chapter-1.ppt Control system engineering electronics
phahamza878
5 views
41 slides
Aug 22, 2024
Slide 1 of 41
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
About This Presentation
Control system
Slide Content
Illustrations
In this chapter we describe a general process for designing a control system.
A control system consisting of interconnected components is designed to achieve a
desired purpose. To understand the purpose of a control system, it is useful to
examine examples of control systems through the course of history. These early
systems incorporated many of the same ideas of feedback that are in use today.
Modern control engineering practice includes the use of control design strategies for
improving manufacturing processes, the efficiency of energy use, advanced
automobile control, including rapid transit, among others.
We also discuss the notion of a design gap. The gap exists between the complex
physical system under investigation and the model used in the control system
synthesis.
The iterative nature of design allows us to handle the design gap effectively while
accomplishing necessary tradeoffs in complexity, performance, and cost in order to
meet the design specifications.
Chapter 1: Introduction to Control Systems
Objectives
In this chapter we describe a general process for designing a control system.
A control system consisting of interconnected components is designed to achieve a
desired purpose. To understand the purpose of a control system, it is useful to
examine examples of control systems through the course of history. These early
systems incorporated many of the same ideas of feedback that are in use today.
Modern control engineering practice includes the use of control design strategies for
improving manufacturing processes, the efficiency of energy use, advanced
automobile control, including rapid transit, among others.
We also discuss the notion of a design gap. The gap exists between the complex
physical system under investigation and the model used in the control system
synthesis.
The iterative nature of design allows us to handle the design gap effectively while
accomplishing necessary tradeoffs in complexity, performance, and cost in order to
meet the design specifications.
Chapter 1: Introduction to Control Systems
Objectives
Illustrations
Introduction
System – An interconnection of elements and devices for a desired purpose.
Control System – An interconnection of components forming a system
configuration that will provide a desired response.
Process – The device, plant, or system
under control. The input and output
relationship represents the cause-and-
effect relationship of the process.
Introduction
System – An interconnection of elements and devices for a desired purpose.
Control System – An interconnection of components forming a system
configuration that will provide a desired response.
Process – The device, plant, or system
under control. The input and output
relationship represents the cause-and-
effect relationship of the process.
Illustrations
Introduction
Multivariable Control System
Open-Loop Control Systems
utilize a controller or control
actuator to obtain the desired
response.
Closed-Loop Control
Systems utilizes feedback to
compare the actual output to
the desired output response.
Introduction
Multivariable Control System
Open-Loop Control Systems
utilize a controller or control
actuator to obtain the desired
response.
Closed-Loop Control
Systems utilizes feedback to
compare the actual output to
the desired output response.
Illustrations
History
Watt’s Flyball Governor
(18
th
century)
Greece (BC) – Float regulator mechanism
Holland (16
th
Century)– Temperature regulator
History
Watt’s Flyball Governor
(18
th
century)
Greece (BC) – Float regulator mechanism
Holland (16
th
Century)– Temperature regulator
Illustrations
History
Water-level float regulator
History
Water-level float regulator
Illustrations
History
History
Illustrations
History
18th Century James Watt’s centrifugal governor for the speed control of a steam
engine.
1920s Minorsky worked on automatic controllers for steering ships.
1930s Nyquist developed a method for analyzing the stability of controlled systems
1940s Frequency response methods made it possible to design linear closed-loop
control systems
1950s Root-locus method due to Evans was fully developed
1960s State space methods, optimal control, adaptive control and
1980s Learning controls are begun to investigated and developed.
Present and on-going research fields. Recent application of modern control theory
includes such non-engineering systems such as biological, biomedical, economic and
socio-economic systems
???????????????????????????????????
History
18th Century James Watt’s centrifugal governor for the speed control of a steam
engine.
1920s Minorsky worked on automatic controllers for steering ships.
1930s Nyquist developed a method for analyzing the stability of controlled systems
1940s Frequency response methods made it possible to design linear closed-loop
control systems
1950s Root-locus method due to Evans was fully developed
1960s State space methods, optimal control, adaptive control and
1980s Learning controls are begun to investigated and developed.
Present and on-going research fields. Recent application of modern control theory
includes such non-engineering systems such as biological, biomedical, economic and
socio-economic systems
???????????????????????????????????
Illustrations
(a) Automobile
steering control
system.
(b) The driver uses
the difference
between the actual
and the desired
direction of travel
to generate a
controlled
adjustment of the
steering wheel.
(c) Typical direction-
of-travel response.
Examples of Modern Control Systems
(a) Automobile
steering control
system.
(b) The driver uses
the difference
between the actual
and the desired
direction of travel
to generate a
controlled
adjustment of the
steering wheel.
(c) Typical direction-
of-travel response.
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
Examples of Modern Control Systems
Examples of Modern Control Systems
Illustrations
The Future of Control Systems
The Future of Control Systems
Illustrations
The Future of Control Systems
The Future of Control Systems
Illustrations
Control System Design
Control System Design
Illustrations
Illustrations
Design Example
Design Example
Illustrations
ELECTRIC SHIP CONCEPT
Ship
Service
Power
Main Power
Distribution
Propulsion
Motor
Motor
Drive
Generator
Prime
Mover
Power
Conversion
Module
Electric Drive
Reduce # of Prime
Movers
Fuel savings
Reduced maintenance
Technology
Insertion
Warfighting
Capabilities
VisionVision
IntegratedIntegrated
PowerPower
SystemSystem
AllAll
ElectricElectric
ShipShip
ElectricallyElectrically
ReconfigurableReconfigurable
ShipShip
Reduced manning
Automation
Eliminate auxiliary
systems (steam,
hydraulics, compressed
air)
Increasing Affordability and Military Capability
Design Example
ELECTRIC SHIP CONCEPT
Ship
Service
Power
Main Power
Distribution
Propulsion
Motor
Motor
Drive
Generator
Prime
Mover
Power
Conversion
Module
Electric Drive
Reduce # of Prime
Movers
Fuel savings
Reduced maintenance
Technology
Insertion
Warfighting
Capabilities
VisionVision
IntegratedIntegrated
PowerPower
SystemSystem
AllAll
ElectricElectric
ShipShip
ElectricallyElectrically
ReconfigurableReconfigurable
ShipShip
Reduced manning
Automation
Eliminate auxiliary
systems (steam,
hydraulics, compressed
air)
Increasing Affordability and Military Capability
Design Example
Illustrations
CVN(X) FUTURE AIRCRAFT CARRIER
Design Example
CVN(X) FUTURE AIRCRAFT CARRIER
Design Example
Illustrations
Design Example
EMALS
Design Example
EMALS
Illustrations
Design Example
Design Example
Illustrations
Design Example
Design Example
Illustrations
Design Example
Design Example
Illustrations
Design Example
Design Example
Illustrations
Illustrations
Illustrations
Design Example
Design Example
Illustrations
Design Example
Design Example
Illustrations
Sequential Design Example
Sequential Design Example
Illustrations
Illustrations
Sequential Design Example
Sequential Design Example
Illustrations
Illustrations
Illustrations
Mistakes
Challenger
Tacoma Bridge
Mistakes
Challenger
Tacoma Bridge
Illustrations
References, and Resources
http://www.ieeecss.org/siteindex/SITEindex.html
http://www-control.eng.cam.ac.uk/extras/Virtual_Library/Control_VL.html
References, and Resources
http://www.ieeecss.org/siteindex/SITEindex.html
http://www-control.eng.cam.ac.uk/extras/Virtual_Library/Control_VL.html
Illustrations
Exercises and Problems
Exercises and Problems
Illustrations
Exercises and Problems
Exercises and Problems
Tags
Categories
ScienceDownload
Download Slideshow Get the original presentation fileQuick Actions
Statistics
- Views 5
- Slides 41
- Age 466 days
Related Slideshows
23
Earthquakes_Type of Faults_Science G8.pptx
OctabellFabila1
31 views
15
Quiz #1 Science 10 in the first quarter for jhs
HendrixAntonniAmante
30 views
9
Astronomy history from long ago till doday
ssuserbd9abe
29 views
9
Great history of astronomy from long ago till today
ssuserbd9abe
27 views
20
EARTHQUAKE-DRILL.powerpoint.............
chalobrido8
30 views
9
History of astronomy from old times to the present times
ssuserbd9abe
30 views