ME451: Control Systems - Michigan State University

64672_3ME451_L1_Introduction.pdf

Fall 20081

ME451: Control Systems

Dr. Jongeun Choi

Department of Mechanical Engineering

Michigan State University

Lecture 1

Introduction

Fall 20082

Instructor

ƒClass Instructor:Dr. Jongeun Choi,

ƒ

Website:

http://www.egr.msu.edu/~jchoi/

ƒAssociate Professor at ME department,

ƒ2459 Engineering Building,

ƒEmail: jchoi@egr.msu.edu

ƒOffice Hours

ƒ2459 EB, MW10:00-11:00am, Extra hours by

appointment

ƒLaboratory Instructor:Dr. Jongeun Choi

3

Course information

ƒLecture:

ƒWhen: MWF: 11:30am-12:20pm

ƒWhere:

008 Urban Plan & Land Arch

Bldg

ƒClass and Laboratory website:

http://www.egr.msu.edu/classes/me451/jchoi/2014/ ƒhttp://www.egr.msu.edu/classes/me451/me451_labs/Fall_201

4/index.html

ƒRequired Textbook:

ƒModern Control Systems, Richard C. Dorfand Robert H. Bishop, Prentice Hall, 12th edition, 2010, ISBN-10: 0-13-

602458-0

Fall 20084

Main components of the course

ƒ

Lectures (about 40 lectures)

ƒ

Midterm1 (October 3rd, Friday, in class)

ƒ

Midterm2

ƒ

Final (Final exam period)

ƒ

Laboratory work

ƒGrading:

ƒHomework (15%), Exam 1 (15%), Exam 2 (15%),

Final Exam (comprehensive) (30%), Laboratory work (25%) ƒHomework will be due in one week from the day it is assigned

Fall 20085

Tips to pass this course

ƒ

Come to the lectures as many times as you can.

ƒ Print out and bring lecture slides to the lecture. ƒ ƒ

Read the textbook and the slides.

ƒ ƒ

Fall 20086

ƒ

Make some object (called

system, or plant ) behave as we desire. ƒ ƒ

Room temperature control

ƒ

Car/bicycle driving

ƒ

Voice volume control

ƒ ƒ

Cruise control or speed control

ƒ

Process control

ƒ etc.

Fall 20087

ƒ

Why do we need control systems?

ƒ

Convenient (room temperature control, laundry

machine) ƒ

Dangerous (hot/cold places, space, bomb removal)

ƒ

Impossible for human (nanometer scale precision

positioning, work inside the small space that human cannot enter) ƒ It exists in nature. (human body temperature control) ƒ

Lower cost, high efficiency, etc.

ƒ

Many examples of control systems around us

Fall 20088

Open -

Loop Control

ƒ Open - loop Control System ƒ

Toaster, microwave oven, shooting a basketball

ƒ

Calibration is the key!

ƒ

Can be sensitive to disturbances

PlantController

(Actuator)

Signal Inputinputoutput

Fall 20089

Example: Toaster

ƒ

A toaster toasts bread, by setting timer.

ƒ

Objective:

make bread golden browned and crisp. ƒ

A toaster does

not measure the color of bread during the toasting process. ƒ For a fixed setting, in winter, the toast can be white and in summer, the toast can be black (Calibration!) ƒ

A toaster would be more expensive with

sensors to measure the color and actuators to adjust the timer based on the measured color.

Toaster

Setting of timer

Toasted bread

Fall 200810

Example: Laundry machine

ƒ

A laundry machine washes clothes, by setting a

program. ƒ

A laundry machine does

not measure how clean the clothes become. ƒ

Control without measuring devices (sensors) are

called open - loop control .

Machine

Program setting

Washed clothes

Fall 200811

Closed

-

Loop (Feedback) Control

ƒ

Compare actual behavior with desired behavior

ƒ

Make corrections based on the error

ƒ The sensor and the actuator are key elements of a feedback loop ƒ

Design

control algorithm Plant

Sensor

Signal InputErroroutput

+-

ActuatorController

Fall 200812

ƒ Attempts to change the direction of the automobile. ƒ

Manual closed

- loop ( feedback ) control. ƒ input and the output of the system can be different, depending on control objectives !

Ex: Automobile direction control

Auto

Steering

wheel angle

Direction

Desired

direction Eye Hand Brain Error

Fall 200813

ƒ

Attempts to maintain the speed of the automobile.

ƒ

Cruise control can be both manual and automatic.

ƒ

Note the similarity of the diagram above to the

diagram in the previous slide!

Ex: Automobile cruise control

Auto

Acceleration

Speed

Desired

speed

Sensor

Actuator

Controller

Disturbance

Error

Fall 200814

Basic elements in feedback control

systems Plant Input

Output

Reference

Sensor

Actuator

Controller

Disturbance

Control system design objective

To design a controller s.t. the output follows

even in the face of disturbances. Error

Fall 200815

Systematic controller design process

Plant Input

Output

Reference

Sensor

Actuator

Controller

Disturbance

1. Modeling

Mathematical model

2. Analysis

Controller

3. Design

4. Implemenation

Fall 200816

Goals of this course

To learn basics of feedback control systems

ƒ

Modeling

as a transfer function and a block diagram

Laplace transform (Mathematics!)

Mechanical, electrical, electromechanical systems

ƒ

Analysis

Step response, frequency response

Stability: Routh

-

Hurwitz criterion, (Nyquist criterion)

ƒ

Design

Root locus technique, frequency response technique,

PID control, lead/lag compensator

ƒ Theory, (simulation with Matlab), practice in laboratories

Fall 200817

Course roadmap

Laplace transform

Transfer function

Models for systems

mechanical electrical electromechanical

Linearization

Modeling

Analysis

Design

Time response

Transient

Steady state

Frequency response

Bode plot

Stability

Routh -

Hurwitz

(Nyquist)

Design specs

Root locus

Frequency domain

PID & Lead

- lag

Design examples

(Matlab simulations &) laboratories

Fall 200818

Summary & Exercises

ƒ

Introduction

ƒ

Examples of control systems

ƒ

Open loop and closed loop (

feedback ) control ƒ

Automatic control is a lot of fun!

ƒ Next ƒ

Laplace transform

ƒ

Exercises

ƒ

Buy the course textbook at the Bookstore.

ƒ

Read Chapter 1 and Apendix A, B of the textbook.