Ders Planı

Lesson Information

Course Credit	4.0
Course ECTS Credit	7.0
Teaching Language of Instruction	Türkçe
Level of Course	Bachelor's Degree, TYYÇ: Level 6, EQF-LLL: Level 6, QF-EHEA: First Cycle
Type of Course	Compulsory
Mode of Delivery	Face-to-face
Does the course require compulsory or optional work experience?	Z
Course Coordinator
Instructor (s)	Assist. Prof. Dr. İLKNUR HOŞ\|Prof. Dr. ÇİĞDEM GENCER BALBİANİ
Course Assistant

Purpose and Content

The aim of the course	This module aims to provide an accessible review of the advanced calculus from the text book to long after the class and to provide the concepts integration and the applications of integration. It presents a source for undergraduate students at their first year. Calculus is taught in a traditional lecture format or in laboratories with individual and group learning focusing on numerical and graphical experimentations. Give an ability to apply knowledge of mathematics on engineering problems. Provide the evaluation of integrals by using integral techniques. Give the basic concepts of analytic geometry. Give a broad knowledge and basic understanding of sequences and series. Provide the limit, continuity and integral of vector-valued functions in application.
Course Content	Concept of area, estimating with finite sums, sigma notation and limits of finite sums, definite integral, The Fundamental Theorems of Calculus and Integral,integration by parts,substitution rule, indefinite integrals, numerical integration , hyperbolic and inverse hyperbolic functions, techniques of integration, area, lengths of plane curves, volumes of a solid of revolution, areas of surfaces of revolution, moments and centers of mass, moments of inertia, Pappus theorems, areas and lengths in polar coordinates. improper integrals, sequences, infinite series, tests of convergence for arithmetic,geometric,harmonic, alternating series ,absolutly convergent, conditionaly convergent,derivation and interal of power series,convergence of power series, Taylor and Maclaurin Series, Fourier Series,vectors, dot Product, cross product, lines and planes in space, cylinders and quadric surfaces, vector-valued functions, limits and continuity and integrals of vector-valued functions.

The aim of the course

This module aims to provide an accessible review of the advanced calculus from the text book to long after the class and to provide the concepts integration and the applications of integration. It presents a source for undergraduate students at their first year. Calculus is taught in a traditional lecture format or in laboratories with individual and group learning focusing on numerical and graphical experimentations. Give an ability to apply knowledge of mathematics on engineering problems. Provide the evaluation of integrals by using integral techniques. Give the basic concepts of analytic geometry. Give a broad knowledge and basic understanding of sequences and series. Provide the limit, continuity and integral of vector-valued functions in application.

Course Content

Concept of area, estimating with finite sums, sigma notation and limits of finite sums, definite integral, The Fundamental Theorems of Calculus and Integral,integration by parts,substitution rule, indefinite integrals, numerical integration , hyperbolic and inverse hyperbolic functions, techniques of integration, area, lengths of plane curves, volumes of a solid of revolution, areas of surfaces of revolution, moments and centers of mass, moments of inertia, Pappus theorems, areas and lengths in polar coordinates. improper integrals, sequences, infinite series, tests of convergence for arithmetic,geometric,harmonic, alternating series ,absolutly convergent, conditionaly convergent,derivation and interal of power series,convergence of power series, Taylor and Maclaurin Series, Fourier Series,vectors, dot Product, cross product, lines and planes in space, cylinders and quadric surfaces, vector-valued functions, limits and continuity and integrals of vector-valued functions.

Learning Outcomes

Adequate knowledge in mathematics, physical sciences and the engineering subjects of individual branches; the ability to implement theoretical and practical knowledge in the respective areas to modeling and solving engineering problems.
Ability to identify, define, formulate and solve complex engineering problems; ability to select and implement the appropriate analysis and modeling methods in this respect.
Ability to design and conduct experiments for analyzing engineering problems or research subjects specific to the discipline, to collect data, to analyze and interpret the results.
Ability to use, choose and develop modern techniques and means required for engineering applications; ability to use information technologies effectively.
An ability to design and conduct experiments, collect data, analyze and interpret results for the study of complex engineering problems or discipline-specific research topics.
Awareness of the necessity of lifelong learning; ability to reach information, follow the latest developments in science and technology; ability to ensure self-renewal perpetually.
Acting in line with ethical principles, sense of professional and ethical responsibility; knowledge on the standards of engineering applications.
Ability to work effectively in interdisciplinary and multi-disciplinary teams and individual works.
Information about the effects of engineering applications on health, environment and safety in terms of universal and social aspects and information about the problems of the era; awareness about the legal results of engineering solutions.
Ability to communicate efficiently both in oral and written ways in Turkish; knowledge of at least one foreign language; ability to effectively prepare reports and understand written reports, prepare design and production reports, effective presentation, giving and receiving clear and understandable instructions.
Knowledge of business practices such as project management, risk management and change management; awareness of entrepreneurship, innovation; information about sustainable development.

Weekly Course Subjects

1	Concept of area, estimating with finite sums, sigma notation and limits of finite sums, definite integral, the fundamental theorems of calculus
2	Evaluation of Limit using the definite integral, indefinite integral and its properties
3	Integration by parts, substitution rule, integral formulas
4	Numerical integration metods, hyperbolic and inverse hyperbolic functions
5	Techniques of integration
6	Techniques of integration
7	Area, lengths of plane curves, volumes of a solid of revolution, areas of surfaces of revolution
8	Moments and centers of mass, moments of inertia, Pappus theorems
9	Areas and lengths in polar coordinates, improper integrals, Midterm Exam
10	Sequences, infinite series, tests of convergence for arithmetic, geometric,harmonic, alternating series
11	Absolute convergent, conditional convergent, convergence of power series
12	Derivation and integral of power series, Taylor and Maclaurin Series, Fourier Series
13	Vectors, dot product, cross product, lines and planes in space, cylinders and quadric surfaces
14	Vector-valued functions, limits and continuity and integrals of vector-valued functions

Resources

1- G.B Thomas, M.D.Weir, J.Hass and F.R.Giordano,Thomas’ Calculus, 11th Edition, Addison-Wesley, 2005.
2- Mustafa Balcı,Genel Matematik I,Balcı Yayınları,Ankara,2008.
3-Mustafa Bayraktar, Analize Giriş II(2.Baskı) , Grafiker Yayınları,Ankara,2007.
4- Speigel, M. R., Çeviri Editörü: H. H. Hacısalioğlu, İleri Matematik, 6. Baskı, McGraw-HILL, Schaum’s Outline Series, NY., Ankara Üniversitesi,1997.
5- Ahmet Dernek, Genel Mat ematik, 3. Baskı, Nobel Yayın Dağıtım Tic. Ltd. Şti. Ankara,2009

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Lesson Information

Purpose and Content

Learning Outcomes

Weekly Course Subjects

Resources

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