Course Name Code Semester T+U Hours Credit ECTS
Structure-Soil Dynamic Interaction INM 607 0 3 + 0 3 6
Precondition Courses
Recommended Optional Courses <p>Soil Dynamics and Advanced Structural Dynamics</p>
Course Language Turkish
Course Level Doctorate Degree
Course Type Optional
Course Coordinator Prof.Dr. ERKAN ÇELEBİ
Course Lecturers Prof.Dr. ERKAN ÇELEBİ,
Course Assistants
Course Category
Course Objective

The dynamic reciprocal interaction between superstructure and soil is required to well comprehend because of the behavior opposing earthquake of the significant structure systems such as high-rise buildings, viaducts, dams, suspension bridges, nuclear power centrals which are built on the soft soil conditions. The aim of this course is to gain the ability to improve the mathematical model and to teach the computation methods for the earthquake analysis of engineering structures including soil-structure interaction.

Course Content

1-) General overview of fundamentals for input earthquake motion and mechanics of earthquake wave propagation
2-) Geotechnical  considerations for earthquake analysis of soil-structure coupled systems and modeling of soil dynamic behaviour under cyclic loads
3-) Ground response analysis in geotechnical earthquake engineering and soil amplification effect 
4-) The basis of spatial modeling of analyzed soil region under dynamic loads 
5-) Fundamental principles of substructure method for analysis of structure-foundation-soil dynamic interaction problem and numerical applications
 

# Course Learning Outcomes Teaching Methods Assessment Methods
1 To understand the working mechanism of mathematical models based on the impedance functions in consideration of reciprocal interaction of the structure-foundation-soil systems, to gain the theoretical tools for interpretation of dynamic response of those Lecture, Question-Answer, Discussion, Drilland Practice, Homework, Testing,
Week Course Topics Preliminary Preparation
1 Definition of input earthquake motion at seismic bedrock/elastic base and mechanics of wave propagation (Amplication of earthquake wave)
2 Analysis of elastic wave motion in unbounded media, a semi-infinite body and layered body (attenuation of earthquake wave)
3 Soil behavior and dynamics under cyclic loads (shear modulus and damping modeling in equivalent linear soil models)
4 Soil behavior and dynamics under cyclic loads (non-linear soil models)
5 Ground response analysis in geotechnical earthquake engineering
6 One dimensional ground response analysis (linear approach)
7 One dimensional ground response analysis (nonlinear approach)
8 General overview of two and three dimensional ground response analyses based on finite element method
9 The effect of dynamic foundation-soil interaction on structural response (kinematic and inertial interaction effects)
10 General overview of direct analysis approaches based on finite element and boundary element methods
11 Substructure method based on impedance functions for surface/embedded rigid foundations on elastic half-space
12 Substructure method based on impedance functions for surface/embedded rigid foundations on elastic half-space
13 Substructure method based on impedance functions for surface/embedded rigid foundations on layered soil medium
14 Substructure method based on impedance functions for surface/embedded rigid foundations on layered soil medium
Resources
Course Notes <p>&Ccedil;elebi, E.; Soil-Structure Dynamic Interaction, Lecture notes, 2020</p>
Course Resources

1-)Yoshida, N., Geotechnical, Geological and Earthquake Engineering, Volume 36, Seismic Ground Response Analysis, Springer, London, 2015.2-) Chowdhury, I., Dasgupta, S. P., Dynamics of Structures and Foundation, A Unified Approach, 2. Applications, CRC Press, Taylor and Francis Group, Balkema Book, London, 2009.3-) Jia, J., Soil Dynamics and Foundation Modeling, Offshore and Earthquake Engineering, Springer, Cham, 2018.4-) Soil-Structure Interaction for Building Structures, NIST GCR 12-917-21 Report, 2012. 5-) Schmid, G., Tosecky, A., Soil-Structure Interaction, Foundations Vibrations, Lecture Notes, Skopje, 2003. 6-) Sieffert, J., G., and Cevaer F., Handbook of Impedance Functions, Surface Foundations, Quest Editions, Nantes, 1991. 7-) Talaganov, K., Soil and foundation dynamics, Lecture Notes, Skopje, 1998. 8-) Cramer, S. L., Geotechnical Earthquake Engineering, Prentice Hall, 1996.

Week Documents Description size
6 YZDE_2020Güz_DN_6 6.79 MB
8 YZDE_2020Güz_DN_8 4.58 MB
8 YZDE_2020Güz_DN_7 8.75 MB
7 YZDE_1Ödev_2020Güz 1. ÖDEV 0.53 MB
2 YZDE_2020Güz_DN_1 11.76 MB
3 YZDE_2020Güz_DN_2 8.76 MB
2 YZDE_2020Güz_DN_2 6.79 MB
11 YZDE_2020Güz_DN_8 9.78 MB
13 YZDE_2020Güz_DN_9 8.66 MB
5 YZDE_2020Güz_DN_5 9.33 MB
5 YZDE_2020Güz_DN_5 6.57 MB
1 YZDE_2020Güz_DN_1 10.49 MB
10 YZDE_1Ödev_2021Bahar 0.49 MB
9 YZDE_2020Güz_DN_6 8.68 MB
1 YZDE_2020Güz_DN_1 10.52 MB
12 YZDE_2Ödev_2020Güz 0.5 MB
6 YZDE_2020Güz_DN_4 7.69 MB
8 YZDE_2020Güz_DN_5 6.85 MB
3 YZDE_2020Güz_DN_3 8.59 MB
3 YZDE_2020Güz_DN_3 Yeni versiyon 7.04 MB
4 YZDE_2020Güz_DN_3 9.23 MB
4 YZDE_2020Güz_DN_4 7.62 MB
1 YZDE_2020Güz_DN_1 10.49 MB
2 YZDE_2020Güz_DN_2 6.79 MB
Order Program Outcomes Level of Contribution
1 2 3 4 5
1 ability to access wide and deep information with scientific researches in the field of Engineering, evaluate, interpret and implement the knowledge gained in his/her field of study X
1 ability to access wide and deep information with scientific researches in the field of Engineering, evaluate, interpret and implement the knowledge gained in his/her field of study X
2 ability to complete and implement “limited or incomplete data” by using the scientific methods. X
2 ability to complete and implement “limited or incomplete data” by using the scientific methods. X
3 ability to consolidate engineering problems, develop proper method(s) to solve and apply the innovative solutions to them X
3 ability to consolidate engineering problems, develop proper method(s) to solve and apply the innovative solutions to them X
4 ability to develop new and original ideas and method(s), to develop new innovative solutions at design of system, component or process X
4 ability to develop new and original ideas and method(s), to develop new innovative solutions at design of system, component or process X
5 gain comprehensive information on modern techniques, methods and their borders which are being applied to engineering X
5 gain comprehensive information on modern techniques, methods and their borders which are being applied to engineering X
6 ability to design and apply analytical, modelling and experimental based research, analyze and interpret the faced complex issues during the design and apply process X
6 ability to design and apply analytical, modelling and experimental based research, analyze and interpret the faced complex issues during the design and apply process X
7 gain high level ability to define the required information and data X
7 gain high level ability to define the required information and data X
8 ability to work in multi-disciplinary teams and to take responsibility to define approaches for complex situations X
8 ability to work in multi-disciplinary teams and to take responsibility to define approaches for complex situations X
9 systematic and clear verbal or written transfer of the process and results of studies at national and international environments X
9 systematic and clear verbal or written transfer of the process and results of studies at national and international environments X
10 aware of social, scientific and ethical values guarding adequacy at all professional activities and at the stage of data collection, interpretation, and announcement X
10 aware of social, scientific and ethical values guarding adequacy at all professional activities and at the stage of data collection, interpretation, and announcement X
11 aware of new and developing application of profession and ability to analyze and study on those applications X
11 aware of new and developing application of profession and ability to analyze and study on those applications X
12 ability to interpret engineering application’s social and environmental dimensions and it’s compliance with the social environment X
12 ability to interpret engineering application’s social and environmental dimensions and it’s compliance with the social environment X
Evaluation System
Semester Studies Contribution Rate
1. Ara Sınav 50
1. Kısa Sınav 15
1. Ödev 10
2. Kısa Sınav 15
2. Ödev 10
Total 100
1. Yıl İçinin Başarıya 50
1. Final 50
Total 100
ECTS - Workload Activity Quantity Time (Hours) Total Workload (Hours)
Course Duration (Including the exam week: 16x Total course hours) 16 3 48
Hours for off-the-classroom study (Pre-study, practice) 16 3 48
Mid-terms 1 12 12
Quiz 2 6 12
Assignment 2 6 12
Final examination 1 12 12
Total Workload 144
Total Workload / 25 (Hours) 5.76
dersAKTSKredisi 6