〔教　授　要　目〕

　コンクリート構造物のせん断問題に関して，耐荷力，破壊メカニズム等の定量的な評価方法を習得する。またそれとともに，コンクリートの破壊力学と寸法効果，格子モデルを用いたせん断問題の解析方法，繊維補強コンクリートや超軽量コンクリートのせん断耐荷特性等の最新の研究成果についても理解していく。

1. 総説
2. コンクリート構造物のせん断問題
3. コンクリートの破壊力学と寸法効果
4. 格子モデルによるせん断解析
5. 繊維補強コンクリートの破壊力学特性とせん断耐荷特性
6. 超軽量コンクリートの破壊力学特性とせん断耐荷特性

Mechanics of Structural Concrete（コンクリート構造特論）
　1st Semester (April) (2−0−0) (Odd years)
　Prof. Junichiro Niwa

1. Lectures on the mechanics of structural concrete. Some recent topics related to fracture mechanics of concrete are included.
2. 1．Introduction
   2．Ultimate shear capacity of structural concrete
   3．Ultimate torsional capacity of structural concrete
   4．Ultimate capacity of RC short column
   5．Ultimate capacity of RC slender column
   6．Fracture mechanics of structural concrete
   7．Prediction of structural size effect

Advanced Concrete Technology（コンクリート工学特論）
　2nd Semester (October) (2−0−0)
　Prof. Nobuaki OTSUKI

　国際開発工学専攻の教授要目を参照のこと。

61048
Advanced Course on Elasticity Theory
　2nd Semester (October) (2−0−0)
　Assoc. Prof. Anil C. WIJEYEWICKREMA

1. Mathematical preliminaries - Cartesian tensors
2. Mathematical preliminaries - Tensor algebra
3. Kinematics - Configurations and motions
4. Kinematics - Deformation gradient and deformation of volume and surface elements
5. Kinematics - Strain, stretch, extension and shear
6. Kinematics - Geometrical interpretation of the deformation
7. Analysis of motion - Deformation and strain rates
8. Balance laws
9. Cauchy stress tensor and Nominal stress tensor
10. Conjugate stress analysis
11. Constitutive laws
12. Linear anisotropic elasticity
13. Lekhnitskii formalism
14. Stroh formalism

61065
Introduction to Solid Mechanics
　1st Semester (April) [Credit]　　2−0−0
　Assoc, Prof. Anil C. Wijeyewickrema

1. Mathematical preliminaries - Index notation
2. Mathematical preliminaries - Vectors and Cartesian tensors
3. Mathematical preliminaries - Eigen-value problems, vector and tensor calculus
4. Stress and strain - Stresses, traction and equilibrium equations
5. Stress and strain - Principal stress and maximum shear stress
6. Stress and strain - Strain tensor
7. Cylindrical polar coordinates
8. Spherical coordinates
9. Linear elasticity - Hooke's law
10. Linear elasticity - Introduction to anisotropic elasticity
11. Elastostatic plane problems - Classification of two-dimensional elasticity problems
12. Elastostatic plane problems - Airy stress functions
13. Elastostatic plane problems - Infinite plate problem and Kirsch solution
14. Elastostatic plane problems - Infinite plane with a uniform body force in a circular region

61005
Fracture Control Design of Steel Structures
　2nd Semester (October) (2-0-0) (Odd Years)
　Prof. Chitoshi Miki

1. Classification of Fracture Modes of Steel Structures
2. Damage Cases in Steel Structures during Earthquakes
3. Fundamental Concepts of Fracture Mechanics
4. Fracture Toughness of Steels
5. Predominant Factors of Brittle Fracture
6. Fatigue Strength of Structural Elements
7. Nominal Stress Based Fatigue Design
8. Structural Stress Based Fatigue Design
9. Quality Control of Structural Elements
10. Fatigue Strength Improvement Methods
11. Maintenance of Steel Bridges
12. Characteristics and Prevention of Brittle Fracture during Earthquakes
13. Lessons learned from Failure
14. Discussions: Case Studies

61059
Retrofit Engineering for Urban Infrastructures
　2nd Semester (October) (2-0-0) (Even Years)
　Prof. Chitoshi Miki, Assoc. Prof. Kiyoshi Ono

1. Recent Problems in Urban Infrastructures
2. Classification and Causes of Deterioration of Infrastructures
3. Inspection and Measurement
4. Application and Recent Problems of Nondestructive Evaluations
5. Health Monitoring Systems with Sensors for Damage Detection
6. Evaluation of Actual Strengths of Existing Structures
7. Ultimate Strengths of Deteriorated Structural Elements
8. Retrofitting of Corroded Structural Elements
9. Seismic Retrofitting of Deteriorated Structural Elements
10. Fatigue Retrofitting of Deteriorated Structural Elements
11. Strengths of Repaired Structural Elements and Structures
12. Life Cycle Cost Evaluation
13. Strategy of Health and Damage Assessment of Existing Structures
14. Discussions: Case Studies

　都市施設として代表的な橋梁を中心に，耐震設計法に関して講義する。内容は以下の通りである。

1. 過去の地震被害
2. 地震動の工学的特性と設計地震動
3. 構造物の非線形動的応答と荷重低減係数
4. 構造部材の動的耐力・変形性能
5. 耐震設計法
6. 性能目標と性能規定型耐震設計法
7. 耐震性判定法と耐震補強

Seismic Design of Urban Infrastructures
　1st Semester (April) (2-0-0) (Odd Years)
　Prof. Kazuhiko Kawashima

　Enhancing seismic performance of urban infrastructures is essential to mitigate loss of function of urban areas during and after a significant earthquake. Seismic design of urban infrastructures is an important part of securing the seismic performance of urban aveas. Emphasis of this lecture will be placed on the seismic design of transportation facilities including bridges and underground structures in soft soil deposits. It has been revealed in the 1994 Northridge, USA earthquake and 1995 Kobe, Japan earthquake that bridges and underground structures are vulnerable to near-field ground motions. The 1999 Bolu, Turkey earthquake and the Chi Chi, Taiwan earthquake resulted in the significant damage of bridges and underground structures by fault-induced displacements. Presented in this lecture are the characterization of ground motions, past damage of transportation facilities, linear and nonlinear dynamic response of bridges and underground structures, effect of poundings, strength and ductility of reinforced concrete piers, columns and walls, performance goals and performance-based seismic design, seismic deformation method, and seismic evaluation and seismic retrofit.

　都市施設として代表的な橋梁を中心に，免震設計に関して講義する。内容は以下の通りである。

1. 過去の地震被害
2. 設計地震動
3. 構造物の非線形動的応答
4. 構造部材の動的耐力・変形性能
5. 免震設計の歴史
6. 免震設計の基本
7. 免震設計の適用
8. 長大橋の免震設計
9. 免震設計を用いた耐震補強

Seismic Response Modification of Urban Infrastructures
　2nd Semester (October) (2-0-0) (Even Years)
　Prof. Kazuhiko Kawashima

　A variety of seismic response modification technologies are effectively used to mitigate damage of urban infrastructures during a significant earthquake. Seismic isolation is widely adopted for bridges. Isolation of underground structures from the surrounding soft soils is often used to mitigate the response. Various damper technologies are used in not only standard bridges but also long-span bridges. Rocking isolation is attracting increased interest. Emphasis of this lecture will be placed on the seismic design of transportation facilities including bridges and underground structures in soft soil deposits. The target of the seismic response modification of bridges and underground structures is not to secure the comfort of residence during small to moderate earthquakes as buildings but to enhance the seismic performance during a significant earthquake. Presented in this lecture are passive and semi-active damper technologies, variable dampers, advanced magnetic rheological damper, seismic isolation using elastomeric bearings including the lead rubber bearings and the high damping rubber bearings, effect of pounding of decks, rocking response isolation of foundations, isolation of underground structures, and implementation of seismic isolation to seismic retrofit of existing bridges.

1. Introduction
2. Role of probability in Engineering Design
3. Design and Decision Making Under Uncertainty
4. Basic probability Concepts
5. Analytical Models of Random Phenomena
6. Functions of Random Variables
7. Estimating Parameters form Observations
8. Empirical Determination of Distribution Models
9. Decision Analysis
10. Statistics of Extremes
11. Reliability and Reliability Based Design

61049
Geo-environmental Engineering（地盤環境工学）
　1st Semester (April) (2−0−0)
　○Assoc. Prof. Jiro TAKEMURA

1. Introduction
2. Ground contaminants-its mechanism and physical laws
3. Characteristics of ground water and geochemistry
4. Waste disposal
5. Remediation technology
6. Monitoring and prediction methods
7. Site visits

61034
Stability Problems in Geotechnical Engineering（地盤安定論）
　2nd Semester (October) (2−0−0)
　○Assoc. Prof. Akihiro TAKAHASHI, Prof. Masaki KITAZUME, Assoc. Prof. Jiro TAKEMURA

　Explain on various theories of stability analysis and their applications to geotechnical engineering problems.
　Various construction techniques for underground structures are also explained.

1. Introduction
2. Stability Analysis
   1）Limit Equilibrium
   2）Limit Analysis
   3）Finite Element Method
3. Application to geotechnical engineering problems
4. Interaction between soil and structure
5. Construction of underground structures
6. Ground improvement
7. Site visit

61061
Physical Modeling in Geotechnics
　2nd Semester (October) (2-0-0)
　Assoc. Prof. Jiro Takemura, Assoc. Prof. Akihiro. Takahashi

　This course covers scaling laws and modeling considerations for physical modeling in geotechnical problems both for static and dynamic conditions with laboratory exercises.

1. Introduction
2. Similitude and modeling principle
3. Design of physical model and model ground preparation
4. Model planning and measurement strategy
5. Sensors
6. Recent development in physical modeling
7. Modeling exercise

61038
Mechanics of Geo-materials（地盤材料学特論）
　1st Semester (April) (2−0−0)
　○Prof. Masaki KITAZUME, Assoc. Prof. Pipatponsa Thirapong

　This course explains mechanical characteristics of various geo-materials, covering from naturally deposited soils and artificial materials.

1. Introduction
2. Behaviour of grains and packing of granular materials
3. Stress space and failure criteria
4. Micro-scopic view of geo-materials
5. Sampling and disturbance
6. Behaviour of naturally deposited soils -1
7. Behaviour of naturally deposited soils -2
8. Behaviour of improved geo-materials
9. Behaviour of reinforced geo-materials
10. Time dependent behaviour of geo-materials
11. Constitutive equations
12. Presentation by students

　非線形計画法（Nonlinear Programing）の理論とアルゴリズムを基礎として，交通ネットワーク分析，とりわけネットワークフローを記述する利用者均衡（User Equilibrium）の理論と数値計算法を解説する。需要固定型の確定的なモデルから，需要変動型の確率的なモデルまで体系的に論じるとともに，UEモデルが交通計画にどのように応用されるかについて述べる。

1. 交通ネットワーク分析の役割
2. 非線形最適化の理論
3. 非線形最適化のアルゴリズム
4. 需要固定型利用者均衡モデル
5. 需要変動型利用者均衡モデル
6. 確率的利用者均衡モデル
7. 利用者均衡モデルの応用

（講義番号）
Transportation Network Analysis（交通ネットワーク分析）
　2nd Semester (October) (Even Years) (2−0−0)
　Prof. Yasuo ASAKURA

　Mathematical formulation and solution algorithms for User Equilibrium models in transportation networks are described based on the nonlinear optimization framework. A variety of UE models are introduced including deterministic UE model with fixed OD demand and stochastic UE model with variable OD demand. Possible applications of those models to transportation planning are also discussed.

1. Roles of transportation network analysis
2. Nonlinear optimization theory
3. Solution algorithms
4. User Equilibrium model with fixed OD demand
5. User Equilibrium model with variable OD demand
6. Stochastic User Equilibrium
7. Application of UE models

　交通投資や交通政策による社会経済的な影響を評価するために必要とされる交通経済学の理論と応用について学ぶ。具体的には，消費者や企業の行動理論，交通システムの費用構造に関する理論，混雑税の理論と実際，費用便益分析の基礎について解説する。

1. 消費者行動理論
2. 企業の理論
3. 交通の費用
4. 混雑税の理論
5. 混雑税の実際
6. 交通投資の費用便益分析

Transportation Economics（交通経済学）
　2nd Semester (October) (Even Years) (1−0−0)
　Assoc. Prof. Daisuke FUKUDA

　This course is designed to introduce graduate students with engineering background a solid grounding in the economic analysis of transportation.

1. Consumer behavior theory
2. Theory of the firm
3. Transportation costs
4. Congestion pricing: Theory
5. Congestion pricing: Practice
6. Benefit-Cost Analysis of Transport Facilities

　有限要素法及び境界要素法を用いた数値解析の基礎理論を解説する。

1. 変分法
2. 重み付き残差法
3. Galerkin法と有限要素法
4. 境界要素法

Civil Engineering Analysis（土木解析学）
　2nd Semester (October) (Odd Years) (2−0−0)
　Prof. Sohichi HIROSE

1. Lecture on fundamentals of numerical analysis including FEM and BEM
2. 1．Variational method
   2．Weighted residual method
   3．Galerkin method and finite element method
   4．Boundary element method

61067
数値解析法特論�T（Advanced Computational Method in Civil Engineering �T）
　前学期　2−0−0　　中村　恭志　准教授

　土木工学において対象とする物理現象を数値的に解析する際に必要となる数値計算手法について，差分法を中心として講義を行う。なお，講義時には演習を随時織り交ぜながら進める予定である。

1. 数値計算手法概説−微分方程式の差分近似の概念
2. 差分近似の誤差と収束安定性
3. 常微分方程式の高精度差分解法
4. 偏微分方程式の高精度差分解法−双曲・楕円・放物方程式
5. 計算結果の可視化方法

　偶数年に以下を開講

Advanced Computational Method in Civil Engineering �U
　Spring Semester (2−0−0) (Even Years)

61014
土木・交通計画のための数理分析特論
（Advanced Mathematical Methods for Infrastructure and Transportation Planning）
　前学期（西暦偶数年）　2−0−0　　福田　大輔　准教授

1. （1）交通需要予測における代表的な分析手法である“離散選択モデル（Discrete Choice Model）”の理論と応用について学ぶ。
2. （2）複数回の演習（データを用いた実際のモデル推定，交通，通信，電力，マーケティング等のデータを用いる）を通じて，実際の分析方法についても習熟する。

1. 二項選択モデルの推定
2. 多項選択モデル：ロジット，プロビット
3. 離散選択モデルの統計的検定
4. IIA，予測，マイクロシミュレーション
5. ネスティッドロジットモデル（NL）
6. ミックスドロジットモデル（MXL），モンテカルロ積分

Advanced Mathematical Methods for Infrastructure and Transportation Planning
（土木・交通計画のための数理分析特論）
　1st (Summer) Semester (Odd Year)　　2−0−0
　Assoc. Prof. Daisuke FUKUDA （Midorigaoka Building No.5, 2nd Floor, Ext.2577）

1. （1） To learn about the theory and application of the “Discrete Choice Model （DCM）”which has been widely used in travel demand forcasting.
2. （2） To learn about the practice of DCM through some computer exercises using the data on transportation, telecommunication, energy and marketing.

1. Estimation of Binary Choice Models
2. Multinomial Choice Models: Probit and Logit
3. Statistical Testing for Discrete Choice Models
4. IIA, Forecasting and Microsimulation
5. Nested Logit （NL） Model
6. Mixed Logit Model （MXL） and Monte Carlo Integration

　主に外国人教員が，その専門とする土木工学の最新の話題について英語により講義を行う。

　主に外国人教員が，その専門とする土木工学の最新の話題について英語により講義を行う。

　国際建設プロジェクトに対応可能な人材の育成を目的として，建設マネジメント，プロジェクトマネジメントの基本的知識，スキル等に関する講義を行う。

1. 建設プロジェクトの流れ
2. 建設産業の特徴と課題
3. 建設業務と会計
4. F/Sの方法と事例
5. 入札・契約
6. タイム・コストマネジメント
7. リスクマネジメント
8. プロジェクトファイナンス
9. 開発途上国における社会基盤整備と国際協力
10. PFIの仕組みと実例
11. アセットマネジメント
12. 建設マネジメントモデルと求められる資質とスキル

Principles of Construction Management（建設マネジメント特論）
　2nd Semester (October) (Odd year) (2−0−0)
　Associate. Prof. A. Hasegawa

　Considering international construction projects, elements of construction/project management will be lectured focusing on basic knowledge/skills/methodology, such as scheduling, cost management, risk management, bid, contract, legal issues, and project cash flow.

1. General Flow and Scheme of Construction Project
2. Bid/Contract
3. Estimation
4. Time Management
5. Cost Management
6. Project Funding / Cash Flow
7. Legal Issue, Claim, Change Order
8. Risk Management
9. O&M Management
10. ODA
11. Necessary Skills for Construction Management

61071
International Collaboration �T
　First Semester (April) (0−1−0) (Every Year)
　Prof. Junichiro Niwa，Prof. Hideaki Kaji

　This is second step course of G-COE's 3 step program. Japanese and foreign students who are interested in the mitigation of seismic mega risk in the urban area are strongly recommended to take this course. Enrolled students are required to visit a downtown Tokyo and make the proposal to mitigate the seismic mega risk. Finally, enrolled students are required to make the presentation of their proposal through the group work.

61072
International Collaboration �U
　Second Semester (October) (0−1−0) (Every Year)
　Prof. Junichiro Niwa，Prof. Hideaki Kaji

　This is the second step course of G-COE's 3 step program. Japanese and foreign students who are interested in the mitigation of seismic mega risk in the urban area are strongly recommended to take this course. Enrolled students have the exercise to write the proposal to mitigate the seismic mega risk of a big city according to the policy of Japan International Cooperation Agency. Finally, enrolled students are required to make the presentation of their proposal through the group work.

International Internship �T
　前学期　0−1−0　　二羽　淳一郎　教授

　G-COEコースの３ステッププログラムの最終段階の科目である。１ステップ目のInternational Communication1,2，２ステップ目のInternational Collaboration1,2に続くものである。１〜２ステップの科目履修を終えた後，実際に海外に行き，現地でG-COEのカウンターパートである大学の教員の指導のもと，現地学生と共同作業で，都市地震工学を対象とした調査・研究・資料収集・レポート作成ならびにプレゼンテーションを行う。

　First Semester (April) (0−1−0) (Every Year)
　Prof. Junichiro Niwa

　This is the third or final step course of G-COE's 3 step program. Japanese and foreign students who are interested in the mitigation of seismic mega risk in the urban area are strongly recommended to take this course. Enrolled students are required to visit a foreign country to have the experience on the site visit, investigation, and make a report with the students of the counterpart university under the supervision of Professors. Finally, enrolled students are required to make the presentation of their report through the collaboration.

International Internship �U
　後学期　0−1−0　　二羽　淳一郎　教授

　G-COEコースの３ステッププログラムの最終段階の科目である。１ステップ目のInternational Communication1,2，２ステップ目のInternational Collaboration1,2に続くものである。１〜２ステップの科目履修を終えた後，実際に海外に行き，現地でG-COEのカウンターパートである大学の教員の指導のもと，現地学生と共同作業で，都市地震工学を対象とした調査・研究・資料収集・レポート作成ならびにプレゼンテーションを行う。

　Second Semester (October) (0−1−0) (Every Year)
　Prof. Junichiro Niwa

　This is the third or final step course of G-COE's 3 step program. Japanese and foreign students who are interested in the mitigation of seismic mega risk in the urban area are strongly recommended to take this course. Enrolled students are required to visit a foreign country to have the experience on the site visit, investigation, and make a report with the students of the counterpart university under the supervision of Professors. Finally, enrolled students are required to make the presentation of their report through the collaboration.

61073
Aquatic Environmental Science
　First Semester (April) (Even Years) (2−0−0)
　Chihiro Yoshimura, Associate Professor

　This lecture is given to provide the fundamentals to understand aquatic ecosystems and their applications to assess aquatic environments for sustainable management. The fundamentals include aquatic chemistry, biogeochemistry, and aquatic ecology, which are common for freshwater and saltwater systems.

1. Major compounds in natural water
2. Basic analytical chemistry
3. Acidity of water
4. Oxidation and reduction
5. Dissolution and deposition
6. Particles and colloids
7. Nutrient cycles
8. Organic carbon dynamics
9. Contaminant behavior
10. Primary production
11. Microbial decomposition
12. Trophic relationships
13. Biodiversity and ecological disturbance

61074
Environmental Statistics
　First Semester (April) (Odd Years) (2−0−0)
　Chihiro Yoshimura, Associate Professor

　This lecture is given to provide common statistical skills to analyze and interpret data sets obtained in environmental science and engineering. Main topics are sampling design, hypothesis testing, multivariate analysis, and time series analysis. Students are required to work on exercises to promote theoretical understanding.

1. Hypothesis and sampling design
2. Probability distribution
3. Hypothesis test
4. Simple regression analysis
5. Multiple regression analysis
6. Data transformation
7. Analysis of variance
8. Multivariate exploratory technique
9. Nonparametric analysis
10. Time series analysis
11. Monte-Carlo method

GIS in water resources engineering
　First Semester　1−1−0
　Oliver C. SAAVEDRA V.

　This lecture supports students to get benefit from Geographical Information Systems（GIS）tools in water resources engineering. It introduces concepts of spatial coordinate systems, and raster and vector data types. The procedures of surface analysis using Digital Elevation Models（DEM）to the watershed delineation, including river networks are studied. In addition, the preparation of input data for hydrological models is applied. Actually, this includes the usage of advanced on-site observations, remote sensing sources handled by GIS. Then, different applications in water supply and water management are reviewed. Finally, a final project should be presented by students applying GIS. Hands-on learning followed by theory introduction is expected.

1. Introduction to GIS
2. Application of Geographic Information Systems in Water Resources
3. GIS data and database
4. Coordinate systems and geocoding
5. GIS analysis functions
6. GIS operations and management
7. GIS for surface-water hydrology
8. How to delineate a watershed from a DEM
9. How to prepare Soil and land-use data
10. How to prepare precipitation data
11. GIS for groundwater hydrology
12. GIS for water supply
13. GIS for floods and droughts
14. Application of remote sensing data in Hydrology

Advanced Hydrology and Water Resources Management
　Second Semester (October)　　2−0−0
　Oliver C. SAAVEDRA V.

　This lecture covers topics related to hydrological modeling, water resources engineering and management. It introduces physically-based hydrological models as a tool for water assessment and decision support. Actually, the characteristics of input data to these models are reviewed. Optimization techniques in water resource are also introduced. Then, water management experiences from different regions of the world are reviewed. Finally, the concepts of integrated water management are updated.

1. The water cycle and its main processes
2. Physically-based hydro-meteorology
3. Monitoring of hydro-meteorology
4. Remote sensors used in Hydrology
5. Introduction of optimization algorithms
6. Application of optimization algorithms in water resources
7. Structural Flood control in South East Asia
8. Non-structural Flood control in South East Asia
9. Nile River water resources, Egypt
10. Water scarcity in La Plata Basin, South America
11. Water uses and withdraws in the USA
12. Water for Hydropower generation
13. Management concepts in water
14. Integrated water resources experiences

61075
実務耐震工学�T（Seismic Engineering in Practical Implementation �T）
　前学期　1−0−0　　松田　　隆　特任教授（連絡担当：二羽　淳一郎）

　建設実務における耐震工学の現状を，設計基準の変遷，解析手法，地盤の液状化，振動台実験，等々を通して講述する。地震被災例とその復旧に関しても，随所に開設する。全部で７回の講義（１単位）である。主な内容は下記の通り。

1. 耐震設計基準の変遷と現状
2. 実務耐震解析手法（構造物）の分類と特徴
3. 実務耐震解析手法（地盤と土構造物）の分類と特徴
4. 液状化予測解析の分類と特徴
5. 振動台実験の適用例
6. 遠心模型振動実験の適用例
7. 液状化時の構造物とその対策

61076
実務耐震工学�U（Seismic Engineering in Practical Implementation �U）
　後学期　1−0−0　　松田　　隆　特任教授（連絡担当：二羽　淳一郎）

　前期に続き，建設実務における耐震工学の現状を，様々なトピックスと関連付けながら紹介していく。海外での事例や，プロジェクト管理手法についても概説する。全部で７回の講義（１単位）である。主な内容は下記の通り。

1. 遠心模型実験装置の開発と運用
2. コンクリート構造物の非線形動的応答解析プログラムの開発
3. 米国における橋梁建設事情（フーバーダムアーチ橋）
4. 免震・制震構造の実務適用
5. 震災に対応した事業継続計画支援
6. GPS機能を用いた３次元大工事管理手法
7. 耐震設計の実務展開・現状と方向

　情報環境学専攻の教授要目を参照のこと。

Analysis of Vibration and Elastic Wave（振動・波動解析論）
　1st Semester (2−0−0) (Odd Years)
　Prof. Sohichi HIROSE

　情報環境学専攻の教授要目を参照のこと。

92008
Basics and Applications of Stochastic Processes
　後学期　1−1−0　　盛川　　仁　准教授

　人間環境システム専攻の教授要目を参照のこと。

　国際開発工学専攻の教授要目を参照のこと。

77048
Advanced Course on Coastal Environments（沿岸環境学特論）
　2nd Semester (October) (Even Years) (2−0−0)
　Prof. Kazuo NADAOKA

　情報環境学専攻の教授要目を参照のこと。

　情報環境学専攻の教授要目を参照のこと。

77046
環境数値シミュレーション２（Numerical Simulation of Environments 2）
　後学期　2−0−0　　灘岡　和夫　教授ほか

　情報環境学専攻の教授要目を参照のこと。

77052
環境モニタリングと情報化２（Environmental Monitoring and Data Processing 2）
　後学期　2−0−0　　灘岡　和夫　教授ほか

　情報環境専攻の教授要目を参照のこと。

77063
Global Water Cycle and Terrestrial Environment
　前学期　2−0−0　鼎　准教授

　情報環境学専攻の教授要目を参照のこと。

70043
Advanced Concrete Technology
　後学期　2−0−0　大即　信明　教授

　国際開発後学専攻の授業要目を参照のこと。

70041
Utilization or Resources and Wastes for Environment
　後学期　2−0−0　大即　信明　教授

　国際開発工学専攻の授業要目を参照のこと。

　国際開発工学専攻の教授要目を参照のこと。

Project Evaluation for Sustainable Infrastructure
　Spring Semester (2−0−0) (Every Year)　　前期
　Assoc. Prof. Shinya Hanaoka, Department of International Development Engineering

　Refer to International Development Engineering department page.

98001
環境水理学特論（Advanced Environmental Hydraulics）
　前学期　2−0−0　　石川　忠晴　教授・中村　恭志　准教授

　環境理工学創造専攻の教授要目を参照のこと。

92047
Theory of Regional Planning Process（国土と都市の計画プロセス）
　1st Semester (April) (Even Years) (2−0−0)
　Prof. Tetsuo YAI

　人間環境システム専攻の教授要目を参照のこと。

92005
都市計画（City Planning）
　後学期　2−0−0　　室町　泰徳

　人間環境システム専攻の教授要目を参照のこと。

61062
Advanced Technical Communication Skills �T
　1st Semester　1−1−0
　Prof. David B. Stewart

　This course is designed to improve technical communication skills including presentations, writing, speaking, mind mapping and so on.

61063
Advanced Technical Communication Skills �U
　2nd Semester　1−1−0
　Prof. David B. Stewart

92048
環境交通工学
　後学期　1−0−0　　屋井　鉄雄　教授

　人間環境システム専攻の教授要目を参照のこと。

92037
Environmental Traffic Engineering
　2nd Semester　1−1−0
　Prof. Tesuo YAI

　人間環境システム専攻の教授要目を参照のこと。

92035
City/Transport Planning and the Environment
　2nd Semester　1−1−0
　Prof. Tesuo YAI

　人間環境システム専攻の教授要目を参照のこと。

　（Special Experiments of Civil Engineering �T−�W）

　各指導教員の指導によって，高度かつ専門的な実験，演習，設計等を行う。

Special Experiments of Civil Engineering, �T, �V
　1st Semester (April) (0−0−1)

Special Experiments of Civil Engineering �U, �W
　2nd Semester (October) (0−0−1)

　Advanced and specialized research under instruction of each supervisor.

　（Seminar in Civil Engineering �T−�W）

　指導教員を中心として専攻に関連する諸問題につき内外の論文，著書の輪講，研究事項の討論を行う。

Seminar in Civil Engineering �T, �W
　1st Semester (April) (1unit)

Seminar in Civil Engineering �U, �W
　2nd Semester (October) (1unit)

　Colloquium on topics relating to each course by means of reading research papers and books, and discussion with each supervisor.

　（Seminar in Civil Engineering �X−�]）

　いずれも博士後期課程における学科目であり，それぞれ示した期間に履修するものとする。この内容は博士後期課程相当の高い程度の輪講，演習，実験，設計等によりなるものである。

61801, 61803, 61805
Seminar in Civil Engineering �X, �Z, �\
　1st Semester (April) (2units)

61802, 61804, 61806
Seminar in Civil Engineering �Y, �[, �]
　2nd Semester (October) (2units)

　All are offered in Ph, D. course and should be taken in the semester shown above. Advanced and high level researches including colloquium, practice and experiment are required.

61501, 61502, 61503, 61504, 61505, 61506
土木工学特別講義第一〜第六（Special Lecture on Civil Engineering �T−�Y）
　前・後学期　各1〜2単位　　各　教　員

　各教員がそれぞれの専攻する分野において特殊の題目を選択して随時開講するものである。

　Particular instructors gives lectures on special topics in their own research field on demand.

61715, 61717
Special Experiments of Development and Environmental Engineering （CE） �T, �V
　Autumn Semester (1unit)
　Academic Advisor

　Experiments, exercises and field works on topics relating to each field under the supervision by each supervisor and course coordinator.

61716, 61718
Special Experiments of Development and Environmental Engineering （CE） �U, �W
　Spring Semester (1unit)
　Academic Advisor

　Experiments, exercises and field works on topics relating to each field under the supervision by each supervisor and course coordinator.

61705, 61707
Seminar in Development and Environmental Engineering （CE） �T, �V
　Autumn Semester (1unit)
　Academic Advisor

　Colloquium on topics relating to each course by means of reading research papers and books, and discussion with each supervisor and couse coordinator.

61706, 61708
Seminar in Development and Environmental Engineering （CE） �U, �W
　Spring Semester (1unit)
　Academic Advisor

　Colloquium on topics relating to each course by means of reading research papers and books, and discussion with each supervisor and couse coordinator.

61851, 61853, 61855
Seminar in Development and Environmental Engineering （CE） �X, �Z, �\
　Autumn Semester (2units)
　Academic Advisor

　All are offered for Master degree holders. Advanced and high level researches including colloquium, practice and experiment are required.

61852, 61854, 61856
Seminar in Development and Environmental Engineering （CE） �Y, �[, �]
　Spring Semester (2units)
　Academic Advisor

　All are offered for Master degree holders. Advanced and high level researches including colloquium, practice and experiment are required.

61551, 61552
Development and Environmental Engineering Off-Campus Projects （CE） �T, �U
　Spring Semester Autumn Semester each　0−4−0

　Either of above two projects is required for Doctoral degree. The student will take part in an actual project done by an institution or private company. Project period is from three to six months, in which the student should work more than 160 hrs in total. Through this internship projects the student will experience the actual practice in her/his own field and have proper prospects of her/his future profession.