CAD electronic devices
Description: The discipline systematizes the principles of organizing computer-aided design (CAD) systems, computer-aided design methods, mathematical models, software and hardware tools used in the design of automation devices and systems.
Amount of credits: 5
Пререквизиты:
- Digital devices
Course Workload:
Types of classes | hours |
---|---|
Lectures | 15 |
Practical works | |
Laboratory works | 30 |
SAWTG (Student Autonomous Work under Teacher Guidance) | 30 |
SAW (Student autonomous work) | 75 |
Form of final control | Exam |
Final assessment method |
Component: Component by selection
Cycle: Profiling disciplines
Goal
- Studying the basic techniques of systems engineering based on methods of mathematical and computer modeling; students mastering the theoretical foundations of computer-aided design systems used in the development of automation devices and systems; gaining skills in solving engineering problems of designing complex technical automation systems using CAD.
Objective
- - mastering the classification of existing CAD systems and automation systems and areas of their use for solving a variety of tasks related to product design; - determination of the characteristics of functional CAD subsystems, the development of methods for their construction; - the practical development of a number of CAD systems that are widespread in industry and are characteristic representatives of individual classes of systems; - develop skills in a systems engineering approach in integrated design; - to develop among students the ability to independently acquire and deepen the knowledge gained in studying the course; - familiarization with the prospects and main directions of improving CAD systems and automation systems.
Learning outcome: knowledge and understanding
- - current trends in the development of automation and control tools and systems; - Prospects and trends in the development of information management technologies; - standards, methodological and normative materials accompanying the design of production and operation of automation and control equipment and systems; - modern means of computer technology, communications and communications; - methods and means of developing mathematical, linguistic, information and software systems for automation and control; - rules, methods and means of preparing technical documentation; - technical characteristics and economic indicators of domestic and foreign models of software and hardware systems for automation and control; - characteristic features of design automation based on computer technology; - the requirements that must be met by a computer-aided design system; - CAD software structure.
Learning outcome: applying knowledge and understanding
- analyze and improve the quality of functioning of automation and control systems; - use mathematical modeling and computer-aided design systems to create and improve software and hardware and automation and control systems; - organize in the teams of performers the development and production of means and systems of automation and control;
Learning outcome: formation of judgments
- - carry out a system analysis of technical systems, processes and industries; - analyze and improve the quality of functioning of automation and control systems; - use mathematical modeling and computer-aided design systems to create and improve software and hardware and automation and control systems; - organize in the teams of performers the development and production of means and systems of automation and control;
Learning outcome: communicative abilities
- - the ability to work on the development of complex projects for the design of devices and automation systems in an organization with corporate data exchange systems
Learning outcome: learning skills or learning abilities
- - logical thinking in the design of devices and systems; - the use of modern computer systems for the development of design and technical documentation of new devices and automated control systems; - work with modern design software; - work taking into account real production relations; - use of standards, GOSTs and ESKD.
Key reading
- 1. Головицына М.В. Основы САПР. М.: Интернет – Университет Информационных технологий, 2011. http://www.intuit.ru/studies/courses/2264/227/info 2. Дьяконов В.П. MATLAB. Основы применения. Серия «Библиотека профессионала». – М.:–СОЛОН–Пресс, 2005.–800с.:ил. ISBN 5-98003-181-2 3. Кондаков А.И. САПР технологических процессов: учебник для студ. высш. учеб. заведений.–М.:Издательский центр «Академия», 2007.–272с. – ISBN 978-5-7695-3338-9 4. Норенков И. П. Основы автоматизированного проектирования: учеб. для вузов. — 4-е изд., перераб. и доп. — М.: Изд-во МГТУ им. Н. Э. Баумана, 2009. — 430 с. — ISBN 978-5-7038-3275-2 5. Черных И.В. Моделирование электротехнических устройств в Matlab, Sim Power Systems и Simulink.– М.: ДМК Пресс; СПб.: Питер, 2008. – 288с.: ил. ISBN 5-94074-395-1