- •Предисловие
- •History and Development of Automatic Control
- •Introduction to Control Systems
- •From the History of Automatic Control Theory
- •Управление
- •Elements and Structure of Automatic Control Systems
- •Automation
- •Business Systems
- •Comparing Feed forward and Feedback Controllers
- •Types of Feedback Control Systems
- •History of the word "cybernetics"
- •The History of Cybernetics
- •Cybernetics
- •Сфера кибернетики
- •The heritage and revival of cybernetics
- •Distributed Control System (dcs) History
- •Servomechanism, Regulator and Process Control
- •Data acquisition
- •Methodology Source
- •Signals
- •Daq hardware
- •Daq software
- •Алгоритмы функционирования технологических объектов, управляемых асутп
- •What is Artificial Intelligence?
- •Составление реферата
- •Hart-коммуникация
- •Беспроводные интерфейсы
- •The End of a Monopoly Era
- •The End of a Monopoly Era
- •Artificial Intelligence
- •Robot programming and interfaces
- •Writing a Summary
- •Experimental modeling and adaptive power control of a 750mw once-through boiler
- •I. Industrial robot
- •II. Robot types, features
- •III. Defining parameters
- •IV. End –of-arm Tooling
- •V. Controlling Movement
- •VI. Robotics
- •Функции асу тп
- •Grammar Reference Passive Voice
- •Сопоставление русских и английских времен в Passive
- •The Infinitive
- •Forms of the Infinitive
- •Functions of the Infinitive
- •2) Частью сказуемого.
- •The Complex Object
- •The Complex Subject
- •The Participle
- •The Absolute Participle Construction
- •The Gerund
- •Forms of the Gerund
- •Functions of the Gerund
- •Supplementary Texts Types of control systems
- •History of Cybernetics and Systems Science
- •The Search for New Tools
- •Industrial Robots
- •An Introduction to Artificial Intelligence
- •Applications of ai
- •Artificial intelligence
- •Open and closed – loop systems
- •Inputs and Outputs
- •Interface
- •Technological revolution in Russia
- •Асу тп сегодня
- •Microprocessor
- •External Processor Interfaces and Operation
- •Trigonometry. Units of Measurement
- •Figure 1 - a radian defined
- •Interrupts
- •Programs
- •Other microcontroller features
- •Higher integration
- •What Is a Control Engineer?
- •Специальность «Автоматизация и управление»
- •Linear versus Nonlinear Control Systems
- •Principles of Automatic Emergency Control
- •Сети следующего поколения
- •Список литературы
- •Содержание
- •Предисловие
- •History and Development of Automatic Control
- •Introduction to Control Systems
- •From the History of Automatic Control Theory
- •Управление
- •Elements and Structure of Automatic Control Systems
- •Automation
- •Business Systems
- •Comparing Feed forward and Feedback Controllers
- •Types of Feedback Control Systems
- •History of the word "cybernetics"
- •The History of Cybernetics
- •Cybernetics
- •Сфера кибернетики
- •The heritage and revival of cybernetics
- •Distributed Control System (dcs) History
- •Servomechanism, Regulator and Process Control
- •Data acquisition
- •Methodology Source
- •Signals
- •Daq hardware
- •Daq software
- •Алгоритмы функционирования технологических объектов, управляемых асутп
- •What is Artificial Intelligence?
- •Составление реферата
- •Hart-коммуникация
- •Беспроводные интерфейсы
- •The End of a Monopoly Era
- •The End of a Monopoly Era
- •Artificial Intelligence
- •Robot programming and interfaces
- •Writing a Summary
- •Experimental modeling and adaptive power control of a 750mw once-through boiler
- •I. Industrial robot
- •II. Robot types, features
- •III. Defining parameters
- •IV. End –of-arm Tooling
- •V. Controlling Movement
- •VI. Robotics
- •Функции асу тп
- •Grammar Reference Passive Voice
- •Сопоставление русских и английских времен в Passive
- •The Infinitive
- •Forms of the Infinitive
- •Functions of the Infinitive
- •2) Частью сказуемого.
- •The Complex Object
- •The Complex Subject
- •The Participle
- •The Absolute Participle Construction
- •The Gerund
- •Forms of the Gerund
- •Functions of the Gerund
- •Supplementary Texts Types of control systems
- •History of Cybernetics and Systems Science
- •The Search for New Tools
- •Industrial Robots
- •An Introduction to Artificial Intelligence
- •Applications of ai
- •Artificial intelligence
- •Open and closed – loop systems
- •Inputs and Outputs
- •Interface
- •Technological revolution in Russia
- •Асу тп сегодня
- •Microprocessor
- •External Processor Interfaces and Operation
- •Trigonometry. Units of Measurement
- •Figure 1 - a radian defined
- •Interrupts
- •Programs
- •Other microcontroller features
- •Higher integration
- •What Is a Control Engineer?
- •Специальность «Автоматизация и управление»
- •Linear versus Nonlinear Control Systems
- •Principles of Automatic Emergency Control
- •Сети следующего поколения
- •Список литературы
- •Содержание
- •Предисловие
- •History and Development of Automatic Control
- •Introduction to Control Systems
- •From the History of Automatic Control Theory
- •Управление
- •Elements and Structure of Automatic Control Systems
- •Automation
- •Business Systems
- •Comparing Feed forward and Feedback Controllers
- •Types of Feedback Control Systems
- •History of the word "cybernetics"
- •The History of Cybernetics
- •Cybernetics
- •Сфера кибернетики
- •The heritage and revival of cybernetics
- •Distributed Control System (dcs) History
- •Servomechanism, Regulator and Process Control
- •Data acquisition
- •Methodology Source
- •Signals
- •Daq hardware
- •Daq software
- •Алгоритмы функционирования технологических объектов, управляемых асутп
- •What is Artificial Intelligence?
- •Составление реферата
- •Hart-коммуникация
- •Беспроводные интерфейсы
- •The End of a Monopoly Era
- •The End of a Monopoly Era
- •Artificial Intelligence
- •Robot programming and interfaces
- •Writing a Summary
- •Experimental modeling and adaptive power control of a 750mw once-through boiler
- •I. Industrial robot
- •II. Robot types, features
- •III. Defining parameters
- •IV. End –of-arm Tooling
- •V. Controlling Movement
- •VI. Robotics
- •Функции асу тп
- •Grammar Reference Passive Voice
- •Сопоставление русских и английских времен в Passive
- •The Infinitive
- •Forms of the Infinitive
- •Functions of the Infinitive
- •2) Частью сказуемого.
- •The Complex Object
- •The Complex Subject
- •The Participle
- •The Absolute Participle Construction
- •The Gerund
- •Forms of the Gerund
- •Functions of the Gerund
- •Supplementary Texts Types of control systems
- •History of Cybernetics and Systems Science
- •The Search for New Tools
- •Industrial Robots
- •An Introduction to Artificial Intelligence
- •Applications of ai
- •Artificial intelligence
- •Open and closed – loop systems
- •Inputs and Outputs
- •Interface
- •Technological revolution in Russia
- •Асу тп сегодня
- •Microprocessor
- •External Processor Interfaces and Operation
- •Trigonometry. Units of Measurement
- •Figure 1 - a radian defined
- •Interrupts
- •Programs
- •Other microcontroller features
- •Higher integration
- •What Is a Control Engineer?
- •Специальность «Автоматизация и управление»
- •Linear versus Nonlinear Control Systems
- •Principles of Automatic Emergency Control
- •Сети следующего поколения
- •Список литературы
- •Содержание
Figure 1 - a radian defined
In line with this definition of a radian, the relationship between radians and degrees can be worked out. The full circumference of the circle (length 2π r) subtends an angle of 360° at the center of the circle. An arc of length r will subtend an angle of
Therefore 1 radian = 180/π deg, or π radians = 180°.
The actual value of a radian is 57°17'45", although this value is hardly ever required in control systems analysis.
If the base line OB in Figure remains fixed and the radius OP is allowed to rotate counterclockwise around the center O, then the angle 6 (or POB) increases. If the starting point for OP is coincident with OB, and OP rotates one complete rotation (or cycle) until it is again coincident with OB, then the angle 6 will be 360°. From this it is evident that 1 cycle = 360° = 2n radians.
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Text
A microcontroller (sometimes abbreviated µC, uC or MCU) is a small computer on a single integrated circuit containing a processor core, memory, and programmable input/output peripherals. Program memory in the form of NOR flash or OTP ROM is also often included on chip, as well as a typically small amount of RAM. Microcontrollers are designed for embedded applications, in contrast to the microprocessors used in personal computers or other general purpose applications.
Microcontrollers are used in automatically controlled products and devices, such as automobile engine control systems, implantable medical devices, remote controls, office machines, appliances, power tools, toys and other embedded systems. By reducing the size and cost compared to a design that uses a separate microprocessor, memory, and input/output devices, microcontrollers make it economical to digitally control even more devices and processes. Mixed signal microcontrollers are common, integrating analog components needed to control non-digital electronic systems.
Some microcontrollers may use four-bit words and operate at clock rate frequencies as low as 4kHz, for low power consumption (milliwatts or microwatts). They will generally have the ability to retain functionality while waiting for an event such as a button press or other interrupt; power consumption while sleeping (CPU clock and most peripherals off) may be just nanowatts, making many of them well suited for long lasting battery applications. Other microcontrollers may serve performance-critical roles, where they may need to act more like a digital signal processor (DSP), with higher clock speeds and power consumption.
Embedded design
A microcontroller can be considered a self-contained system with a processor, memory and peripherals and can be used as an embedded system. The majority of microcontrollers in use today are embedded in other machinery, such as automobiles, telephones, appliances, and peripherals for computer systems. While some embedded systems are very sophisticated, many have minimal requirements for memory and program length, with no operating system, and low software complexity. Typical input and output devices include switches, relays, solenoids, LEDs, small or custom LCD displays, radio frequency devices, and sensors for data such as temperature, humidity, light level etc. Embedded systems usually have no keyboard, screen, disks, printers, or other recognizable I/O devices of a personal computer, and may lack human interaction devices of any kind.