Engineering drawing is the language of the engineers and technicians. Therefore, it is the intent of this course to equip students with the fundamentals of this unique language and to give them the skills necessary to prepare complete, concise, and accurate communications through engineering drawings using AutoCAD.

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This course aims to give a background to students on the structure of matter and its mechanical properties to better understanding for construction materials course. It contains; atomic arrangements, structural imperfections, concepts of force, stress, deformation and strain, elasticity, elastic and plastic behavior, viscosity and creep, brittleness, ductility, hardness, fatigue, toughness characteristics of materials. The course will be extended laboratory experiments for better understanding of the concepts.

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Introduction of the Mechanical Engineering Program and the regulations. Engineering profession and the place of mechanical engineering in it. Development of mechanical engineering. Engineering ethics. Contribution of ME to the solution of societal problems. Principal application areas of ME.

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Summer Practice/Community Service

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Principles of statics, force vector, equilibrium of particle, moment of a couple, equilibrium of rigid body, planar forces, center of gravity, Theorem of Pappus-Guldinus, distributed loads and hydrostatics forces, supports and support reactions, Gerber beam, frames, simple machines, trusses, cables, friction, virtual work

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Basic Concepts of Solid Mechanics. Mechanical Properties of Materials. Axial Loading. Transverse Shear. Bending. Deflection of Beams. Torsion. Buckling of Columns. States of stress and strain. Criteria for Failure. Combined Loading. Fatigue

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Kinematics of particles; velocity and acceleration in rectangular, cylindrical, spherical and normal and tangential coordinates. Rectilinear motion. Relative motion. Kinetics of particles; Newton’s law of motion. Equation of motion. Work. Impulse. Momentum. Principle of work and energy, principle of impulse and momentum. Angular momentum, angular impulse and momentum principle. Kinetics of systems of particles. Planar kinematics of rigid bodies, instantaneous center of rotation. Planar kinetics of rigid bodies. Three dimensional kinematics of rigid bodies. Three dimensional kinetics of rigid bodies.

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Introduction to the First and Second Laws of Thermodynamics. Thermodynamic properties of pure substances and ideal gases. Analysis of ideal and real processes. Control volume analysis using energy. Entropy and Exergy Analysis.

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Engineering applications of thermodynamics including vapor power systems, gas power systems, refrigeration and heat pump systems, pyschrometric applications, reacting mixtures and chemical applications.

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Summer Practice/Community Service

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Description of Numerical Methods and application of them particularly inengineering. Error analyses in numerical methods, analitical solutions,numerical methods for the solution of systems (lineer and non linear), approximation methods, interpolation, linear regression, numerical integration.

Principles and classifications of processes in manufacturing; advantages, limitations and comparisons of material processing. Design and manufacturing; selection of process. Casting, welding, forming, machining, and powder metallurgy. Manufacturing of polymer and composites parts. Rapid prototyping and ceramic part manufacturing.

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Mechanical engineering design activity and importance of machine elements knowledge in this activity. Fundamentals of design and applications of machine elements. Welded, soldered, adhesive bonded, riveted joints. Shaft-hub connections. Bolted joints and power screw mechanisms. Pins, knuckles, springs, shafts and axles, coupling and clutches, lubricants and lubrication theory, sliding and rolling bearings Fundamentals of speed reduction mechanisms, kinematics and geometry of gears, spur, helical, bevel, spiral and worm gear mechanisms, belt drive and chain mechanisms.

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The importance of machine elements knowledge in the mechanical engineering design activity is emphasized. The course covers the fundamentals of design and applications of machine elements (mechanical springs, flywheels, belt drive and chain mechanisms, clutches, brake systems). Besides, the course is aimed to gain a grasp of the relations between the machine elements.

Introduction to system dynamics and control, Transfer function of linear systems. Linearization, Transient response analysis, Stability analysis, Basic control algorithms and structures, PID tuning methods, Frequency response analysis, Basic controller design methods and examples.

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Basic concepts in measurement. Statistics. Uncertainty and statistical analysis of experimental data. Report writing and presentation. Basic analog electronics. Methods and sensors for displacement, pressure, flow, temperature, force, strain, vibration and sound measurements.

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Basic concepts and definitions. Fluid kinematics. Fluid statics. Manometers and pressure measurements. Hydrostatic forces on immersed bodies. Solid body translation and rotation. Equations of conservation of mass, momentum and energy for systems and control volumes Bernoulli equation and applications. Navier-Stokes equations and its applications. Stream function and flow potential. Dimensional analysis and similarity. Viscous Flow in pipes and ducts. Laminar and turbulent boundary layers. Major and minor losses in pipes. Flow over immersed bodies. Boundary layer equations. Compressible flow. Fluid Machinery. Water hammer

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In this course Advanced Fluid Mechanics and Energy Transfer content will be covered together. The course covers the Enginnering Design and Research content of Thermodynamics, Fluid Mechanics and Heat Transfer.

Mechanisms of heat transfer. Steady and transient heat conduction in solids, solution methods. Laminar and turbulent forced convection, natural convection. Phase change heat transfer. Heat exchangers. Radiation heat transfer.

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In this course Projects will implemented to develop Mechanical Design Projects by using International Standart Computer Programs. Course will cover Computer Aided Drafting/Design skills through homeworks and a Semester Project.

This no-lecture course includes an appropriate design project with all the design phases starting from project selection to completion and presentation, and which leads the students use the knowledge they gained during their tenure in the department and gain complete design experience. In this course, design of a machine, system or process is conducted in the framework of an open-ended engineering problem and a team of students develops the solution

• Mechanical Engineering | Curriculum | Prerequisites / Conditions Graph

This no-lecture course includes an appropriate design project with all the design phases starting from project selection to completion and presentation, and which leads the students use the knowledge they gained during their tenure in the department and gain complete design experience. In this course, design of a machine, system or process is conducted in the framework of an open-ended engineering problem and a team of students develops the solution

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This is a first course on the fundamental sequence of calculus-based physics. It mainly covers mechanics, which is about the motion of objects. Subjects covered include kinematics of motion, Newton's laws of motion, gravitation, work, energy, momentum, rotational motion, static equilibrium and oscillations. The concepts of temperature and heat are also introduced.

This is a first course on the fundamental sequence of calculus-based physics. It mainly covers mechanics, which is about the motion of objects. Subjects covered include kinematics of motion, Newton's laws of motion, gravitation, work, energy, momentum, rotational motion and static equilibrium. In addition to the face to face lectures, online studies and laboratory sessions are part of the course.

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• Electrical and Electronics Engineering | Curriculum | Prerequisites / Conditions Graph
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• Computer Engineering | Curriculum | Prerequisites / Conditions Graph
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This is the second course on the fundamental sequence of calculus-based physics. It mainly covers various concepts and laws about electricity and magnetism. Subjects covered are electric charge, electric field, Gauss's law, electric potential, electric current, Kirchoff's laws, resistance, capacitance, electromotive force and direct current circuits followed by the properties of magnetic fields, Ampére's law, Faraday's law, inductance and alternating current circuits. In addition to the face to face lectures, online studies and laboratory sessions are part of the course.

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This course aims to familiarize students with the nature of light and the principles of optics. After a review of Maxwell's equations, the nature of light will be covered in detail. Subjects covered also include reflection, refraction, image formation by various optical instruments, wave optics, diffraction patterns and polarization.

This course aims to familiarize students with the concepts of modern physics. A detailed introduction to special relativity is followed by a general introduction to quantum physics and quantum mechanics. In the last part of the course a review the atom from early models to the quantum model is made with various applications.