Curriculum
| Summary | English |
|---|---|
| Multi-functional Smart Construction Material | |
| This course deals with multi-functional construction material (MFCM) to endow electrical and thermal function to traditional constructional material. Theory, fabrication, application, and numerical modeling of MFCM will be comprehensively studied in this course. | |
| Smart Earthquake Resistance Engineering | |
| Design of single and multi-degree of freedom system based on smart earthquake engineering resistance | |
| Smart Water Management | |
| This course deals with water resources big-data collection, analysis, and prediction theory, big-data quality control algorithm and optimization technique for smart water management | |
| Individual study (smart maintenance) | |
| graduate students in the field of smart maintenance conduct independent research with their advisors. Dissertations in the field of smart maintenance on the research topics will be conducted individually. | |
| Individual study (smart disaster metigation) | |
| graduate students in the field of smart disaster metigation conduct independent research with their advisors. Dissertations in the field of smart disaster metigation on the research topics will be conducted individually. | |
| Individual study (smart construction) | |
| graduate students in the field of smart construction conduct independent research with their advisors. Dissertations in the field of smart construction on the research topics will be conducted individually. | |
| Advanced Environmental Reaction Engineering | |
| Characteristics of reactions, principles, reaction kinetics analysis, application of reaction characteristics, unit process design and reactor design in water and wastewater treatment processes. | |
| Theory and Design of Adsorption | |
| Theory of adsorption, types and properties of adsorbents, characterization of adsorption phenomena (equilibrium and kinetics), interactions between adsorbents and adsorbates, and design of adsorption process for water and wastewater treatment. | |
| Engineering Hydrology | |
| Analysis of rainfall, evaporation and infiltration, rainfall-runoff simulation, flood runoff, flood routing methods, frequency analysis. | |
| Special Topics in Ground-Water | |
| Groundwater properties, groundwater flow equation, permeability coefficient, type of aquifer and permeability, groundwater well theory, groundwater balance, groundwater modelling. | |
| Water Resources Engineering | |
| Lectures on concepts and application examples of various machine learning techniques applied to water engineering. | |
| Industrial Waste Water Treatment | |
| Classification of wastewater generated by factories according to characteristics and characteristics, and adoption of appropriate treatment methods and lectures on optimal operating factors. | |
| Advanced Oxidation Processes | |
| Lecture on basic theory and application of chemical reaction used in environmental engineering to understand and analyze pollutants and to understand and design physicochemical and biological treatment process. | |
| Statistical Hydrology | |
| Learn the basic principles of various statistical theory and models, and lecture on application to civil and water resources engineering. | |
| Water Resources Systems Design | |
| Characteristics of water resources system, analysis of system, application of water resource system, water management system, application of linear, nonlinear programming method, dynamic programming method in water resource planning. | |
| Soil and Ground Water Remediation | |
| Study of contaminated soil and groundwater to address water shortage and water pollution. | |
| Theory and Design of Water Treatment Plant | |
| Theories of coagulation, sedimentation and filtration used in the treatment of water, and design methods of water treatment facilities using these processes. | |
| Theory of physical treatment process | |
| Lecture on physicochemical process in pollutant removal process. | |
| Environmental microbiology | |
| This course will expose students to fundamentals of applied and environmental microbiology in context of environmental science and engineering. | |
| Biological wastewater treatment | |
| This course will expose students to fundamentals of environmental biological processes and skills and application of biological, chemical and physical principles to the analysis and design of biological processes for the treatment of municipal and sludge. | |
| Environmental genomics | |
| This course will expose students to fundamentals of environmental microbiology, molecular microbiology, and bioinformatics and their applications in context of environmental engineering and science. The course will introduce students to 1) state-of-the-art computational microbiology techniques for analyzing molecular data (e.g., DNA, RNA, and protein) associated with environmental biotechnology and microbial ecology, 2) inferential statistics, and 3) molecular microbiological tools. Upon successful completion of this course, students will be able to apply the skills and knowledge they learn from this course to their own research projects related to environmental biological processes. | |
| Special topics in environmental biotechnology | |
| This course will deal with recent advances in environmental biotechnology and ecological engineering and discuss select papers associated with applications of environmental genomics and bioinformatics into environmental engineering. | |
| Urban Hydrology | |
| Analysis of rainfall, evaporation and infiltration, groundwater flow, river flow measurement and calculation, flood runoff, flood tracing hydrological simulation, probabilistic hydrographic analysis in urban area. | |
| Reliability Theory in Civil Engineering | |
| Analysis of safety and reliability of structures, theory of load and resistance model development, application to system | |
| Earthquake Resistant Design | |
| Basic concepts of earthquake, seismic analysis, seismic design of bridge structures, seismic design, etc. | |
| Dynamics | |
| Dynamic analysis theory of multi-degree-of-freedom structures, computer application, structure-soil-fluid interaction. | |
| Finite Element Methods | |
| Galerkin method, formulation of finite element method by variational method, boundary value problem, shape function, etc., are analyzed and applied to Frame, Plate, Shell etc. | |
| Advanced Mechanics of Materials | |
| Failure, stress and strain at arbitrary points, asymmetric bending shear, energy law, etc. | |
| Mechanics of Composite Material for Construction | |
| Lecture on manufacturing of composites applicable to construction field, material characteristics, lamination analysis, fracture criterion. | |
| Nonlinear Structure Analysis | |
| Nonlinear analysis algorithm, nonlinear material model, 1-dimensional and 2-dimensional nonlinear element. | |
| Design and Analysis of Concrete Pavement Structures | |
| The behavior and performance of concrete pavement structures and the design and analysis methods are taught. | |
| Special Topics in Prestressed Concrete Structure | |
| Pre-Stressing theory is discussed, and the techniques applied to the design of P.C structures such as P.C beam, Slab, and Box girder are discussed. | |
| Structural analysis of pavement system | |
| This course deals with the general aspects of pavement engineering, including the characteristics of the materials used for pavement and the factors affecting other pavements, such as climate, environmental conditions and traffic conditions, and pavement structural analysis techniques to predict pavement behavior. | |
| Soil Behavior | |
| Understanding the behavior of soils according to various physical, chemical, and mechanical conditions. | |
| Laboratroy and In-situ Geotechnical Testing Methods | |
| Based on understanding of the various laboratory and in-situ geotechnical testing methods, geotechnical properties of soils can be estimated. | |
| Geotechnical Numerical Analysis | |
| Various geotechnical problems are analyzed based on numerical analysis methods such as determinant, linear algebra, eigenvalue analysis, analysis of equation, integral method and differential equation. | |
| Deep Foundation | |
| Deep foundation concepts, pile foundations, caisson foundations, tundish foundations, pond foundations. | |
| Soil and Rock Dynamics 1 | |
| Dynamic analysis of terminal guiding system, Propagation of elastic wave, Seismic wave test, Dynamic strain characteristics. | |
| Highway Engineering & Design | |
| A brief lecture on the selected topic of road engineering and a report on how to express it in a report. | |
| Special Topics in Highway Engineering | |
| A brief lecture on the selected topic of road engineering and a report on how to express it in a report. | |
| Basic Topic in Pavement Engineering | |
| This course deals with the general aspects of pavement engineering, including the characteristics of the materials used for pavement and the factors affecting other pavements, such as climate, environmental conditions and traffic conditions, and pavement structural analysis techniques to predict pavement behavior. | |
| Asphalt Materials Performance | |
| Study on the types of materials used for road pavement, road construction using new materials and recycling of construction materials. | |
| Complex and Linear Analysis | |
| Topics include theory and linear equations for complex functions such as Taylor series, complex Fourier series, complex integral and Laplace inversion formulas. | |
| Pavement Design | |
| The types and materials of materials used for stabilization of each layer of road pavement, Criteria requiring stabilization, Test method, Recycling through stabilization of waste materials. | |
| Asphalt Pavement Engineering | |
| This course deals with the general aspects of pavement engineering, including the characteristics of the materials used for pavement and the factors affecting other pavements, such as climate, environmental conditions and traffic conditions, and pavement structural analysis techniques to predict pavement behavior. | |
| Pavement management system | |
| Lecture on maintenance system of road and road facilities and specific network level. | |
| Advanced Pavement Design | |
| Lecture on the evolution of packaging design techniques, commentary on design methods used in foreign countries, and design methods in Korea. | |
| Individual study (Ph.D course) | |
| Graduate students of Ph.D. in Social Infrastructure Systems Engineering conduct independent research with their advisors. In-depth research on the subject of Ph.D dissertation in Civil Engineering is conducted individually. | |
| Advanced Engineering Mathematics | |
| Special function, orthogonal function, vector space, partial differential equation, Green function. | |
| Graduate Seminar for Civil Engineering | |
| Graduate students of the Department of Social Infrastructure System Engineering will hold various seminars on advanced theories of civil engineering. We learn how to deal with the theory in the course of civil engineering construction through seminar class. | |
| Environmental biological system: design | |
| This course will expose students to applications of environmental microbiology and environmental bioengineering. Students will be to design a single or a treatment train of an environmental biological system such as biological water, wastewater, and waste treatment processes. | |
| Environmental biological system: operation and analysis | |
| This course will expose to operational and trouble shooting skill/knowledge of environmental biological systems. Students will be to collect, process, and analyze various types of physicochemical and biological data from the systems, with which they will learn predictive controls and decision makings for sustainable management of the systems. | |
| Climate change (the) adaptation | |
| This lecture covers theories of science and current status of climate change, impact and response of climate change, climate negotiations, climate change economics, and climate change adaptation policy to understand the overall contents of climate change adaptation. Moreover, based on civil engineering background, we learn how to apply and implement our climate change knowledge. |