General concepts about the course, collapse of the Ottoman Empire, leading to National Struggle, congresses, Sevres Treaty, wars, opening of Turkish Great National Assembly, Mudanya Armistice, Lausanne Treaty discussions.

Abolishment of sultanate and declaration of Republic, strategy and importance of Turkish Revolution, financial, social, legal, educational and cultural renovation, experiments for multi- party system, Turkish foreign policy during Atatürk?s term, basic principles of Atatürkism.

OHS regulations; hazards in workplace environment and preventing form these dangers; risk assessment; personal protective equipment.

This course is a follow up of the first part of the Health and Safety at work; understanding how important is employee health and safety, its principles, legislative perspective, environmental aspects, employer, employee relationships, training employees on recently developed health and safety measures, some legal aspects at workplace, increasing awareness of occupational health and safety, hazardous and dangerous goods handlings, identifying occupational diseases ,early detection of work-related diseases and remedies and supplemental measures to take at workplace; first aid practices, some measurements about threshold limits and how they are calculated.

Physics and measurement; physical quantities; motion in one dimension; vectors; motion in two dimensions; Newton's laws of motion; work and kinetic energy; potential energy and conservation of mechanical energy; linear momentum, conservation of linear momentum; collisions; dynamics of a system of particles; rotational dynamics; torque and angular momentum; equilibrium of rigid bodies.

Electrical charge and Coulomb law; electrical field and the Gauss law; electrical potential; capacitors and dielectrics; current and resistance; magnetic field; ampere law; Faraday law; magnetic properties of matter; electromagnetic oscillations; sources of light; reflection and refraction; interference; polarization.

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Introducing Civil Engineering and its sub-disciplines. Historical background, current status and future challenges of civil engineering profession. Ethics and professional responsibility. Written and oral communication. Concepts of analysis, design, computational approaches, experiments. Interpretation of results and decision making. Invited lecturers. Site visits.

Goals and definitions. Introducing technical drawing tools and instruments. Technical drawing standards, standard fonts and shapes. Fundamental geometrical drawings, geometrical drawing applications. Standard parallel perspectives, perspective drawing applications, projections and projection methods. View drawing with European and American methods. Single and multi-view drawing. Working drafts, bolts and screws. Dimensioning and dimensioning rules. Section views. Assembling and manufacturing methods.

Mainfeatures of numerical and symbolical calculations by means of MATLAB; scalar and vector operations with arrays and matrices. Fundamentals of algorithms and programming; flow control and loops. Graphical representation of quantities.

General principles. Force vectors, particle equilibrium, force system components, rigid system equilibrium. Structural analysis, inner forces, friction. Center of gravity and geometrical center, inertia moments. Wirtual work.

Definition of topography. Maps. Coordinate and projection systems. Measurement units. Map scale. Measurement errors. Distance and angle measurement. Angle and coordinate computations. Traversing. Measurement and calculation of elevations. Area and volume computations. Map production. Global navigation satellite systems (GNSS). Modern surveying tools and methods.

Materials and their properties. Atomic bonds and their arrangements. Properties of crystal and non- crystal materials. Structural defects. Motion of atom. Elastic, plastic and viscoelastic deformation of materials. Equilibrium diagrams. Metals and their properties. Change in the material properties upon change in structure. Organic materials and their properties.

Simulation related with atoms. Bio material. Founding relations. Elastic behavior. Environmental effects. Wearing. Fracturing. Stretching with high temperature. Adhesion pressure, enforcement pressure, material enforcement adhesion pressure. Mechanical behavior. Metals, polymers, ceramics, intermetallics and composites. Micro possession relations. Material phase transformations. Plastic behavior. Principles and micro ? macro transition.

Introduction, basic principles. Strain, form change, relationships between strain- form change. Resistance hypothesis. Cross section effect in bars, normal force effect, cut force effect, inertia moments, bending effect, torsion.

Bending with shear. The shear center. The shear center of thin walled sections. Elastic curve for symmetrical cross-sections. Study of elastic curve by various methods. Effect of shear on the elastic curve. Axial force with bending. Materials not resistant to tension. Bending with torsion. Energy methods. Theorem of virtual work. Theorems of Betti and Castigliano. Minimum principles. Elastic stability. Euler cases. Buckling beyond the elastic limit, method of omega multiplier, approximate methods, Rayleigh ratio.

Fundamental properties of fluids, hydrostatic pressure and fluid statics, fluid kinematics, fundamental flow equations (continuity, impulse-momentum and energy equations), flow of ideal and real fluids, dimensional analysis.

Formation of earth. Age of Earth and formations. Deformations in earth crust (volcanoes, orogenesis, methamorphosis, tectonics, plate tectonics and subdation zones. Formation of rocks and soils, their origines (magmatics, methamorphics, sedimaentary),kinds, ages, and properties. Subsurface resources (minerals, petroleum, geothermal, geothermal, potable and irrigation water, rock quarries). Ground water, earth structure of Turkey. Seismic reflection and refraction, DC electrical resistivity, electromagnetics, gravity and magnetics, GPR-Radar, Geophysical well loggings, drilling and sampling. Borehole geophysical experiments (inclinometer, extensometers, etc.), and seismology. Earthquake predictions, types of faults and cracks, fault mechanisms, detection of the embedded faults. Internal and external structure of earth. Magnetic field, dynamic behavior of earth. Strength and bearing properties of rocks and soils. Testing with geophysics. Natural hazards influencing urbanizations: earthquakes, landslides, floods and ground failures. Determination of ground problems by geophysical methods: liquefaction, safe bearing capacity, resonance, subsidence, elasticity, shearing, ground classification by Vs and Vp, ground water, underground discontinuities (layers, voids, discontinuities), determination of fdepth of foundation .Field classification of urbanization area, ground selection and area usage. Inter Ground-Earthquake and Structure interaction. Construction Geophysics. Things to do for the structures that can not be demolished by earthquakes.

Definition and classification of mechanics, aim, basic concepts, principles of mechanics-Newton laws. Dimensional analysis, vector mechanics. Moment-plane and space problems. Equilibrium of plane and space systems. Dispersive effects-center of gravities-center of gravities of linear components, geometrical center of plane surfaces, volumetric centers-mass centers, inertia moments, inertia moments of masses, dynamic equilibrium-inertia force. Kinematics of material points (change of place-speed-acceleration) derivatives of vectorial functions, absolute and relevant motion. Coordinate transformations, kinetics of material points (force-mass-acceleration), motion equations.

This course is consisted of 30 days of industrial training. Properties of the training place, training period and duration, documents, application procedure, technical training report, assessment of the training work and other issues about the training are explained in the Deparmental Rules and Regulations for Industry Training. For the completion of the training successfully, the rules and the regulations in the Deparmental Rules and Regulations for Industry Training must be obeyed.

General concepts. Analysis of statically determinate structures. Determination of internal forces, internal force diagrams. Analysis for moving loads: influence lines. Analysis of basic statically determinate systems: multi-span compound systems, three-hinged frames and arches, trusses. Principle of Virtual Work. Computation of deformations and displacements for statically determinate structures.

General information about steel. Joints used in steel construction. Tension and pressure rods. Eccentric rods exposed to pressure. Full bodied beams, beam attachments and combinations. High strength bolts. Continuous beam combinations. Additional girth. Frames, frame corners, frame legs. Light steel structures.

Concrete and reinforced concrete properties. Basic behavior of reinforced concrete and fundamentals of design. Structural safety. Axially loaded members. Behavior of axially loaded members (Columns). Ultimate strength of members subjected to flexure. Analysis of beams. Design of beams. Combined flexure and axial load-RC columns. Ultimate strength of RC sections subjected to axial forces and flexure.

Ultimate strength of members subjected to axial load and biaxial bending. Effect of concrete strength on the ultimate capacity. Design of columns. Slenderness effect (Second Order Moments). Ultimate strength of members subjected to shear-diagonal tension. Design of shear reinforcement. Punching effect. Torsion in reinforced concrete structures and members.

The physical and index properties of soils, their classification, compaction. Hydraulic properties. Capillarity, permeability. Freezing effect. Effective, neutral and total stress. Deformation correlation. Stress distribution. Consolidation. Land slide resistance. Soil pressure.

Ground analysis. Land experiments. Bevel stability. Reliance walls, sheet pile curtains. Conveyor capacity of the surface base, conveyor capacity of the deep base. Production methodology of the poled bases. Ground treatment methods. Digging the base hole. Hole pavings. Tracking the structure behavior and the measurement tools.

Pressurized flow (pipe flow), major and minor head losses, pipelines in series and parallel, branching pipe systems, pipe networks, free surface flow (open channel flow), uniform flow, hydraulic efficiency of open channel sections, specific energy, rapidly varied flow, hydraulic jump, gradually varied flow, classification and computation of water surface profiles.

Fundamentals of transportation systems, transportation and traffic engineering. Principles of highway route selection. Highway planning and design. Urban transportation. Planning of urban roads and intersections. Volume, speed, travel time and congestion analyses. Traffic control systems.

This course in an in depth study of the computation of solutions to applicable civil engineering problems using spreadsheets. It contributes to effective usage of spreadsheet software, functions of wihch are dealt in detail. Also, students attain a level taht they can dvelop solution strategies on the problems and apply them within the capabilities of spreadsheet software. Applications include activity planning and time scheduling in project management, structural analysis of plane trusses and simple beams using matrix, computation of flow rates in pipe networks and design of retaining walls.

Introduction to ethics. Ethical theory, ethics and cooperate. Professional models. Ethical research. Incorrect scientific management. Professional responsibility to clients and employers. Honesty, integrity and reliability. Environment and ethics.

Use of numerical techniques to investigate case studies in civil engineering topics including hydraulics, geotechnics and structures. Interpolation and numerical integration techniques; numerical solutions to ordinary differential equations using Runge-Kutta and multistep techniques; application of finite difference techniques to partial differential equations using parabolic and elliptic equations; convergence and error analysis, development and application of computer programs to case studies derived from civil engineering practices.

The aim is building a capacity to solve engineering problems using some package programs (SAP 2000)

This course is consisted of 30 days of industrial training. Properties of the training place, training period and duration, documents, application procedure, technical training report, assessment of the training work and other issues about the training are explained in the Deparmental Rules and Regulations for Industry Training. For the completion of the training successfully, the rules and the regulations in the Deparmental Rules and Regulations for Industry Training must be obeyed.

Reinforced concrete slabs. Slab and beam floor; one-way slab,two-way slab. Flat slabs; with T-beam and/or capitals, without T-beam and/or capitals. Ribbed floor; one-way slab,two-way slab. Foundations. Individual footings. Continuous footings; one-way continuous footing, two-way continuous footing. Raft foundation. Pile foundation.

Earthquakes. Earthquakes zones. Force and equal force curves. Magnetics and energy. First-order free systems vibrations. Isolation of vibration. Vibration measurement devices. Earthquake movements and system behavior. Strong motion earthquakes. Numerical method for spectrum. Soil speed and displacement. Seismic design of structures. Seismic design of buildings. Industrial shafts and supporting walls.

International objectives and trends in civil and construction management education. The properties of construction sector and the construction manufacturing. Rationalization by construction manufacturing and cost functions. Introduction to project management in construction. Time-bound planning techniques. Preparing construction schedules with OK type (CPM) network diagrams. Bidding process. Preparing appraisals for state-owned constructions. Footage, materials, labor cost and prime cost estimations. Administration of the implementation and control documentation. Progress and conclusive bill preparation.

Beams on elastic foundation. Theory of Winkler. Theory of curved bars. Stresses in the cross-section of bars of circular axes. Torsion of thin-walled open cross-sections. Contact problems. Hertz problem. Symmetric deformations with respect to an axis. Thick-walled cylinders. Rotating disks. Circular plates. Circular plates with holes. Axially symmetric membrane shells. Buckling of straight rods by energy method. Rayleigh?s ratio.

Laboratory and field testing, soil characterization, problematic soils, factors to consider in foundation design, soil improvement techniques, slope stability.

General concepts of structural analysis, structural elements and loads. Isostatic systems. Moving loads. Influence lines. Relocation account. Indeterminate systems. Construction of idealized systems. Reinforced concrete design concepts. Design concepts of steel, steel building structures. Regulations. Plastic design concepts.

The aim of this course is to gain the competence in general problems related to geotechnical engineering and geotechnical engineering structures by using computer modelling and analytical methods for the students of the Engineering and Natural Sciences Faculty. To intorduce material behavior models to be used for modelling and analytical methods used in solutions is also a goal of this course.

General information about engineering structures, silos and bankers. Stock materials. Statistical loads analysis. Warehouses and retaining structures.

Blending finance and money management issues in engineering and its effective use in construction sector. Improvement of financial
modeling skills and more accurate results in valuation studies and development of successful investment plans. Proper presentation of the
plans produced and effective transfer to the target audience.

To know natural and ecological balance. Learning the factors affecting on ecological balance. Classification of environmental pollution. Solving the environmental problems that need to be solved using a holistic approach. To learn decisions based on environmental risk analysis and ethical analysis in engineering decisions. Development of sustainable environmental business plans / applications in the construction field.

General concrete. Durability and corrosion. Quality control and quality assurance. Transportation of concretes. Hot and cold weather concreting. Ready mixed concrete, pumping concrete, shocked concrete, injection mortar, Vacuum concrete, preplaced concrete. Mineral additives, admixtures. Repair and rehabilitation of concrete structures. Strengthening techniques and design calculation.

The examination of refineries as special energy structures. Iron steel factories. Gas and oil (petroleum) line. The examination of the water refining factories from sea water, the examination of the economic and environmental factors of these structures.

Statistics, frequency distributions, probability, probability distribution and densities,moment generating functions, joint distributions (discrete and continuous), sampling distributions,

The main purpose of the course is practical application of the acquired knowledge during education of civil engineering. Here especially, the quality criteria and problems are taken into account and the project should be maintained in accordance with the all possible management techniques by the student. The achievement of the student is depending on that whether the solution of the consumer?s problem (sector-specific problem) is performed satisfactorily.

The main purpose of the course is practical application of the acquired knowledge during education of civil engineering. In the scope of this course a practical engineering problem is given to the student. The given problem is expected to be solved by means of a proper method valid in the industry and presented.

Properties of the matter, Atoms and atomic structure, molecules and ions, Chemical compounds, Reactions in aqueous solutions,oxidation-reduction, Gases, Solutions and their physical properties, Acids and bases, Chemical kinetics, Principles of chemical equilibrium.

To create awareness among students about "career"; to help students to make a personal career planning by gaining awareness of their interests, personal characteristics and values and by getting to know different sectors.

Definition and types of functions, drawing their graphics, limits and continuity, definition of derivative and geometric meaning, differentiation rules, integration, definite and indefinite integrals.

Sequences and infinite series, parametrizations of plane curves, polar coordinates, vectors and the geometry of space, functions of several variables, limits and continuity in higher dimensions, partial derivatives, directional derivatives and gradient vectors, extreme
values and saddle points, Lagrange multipliers, multiple integrals

System of linear equations; Matrices and algebraic operations of matrices; methods for solving linear equation systems; Gauss and
Gauss-Jordan methods; determinants and properties of determinants; Cramer's rule; Vector spaces and Subspaces; Basis, dimension and rank; Eigenvalues and Eigenvectors; Diagonalization.

Inıtial-boundary value problems, first-order differential equations; exact differential equations and integrating factor, linear equations, Bernoulli equations, homogen equations, higher order linear differential equations, constant-coefficient linear differential equations, undetermined coefficients method, variation of parameters, Cauchy-Euler differential equations, Laplace transforms and solving linear equtions with Laplace transforms, series solutions of second order linear differential equations.

Statistics,frequency distributions, probability, probability distribution and densities, moment generating functions, joint distributions (discrete and continuous), sampling distributions, estimation, test of hypotheses.

In this course, the studies will be made about the understanding, explanation, reading and writing, various features of written explanation will be considered and examined with critical viewpoint. The punctuation marks which are the basis of the written explanation and writing rules will be made evident and the correct use of such rules for efficient and sound expression will be elicited.

In this course, the studies will be made about the understanding, explanation, reading and writing, various features of written explanation will be considered and examined with critical viewpoint. The punctuation marks which are the basis of written explanation and writing rules will be made evident and the correct use of such rules for efficient and sound expression will be elicited.