Assist.Prof. Dr. Gözen Elkıran

Assist.Prof. Dr. Rifat Reşatoğlu

Assist.Prof. Dr. Pınar Akpınar

CODE | COURSE TITLE |
CREDIT |
---|---|---|

CE 505 | MATHEMATICAL METHODS IN ENGINEERING | (3-0) 3 |

CE 523 | THEORY OF PLATES | (3-0) 3 |

CE 524 | THEORY OF SHELLS | (3-0) 3 |

CE 525 | THEORY OF ELASTICITY | (3-0) 3 |

CE 526 | MATRIX METHODS FORSTRUCTURAL SYSTEMS | (3-0) 3 |

CE 527 | FRACTURE MECHANICS | (3-0) 3 |

CE 528 | THIN WALLED STRUCTURES | (3-0) 3 |

CE 529 | ADVANCED STRENGTH OF MATERIALS | (3-0) 3 |

CE 531 | MECHANICS OF COMPOSITE MATERIALS | (3-0) 3 |

CE533 | ADV. BUILDING AND CONSTRUCTION MANAGEMENT | (3-0) 3 |

CE 534 | THEORY OF ELASTIC STABILITY | (3-0) 3 |

CE 535 | STRUCTURAL DYNAMICS | (3-0) 3 |

CE 536 | ENERGY METHODS | (3-0) 3 |

CE 537 | FINITE ELEMENT METHOD | (3-0) 3 |

CE 538 | PRESTRESSED CONCRETE | (3-0) 3 |

CE 539 | INDUSTRIAL STEEL STRUCTURES | (3-0) 3 |

CE 540 | NUMERICAL ANALYSIS IN STRUCTURAL ENGINEERING | (3-0) 3 |

CE 541 | REPAIRING AND STRENGTHENING OF STRUCTURES | (3-0) 3 |

CE 542 CE 543 |
CONCRETE DURABILITY CEMENTITIOUS MATERIALS |
(3-0) 3 (3-0) 3 |

CE 544 | ADVANCED CONCRETE TECHHOLOGY | (3-0) 3 |

CE 545 | BEHAVIOUR OF REINFORCED CONCRETE MEMBERS& STRUCTURES | (3-0) 3 |

CE 546 | REINFORCED CONCRETE BUILDING DESIGN FUNDAMENTALS & DETAILS | (3-0) 3 |

CE 547 | LIMIT ANALYSIS | (3-0) 3 |

CE 548 | COMPUTER AIDED TWO DIMENSIONAL | (3-0) 3 |

CE 549 | STRUCTURAL USE OF TIMBER | (3-0) 3 |

CE 550 | EXPERIMENTAL STUDIES IN STRUCTURAL MECHANICS | (3-0) 3 |

CE 551 | NON-LINEAR ANALYSIS OF STRUCTURAL SYSTEMS | (3-0) 3 |

CE 552 | TEORY OF YIELD LINES | (3-0) 3 |

CE 553 | EARTHQUAKE ENGINEERING | (3-0) 3 |

CE554 | NUMERICAL AND CONSTITUTIVE MODELLING FOR REINFORCED CONCRETE | (3-0) 3 |

CE 555 CE556 |
MATERIALS OF CONSTRUCTION LABORATORY SPECIAL CONCRETES |
(2-2) 3 (3-0) 3 |

CE 560 | GEOTECHNICAL INVESTIGATION | (3-0) 3 |

CE 566 | CONSTRUCTION SITE PLANNING & CONSTRUCTION TIMETABLE CONCEPT | (3-0) 3 |

CE568 | BOUNDARY LAYER FLOWS |
(3-0) 3 |

CE569 | TURBBULENT FLOWS |
(3-0) 3 |

CE 570 | STATISTICS IN HYDROLOGY AND WATER RESOURCES | (3-0) 3 |

CE 571 | ADVANCED MECHANICS OF FLUIDS | (3-0) 3 |

CE 572 | HYDRAULIC SYSTEM DESIGN I | (3-0) 3 |

CE 573 | WATER RESOURCES SYSTEM ENGINEERING I | (3-0) 3 |

CE 574 | SEDIMENT TRANSPORT | (3-0) 3 |

CE 575 | ADVANCED HYDROLOGY | (3-0) 3 |

CE 576 | HYDROPOWER ENGINEERING | (3-0) 3 |

CE 577 | GROUNDWATER ENGINEERING | (3-0) 3 |

CE 578 | IRRIGATION AND DRAINAGE ENGINEERING | (3-0) 3 |

CE 579 | SOIL AND WATER CONSERVATION | (3-0) 3 |

CE 580 | COMPUTER APPLICATION FOR THE DESIGN OF WATER DISTRIBUTION NETWORKS | (3-0) 3 |

CE 581 | UNIT OPERATIONS IN ENVIRONMENTAL ENG. | (3-0) 3 |

CE 582 | ENVIRONMENTAL CHEMISTRY | (3-0) 3 |

CE 583 | HYDROINFORMATICS | (3-0) 3 |

CE 588 | SEMINAR | |

CE 598 | MASTER THESIS |

**CE 505 Mathematical Methods in Engineering**

Review of matrix algebra and calculus of variations, formulation of second and fourth – order boundary value problems, Numerically integrated elements, Eigenvalue and time dependent problems, ordinary differential equations. Series solutions of linear ordinary differential equations, gamma, bessel, hermite, laguerre, legendre flinctions, second order linear partial differential equations, fourier series and fourier integral.

**CE 523 Theory of Plates**

Introduction. Theory of thin elastic plates (Kirchhoff theory), basic assumptions, strain-displacement relations, plate equation, boundary conditions, strain energy, rectangular plates. Navier and Levy type solutions, rectangular plates with various boundary conditions, plate strips. Circular plates, energy methods. Ritz and Galerkin method, method of least squares, plates with various shapes, continuous rectangular plates, plates resting on elastic foundations, bending of anisotropic plates. numerical methods, finite difference, finite element and boundary element method. Effect of transverse shear deformation on the bending of thin plates, large deflections of plates, vibrations of plates, buckling of plates.

**CE 524 Theory of Shells**

Differential geometry of surfaces and curves. Theory of thin elastic shells. Basic assumptions, strain displacement relations, differential equations of equilibrium. Boundary conditions, strain energy, membrane theory of shells. Displacements and deformations of shells without bending resistance, shells with bending resistance. Spherical and cylindrical shells, shells with various shape, shallow shells. Approximate analysis of shells. Energy methods, Ritz and Galerkin method. Numerical analysis of shells, finite difference and finite element method. Dynamic analysis of shells .

**CE 525 Theory of Elasticity**

The state of stress and strain in plate. Stress-strain relations. Hooke constants for orthotropic and isotropic plates. General equations of plate. Stress and displacement problems in long cylinder. General equations of long cylinder. Airy stress function. Polynomial solutions. Fourier series solutions. Finite-difference solutions. Solutions in polar coordinates. Hole and notch problems in plate. Solutions in curvilinear coordinates.

**CE526 Matrix Methods for Structural Systems**

Matrix methods of structural analysis in two and three dimensional bar structures. Stiffness properties of plane trusses, plane frames, grids, space trusses and space frames. Study of computer programming techniques. Applications to selected problems. Matrix displacement method.

**CE 527 Fracture Mechanics**

Mechanisms of failure for brittle and ductile materials. Stress concentration. Elastic stress fields around cracks. Plasticity effect. Fracture criteria. Crack propagation and methods of crack at rest. Fatigue. Fracture testing.

**CE528 Thin Walled Structures **

Some basic ideas of structural theory. First-order theory for bending and torsion of thin-walled beams, governing equations obtained by the equilibrium. Compatibility method, energy method for setting up governing equations. Applications of the theory of thin-walled structures to bending and lateral buckling of beams and flexural torsional buckling of columns. Bending and twisting of prismatic beams, warping torsion of continuous beams, flexural torsional buckling of columns, lateral buckling of beams.

**CE529 Advanced Strength of Materials**

Space stresses and position of deformation. Torsion of Saint Venant, analogy of mambran. Non uniform torsion. Bending of curved beam. Non elastic bending of beams. Relation between shearing force and elastic curve. Variable section beams. Concentric longitudinal force case of indeterminate to the second degree theory. Deformation work. Principles of complementary energy, Ritz method. Elasto-kinetic.

**CE 531 Mechanics of Composite Materials**

The nature and scope of composite materials. Fundamental aspects of the theory of the linear an isotropic elasticity. Prediction of macroscopic mechanical properties of composite materials. Analysis of internal fields in heterogeneous medium. Wave propagation and dynamics effects in composites. Effective stiffness theory considerations, lattice model representations.

**CE 533 Advanced Building and Construction Management**

Apply and evaluating the local building codes and standards to the construction process.

Legal obligations of a building or construction contract as well as how and where to get all the necessary permissions to obtain the building permit. Virtual construction stage; where the student virtually constructs a building from the very beginning up to getting the resident permit and final approval from the local municipality.

**CE 534 Theory of Elastic Stability**

Stability concept and definitions. Solution methods. Buckling of a linear bar. Buckling analysis of bars by using method of neutral equilibrium. Buckling criteria. The critical load of the Euler column. Method of Empirical formulas. Buckling problems. Buckling load of column with variable cross section. Eccentrically loaded columns. Lateral buckling. Buckling under combined loadings. Buckling of frames and arches. Definitions and types of linear and non-linear buckling.

**CE535 Structural Dynamics**

Dynamic loads. Dynamic characteristics of structural systems. Lumped parameter systems, free vibrations of single-degree-of-freedom systems (SDF). Damped vibrations, response of SDF systems to harmonic loading, to periodic loading, to general dynamic loading, Generalized SDF systems. Rayleigh method, vibration isolation. Multi-degree-of-freedom systems (MDS), equations of motions, undamped free vibrations of MDS. Free vibrations, orthogonality conditions, dynamic response, mode shapes, forced vibrations. Mode superposition analysis, numerical methods for determination of mode shapes and frequencies. Rayleigh method, systems with distributed parameters, equations of motion, axial, shear and bending vibrations, earthquake response of SDF systems. Response spectra, earthquake response of MDF systems. methods for modal combination, numerical methods.

**CE 536 Energy Methods**

Force fields. Work. Principles of variations, variational principles for discrete systems. Elements of the mechanics of continua. Hellinger, Reissner, and Hamilton principles. Castigliano’s theorem, theorems of work and reciprocity. Application to elastic rods, structural systems, elastic plates and shells. Stability.

**CE537 Finite Element Method**

Introduction, general concepts. Summary of analysis procedure by a simple example. Truss analysis. Variational and weighted residual methods. The Ritz method, the Ritz and Rayleigh-Ritz FEM. General approach to structural analysis. Principal of minimum potential energy and virtual displacement methods. The shape functions, parameter functions, convergence requirements. One, two and three dimensional elements, axisyymetric elements. Stress analysis, plane stress and plain strain. Beam and frame elements, substricturing. Element rigidity and load matrices, a detailed application. Axisyymetric and 3D stress analysis. Bending of plates, a detailed numerical example.

**CE538 Prestressed Concrete**

Analysis of determinate cable structure members. Bending analysis of cable structure elements with constant height, and uniform section.. Differences between anchored structure and cable structure members, and calculus properties. Detail of prestressed bars in beam. Loss of stress due to friction of cable in prestressed structure members in time. Analysis of prestressed structure members against shear force. Comparisons of with partial prestressed concrete and prestressed concrete.

**CE539 Industrial Steel Structures**

Rigid beam-column connections in frames. Directly welded beam-column connections and welded rigid beam-column connections with plate. Construction and calculation of R and Castellated beams. Steel hall structures. General Knowledge; static structures, transportation (carrying) vehicle, special purpose halls, forming walls, roof additional. Cranes, codes, rails crane beams. Stability controls. Light constructions, usage instructions, calculation bases.

**CE540 Numerical Analysis in Structural Engineering**

Finite differences method. Finite elements method. Interpolations of Langrange, Newton, Hermite. Mistakes in structural engineering. Eigenvalue problems in structural dynamics. Linear and nonlinear equation systems and differential equations and solutions. Boundary value problems. Variation analysis. Other applications in structural engineering.

**CE541 Repairing and Strengthening of Structures**

Techniques and reasons for repairing and strengthening of structures. Repairing and strengthening of reinforced concrete structures. Groups of repairing and strengthening. Necessary works to be made on the earthquake area, and urgent precautions. Materials and techniques used. Determination of level of repairing and strengthening and techniques. Some examples related to repairing and strengthening of reinforced concrete structures. Strengthening of structures adding new structural elements.

**CE 542 Concrete Durability**

Definition of concrete durability. Principal durability problems in concrete: Leaching, carbonation, alkali-aggregate reactions, sulfate attack mechanisms, acid attacks, corrosion of reinforcements and its effects on concrete, freezing-thawing and abrasion problems. Chemical and physical effects of aforementioned problems on concrete, testing methods and protection techniques.

**CE543 ****Cementitious Materials:**

Historical uses of gypsum and lime as cementitious materials. Manufacture and properties of contemporary PC types. Natural Pozzolans, Fly ash, Silicafume, Gound Granulated Blast-Furnace Slag and their cementitious properties, their interactions in cementitious media. Effects of these cementitious materials on fresh & hardened concrete and on long-term durability of concrete.

**CE 544 Advanced Concrete Technologv**

Understanding fundamentals of cement chemistry: different clinker compositions and cement hydration reactions. Significance of each cement hydration product and formation of concrete micro-structure. Properties of different cement types. Effects of natural and artificial pozzolans on cement hydration and concrete properties. Chemical and physical effects of admixtures on concrete performance. Effects of aggregate characteristics on fresh and hardened concrete. Introduction to the fundamentals of manufacture of special concretes.

**CE 545 Behaviour of Reinforced Concrete Members and Structures**

Failure patterns of reinforced concrete members and structures, and ultimate load theories. A critical look at various design specifications with emphasis on research results. Review of theoretical and experimental research and their influence on reinforced concrete members and structures.

**CE 546 Reinforced Concrete Building Design Fundamentals & Details**

Statical analysis of buildings. Behaviour and design of footings. Long and short column concept. Deep and shallow beam theory and design. Types of slabs and slab design. Concept of retaining wall design.

**CE 547 Limit Analysis**

Basic hypotheses. Simple cases of collapse. upper bounds, and lower bounds and unigueness theorems. Introduction to design, limit analysis of frames, and multi-storey buildings, grids. Displacement in beams and frames. Stability consideration. Notes on ultimate load analysis of reinforced concrete structures.

**CE 548 Computer Aided Two Dimensional Structural Analysis**

Introduction to computers. Moments distribution method. Fixed end moments and automated matrix displacement concept. Earthquake effects on buildings. Building design with earthquake concept and standards. Programming and analysis of two dimensional structures using basic language.

**CE 549 Structural Use of Timber**

Types of Timber. Timber behaviour, composition and potential usage. Compression, Tension, fatigue and impact strengths. Mechanical behaviour of timber. Structural design using timber.

**CE 550 Experimental Studies in Structural Mechanics**

Introduction. Importance and necessity of experimental studies in structural mechanics. Description of general lab. equipments. Routine and special experiments realised in structural lab. Designing and preparing of a test set-up. Terms of load, deformation and strain. Characteristics of mechanical and electronic measurement devices. Types of loading systems. Static and dynamic loadings. Recording of data.and evaluation of experimental results.

**CE 551 Non-Linear Analysis of Structural Systems**

Sources of nonlinearity. Nonlinear theory, modelling, analysis and design methods of materially and geometrically nonlinear structures. Elastoplastic theory, plastic section concept and applications. Second-order and large deformation theories. Stability and buckling. Performance based design, nonlinear static (Pushover) analysis, computer software and applications. Introduction to nonlinear dynamic analysis.

**CE552 Theory of Yield Lines**

Analysis of thin plates according to elasticity theory. Introduce to plastic analysis. Theory of yield lines. Analysis with static equilibrium method. Effect of single load and column. Superposition principle. Rectangular plates with and without beams. Alternative methods.

**CE553 Earthquake Engineering**

Earthquake mechanism, spectrum concept. Multi degree of freedom system, modal analysis in earthquake response. Earthquake resistant design, main philosophy of earthquake codes, earthquake codes and design criteria. Spectral analysis of structures and simplified approaches. Behavior of reinforced concrete structures subjected to earthquake ground motion. Plastic hinge concept, capacity concept in design, earthquake resistant design, safety to earthquakes, limit states. General behavior of structures, structural irregularities, design spectra, elastic equivalent earthquake load. Effect of earthquake load, acceleration spectrum. Ductility of structures, equivalent earthquake load. Modal superposition method. Structural systems, construction rules for reinforced concrete structures, story displacements. Design of base isolated structures, retaining walls.

**CE554 Numerical and Constitutive Modelling for Reinforced Concrete **

Examination of one, two and multi axial behaviors of concrete under tension and compression. Interfas behavior and crack occurring of concrete. Nonlinear elastic material models for concrete. Crack models for concrete. Failure mechanism models. Plasticity in concrete. Failure and yielding criterion for concrete. Computer programs SAP2000n, LUSAS, ANSYS and nonlinear analysis methods. Nonlinear finite element analysis for RC elements.

**CE 555 Materials of Construction Laboratorv**

Presentation of principal standard test methods on cement, aggregate and concrete properties. Usage of materials of construction laboratory equipments according to related standard methods. Exercises on concrete mix design, producing concrete samples, curing and storage, as well as performing mechanical tests on the produced samples.

**CE556 Special Concretes**

Properties, materials and manufacure of: “(Ultra) High Performance Concrete”, “Self Compacting Concrete”, “Shotcrete”, “Transparent Concrete”, “Fiber Concrete”, “Aerated Concrete” and “Under-water concrete” and their long-term performance.

**CE 560 Geotechnical Investigation**

Planning and executing subsurface explorations, exploratory holes and sampling. Field instrumentation, field measurement and in-situ testing. Geophysical methods. Interpretation of field data and selection of soil parameters for geotechnical designs. Case studies of predicted behaviour and performance of structures.

**CE 566 Construction Site Planning & Construction Timetable Concept**

Exploring the construction site. Construction site arrangements concepts. Lay outing, construction material stocking and supply. Time table concept and design. Directing the work force. Balance keeping with work force, construction materials and nature.

**CE 568 Boundary Layer Flows**

Preliminary concepts and fundamentals equations: solutions of Newtonian flows. Laminar boundary layers: stability and transition, turbulent boundary layers.

**CE 569 Turbulent Flows**

Stability theory and transition, Reynolds equations, physical structure of turbulent boundary layer, turbulent pipe and channel flow, analysis of flat plate integral analysis, jets, wakes, free-shear layers, turbulence modeling, isotropic, energy spectra, correlations, measurement methods, hot wire and LDV systems.

**CE 570 Statistics in Hydrology & Water Resources**

Probability distribution used in Hydrology. Analytical and numerical solutions of hydrologic models. Linear and multiple regression analysis.

**CE 571 Advanced Mechanics of Fluids**

Fundamentals equations, flow kinematics and special forms of governing equations. Potential flow, Viscous flow of incompressible fluids. compressible flow of inviscid fluids.

**CE 572 Hydraulic Svstem Design I**

Fundamentals of open channel flow, Steady and unsteady non-uniform flow computation and analysis in open channel systems Hydraulic analysis and design of controls for free surface.

**CE 573 Water Resources System Engineering I**

System analysis; Concepts, terminology, phases. System approach to solving Water Resources problem. The nature and the objectives of Water Resources

systems. General review of optimisation techniques. flindamentals of linear programming. Classical optimisation methods. Computer applications and case studies in Water Resources engineering.

**CE 574 Sediment Transport**

Principles of upland erosion and reservoir sedimentation. Sediment transport phenomena in free surface flow, scour criteria, bed load, suspension and total load theories. Optimal design of earth channels.

**CE 575** **Advanced Hydrology**

System approach to the hydrologic cycle. Deterministic treatments of catchment behaviour. Statistical models in hydrology. Presentation of advanced topics in hydrology.

**CE 576 Hydropower in Engineering**

Reservoir operation studies, water storage capacities, Load curve. Power generation and storage. Pumps and turbines. Hydropower plants in multi-sectorial plans.

**CE 577** **Groundwater Engineering**

The occurrence, sources, distribution and movement of groundwater. Aquifer types, differential equations of confined and unconfined aquifer. Well hydraulics, graphical, analytical, numerical and experimental solution of groundwater flow. Groundwater investigation wells, well drilling. Construction and operation. Salt water intrusion.

**CE 578 Irrigation and Drainage Engineering**

Introduction to irrigation methods and practices. Surface and subsurface sprinkler and trickle irrigation. Comparison of irrigation systems. Capacity determination of irrigation projects; demand, rotation, continuos flow and unit area – unit water systems. Irrigation networks; open channels, pipes, canalets (flumes) and sprinkler. Drainage networks; open drains and tile drains. Capacity of drainage networks. Irrigation structures. Operation and maintenance of irrigation projects.

**CE 579 Soil and Water Conservation Engineering**

Soil erosion principles. Soil loss equations. Wind erosion control. Countering, terracing and conservation structures. Earth embankments. Head water and flood control. Open channels. Farm ponds and small reservoir design.

**CE 580 Computer Application for Design of Water Distribution Networks**

Introduction. Water distribution systems Hydraulic design of water distribution system. Computer programs by micro-computers.

**CE 581 Unit Operations in Environmental Engineering**

Clean – up of water and waste – water by physical, chemical or biological techniques. Sedimentation, coagulation and flocculation, screening, filtration by membrane technology, ion – removed precipitation, ion – exchange, adsorption air – stripping, biological processes (Single or hybrid systems), batch and continuous culture systems, aerobic and anaerobic digestion.

**CE 582 Environmental Chemistry**

Significance of environmental chemistry, environmental chemistry of atmosphere, biosphere and lithosphere. Nature and composition of natural waters. Application of environmental chemistry to wastewater analysis and studies related to receiving water bodies and pollution. Redox, homogeneous and heterogeneous equilibria and complex formation processes in environmental systems and pollution control. Acidity, alkalinity, DO, BOD, total hardness.

**CE 583 Hydroinformatics**

Concepts and introduction to Hydroinformatics, data pre and post- processing, statistical analysis of data, review and practice with general commands and functions of MATLAB, introduction to ANN ,Fuzzy set, ANFIS , genetic algorithm and programming soft computing tools and related toolboxes of MATLAB. Solving real word problems via these tools in MATLAB.