Kocaeli University / European Credit Transfer System (ECTS)

Name of Lecturer(s)

Associate Prof. Dr. Orhan KURT

Learning Outcomes of the Course Unit
Program Competencies-Learning Outcomes Relation

Learning Outcomes of the Course Unit

1) Clarify the concept and the models of deformation.
2) Establish the geodetic networks in 1D, 2D and 3D for monitoring deformation.
3) Evaluate the geodetic networks in 1D, 2D and 3D for monitoring deformation.
4) Test the results acquired from the geodetic networks in 1D, 2D and 3D.
5) Choose the stable and moving points on the networks and decide for time span between observation periods.
6) Analyze the static deformation models.
7) Analyze the kinematics deformation models.
8) Comprehend the dynamical deformation analysis.

Program Competencies-Learning Outcomes Relation

		Program Competencies
		1	2	3	4
Learning Outcomes
	1	High	Middle	Low	No relation
	2	High	Low	No relation	Middle
	3	High	Middle	No relation	Middle
	4	High	Middle	No relation	Middle
	5	High	Middle	No relation	Middle
	6	High	Middle	No relation	Middle
	7	High	Middle	No relation	Middle
	8	High	Middle	No relation	Middle

Mode of Delivery

Face to Face

Prerequisites and Co-Requisites

None

Recommended Optional Programme Components

Geodetic Parameters Estimation and Linear Hypothesis Testing Analysis and Evaluation of GNNS Data Monitoring of Deformation Networks

Course Contents

Deformation analysis and its application areas. Model of deformation analysis, the models: static, kinematics and dynamic. Determination characteristics of the working area, choosing stable and unstable points on the area and deciding for time span between two sequential periods. 1D, 2D and 3D mathematical model at the geodetic networks. Quality and reliability optimization for the geodetic networks. Evaluating observation in the geodetic networks, S-transformations. Testing for the mathematical models and outlier tests. Models of static deformation and their analysis. Searching of displacements at the network points and determining quantities of the displacements. Geometric deformation analysis and its interpretation. Models of kinematics deformation and their analysis. Deformation analysis with Kalman-filter. Statistical tests for the kinematics deformation analysis.

Weekly Schedule

1) Deformation analysis and its application areas
2) Model of deformation analysis, the models: static, kinematics and dynamic
3) Determination characteristics of the working area, choosing stable and unstable points on the area and deciding for time span between two sequential periods
4) 1D, 2D and 3D mathematical models on the geodetic networks
5) Quality and reliability optimization for the geodetic networks
6) Evaluating observation in the geodetic networks, S-transformations
7) Testing for the mathematical models and outlier tests
8) Midterm examination/Assessment
9) Searching of displacements at the network points and determining quantities of the displacements
10) HOMEWORK-I delivery: The static deformation analysis in a 2D horizontal control network observed at two sequential periods
11) Geometric deformation analysis and its interpretation
12) Models of kinematics deformation and their analysis
13) Deformation analysis with Kalman-filter
14) Statistical tests for the kinematics deformation analysis
15) HOMEWORK-II delivery: Kinematics deformation analysis in a 1D vertical control network observed among three sequential periods
16) Final examination

Recommended or Required Reading

1- Walter M. Welsch, Otto Heunecke (2001), Models and Terminology for the Analysıs of Geodetic Monıtoring Observations, The 10th FIG International Symposium on Deformation Measurements, 12-22 March 2001, Orange, California, USA. http://www.fig.net/com6 orange/pdf/Session%20XI Paper%201.pdf
2- Wilhelm F. CASPARY, W. Haen, and H. Borutta (1990), Deformation Analysis by Statistical Methods, Technometrics, Fe Bruary1 990, Vol. 32, No. 1. http://www.jstor.org/stable/pdfplus/1269844.pdf?acceptTC=true
3- Nicholas SITAR and Mary M. MACLAUGHLIN (1997), Kinematics and Discontinuous Deformation Analysis of Landslide Movement, Invited Keynote Lecture II Panamerican Symposium on Landslides, Rio de Janeiro, Nov. 10-14th, 1997, http://www.ce.berkeley.edu/geo/research/DDA/pubs/panam.pdf
4- Andreas EICHHOM (2007), Tasks And Newest Trends In Geodetic Deformation Analysis: A Tutorial, 15th European Signal Processing Conference (EUSIPCO 2007), Poznan, Poland, September 3-7, 2007, copyright by EURASIP. http://www.eurasip.org/Proceedings/Eusipco/Eusipco2007/Papers/c1l-b01.pdf
5- Serif HEKIMOGLU, Hüseyin DEMIREL, Cüneyt AYDIN (2002), Reliability of the Conventional Deformation Analysis Methods for Vertical Networks, FIG XXII International Congress Washington, D.C. USA, April 19-26 2002. http://www.yildiz.edu.tr/~caydin/publications dosyalar/defnew.pdf
6- Karl-Rudolf KOCH (1999), Parameter Estimation and Hypothesis Testing in Linear Models, Springer-Verlag Berlin Heidelberg Newyork, ISBN-540-65257-4.
7- Hüseyin DEMİREL (1987), S-Transformasyonu ve Deformasyon Analizi, TMMOB, HKMO, Türkiye I.Harita Bilimsel ve Teknik Kurultayı, s.593-609, 23-27 Şubat, Ankara.
8- Ahmet AKSOY (1987), Jeodezik Değerlerin Matematik-İstatistik Testlerle İrdelenmesi, TMMOB, HKMO, Türkiye I.Harita Bilimsel ve Teknik Kurultayı, s.559-593, 23-27 Şubat, Ankara.
9- Öztürk, E. ve Şerbetçi, M., (1992), Adjustment, Volume III, KTÜ, MMF, Number of General Publication:144, Number of Faculty Publication:40, Trabzon.

Planned Learning Activities and Teaching Methods

1) Lecture
2) Discussion
3) Demonstration
4) Group Study
5) Problem Solving

Assessment Methods and Criteria

Contribution of Quiz to Course Grade	70%
Contribution of Final Examination to Course Grade	30%
Total	100%

Language of Instruction

Turkish

Work Placement(s)

Not Required

Course Unit Title	Course Unit Code	Type of Course Unit	Level of Course Unit	Year of Study	Semester	ECTS Credits
Monitoring of Geodetic Networks	JJM602	Elective	Doctorate degree	1	Spring	9