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Lecturer(s)
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Remeš Radim, Mgr. Ph.D.
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Milota Josef, RNDr.
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Beránek Ladislav, prof. Ing. CSc., MBA
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Course content
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Lectures: 1 - Object-oriented concepts 2 - Introducing classes, structs and namespaces: Classes and Types, Inheritance, Abstract 3 - Classes and Interfaces, Nested Classes, Structs, Namespaces 4 - Class declaration: Attributes, Class Modifiers, Class Base, Interface Declarations 5 - Introducing Methods: Attributes, Method Modifiers, Formal Parameters, Parameter Passing 6 - The params modifier, Return Type, Method Overloading 7 - Polymorphism: Member Overriding, Member Hiding 8 - Operators: overloading operators 9 - Constants, Fields, Properties and Indexers 10 - Delegates and Events 11 - Exceptions 12 - Attributes, reflection Seminars: 1 - Object-oriented concepts 2 - Introducing classes, structs and namespaces: Classes and Types, Inheritance, Abstract 3 - Classes and Interfaces, Nested Classes, Structs, Namespaces 4 - Class declaration: Attributes, Class Modifiers, Class Base, Interface Declarations 5 - Introducing Methods: Attributes, Method Modifiers, Formal Parameters, Parameter Passing 6 - The params modifier, Return Type, Method Overloading 7 - Polymorphism: Member Overriding, Member Hiding 8 - Operators: overloading operators 9 - Constants, Fields, Properties and Indexers 10 - Delegates and Events 11 - Exceptions 12 - Attributes, reflection
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Learning activities and teaching methods
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Monologic (reading, lecture, briefing), Dialogic (discussion, interview, brainstorming)
- Preparation for classes
- 44 hours per semester
- Preparation for credit
- 30 hours per semester
- Preparation for exam
- 40 hours per semester
- Class attendance
- 16 hours per semester
- Semestral paper
- 38 hours per semester
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Learning outcomes
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The main objective is to gain basic experience with object-oriented programming language. Philosophy of OOP. Classes, objects, instances of classes and other types. Class methods. Inheritance, multiple inheritance. Private attributes and methods, name spaces. Destructors and memory management. Modeling of classes using UML.
Students understand the basic principles of object-oriented programming, they are able to create basic class models in developer studio and to complete basic object-oriented programs.
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Prerequisites
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The course has no prerequisities.
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Assessment methods and criteria
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Analysis of student's work activities (technical works), Combined exam
Credit Requirements: Programming partial short tasks, creating a project application. Global success rate minimally 65%. Examination Requirements: Students will demonstrate complex knowledge of programming in programming language.
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Recommended literature
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Deitel, H., Deitel, P. Visual C# How to Program, 6th Edition. Hoboken, New Jersey, USA: Pearson Education, 2016.
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Jamro, M. C# Data Structures and Algorithms. Birmingham, UK: Packt., 2018.
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Michaelis, M. Essential C# 7.0, 6th Edition. Bostom, USA: Addison-Wesley Professional, 2018.
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Nesteruk, D. Design Patterns in .NET: Reusable Approaches in C# and F# for Object-Oriented Software Design. New York, NY (USA): Apress., 2019.
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Sarcar, V. Design Patterns in C#: A Hands-on Guide with Real-World Examples. Karnataka, India: Apress, 2018.
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Taher, R. Hands-On Object-Oriented Programming with C#. Birmingham, UK: Packt., 2019.
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