held on the sites which all the activities happen: laboratory, studio, working place, and even in-between those. Students are subject to submit their reports with flexible formats and to exhibit those as either scientist, engineer, philosopher, or artist, at the end of the semester.