The contents of this course is: matter and measurement (precision and accuracy), atoms, molecules, ions, and their properties, stochiometry and chemical calculations, chemical reactions in aqueous solutions, thermochemistry, atomic structure, electron configurations, atomic properties and the periodic table.
In this course, the mechanics of deformable bodies and the stress that occurs due to the external loadings is defined. The calculation of stresses for different loading effects, the internal force diagrams of beams will be defined. The definition of axial loading, bending, shear, torsion, and combined loading effects is examined.
In this course, basic information about the structure and general properties of engineering materials is planned to introduce. Within the scope of the course, information is gained to define material properties such as force, stress, strain, deformation, elastic and plastic behavior, brittleness, toughness, ductility, viscosity, resilience, rheological models, creep, hardness and fatigue. It presents basic information about building materials such as gypsum, cement, concrete and it is planned to make a concrete mix design.
The course covers fundamental concepts and fluid characteristics, fluid statics, hydrostatic compression forces on planary and curvilinear surfaces. It also includes the Bernoulli equation, the Impuls-momentum equation, potential flows and dimensional analysis, which are among the basic equations of fluid dynamics.
In this course, introduction to engineering drawing, basic dimensioning and annotation techniques, sectioning, plotting and printing techniques is examined. The course gives the students the ability of creating any technical engineering drawing and Civil Engineering applications in AutoCAD software environment.
In this course, basic concepts about the principles of engineering dynamics are given. The course covers the axioms of Newton’s mechanics, kinematics of particles, kinetics of particles: vibration, work and energy, impulse and momentum, collision, kinetics of rigid body and vibration of a rigid body.
In this course, general information about the surveying is given. The importance of the geological conditions is examined in the formation and prevention of natural disasters.
In this course, basic information about the principles of engineering mechanics is introduced. The course covers the principles of calculation of the equilibrium of the rigid bodies, concepts of moment, couple and resultant. Equations of equilibrium, drawings of free-body diagram, shear and bending moment diagrams of beams, calculation of centroid of area, moment of inertia, distributed and hydrostatic forces, solution of frame and truss systems, cables, friction and virtual work method is planned to discuss.
In this course, an overview of hydromechanics is given. The course covers the principles of pipe flow hydraulics. The solution methods of open channel flow hydraulics, water surface profiles and flow control is planned to discuss.
In this course, structural systems will be classified, assumptions in calculations will be examined and concepts of load, support reaction, equilibrium, internal force and displacement will be learned. Internal force diagrams of different structural systems will be drawn and the methods used in displacement calculations will be examined.
In this course, the behavior of reinforced concrete and basic principles for calculation will be focused. By analyzing the mechanical properties of concrete and steel reinforcement materials that make up reinforced concrete, the calculation of reinforced concrete beams under the effect of pure bending will be carried out. Calculation of reinforced concrete columns under pure axial force and combined bending and axial load will be handled to examine the shear effect on reinforced concrete elements.
In this course, basic information about the RC slabs and foundation is presented. The course covers the principles of calculation of the deflection control in slabs. Seismic behavior of RC members, structural analysis and RC design of multi-story buildings is examined.
In this course, basic information about soil formation and classification is given. The course covers the principles of stress, compaction, consolidation, and shear strength and earth pressure. Laboratory tests will be held to determine the soil properties.
In this course, basic information about the solution of linear and nonlinear equation system is given. The course covers the principles of the calculation of the iterative methods, interpolation, cubic splines, numerical differentiation, numerical integration, numerical solution of nonlinear equations, initial value problems, numerical solution of ordinary differential equations, finite difference method. Civil engineering application problems method will be discussed.
Internship covers field experience at any work place for 4 weeks. Students should follow the instructions stated in IUE Internship Guide in order to successfully complete their internships.
Internship covers field experience at any work place for 4 weeks. Students should follow the instructions stated in IUE Internship Guide in order to successfully complete their internships.
Vector spaces, bases, GramSchmidt, linear maps and matrices, linear functionals, the transposed matrix and duality, kernel, image and rank, invertibility, triangularization, determinants and multilinear forms, powers of matrices, the exponential of a matrix, eigenvalues, eigenspaces, singular value decomposition, Jordan normal form. Symmetric hermitian and positive definite matrices, diagonalizability, unitary matrices. Solution of firstorder ODEs by analytical, graphical, and numerical methods. Linear ODEs, primarily second order with constant coefficients. Complex numbers and exponentials. Inhomogeneous equations: polynomial, sinusoidal, and exponential inputs. Laplace transform methods; convolution and delta function. Matrix methods for the solution of ODEs: eigenvalues and eigenvectors, matrix exponentials, variation of parameters. MATLAB is introduced for problem sets.
Vector fields, gradient, curl, divergence. Multiple integrals, line integrals, surface integrals. Stokes' theorem in one, two, and three dimensions. Complex algebra and functions; analyticity; contour integration, Cauchy's theorem; singularities, Taylor and Laurent series; residues, evaluation of integrals; Fourier analysis, Laplace transforms.
This course aims at preparing students to use academic skills in English.
ENG 102 is a compulsory course for first year students. ENG 102 focuses on the cognitive skills of listening, reading, writing and speaking. Students' academic listening skills will be improved by listening to important / relevant information from lectures or discussions and reading skills by reading recent academic texts and then using this information to create an output task. Speaking focuses on giving presentations and students get prepared to express their ideas and opinions by speaking persuasively and coherently. The writing component is a consolidation of the speaking activities.
The course focuses on technical writing and oral presentation skills by engaging students in project work related to their departments. It also covers language areas specific to the genre of technical reports, summaries and project proposals.
In this course, the main aspects of engineering history, the fundamentals of ethics in engineering, the analysis of engineering applications from an ethical perspective, the environmental, social, and economic sustainability of engineering applications. The public health and safety impacts of engineering applications, the fundamentals of entrepreneurship and innovation, success stories of entrepreneurial engineers, the methods of obtaining scientific information, the usage of scientific databases will be covered.
The course will cover basic engineering concepts such as units, engineering analysis and design process. The second half of the course will be dedicated to program-based introductory content.
The design, analysis and business-plan development of a project by teams of students by using engineering techniques; preparation of project reports and presentation by using state-of-the-art tools and methods.
Students in teams can specify, analyze and handle business plan of a project using engineering fundamentals. They can realize and implement the project using emerging tools. They can report and present all the details of their final product.
This course provides a general information of the events from the end of the 19. century until the end of the Turkish War of Independence and the signing of the Treaty of Lausanne in 1923 and the following period until 1990’s.
The course will help students recognize the skills needed for university life and their career goals. These skills include self-awareness, goal setting, time management, effective communication, mindfulness and analytical thinking. The course will also raise students’ awareness on problems such as addiction and bullying.
Calculus I provides important tools in understanding functions of one variable and has led to the development of new areas of mathematics.
In this course, integration techniques and application of integration, Taylor and Maclaurin series and their applications, functions of several variables, their derivatives, integrals and applications are examined.
This course focuses on sampling distributions, statistical estimation, hypothesis testing, simple and multiple linear regression. In addition, experimental design and applications of these methods to industrial systems engineering are discussed.
In this course some important theorems about probability are investigated. In addition, applications of random variables and their probability distributions are discussed.
In this course, we will discuss the subjects of motion along a straight line, motion in two and three dimensions, Newton’s laws, work and kinetic energy, potential energy and conservation of energy, momentum, collisions, dynamics of rotations, gravitation and periodic motion.
In this course, we will cover the topics of electric field and charge, Gauss’s law, electric potential, capacitance and dielectrics, current, resistance and electromotive force, direct-current circuits, magnetic field and magnetic field sources and induction.
Course Content This course introduces the students to the fundamental concepts of programming using Python programming language.
Students will be taught how to use the written and verbal communication tools accurately and efficiently in this course. Various types of verbal and written statements will be examined through a critical point of view by doing exercises on understanding, telling, reading, and writing. Punctuation and spelling rules, which are basis of written statement, will be taught and accurate usage of these rules for efficient and strong expression will be provided. As for verbal statement, students will be taught how to use the body language, use accent and intonation elaborately, and use presentation techniques.
This course will cover basic topics in Transmission Fundamentals; Communication Networks; Wireless Channel; Signal Encoding Techniques; OFDM and Spread Spectrum; Coding and Error Control; Wireless LANs; Bluetooth and PAN; Cellular Networks -4G and LTE; Mobile IP; Satellite Communications.
The following topics will be included: getting and cleaning data, exploring data, statistical models of data, statistical inference, main machine learning methods in data science including linear regression, SVM, k-nearest neighbors, Naïve Bayes, logistic regression, decision trees, random forests, clustering, and dimensionality reduction, over-fitting, cross-validation, feature engineering.
This course introduces the general information about the steel design. The course covers the principles of steel design specifications, design methods of tension members, compression members, beams, beam columns and connections.
This course explains general information about the geotechnical properties of soils. The course covers subsurface investigations, shallow foundations, mat foundations, lateral earth pressures, retaining structures, sheet piles, braced cuts, pile foundations, drilled shafts and soil improvement techniques.
The course introduces finite element (FE) analysis as a common numerical analysis tool. It covers the fundamental theoretical approach beginning with a review of numerical integration, parametric geometry, and integral formulation and the implementation of FE analysis using Finite Element Programs. Students learn to use a commercial finite element software upon graduation.
Structural Health Monitoring covers the concepts of rapid after disaster assessment of civil infrastructure. The tools and skills incorporated within the curriculum of this class provide quantitative means to assess the structural integrity loss a system undergoes after natural disasters and other hazardous events.
This course outlines the Force Method, Slope-Deflection Equations, and Moment Distribution (Cross) Method used in the analysis of statically indeterminate systems.
In this course, the analysis of different types of structures using matrix methods is explained. An advanced level of structural analyses is examined for the advanced structural systems.
In this course, basic information about the basin and hydrologic cycle is introduced. The course covers the principles of precipitation, evaporation and seepage by introducing statistical methods in hydrology.
In this course, basic information about the use of commercial software in structural engineering will be given. SAP2000 interface will be introduced and the ability to design the frame-wall systems with respect to the provisions of related code will be gain by making structural design.
This course covers the dynamic stability of structures, the response of a single degree of freedom system to a dynamic load. The solution methods for dynamic behaviour of the structures are given in accordance with the basis of structural seismic design codes.
This course covers the general description of commonly used NDT methods to estimate strength and other properties of masonry. The tools and skills incorporated within the curriculum of this class provide the assessment of masonry structures, test techniques and working principles of surface hardness, penetration resistance, stress wave propagation methods, magnetic and electrical testing, and applications of infrared thermography and radar techniques.
The course focuses on the earthquake ground motion, fault mechanisms and earthquake parameters. Basic principles of Structural Dynamics in terms of Earthquake Engineering will be taken into account to investigate the behavior of the structural systems under earthquake ground motion and the earthquake load acting on the structures will be calculated. The concept of Earthquake Spectra will be introduced and the design spectra in the Earthquake Design Codes will be examined.
In this course, general information about the properties of water and sediment is given. The course covers the principles of incipient motion criteria and applications, resistance to flow and bed forms, bed load suspended load and total load theories, reservoir sedimentation, special topics in sediment transport.
This course includes concepts of history of prestressed concrete, equipment used, production techniques and principles, design principles, prestressed concrete in industrial structures, prestressed concrete in bridges, industrial building examples, bridges, quality control principles.
The course plans to discuss each of the hydraulic structures in detail, with sample worked examples, the design aspects of the hydraulic structures meant for storage, diversion, conveyance and distribution of water.
The course plans to discuss the causes and results of the unsteady flow problems in detail, with sample worked examples, computational methods in the unsteady flow analysis as well as the procedures to control the undesirable results
In this course, basic information about dimensionless parameters is given. The course covers the principles of hydraulic physical model theories as Reynolds models, Froude models and distorted models.
The course covers concrete types and practical application, selection of concrete mix, fresh/hardened concrete properties, cement types and their properties, pozzolanic additives, properties of the binder phase. properties of aggregates, types and use of admixtures, curing technology and shrinkage/crack sensitivity, mechanical properties of concrete, permeability, durability and reinforcement corrosion.
In this course, general information about groundwater engineering is discussed. The course covers the principles of analyze and design of subsurface flow and transport.
This course includes concepts of industrial construction technologies, prefabricated concrete high structures, prefabricated concrete production methods, mold designs, production planning, prefabricated element handling criteria, prefabricated building assembly methods, design examples, prefabrication in industrial buildings and bridges.
This course comprises definitions, planning in transportation, road capacity, classification of highways, and determination of routes, geometrical design (design of horizontal and vertical design).
The course includes the design of the engineering infrastructures which are used to transfer water from source to the city and distribute it through the city.
Within the scope of the course, basic parameters of earthquake ground motion, methods used in earthquake load calculation of structures, rules of earthquake regulations, damage to structures due to earthquakes, and structural repair and retrofitting are discussed.
This course explains the concepts of coastal structures and their conservation to the students. It also gives detailed information about waveforms, effects on coastal structures and hydrodynamics.
The course introduces the various types of improvement methods of engineering properties of soils and the application of engineering methods to ground improvement projects.
The course covers concept of coastal zone management: coastal definition, coastal resources, coastal ecosystems, sustainable resource management.
This course includes concepts of construction management and site management. During the classes, various quantity takeoff applications and management problems solve.
In this course soil mechanics and applications, slope stability, and flow networks is explained. Practical informations about insitu tests ise given during the laboratory courses.
Economic analysis for engineering and managerial decision making. Techniques for evaluating the worth of prospective projects, investment opportunities and design choices. Interest and time value of money, methods for evaluation of alternatives: present worth, annual equivalent worth, rate of return, and payback method. Inflation, after tax economic analysis. Sensitivity and risk analysis.
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This course covers topics related with IE372 and ISE 380
Students will learn to make decisions by taking into account such features as interest rates, and rates of return. They will learn about the concept of arbitrage, and when consideration of such is sufficient to price different investments. Applications to call and put options will be given. Students will learn when arbitrage arguments are not sufficient to evaluate investment opportunities. They will learn to make use of utility theory and mathematical optimization models to determine optimal decisions. Dynamic programming will be introduced and used to solve sequential optimization problems. The use of simulation in financial engineering will be explored.
Composite materials. Definitions and classification of composites. Matrix materials. Fiber (reinforcement) materials. Metals, ceramic and polymer matrix composites. Production methods for composite materials. The strength properties of unidirectional composites. Mechanical Testing of Composites. Visco-elastic properties of composite materials.
Definition of nanomaterials, classification of nanomaterials, properties of nanomaterials, applications in nanotechnology, nanochemisry
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In this course, students learn about the process of video game development and use this information to develop their own computer games.
The purpose of this course is to inform the how e-business will be implemented under different conditions and environments.
