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98
1, 2
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SERVICE STUDY (1) (2)
E117910 E117920
1 2 3
0
62101
Office Hours
:
0
98
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SERVICE STUDY (3)
E117930
1 2 3
0
62101
Office Hours
:
0
(18)
98
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ENGINEERING GRAPHICS (1)
E110210
1
1
,
62170, 6215915
Office Hours
1400-17001400-1700
1*
2,,
3
4
5
1
2CNS
3
4http://www.edrawing.org.
(a) (b) 10%(c) 20% (d)(e)
3014~6
98
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ENGINEERING GRAPHICS (1)
E110620
1
1
,
62170, 6215915
Office Hours
Chapter 6
*
* *
*
*
*
* *
* *
*
Chapter 7
**
**
*
*
*
ProE
3/31~4/24/5
Chapter 8
*
*
Chapter 9
***
***
*
AUTOCAD
1.AUTOCAD2.WINDOW3.4. 5.6. 7.
1.NEW 2.OPEN 3.SAVE/QSAVE/SAVE AS
1.HELP 2.PROTOTYPE 3.LIMITS 4.UNITS 5.SNAP 6.GRID 7.ORTHO 8. 9. 10.VIEWWRS 11.DRAG MODE
1.OINT 2.LINE 3.CORCLE 4.ARC 5.POLYGON 6.SOLID 7.FILL 8.ELLIPSE 9.RECTANG 10.TEXT 11.IMPORT TEXT
1.ERASE 2.OOPS 3.MOVE 4.PAN 5.COPY 6.U 7.REDO 8.UNDO 9.EXTEND 10.ARRAY 11.BREAK 12.FILLET 13.CHAMFER 14.MIRROR 15.ROTATE 16.MEASURE17.GRIP
1.LIST 2.ID 3.DIST 4.AREA 5.LINETYPE 6.LAYER 7.COLOR 8.
AUTOCAD
1
2http://www.edrawing.org.
3
(a) (b) 5%
(c) 20% (d)
(e)
98
1
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APPLIED MECHANICS(1)
E111110
3
62164
Office Hours
Force Vectors
3
Equilibrium of a Particle
3
Force System Resultants
6
Equilibrium of a Rigid Body
9
Structure Analysis
6
Internal Forces
6
Friction
6
Center of Gravity and Centroid
3
Moments of Inertia
3
Virtual Work
6
R. C. Hibbeler, Engineering Mechanics Statics, 12th Edition, Prentice Hall, Inc., New Jersey, USA, 2009.
20%
225%
30%
98
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APPLIED MECHANICS(1)
1 2 3
3
,,
Office Hours
1.Kinematics of a particle and a system of particles, including introduction and applications of rectangular components, normal and tangential components, and cylindrical components.
2.Kinetics of particle and a system of particles, analyzed by methods of forces and acceleration, work and energy, and impulse and momentum.
3.Planar kinematics of a rigid body, including introduction and applications of inertia reference frame, translational reference frame, and rotational reference frame.
4.Planar kinetics of a rigid body, analyzed by methods of forces and acceleration, work and energy, and impulse and momentum.
5.Three-dimensional kinematics of a rigid body.
6.Vibrations with one degree of freedom.
R. C. Hibbeler, Engineering Mechanics: Dynamics-An Adapted Version, 12th edition, Prentice Hall, Inc., New Jersey, USA, 2009.
: 25% 2: 30% : 20%
:
Quiz #120 pointsQuiz #2 20 pointsQuiz #3 20 points
: 40 points
: 0 points (, )
100 points
98
2
INTRODUTION TO COMPUTERS
E113000
3
62126
Office Hours
C
1.
2.
3.
4.
5.
6.
7.
8.
C
1.Microsoft Visual Studio
2.
3.
4.
5.
6.
7.
8.
9.
1.()2.Ivor Hortons C++1998()
86C3
24%36%40%-1/-0.5/1/+3
http://vr.me.ncku.edu.tw/courses/index-bcc.htm
http://vr.me.ncku.edu.tw/courses/index-bcc.htm
CA
98
2
INTRODUTION TO COMPUTERS
E113000
2
3
62149
Office Hours
C
1. (History)
2. (Hardware &
Software)
3. (Operating Systems)
C
1.Microsoft Visual C++ 6.0
2. (Input & Output)
3. (Data Types)
4. (Conditions)
5. (Loops)
6. (Pointers)
7. (Arrays)
8. (Strings)
9. (Functions)
Matlab
1.
2.
3.
4.
1. , Matlab 7 by Palm, 2005,
2. Ivor Hortons
C++2005
10%
25%
25%
40%
iTeach
98
2
INTRODUTION TO COMPUTERS
E113000
3
3
06-2757575 ext 62181
Office Hours
C
1. (History)
2. (Hardware & Software)
3. (Excel)
4. (PowerPoint)
5. (Internet)
C
1.Microsoft Visual Studio C++
2. (Input & Output)
3. (Data Types)
4. (Conditions)
5. (Loops)
6. (Pointers)
7. (Arrays)
8. (Strings)
9. (Functions)
Ivor Hortons C++1998
98
1
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ENGINEERING MATHEMATICS (1)
E112110
3
(06)2757575ext.62184
Office Hours
()Fourier
()(Green
98
1
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ENGINEERING MATHEMATICS (1)
E112110
2
3
62137
Office Hours
1.O.D.E
2.Matrix
3.Vector Calculus
Chapter 1
(A). (B). (C).
(D).
Chapter 2
(A). (B). (C). (D).
Chapter 3
(A). (B). Green (C).
(D).
Advanced Engineering Mathematics, 6th ed., Peter V. O`Neil.
(1)
1. 2.5/ x 820
2. 4/ x 416
3. 20/ x 240
4. 24 x 124
100
http://myweb.ncku.edu.tw/~n1894127/web/b_mainpage.htm
Email:[email protected]
98
1
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ENGINEERING MATHEMATICS (1)
E112110
3
3
Office Hours
: 1. 2. 3. 4.
: 1. 2.() 3. 4.() 5. 6.ODE
20
: 1. 2.
: 1. 2. 3.n 4.n,, 5. 6. 7. 8. 9.
14
: 1. 2. 3. 4. 5.
,, : 1. 2. 3. 4. 5.
: 1. 2. 3. 4. 5. 6. 7. 8.Stoke's 9.
14
Textbook: Zill, D. G. and Cullen, M. R., Advanced Engineering Mathematics
, 3rd ed., Jones and Bartlett Publishers (2006).
Useful reference: Spiegel, M. R. & Liu, J., Mathematical Handbook of
Formulas and Tables, 2nd ed., Schaums Outline Series, McGrawHill (1999).
(subject to adjustments)
Three exams ~ 85%
Quizzes (approx. once every other week) and projects/homeworks ~ 25%
Course FTP site: IP 140.116.155.111, port 21; username/password: em
98
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ENGINEERING MATHEMATICS(2)
1
()
3
62137
Office Hours
1. Matrix and Linear Algebra
(Eigen Value, Decoupled Modes, Cayley-Hamilton and Sylvester Theorem)
2. Vector Calculus
(Differential, Integral,: Green Theorem, Gauss Theorem and Stokes Theorem)
3. Fourier Series, Integral and Transform
(F.S., F.I. and F.T. )
4. PDE (Optional)
As same as that used by in Fall, 2009.
1. Homework 2.5 % x 8 = 20
2. Quiz : 4 % x 4 = 16
3. Mid-term Exam: 20 % x 2 =40
4. Final Exam: 24 %
98
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ENGINEERING MATHEMATICS(2)
2
()
3
62241
Office Hours
4-6pm
(1) Laplace Transform
(2) Series Solutions
(3) Approximate Solutions (Quiz 1)
(4) Fourier Analysis and Orthogonal Expansions
Fourier Series
Fourier Integral and Fourier transform (Quiz 2)
Special Function and Orthogonal Expansions
(5) Partial Differential Equations
The Wave Equation (Quiz 3)
The Heat Equation
The Potential Equation
P.V. ONeil, Advanced Engineering Mathematics, Thomson
Academic Honest:
(in your own words)()
Home works, Quiz, Comprehensive Final
98
2
()
Engineering Mathematics II
E1121203
3
()
3
62164
Office Hours
This is the second semester course of the Engineering Mathematics. The course material will include (1) the Laplace Transform and Series Solutions of Linear Differential Equations, (2) Orthogonal Functions and Fourier Series, Fourier Integral, and Fourier Transforms, (3) Solutions of Partial differential equations and (4) Integral Transform Method.
The theory and applications of ordinary and partial differential equations
1 The Laplace Transform (Chapter 4)
1.1 Definition of Laplace transform
1.2 Transforms of derivatives
1.3 Translation theorems
1.4 Transform of a periodic function
1.5 The direct delta function
1.6 Convolution theorem
1.7 Inverse transforms
1.8 Applications of the Laplace transform
2 Series Solutions of Linear Differential Equations (Chapter 5)
2.1 Review of power series
2.2 Solutions about ordinary points
2.3 Solutions about singular points
2.4 Bessel equation and Bessel functions
2.5 Legendre functions
3 Orthogonal Functions and Fourier Series, Fourier Integral, and Fourier Transforms (Chapters 12)
3.1 Orthogonal functions
3.2 Fourier series
3.3 Fourier cosine and sine series
3.4 Complex Fourier series
3.5 Sturm-Liouville problems
3.6 Bessel and Legendre Series
4 Boundaryvalue problems in Rectangular Coordinate(Chapter 13)
4.1 Classic equations and boundary value problems
4.2 Wave equation
4.3 Heat equation
4.4 Laplaces equation
4.5 Nonhomogeneous boundary value problems
4.6 Orthogonal series expansions
5 Boundaryvalue problems in Other Coordinate Systems(Chapter 14)
5.1 Problems in Polar Coordinates
5.2 Problems in Cylindrical Coordinates
5.3 Problems in Spherical Coordinates
6 Integral Transform Method(Chapter 15)
6.1 Fourier integral
6.2 Fourier transforms
6.3 Applications of the Laplace transform
6.4 Applications of the Fourier transform
D.G. Zill and M. R.Cullen, Advanced Engineering Mathematics, 3rd Ed., Jones and Bartlett Publishers, 2006.
Midterm Exams 1 and 2: 25% each, Final Exam: 25%, Homework and Class Quiz: 25%
98
1
)
MECHANICAL ENGINEERING DRAWING
E120600
1 3
()
2
Office Hours
(a)/
(b)/
(c)
(d)
(e)
(d)
(e)
(a)
(b)
(c)
(a)
(b)
(c)
(d)
(e)
(a)
(b)
(c)
,,CNS,2004
30%
/40%
30%
98
1
MECHANICAL ENGINEERING DRAWING
E120600
2
()
2
Office Hours
, , , . , ?, .
1.
6
2.
8
3.
8
4.
8
5.
8
6.
8
7.
8
8.
8
9.
8
, CNS ,
+ 60% 40%
98
1
()
THERMODYNAMICS (1)
E121410
1
2
X 62110
Office Hours
4
4
6
6
6
(C.V.)
6
Fundamentals of Thermodynamics, 6th edition, John Wiley & Sons, Inc, 2003
2 Quizs 20%
2 Mid-term Exams 40%
1 Final Exam 30%
Attendance/Participation 10%
www.me.ncku.edu.tw/~wenhtlab
98
1
()
THERMODYNAMICS (1)
E121410
1
2
(06)2757575-62241
Office Hours
1:30-3:30pm
(1) Introduction and Basic Concepts
(2) Energy, Energy Transfer, and General Energy Analysis
(3) Properties of Pure Substances
(4) Energy Analysis of Closed Systems
(5) Mass and Energy Analysis of Control Volumes
(6) The Second Law of Thermodynamics
(7) (Entropy)
Y.A. Cengel, M.A. Boles, Thermodynamics: An Engineering Approach 6th ed., McGraw Hill.
NCKU iteach (iteach.ncku.edu.tw).
3 Quizzes
1 Comprehensive Final
5 Homeworks
Academic Honest:
(in your own words)()
98
1
()
THERMODYNAMICS (1)
E121410
3
2
(06) 2757575~62172
Office Hours
entropy
1.
2.
3.
4.
Chapter 1 Basic concepts of Thermodynamics
Chapter 2 Properties of pure substances
Chapter 3 Energy transfer by heat , work and mass
Chapter 4 The first law of Thermodynamics
Chapter 5 The second law of Thermodynamics
Thermodynamics, Cengel&Boles, Fifth Edition in SI Units
1.
2.
3.office hour
4.
1.(10%)
2.(15%)
3.(75%)
98
2
()
THERMODYNAMICS (2)
E121220
1
()
3
X 62110
Office Hours
1.
2.
3.
4.
5.
Fundamentals of Thermodynamics, 6th edition, John Wiley & Sons, Inc, 2003
1 15%
2 40%
135%
10%
www.me.ncku.edu.tw/~wenhtlab
98
2
()
THERMODYNAMICS (2)
E121220
2
()
3
62151
Office Hours
1.
2. (entropy)
3.
4.
5.
Thermodynamics An
Engineering Approach, Y.A.
Cengel and M.A. Boles, Sixth
Edition.
2 25%30%
4 5%
98
2
()
Thermodynamics (2)
E121220
3
()
3
(06) 2757575~62172
Office Hours
entropy-
1.
2.
3.
4.
Chapter 6 The second law of Thermodynamics
Chapter 7 Entropy
Chapter 9 Gas power cycles
Chapter 10 Vapor and combined power cycles
Chapter 11 Refrigeration cycles
Chapter 12 Thermodynamic property relations
Chapter 13 Gas mixtures
Chapter 14 Gas-vapor mixtures and air-conditioning
Thermodynamics, Cengel&Boles, Sixth Edition in SI Units
1.
2.
3.office hour
4.
1.(10%)
2.(15%)
3.(75%)
98
1
()
MECHANICS OF MATERIALS (1)
E121510
1
()
3
Office Hours
Stress
6
Strain
6
-
6
(Axial Load)
6
(Torsion)
6
(Bending)
-
6
(Transverse Shear)
6
6
R. C. Hibbeler, "Mechanics of Materials", 6th edition. Prentice Hall. Inc., New Jersey, USA, 2004.
25%
50%
25%
98
1
()
()
Mechanics of Materials
E121510-2
()
3
62143
Office Hours
1.
2.
1.
2.
3.
4. (Mohrs circle)
5.
6.
7.
8.
9. (Buckling)
10.
R. C. Hibbeler, Mechanics of Materials, SI edition, Prentice Hall, Inc., Singapore 2003
10%
55%
35%
98
1
()
MECHANICS OF MATERIALS (1)
E121510
3
()
3
Office Hours
1.
2.
3.
4.
5.
6.
7.
8.
98
2
()
MECHANICS OF MATERIALS (2)
E121520
1
()
3
Office Hours
Chapter 1 Pressure Vessels and Combined Loadings (Chapters 5, 6, 7)
1.1Thin-walled pressure vessels (Chapter 5-8)
1.2Thick-walled cylindrical pressure vessels (Chapter 5-10)
1.3Axial and pressure loads (Chapter 5-9)
1.4Axial, torsional, and pressure vessels (Chapter 6-8)
1.5Axial, pressure, flexural, and torsional (Chapter 7-16)
Chapter 2 Analyzing Columns (Chapter 9)
2.1 Introduction
2.2 Buckling of load, straight columns
2.3 Effects of different idealized end conditions
2.4 Eccentrically loaded columns
2.5 Beam-columns*
2.6 Alternative differential equations for beam-columns*
Mid-term
Chapter 3 Energy Methods (Chapter 10)
3.1 Strain energy (Chapter 10-2)
3.2 Elastic strain energy for various loads (Chapter 10-3)
3.3 Impact loading (Chapter 10-4)
3.3 Castiglianos Theorems (Chapter 8-8)
3.4 Applications to axial problems*
3.5 Application to torsional problems*
3.6 Application to beam problems (Chapter 8-8)
Chapter 4 Failure Theories (Chapter 10 Part B)
4.1 Introduction
4.2 Failure theories for ductile materials
4.3 Failure theories for brittle materials
Chapter 5 Inelastic Analysis
5.1 Idealized strain-stress diagrams
5.2 Axially loaded members (Chapter 5-7)
5.3 Torsional members (Chapter 6-10)
5.4 Flexural members (Chapter 7-11)
W. Riley, L. Sturges, and D. Morris Mechanics of Materials 6th ed., John Wiley & Sons, 2007
* Supplement from other textbooks
98
2
()
MECHANICS OF MATERIALS (2)
E121520
2
()
3
06-2757575 ext 62181
Office Hours
()()Failure
1.
2.
3.
4.
5.
W. Riley, L. Sturges and D. Morris, Mechanics of Materials, 6th edition, John Wiley & Sons, Inc., 2007.
98
1
()
MECHANISM (1)
E123010
1 2 3
() ()
2
62156 62190 62274
Office Hours
:
:
:
:
:
()
Cleghorn, W. L., 2005, Mechanics of Machines, Oxford University Press Inc., New York, USA.
http://myweb.ncku.edu.tw/~stchiou/mechanisms/
http://www.me.ncku.edu.tw/~mechanism/mechanisms/
http://csdl.me.ncku.edu.tw/mechanisms/
(:2757575-62246)
98
2
()
MECHANISM (2)
E123020
1 2 3
()
2
, ,
62156, 62274,
Office Hours
1.
2.
3.
4.
5.
Cams
1st Middle-Term Exam.
Gears
Gear Trains (I)
2nd Middle-Term Exam.
Gear Trains (II)
Synthesis of Mechanisms
Final-Term Exam.
Cleghorn, W. L., 2005, Mechanics of Machines, Oxford University Press Inc., New York, USA.
http://myweb.ncku.edu.tw/~stchiou/mechanisms/
http://www.me.ncku.edu.tw/~mechanism/mechanisms/
http://csdl.me.ncku.edu.tw/mechanisms/
98
1
MATERIALS FOR MECHANICAL ENGINEERING
E123100
1
3
Office Hours
,
3
,
3
6
,
,
6
1
,-,,
6
2
,,,
6
,,
6
,,
6
William F.Smith, Foundations of materails science and engineering 3rd, 2002
/:25%
:25%
:25%
:25%
98
1
MATERIALS FOR MECHANICAL ENGINEERING
E123100
2
3
62111
Office Hours
Introduction
Historical perspective
Material science and engineering
Classifications of materials
Advanced materials
Modern material needs
3
Atomic Structure & Atomic Bonding in Solids
Fundamental concepts
Two atomic models and the differences
Periodic Table
Interatomic bonding force and energy
Primary and secondary bonding
5
Structures of Metals and Ceramics
Fundamental concepts
Unit cells
Crystal system and structure
Density calculation
Crystallography, linear/planar density
Silicate ceramic and carbon
Amorphous and crystalline material
Isotropic and anisotropic property
6
Polymer Structures
Hydrocarbon and polymer molecules
Molecular weight and distribution
Molecular shape, structure, configuration
Thermoplastics and thermosetting
Copolymer and crystallinity
Polymer crystal
4
Imperfections in Solids: Defects, dislocations, G.B. etc
Point defects and impurity
Composition conversion
Linear defects- dislocation
Interfacial defects
Bulk defects and atomic vibration
Grain size determination
5
Diffusion
Diffusion mechanism
Steady state diffusion
Non-steady state diffusion
Factors influencing diffusion
Other diffusion paths
Diffusion in ceramics and polymers
3
Mechanical Properties: metals, ceramics and polymers
Stress and strain concept
Elastic deformation and elasticity
Tensile test and true stress-strain
Mechanical properties in metals
Mechanical properties in ceramics
Mechanical properties in polymers
Hardness and other properties
Property variation and design factors
6
Deformation and Strengthening Mechanisms: metals, ceramics and polymers
Plastic deformation
Deformation mechanisms for metals
Strengthening mechanism in metals
Recovery, recrystallization and grain growth
Deformation mechanisms for ceramics
Deformation mechanisms for polymers
6
Failure: Fracture, Fatigue and Creep
Crack initiation and propagation
Ductile and brittle fracture
Fracture mechanism
Impact fracture testing
Fatigue and cyclic stress
Factors affecting fatigue life
Creep behavior in metals
Stress and temperature effects
Creep in ceramic and polymers
5
Phase Diagrams
Phase and solubility limits
Microstructure and phase equilibrium
Equilibrium phase diagrams
Lever rule
Eutetic, eutectoid and peritectic reaction
Ternary phase diagrams
Binary Iron-Carbon system
Microstructures in Fe-C alloys
Influence of other alloying elements
6
Phase Transformations
Kinetics of phase transformation
Metastable vs. equilibrium states
Phase transformation in metals
Microstructure and properties changes in Fe-C alloy
Isothermal and continuous transformation
Martensite transformation
Heat treatment
Precipitation hardening
Melting and glass transition 5
W.D. Callister, Jr., Fundamentals of Materials Science and Engineering, John Wiley & Sons, Inc., v.2, 2005,
()30%
()40%
30%
98
1
Materials for Mechanical Engineering
E123100
3
3
62174
Office Hours
(Introduction)
4
(Atomic structure and interatomic bonding)
6
(The structure of crystalline solids)
7
(Imperfections in solids)
6
(Dislocations and strengthening mechanisms)
6
(Phase diagrams)
7
(Heat treatment of metal alloys)
6
(Mechanical properties of materials)
6
1.
2. William D. Callister, Jr., Fundamentals of Materials Science and EngineeringAn Introduction, 5th edition, John Wiley & Sons, Inc., New York, USA, 2000. ()
3035
()
98
1
()
MACHINE SHOP PRACTICE (I)
E124110
1A 1B 2A 2B 3A 3B
1
06-275-7575 ext.62156
Office Hours
()()NC()()()()
3
1 2
0.5 2.5
NC
1 2
1 2
1 2
1 2
http://www.me.ncku.edu.tw/~workshop
()
98
2
()
MACHINE SHOP PRACTICE (2)
E124120
1A 1B 2A 2B 3A 3B
1
Office Hours
() ()
() ()
()
. ()()
.
.
.
.
http://www.me.ncku.edu.tw/~workshop
98
2
ELECTRICAL ENGINEERING
E120100
1
2
Office Hours
(Kirchhoffs circuit laws)
(1)
(2)
(3)
(4)RCRL
(5)RLCv
(6)
Electrical Engineering (principles and applications),4th edition, Allan R. Hambley
: 0 %
: 30%
: 30%
: 40 %
98
2
ELECTRICAL ENGINEERING
E120100
2
2
62189
Office Hours
(Kirchhoffs circuit laws)
Chap 1 Introduction to Electrical Engineering (1 week)
Chap 2 Fundamentals of Electric Circuits (2 weeks)
Chap 3 Resistive Network Analysis (4 weeks)
Chap 4 AC Network Analysis (3 weeks)
Chap 5 Transient Analysis (2 weeks)
Chap 6 Frequency Response and System Concepts (2 weeks)
Chap 7 AC Power (3 weeks)
Principles and Applications of Electrical Engineering, Fifth Edition, McGraw Hill 2007
Author: G.iorgio Rizzoni
Midterm Exam. 1: 25%
Midterm Exam. 2: 25%
Final Exam.: 25%
Homework: 15%
Quiz: 10%
98
2
ELECTRICAL ENGINEERING
E120100
3
2
06-2757575ext62274
Office Hours
(Kirchhoffs circuit laws)
(1)
(2)
(3)
(4)RCRL
(5)RLCv
(6)
Electrical Engineering (principles and applications),4th edition, Allan R. Hambley
http://myweb.ncku.edu.tw/~cclan/EE2010S/
98
2
MANUFACTURING PROCESSES
E120200
1
3
62183
Office Hours
.
1
2
3
4
5
6
7
8
9
10
11
12
13 -
14
15 -
16
17
18
19
S. Kalpakjian, Manufacturing
Processes for Engineering
Materials, 5/ed., Addison
Wesley Longman, 2008.
10%(4 )
30%
98
2
MANUFACTURING PROCESSES
E120200
2
3
06-2757575-62147
Office Hours
1.
2.
3.
4.
5.
6.
7.
8.
S. Kalpakjian and S.R. Schmid, Manufacturing Processes for Engineering Materials, 5th/ed., Pearson Education/Prentice Hall ,2008, ISBN 0-10 981-06-7953-X
20%50%()30%
98
2
MANUFACTURING PROCESSES
E120200
3
3
62189
Office Hours
()
Chap 1 Introduction
Chap 2 Fundamentals of the Mechanical Behaviors of Materials (2 weeks)
Chap 3 Structure and Manufacturing Properties of Metals (2 weeks)
Chap 4 Surfaces, Tribology, Dimensional Characteristics, Inspection, and Product Quality Assurance (2 weeks)
Chap 5 Metal Casting Processes and Equipment; Heat Treatment (2 weeks)
Chap 6 Bulk Deformation Processes (2 weeks)
Chap 7 Sheet-Metal Forming Processes (2 weeks)
Chap 8 Material-Removal Processes (I): Cutting Process (2 weeks)
Chap 9 Metal Removal Processes (II): Abrasive, Chemical, Electrical and High-Energy Beams (1 week)
Chap 10, 11 Overview on Properties and Processing of Polymers, Metals Powders, Ceramics, Glasses, Composites and Semiconductors. (1 week)
Chap 12 Fabrication of Microelectronics and Micromechanical Devices (1 week)
Manufacturing Processes for Engineering Materials, Fifth Edition, 2008
Authors: S. Kalpakjian and S. Schmid. (Prentice Hall Publishing)
Midterm Exam. 1: 25%
Midterm Exam. 2: 25%
Final Exam.: 25%
Quiz: 10%
Homework: 15%
98
2
Computer Program Design
E120500
3
62126
Office Hours
CC++
1.C
2.
3.
4.
5.
6.
7.
8.
9.
10.
Ivor Hortons C++1998
104
40%60%+3
http://vr.me.ncku.edu.tw/courses/index-pd.htm
http://vr.me.ncku.edu.tw/courses/index-pd.htm
()
98
1
(
()
MACHINE DESIGN(1)
E120310
1
() ()
3
06-2757575-62161
Office Hours
By appointment
Teach students about basic mechanical system design concepts and theories.
1. Introduction
2. Force Analysis
3. Material Study
4. Statics Body Stress
5. Strain, Deflection, and Buckling
6. Failure Theory, Safety Factor, and Reliability
7. Impact Loading
8. Fatigue Loading
9. Surface Damage
Robert C. Juvinall & Kurt M. Marshek, Fundamentals of Machine Component Design, Fourth Edition, Wiley International Edition, John Wiley & Sons, Inc.
Home work for every chapter 50%
2 midterm @15%
1 final exam 20%
98
1
(
()
MACHINE DESIGN(1)
E120310
2
() ()
3
06-2757575 ext.62149
Office Hours
10:00am - noon, Wednesdays, or by appointments
Provide concepts, procedures, and decision analyses that are essential in designing mechanical components.
Students are expected to analyze individual element as well as the interfaces between elements as they work together to form a system.
- Introduce the concept of mechanical design and provide examples (Chap. 1)
- Review force analysis ( Chap. 2)
- Describe mechanical properties of various materials (Chap. 3)
- Perform stress-strain analysis and provide case studies (Chap. 4 and 5)
- Introduce failure theory and reliability (Chap. 6)
- Perform impact analysis (Chap. 7)
- Explain various fatigue-failure models (Chap. 8)
- Demonstrate various surface failure mechanisms(Chap. 9)
- Class review and case study presentations
Fundamentals of Machine Component Design 4th ed. by Robert C. Juvinall, John Wiley & Sons Inc., ( NCKU Bookstore : 06-274-4622 )
Homework and Project:
Five homework sets will be assigned prior to midterm and final exams. These homework sets are based on course materials and discussions from class. In addition, teams of three people are formed to complete a design project. Detail description of the project will be provided in class. All members in the team are required to work on their specific part and then putting components together. Upon the completion of the project, randomly selected team will be asked to present their concepts at the end of the semester.
Homework1 12% (3% each)
Attendance and Participation 10%
Team Project 28% (1%, 5%, 3%, 5%, 2%, 12%)
Midterm Exam #1 15%
Midterm Exam #2 15%
Final Exam 20%
98
1
(
()
MACHINE DESIGN(1)
E120310
3
() ()
3
06-2757575-62125
Office Hours
By appointment
Teach students about basic mechanical system design concepts and theories.
1. Introduction
2. Force Analysis
3. Material Study
4. Statics Body Stress
5. Strain, Deflection, and Buckling
6. Failure Theory, Safety Factor, and Reliability
7. Impact Loading
8. Fatigue Loading
9. Surface Damage
Robert C. Juvinall & Kurt M. Marshek, Fundamentals of Machine Component Design, Fourth Edition, Wiley International Edition, John Wiley & Sons, Inc.
Homework and quiz 27%
2 Midterm 23%
1 Final exam 27%
()
98
2
()
MACHINE DESIGH (2)
E120320
1 2 3
()
3
, ,
Office Hours
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
Juvinall and Marshek 2006, Fundamentals of Machine Component Design, Fourth Edition, John Wiley & Sons, Inc.
- (x2) + (x1)
- 25 x 3%
- (x? ) - 5%/
- (
) - 20%
- + 10 %
Term Project 40%
Attendance and Participation 10%
Midterm Exam #1 15%
Midterm Exam #2 15%
Final Exam 20%
: 27%
(2) : 46%
(1) : 27%
Webpage: http://140.116.165.74/qry/
iTeach
98
1
Fluid Mechanics
E131101
1
4
(06)2757575 x62241
Office Hours
1:30-3:30 pm
(1) Basic properties of fluids
(2) Pressures and its effects
(3) The Bernoulli equation
(4) Kinematics of fluid motion
(5) Control volume analysis
(6) Flow analysis using Differential methods
(7) Dimensional analysis, modeling, and similitude
(8) Internal flow
(9) External flow
(10) Flow machinery
B.R. Munson, D.F. Young,T .H. Okiishi and W.W. Huebsch, Fundamentals of Fluid Mechanics 6th ed.,
Wiley.
NCKU iteach (iteach.ncku.edu.tw).
Academic Honest and Rules:
(in your own words)(Quiz and Exam)
1. 3 Quizes
2. 1 Comprehensive Final
3. 5 Homeworks
4. 6 Team lab reports
98
1
FLUID MECHANICS
E131101
2
4
ext. 62125
Office Hours
1.Fluids and fluid properties
2.Fluid statics
3.Fluid kinematics
4.Flow analysis using control volumes
5.Bernoulli equation
6.Flow analysis using differential approach
7.Dimensional analysis and similitude
8.Viscous flow in ducts
9.External flow pass bodies
B. R. Munson, D. F. Young, T. H. Okiishi, W. W. Huebach, Fundamentals of Fluid Mechanics, 6th ed, Wiley, New York (2006).
Will be mentioned in the class if necessary
1.Homework : 20%
(Cooperation allowed but need to write down your own answers; Do not copy from a common source.)
2.Mid-term I (1.5 hours): 25%
3.Mid-term II (1.5 hours): 25%
4.Final Exam. (1.5 hours) : 30%
Plus
Two bonus Quizzes, 10 extra final points each; problems from homework, textbook examples, and notes.
98
1
FLUID MECHANICS
E131101
3
4
Office Hours
( )
3
3 1 2
3
3
3 1 2
Pi
3
3 1 2
3 1 2
Munson, Bruce R., Young, Donald F. and Okiishi, Theodore H., Fundamentals of Fluid Mechanics, 5th edition, John Wiley & Sons, 2006.
75%
10%
15%
()
98
2
()
EXPERIMENTS IN MECHANICAL ENGINEERING (1)
E134110
1A 1B 2A 2B 3A 3B
1
,,
Office Hours
()
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
(11)
(12)
(13)
(14)
()
(1)
(2)
(3)
(4)
(5)
(6)
(7)
(8)
(9)
(10)
1. 35%
2. 30%
3. 35%
()
98
1
()
EXPERIMENTS IN MECHANICAL ENGINEERING (2)
E134120
1A 1B 2A 2B 3A 3B
1
,,,
Office Hours
()
(1)(2)(3)(4)(5)(6)(7)(8)(9)(10)(11)(12)(13)(14)
()
(1)(2)(3)(4)(5)(6)(7)(8)(9)(10)
1. 35%
2. 30%
3. 35%
()
98
2
()
Mechanical experiment(3)
E134130
1A 1B 2A 2B
1
62146
Office Hours
1.
2.
3.
:
:
:
:
:
:
:
:
60%30%10%
98
2
()
Mechanical experiment(3)
E134130
2A 2B
1
Office Hours
1.
2.
3.
4.
5.
6.
7.
8.
98
2
()
EXPERIMENTS IN MECHANICAL ENGINEERING (3)
E134130
3A 3B
1
Office Hours
(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)
1.
35%
2. 30%
3. 35%
98
1
ELECTRONICS
E134500
1
2
Office Hours
1. (2 Hours)
2. (2)
3. (4)
4. (4)
5. (6)
6. (6)
7. (6)
8. (4)
Electronic Principles, 7th Edition, Albert Malvino & David Bates,
McGraw-Hill, 2007.
25%
25%
25%
10%
15%
98
1
ELECTRONICS
E134500
1
2
62247
Office Hours
,,,.,,.
1)
2)
3)
4)
1) Semiconductor materials and diodes.
2) Diode circuits.
3) The bipolar junction transistor. 4) Basic BJT amplifier.
5) The field-effect transistor
6) Basic FET amplifier
7) The operational amplifier
8) Digital electronics
A. Malvino, Electronic Principles, McGRAW-HILL
2 midterms (30%+30%), 1 final (40%)
98
1
ELECTRONICS
E134500
3
2
Office Hours
(1)(2)(3)(4)(5)(6)(7)(8) (1) (2)P-N()(Clipper&Limiter) (3) (4)() (5)
A.P. Malvino, Electronic Principles, McGRAW-HILL
: 20 %
: 25%
: 25%
: 30 %
98
1
AUTOMATIC CONTROL
E137100
1
()
3
Office Hours
1.Introduction to Control System
2.Mathematical Models of systems
3.Feedback Control System Characteristics
4.Performance of Feedback Control System
5.The Stability of Linear Feedback System
6.The Root-Locus Method
7.Frequency Response Methods
8.Stability in the Frequency Domain
9.Time Domain Analysis of Control System
10.The Design and Compensation of Feedback Control Systems
11.Digital Control System
98
1
AUTOMATIC CONTROL
E137100
2
()
3
06-2757575-62152
Office Hours
1.
1
2.
2
3.
3
4.
4
5.
5
6.
6
7.
7
8.
8
9.
9
10.
10
11.
11
Matlab 5
13
Modern control systems, Richard C. Dorf, Robert H. Bishop 10th ed, 2005. Reference book: Linear Control Systems Engineering, Morris Driels, McGraw Hill 1995.
--25%
10%
--20%
--25%
http://rjchang.me.ncku.edu.tw/rj/class2/
98
1
AUTOMATIC CONTROL
E137100
3
()
3
62175
Office Hours
1.
:
2.
:
3.
:()
4.
:
5.
:-
6.
:
7.
:
8.
:
6
Modern Control Systems, 11th Edition, Dorf and Bishop
: 10%
: 15%
: 25%
: 25%
: 25%
98
2
HEAT TRANSFER
E136800
1
( )
3
Office Hours
Introduction
Theory of Conduction
1-D Steady Conduction
Extended Surfaces
2-D Steady State Conduction
Transient Conduction, Lumped-Capacitance Analysis
1-D Transient Conduction
Transient Conduction in Semi-Region
Fundamentals of Convection Heat Transfer
Convection Transfer Equations, Similarities and Analogies
External Convection Heat Transfer
Internal Convection Heat Transfer
Natural Convection Heat Transfer
Thermal Radiation, Processes
Blackbody Radiation
The View Factor
Diffuse-Gray Enclosure Analysis
Volumetric Radiation, Absorption & Emission
Boiling Heat Transfer
Condensation Heat Transfer
Heat Excahngers
Fundamentals of Heat and Mass Transfer, 6th edition, F. P.
Incropera and D. P. DeWitt, T. L. Bergman, A. S. Lavine, John
Wiley & Sons, 2007.
98
2
HEAT TRANSFER
E136800
2
()
3
06-275757562119
Office Hours
19:10 21:00
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
Fundamentals of Heat and Mass Transfer, F. P. Incropera and D. P. Dewitt, 2007, 6th ed. (2002, 5th ed. is also fine)
20%
30%
20%
30%
http://iteach.ncku.edu.tw
98
2
FERROUS MATERIALS
E122000
3
Ext.62154
Office Hours
1.
2.
3.
4.
5.
6.
()
98
1
()
ENGINEERING JAPANESE (1)
E130510
3
(O) 06-2757575-62138
(H) 06-2747766
Office Hours
(
(
()
6
()
6
()
HYPERLINK "http://zh.wikipedia.org/wiki/%E3%82%AF" \o ""
HYPERLINK "http://zh.wikipedia.org/wiki/%E3%82%BB" \o ""
HYPERLINK "http://zh.wikipedia.org/w/index.php?title=%E3%83%B3&action=edit" \o ""
HYPERLINK "http://zh.wikipedia.org/wiki/%E3%83%88" \o "" ()
3
()
3
()
21
()
12
( (I)
(
() 20%() 60%(20%)
()
98
2
()
ENGINEERING JAPANESE (2)
E130520
()
3
(O) 06-2757575-62138
(H) 06-2611009
Office Hours
(()
(
(
(
((
( (II)
(
(20% (40%)
(40% 20% (60%)
98
1
ENGINEERING MATHEMATICS
E132700
()
3
Office Hours
15
15
15
(2) 30%
10%
30%
98
1
COMPUTER GRAPHICS
E134700
C
3
62126
Office Hours
Day time in office
(CAD)OpenGL
1. (Computer Graphics Software Standard and Hardware)
6
2. (2D Viewing Operations)
6
3.Glut(Glut Windows)
3
4. (3D Viewing Operations)
3
5.OpenGL (OpenGL Library)
9
6., (Hidden Lines, Surfaces and Rendering)
3
7. (Quadratic Surfaces Implementation)
3
8. (Curves)
6
9. (Curves Implementation)
10. (Surfaces)
6
11. (Surfaces Implementation)
12. (Solid Modeling)
3
1. Vera B. Anand, Computer Graphics and Geometric Modeling for Engineers, 1993, John Wiley & Sons, Inc.
2. R.S. Wright, Jr. and M. Sweet, , OpenGL,.
(5*11%)(3*10%)(15%)(3%)
http://vr.me.ncku.edu.tw/courses/
98
1
NUMERICAL ANALYSIS
E141100
()
3
62119
Office Hours
1.
2.
3.
4.
5.
6.
7.
8.
9.
1. Numerical Analysis, R.L. Burden and J.D. Faires, Thomson Brooks/Cole, 8th Ed., 2005. (textbook)
2.
Scilab ()Matlab ()MathematicaCFortran
30%
30%
40%
http://iteach.ncku.edu.,tw/
98
2
Instruments and Measurements
E127100
(, , , )
3
62192
Office Hours
1. (~ 5 Weeks)
2. (~ 3 Weeks)
3. (~ 7Weeks)
4. (~ 2 Weeks)
R. S. Figliola and D. E. Beasley, Theory and Design for Mechanical Measurements, 4th Ed., John Wiley & Sons, 2006. ()
Quiz: 20 *3 = 60; Homework: 15 ; Conceptual Design Project: 15; Instrument Review: 10 (Total= 100 Points).
Quiz I: Part I; Quiz II: Part II, III;Quiz III: Part III, IV
Instrument Review: ( , , , ), , , , .
Conceptual Design Project: , . : ? ? ? !
98
2
BASIC FINITE ELEMENT METHOD
E130800
3
62164
Office Hours
(ANSYS)FORTRAN
1.
2.ANSYS
3.ANSYS
1. Introduction(chapter 1)
2. ANSYS Getting Started
3. Bar, trusses(chapter 3)
4. Beam, frame(chapter 8.2)
5. Review of solid mechanics
6. One-dimensional elements(chapter 3)
7. Analysis of one-dimensional problems(chapter 4)
8. Two-dimensional elements(chapter 5)
9. Analysis of two-dimensional heat transfer problems(chapter 7)
10. Analysis of plane stress and plane strain problems(chapter 8)
11. Analysis of three-dimensional problems(chapter 10)
1.Saeed Moaveni() (), -- ANSYS, , 2001
2.Huei-Huang Lee Finite Element Simulations with ANSYS Workbench 12 Theory Applications Case Studies 2010
40%, 30%, 30%
Tel : 62265
98
2
TOOL DESIGN
E138800
3
Office Hours
98
2
()
Mechanics of Materials
E126400
( () )
3
62143
Office Hours
1.
2.
3.
1.
2.
3.
4.
5. (convolution)
6.
7. (Hamilton)(Lagrange)
8.
L. Meirovitch, Fundamentals of Vibrations, International edition, McGraw-Hill, Inc., Singapore 2001
10%
55%
35%
98
2
Introduction to Components of Control Systems
3
62137
Office Hours
1.
2.
Chapter 1. Review of Modern Control Systems
Chapter 2. Feedback Loop Design
Chapter 3. Power Control and Schmitt Trigger
Chapter 4.Micro-processors
Chapter 5.Switch and Phase Control
Chapter 6.Computer Interface
Chapter 7. Digitalization and PID Controller
Chapter 8. Stepping Motor
Chapter 9. Simulink and Matlab
Chapter 10. Projects
1. Control Sensors and Actuators, by deSilva, Printice Hall.
2. Electrical Sensors and Transducers, by Carstens, Printice Hall.
Project: 15 % x 5 = 75 %
Report: 2 % x 5 = 10 %
Presence: 15 %
98
2
An Introduction to Energy Science and Technology
E132400
(1) (2)
2
x 62110
Office Hours
1.
a.
b.
c.
2.
a.
b.
c.
d.
e.
f.
g.
h.
i.
j.
3.
a.
b.
c.
70%10%20%
www.me.ncku.edu.tw/~wenhtlab
98
2
SERVO CONTROL
E142900
3
886-6-2757575-62173
Office Hours
Servo Control
"" MatlabIsSpice
1.
2.
3.
4.
5.MatlabIsSpice
6.
G. Ellis, Control System Design Guide, Academic Press, Inc.
1.
2.
1. 20%
2. 35%
3. 45%
http://emotors.ncku.edu.tw/script/teach/
62271
98
2
ENGINEERING HYDRAULIC & PNEUMATIC CONTROL
E132000
3
62153
Office Hours
1.
2.
3.
4.
5.
6.
7.
30%
40%
20%
10%
http://www.me.ncku.edu.tw/~fplab/index
100
1
Introduction to Quantum Mechanics
()
3
(06)275-7575 ext. 62124
Office Hours
(1) The Birth of Modern Physicsilluminating the picture of contemporary optoelectronic physics
(2) The Experimental Basis of Quantum Theory
(3) Bohr Bohr Atom Theory, Structure of the Hydrogen Atom and Associated Spectrum(4) Wave properties of Matter(5)Schrdinger Quantum Mechanism and Schrdinger Equation(6) Special Theory for Relativity
R. A. Tipler & R. A. Llewellyn, Modern Physics, 5th ed., W. H. Freeman and Company, New York, 2008,
Homework
30%
Midterm
20%
Final Exam
25%
Report
25%
98
1
Fundamentals of optics
E150100
3
(06)2757575 ext 62170
Office Hours
14:30-16:00,14:30-16:00
1: General Principles
23: Image Formation (First Order Optics)
4: Aberrations
5: Prisms and Mirrors
6: The Eye
7: Stops and Apertures
8: Optical materials and Interference Coatings
9: Radiometry and Photometry
10: Basic Optical Devices
11: Optical Computation
12: Image Evaluation
13: Polarization
: Modern Optical Engineering by Warren J, Smith, McGraw-Hill
:
(1)Optics by Eugene Hecht, Addison Wesley
(2)Fundamentals of opticsF. A. JenkinsH. E. White, McGraw-Hill International Editions
(3)
(1) 30%10.5
(2) 35% :
(3) 25%
(4) 10%
N/A
N/A
98
1
THERMAL ENGINEERING
E132100
()
3
2757575-62142
Office Hours
?1.2.3.4.5.6.7.8.9.10.11.12.13.14.
Applied Thermodynamics Engineering technologists 5th edition , by Eastop & McConkey. Published by Longman Scientific & longman Group UK limited(1993)
98
1
Green Technology Innovative Design
E132500
3
62166
Office Hours
(91721)
,,, ,
1.
2.
(Eco-Innovation)
(Sustainable Innovation)
TRIZ
3.()
TRIZ
TRIZ
4.()
(Green Evolution Rules)
5.()
6.()
QFD
7.()
FMEA
8.()
9.()
10.
(10%), , ((15%), (40%)),Project(30%), Project Presentation(5%).
/
98
1
PRECISION PROCESS & MEASUREMENT
E143200
3
Office Hours
6
8
8
8
8
8
8
8
+ 30%
30% 40%
98
1
GREEN DESIGN
E143400
3
62166
Office Hours
(91721)
,,
1.
2.,
1.: ISO14000
2.: (TPI)
3.:
4.:
5.: TRIZ
6.:
7.: Factor X
8.:
, ()ProjectProject Presentation
(10%)(15%) (20%) (20%)Project(30%)Project Presentation(5%)
/
98
1
Introduction to Microelectronic Fabrication Processes
3
62192
Office Hours
5,6 7
19/14 M,, Historical review
19/16 WIC Fabrication Overview
29/21 MIC Fabrication Overview
Semiconductor Physics and Materials
29/23 WSemiconductor Physics and Materials
39/28 MSemiconductor Physics and Materials
Wafer Manufacturing
39/30 WWafer Manufacturing
410/05 MDiffusion and Oxidation
410/07 WDiffusion and Oxidation
510/12 MDiffusion and Oxidation
510/14 WLithography
610/19 MLithography
610/21 WAdvanced Lithography: EBL, XRL, & NIL
710/26 MIon Implantation
710/28 WIon Implantation
811/02 MEtching
811/04 WEtching
911/09 MThin Film Process
911/11 W:
1011/16 MThin Film Process
1011/18 WThin Film Process
1111/23 MSemiconductor mechanics of materials
1111/25 WMetalization & Interconnection
1211/30 MMetalization & Interconnection
1212/02 WCMP Process Overview
1312/07 MProcess Integration : Isolation
Process Integration : MOS, BJT
1312/09 WA simple circuit example
1412/14 MProcess Integration: CMOS
1412/16 WCharacterization and Diagnostics
1512/21 MLimitation of Semiconductors
Reliability & Yield
Packaging
1512/23 WIntroduction to MEMS
1612/28 MIntroduction to MEMS
1612/30 WIntroduction to MEMS
1701/04 MIntroduction to MEMS
Nanoimprinting technology
1701/06 WNanoimprinting technology
1801/11 W
Course Notes
Homework25%, Paper review report 10%, 3 Quizzes: total 65%
http://140.116.155.39/new_page_4.htm
98
1
Creative Engineering Design
E144200
2
62145
Office Hours
11:00~12:30
1. (2)
2. (2)
3. (2)
4. (4)
5. (6)
6. (2)
7. (2)
8. (6)
9. (6)
10.
1.Yan,H,S., Creative Design of MechanicalDevices,Springer,1998.
()()2006.02
2.
3.
20%20%25%25%10%
http://www.acmcf.org.tw/CED
()
98
1
()
THESIS (1)
E144210
1
Office Hours
()
98
2
()
THESIS (2)
E144220
1
Office Hours
98
1
Introduction to Components of Control Systems
E144500
3
Office Hours
1.
2.
Chapter 1. Review of Modern Control Systems
Chapter 2. Feedback Loop Design
Chapter 3. Power Control and Schmitt Trigger
Chapter 4.Micro-processors and Interface
Chapter 5.Switch and Phase Control
Chapter 6.Computer Interface
Chapter 7.Digitalization and Stability
Chapter 8.Characteristics of Mechatronics Systems
1. Control Sensors and Actuators, by deSilva, Printice Hall.
2. Electrical Sensors and Transducers, by Carstens, Printice Hall.
3. Precision Sensors, Actuators and Systems, by Tzou, Kluwer Academic
4. Measurement, Systems and Sensors, by Nawrocki, Artech House
5. The 8051 Microcontroller, by Ayala, West Publishing Company
Project: 15 % x 5 = 75 %
Report: 2 % x 5 = 10 %
Presence: 15 %
98
1
Experimental Design
E144700
3
0937-341541
Office Hours
15:10~18:00
,,,/,,,,3,,,,3(1);(2);(3),6,3~5,,
1.
2.
3.
4.
5.
6.
Montgomery, D.C., 1997, Design and Analysis of Experiments, John Wiley & Sons ()
, 1998, ,
, , 1998, ,
, , 2002, ,
, 2001, -,
, 1994, ,
, 1993, ,
, 1995, ,
, 2002, ,
(/) 50%; (//) 50%
word(.doc),[email protected]
98
2
PRINCIPLE OF AUTOMOBILE
E140600
3
Office Hours
1.
2.
3.
4.
5.
6.
7.
,.
98
2
()
()
Engineering Refrigeration and Design
E142200
3
(06)275-7575 ext. 62176
Office Hours
Week days 8:00~11:30 AM
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
W.F. Stoecker and J.W. Jone, Refrigeration and Air Conditioning, 2nd ed., McGraw-Hill Book Co., New York.
(1~2)+
98
2
FUNDAMENTALS OF METAL MACHINING AND MACHINE TOOLS
E150700
3
62170
Office Hours
11:30-12:00
Chapter 1
*
*
*
* *
Chapter 2
Chapter 3
42
Chapter 4
Chapter 5
Chapter 6
Chapter 7
Chapter 8
Chapter 9
Chapter 10
Chapter 11
Chapter 13
1. Fundamentals of Metal Machining and Machine tools by Geoffrey Boothroyd
2. Metal Cutting Principles by Milton C. Shaw
3.
(1) 30%1
(2) 35% :
(3) 35%
(), ()
,
98
1
(), ()
SEMINAR (1), (3)
N150110, N150130
1 2 3 4
0
,,,,
Office Hours
1.
2.
12()(5)(12)
1. 10(55)70105
2. 5-10
3.
, (), (), ()
,
98
1
(), (3)
SEMINAR (1), (3)
N150110, N150130
5
0
,
Office Hours
1. (A) (B)
2. (A) (B) 5, 10 () .
A , 30. . , , , .
:
:
i.power point12:00, e-mail , notebook
ii.: ,
iii.
:
i., ,
, 10 (A B 5), 70. (A B ), 5. , .
A:
15~20 ,/ 5-10 , 10 .
B:
, , , .. present .
:
i.,
ii.,
iii.notebook, notebook
iv., PDF , present , post
(), ()
,
98
2
(), ()
SEMINAR (2), (4)
N150120, N150140
1 2 3 4
0
Office Hours
3.
4.
12()(5)(12)
4. 10(55)70105
5. 5-10
6.
, (), (), ()
,
98
2
(), ()
SEMINAR (2), (4)
N150120, N150140
5
0
,
Office Hours
12()(5)(12)
7. 10(55)70105
8. 5-10
9.
http:// iteach.ncku.edu.tw
()
98
1, 2
SEMINAR
1
0
,
Office Hours
12()(5)(12)
1. 4
2.
()
98
1, 2
SEMINAR
N180200
2
0
,
Office Hours
20
30 70 (10 )
(), ()
98
1, 2
(), ()
PAPER DISCUSSION (3), (4)
N110330, N110340
0
,
Office Hours
20
30 70 (10 )
98
1
THEORY OF TURBULENCE
N150400
Fluid Mechanics
3
62169
Office Hours
1. Mathieu J., Scott J., 1999. An Introduction to Turbulent Flow, Cambridge Press.
2. Tennekes, H., Lumley, J.L., 1972. A First Course in Turbulence. MIT Press, Cambridge, MA.
1. (60%)
2. (40%)2020
98
1
LINEAR SYSTEMS
N154000
3
Office Hours
Solvability of systems of linear equations, vector analysis, and vector ordinary differential equations are discussed in the context of finite dimensional linear systems. Specific topics that will be addressed are
1. Mathematical Description of Systems
2. Linear Algebra
3. State-Space Solution and Realizations
4. Stability
5. Controllability and Obervability
6. State Feedback Design
7. Observer Design
8. Kalman Canonical Structures
9. MIMO Poles and Zeros
Help students to develop a solid foundation in the use of dynamical systems for engineering and system-theoretic applications.
C.T. Chen, Linear System Theory and Design, Oxford University Press, 1999.
Homework: 35%. Late homework will not be accepted without prior permission from the instructor.
Midterm: 30%. The midterm will be an in-class exam.
Final exam: 35%. The final exam will most likely be a take-home exam
98
1
POLYMER PROCESSING
N154100
3
Office Hours
1.
2.
3.
A.
B.
C.
D.
4.
5.
6. C-Mold
7.
98
1
Computational Fluid Dynamics
N156100
( FORTRAN )
3
Office Hours
1.CFD2.
1. Introduction
2. Classification of Fluid Flows
3. Introduction to Numerical Methods
4. Finite Difference Methods
5. Finite Volume Methods
6. Solution of Linear Equation Systems
7. Numerical Formulations & Methods of Incompressible Flows
1. Computational Fluid Dynamics, P. J. Roache, Hermosa Publishers, 1975.
2. Computational Methods for Fluid Flow, R. Peyret & T. D. Taylor, Springer-Verlag, 1983.
3. Computational Fluid Mechanics and Heat Transfer, D. A. Anderson, J. C. Tannelhill, and R. H. Pletcher, 2nd ed., Taylor & Francis, 1997.
98
1
Conduction Heat Transfer
N157100
3
Office Hours
1. 2. 3. Duhamel4. 5. 6. 7. Kirchhoff8. 9.
98
1
Engineering Two-Phase Flows
N159000
3
62125
Office Hours
To help students to develop a sufficient understanding of engineering two-phase flows such that both problems in engineering practice and the technical research literature can be approached with confidence.
1.Nucleation Theory and Cavitation
phase change, cavitation and boiling, homogeneous nucleation, heterogeneous nucleation, cavitation inception
2.Bubble Dynamics:
Rayleigh-Plesset equation, bubble dynamics, bubble stability and natural frequencies, bubble collapse, cavitation damage and noise, etc.
3.Single Particle Motion:
classical solutions for flows around a sphere, potential flow, Stokes flow, and Oseen solution, unsteady particle motions and added mass matrices, unsteady potential and Stokes flows, particle equations of motions, estimates of relative motion, effect of concentration, etc.
4.Introduction to Multiphase Flow Modeling
multiphase flow notation, system of model equations, etc.
5.Flow Patterns:
flow regimes map, instability in multiphase flows, etc.
6.Homogeneous Flow:
basic equations, sonic speeds with and without phase change, one dimensional gas/liquid or gas/solid nozzle flows, vapor/liquid nozzle flows, etc.
7.Flows with Bubble Dynamics:
acoustics of bubbly flows, shock waves in bubbly cavitating flows, cloud cavitation dynamics, etc.
8.Flows with Relative Motion between Phases:
separated flow models, friction factor correlations, Lockhart/Martinelli and Martinelli/Nelson correlations, annular two-phase flows, deposition and entrainment, etc.
9.Special Topics:
sprays, system instabilities, granular material flows, etc.
1.Brennen, C.E. (1995). Cavitation and Bubble Dynamics. Oxford University Press. (http://resolver.caltech.edu/CaltechBOOK:1995.001)
2.Brennen, C.E. (2005). Fundamentals of Multiphase Flows. Cambridge University Press. (http://caltechbook.library.caltech.edu/51/01/multiph.htm)
3.Wallis, G.B. (1969). One-dimensional Two-phase Flow. McGraw-Hill. ( 531.11/W158)
Final oral presentation (about 15 mins) and final report
98
1
Introduction to Heat and Mass Transfer
N159400
( )
3
X 62110
Office Hours
1. ;
2. ;
3.
*Introduction
*Theory of Conduction
*Non-Fourier Conduction Equation
*1-D Steady Conduction
*Extended Surfaces
*2-D Steady State Conduction, Integral Solution
*Transient Conduction, Lumped-Capacitance Analysis
*1-D Transient Conduction
*Transient Conduction in Semi-Region
*Melting & Solidification
*Transient Conduction with Concentrated Sources & Sinks
*Theory of Mass Diffusion
*Mass Diffusion without Homogeneous Chemical Reactions
*Steady Mass Diffusion
*Transient Mass diffusion
*Fundamentals of Convection Heat & Mass Transfer
*Convection Transfer Equations, Similarities and Analogies
*External Convection Heat Transfer: Scale Analysis, Similarity Solution, and Integral Solution.
*External Convection Mass Transfer: Similarity Solution.*Internal Convection Heat & Mass Transfer
*Natural Convection Heat & Mass Transfer
*Thermal Radiation, Processes*Blackbody Radiation
*The View Factor
*Diffuse-Gray Enclosure Analysis
*Volumetric Radiation, Absorption & Emission
*Boiling Heat Transfer
*Condensation Heat Transfer
1. R.B. Bird, W.E.Stewart, and E.N.Lightfoot, Transport Phenomena, John Wiley & Sons, Inc., New York, 1960.
2. E.R.G. Eckert and R.M. Drake, Jr., Analysis of Heat and Mass Transfer, McGraw-Hill, New York, 1972.
3. E.P. Incropera and D.P. Dewitt, Fundamentals of Heat and Mass Transfer, John Wiley & Sons, Inc., New York, 1996.
4. A. Bejan, Heat Transfer, John Wiley & Sons, Inc., New York, 1993.
HWs 20%
1 Mid-term Exam 20%
1 Final Exam 30%
1 Take-Home exam 20%
Attendance/Participation 10%
www.me.ncku.edu.tw/~wenhtlab
98
1
Gas Kinetic Theory
N15A800
3
(Chen-I Hung)
Office Hours
1.
2.
3.
4.
5.
6.
7.
1. T.I. Gombosi, Gas Kinetic Theory, Cambridge University Press Press (1994)
2. W.G. Vincenti and C.H. Kruger, Introduction to Physical Gas Dynamics, John Wiley, New York (1965).
3. S. Chapman and T.G. Cowing, The Mathematical Theory of Non-Uniform Gases, Cambridge University Press Press (1952).
40%, 30%, 30%
98
1
ADVANCED THERMODYNAMICS
N167600
3
06-2757575~62172
Office Hours
1. Basic Concepts
2. The First and Second Law of Thermodynamics
3. Exergy Analysis
4. Thermodynamic Relations
5. The Third Law of Thermodynamics
6. Chemical Equilibrium
7. Irreversible Thermodynamics
8. Finite-Time Thermodynamics
1. Wark, Advanced Thermodynamics for Engineering, 1995.
2. Bejan, Advanced Engineering Thermodynamics, 2006.
3. Zemansky, Heat and Thermodynamics, 1997.
1. H.W. (20%)
2. (40%)
3. (40%)
98
1
ENGINEERING REFRIGERATION AND DESIGN
N167700
3
Office Hours
W.F. Stoecker and J.W. Jone, Refrigeration and Air Conditioning, 2nd ed., McGraw-Hill Book Co., New York.
(1~2)+
/
98
1
/
Micro/Nanoscale Heat Transfer
N170800
3
62119
Office Hours
1.
2.
3.
4.
5.
6.
7.
8. /
9.
10. /
1. Nano/Microscale Heat Transfer, Z.M. Zhang, McGraw-Hill, NY, 2007 (textbook). ()
2. Nanoscale Energy Transport and Conversion, G.Chen, Oxford University Press, MI, 2005.
10%
40%
50%
http://iteach.ncku.edu.tw/
98
1
()
WAVE MECHANICS (Dynamics)
N158700
3
Tian-Shiang Yang
62112
Office Hours
By appointment
1. Introduction ~ 1.5 weeks
Course organization, basic ideas.
2. Waves on a stretched string ~ 2.5 weeks
Standing waves, DAlemberts solution, reflection and transmission of
waves by density discontinuities, method of characteristics.
3. Sound waves ~ 3 weeks
Plane waves, acoustic energy transmission, plane waves in tubes, acous-
tic waveguides, acoustic sources, radiation from sources in a plane wall.
4. Linear water waves ~ 3.5 weeks
Gravity waves, capillarygravity waves, edge waves, ship waves, the
solution of initial value problems, shallow water waves, wave refraction.
5. The formation and propagation of shock waves ~ 3 weeks
Traffic waves, compressible gas dynamics.
6. Nonlinear water waves ~ 2 weeks
Nonlinear shallow water waves, nonlinear deep water gravity waves
(Stokes expansion), the Kortewegde Vries (KdV) equation for shallow
water waves, nonlinear capillary waves.
J. Billingham & A. C. King, Wave Motion, Cambridge University Press
(2000).
Midterm exam ~ 40%
Problem sets (one problem set every other week) ~ 40%
IP: 140.116.155.111, port 21; username/password: wave
98
1
POLYMER RHEOLOGY
N159500
3
Office Hours
-
-
98
1
ENGINEERING ANALYSIS
N150200
2
3
Office Hours
1.
2.
3. (eigenvector expansion, similarity transformation)
4.
5. Adjoint operator
6.
7.
8. Lagrange
98
1
MECHANICS OF VIBRATIONS
N151700
( (2) )
3
Office Hours
Free Vibration
Harmonic excitation vibration
Energy method and Lagranges equation
Multiple degrees of freedom systems
Vibrating systems
Continuous systems
Nonlinear vibration
Experimental vibration mechanics
1.General and Advanced Vibration Books
1. : ,
2.W. Thomson and M. D. Dahleh, Theory of Vibration with Applications 5th ed., Prentice Hall, 1998.
3.A. Dimarogonas and S. Hadood, Vibration for Engineers, Prentice-Hall, 1992
4.S. S. Rao, Mechanical Vibrations, Addison Wesley, 1987.
5.S. Kelly, Fundamentals of Mechanical Vibrations, McGraw-Hill, 2000.
6.G. Szuladzinski, Dynamics of Structures and Machinery, Wiley, 1982.
7.G. Genta, Vibration of Structures and Machines, Springer, 1995.
8.M. Roseau, Vibrations in Mechanical Systems, Springer, 1984.
9.C. F. Beards, Structural Vibration: Analysis and Damping, Arnold, 1996.
10.: : , , , , , 1990.
2.Classical Dynamics
1.S. T. Thornton and J. B. Marion, Classical Dynamics of Particles and Systems 5th Ed., Thomson, 2004.
2.W. Greiner, Classical Mechanics, Springer, 2003.
3.Modal Testing and Diagnostics
1.K. G. McConnell, Vibration Testing, Theory and Practice, Wiley, 1995.
4.Vibration Control
1.A. Preumont, Vibration Control of Active Structures, Kluwer, 1997.
2.Gawronski, Advanced Structural Dynamics and Active Control of Structures, Springer, 1998.
3.L. Melverich, Dynamics and Control of Structures, Wiley, 1992.
5.Rotor Dynamics
1.E. Kramer, Dynamics of Rotors and Foundations, Springer, 1993
6.Random Vibration
1.S.H. Crandall and W. D. Mark, Random Vibration in Mechanical Systems, Academic, 1963.
7.Nonlinear Vibration
1.A. H. Nayfeh and D. T. Mook, Nonlinear Oscillations, Wiley, 1979.
2.A. H. Nyfeah and B. Balachandran, Applied Nonlinear Dynamics, Wiley, 1995.
3. : , 2006.
4., , , 2002.
Quiz :100%
Homework:for general evaluation
http://140.116.155.39/new_page_4.htm
98
1
FINITE ELEMENT METHOD
N155000
3
62164
Office Hours
C++
1.
1
2. Basic computer concept and introduction to C++
2
3. Integral formulation and variational method
5
4. Second-Order differential equations in one dimension
7
5. C++array(function)
2
6.
Numerical integration, Gaussian elimination
2
7. Bar, beam and frames
4
8. Second-Order differential equations in two dimensions
8
9
4
10
3-D problems, nonlinear problems, time dependent problems and eigenvalue problems
4
J. N. Reddy An Introduction to the Finite Element, Third Edition Mcgraw-Hill International Edition, 2006.
: 50%
: 25%
: 25%
98
1
Piezoelectric Materials and Acoustical Electronic Devices
N163600
3
62177
Office Hours
Monday 11:00 ~12:00
1. Fundamentals of elasticity and elastic wave propagation - A Review
Strain, stress, tensor and tensor notation, constitutive law, equation of motion, wave equation, bulk waves(L-wave and S-wave), surface wave (Rayleigh Wave), Love wave, waves in anisotropic solids (crystals), vibration and modal analysis
2. Basics in Electrostatics - A Review
Maxwells equation, electromagnetic wave propagation, transmission line, Smiths chart, network theory, matching theory, network analyzer (theory and practice)
3. Piezoelectricity
Crystals and crystalline symmetry, dielectric properties, piezoelectric effects, piezoelectric materials, piezoelectric constants, constitutive equation, wave propagation in piezoelectric materials, vibration of piezoelectric plates
4. Modeling of piezoelectric materials
Equivalent circuit and PSPICE modeling, Mason equivalent circuit model, KLM equivalent circuit model
5. Bulk acoustic wave devices: Resonators
Basic theory of resonators, oscillating circuit , quality factor (Q), crystal quartz oscillator, modeling of resonators, application of piezoelectric resonator, example study
6. Surface acoustic wave devices: SAW Filters
Interdigital transducer (IDT), analysis and modeling of IDT, principle of SAW filter, SAW filter design, example study
7. Acoustic wave sensors
Quartz crystal microbalance (QCM) and its applications, SAW sensor for gas and liquid, Love wave sensor, example study
1. Fundamentals of Piezoelectricity, by T. Ikeda, 1990.
2. Linear Piezoelectric Plate Vibrations, by H.F. Tiersten, 1969.
3. Piezoelectric Resonators and Their Applications, by J. Zelenka, 1986.
4. Acoustic Fields and Waves in Solids, Vol. I & II, by B. A. Auld, 1973.
5. Acoustic Wave Sensors: Theory, Design, and Physico-Chemical Applications,D.S. Ballantine, Jr., et al., 1997.
6. Surface Acoustic Wave Devices for Mobile and Wireless Communication, by C.K. Campbell, 1998.
7. Fundamentals of Engineering Electromagnetics, by D. K. Cheng
8. Physical properties of crystals: their representation by tensors and matrices, by J.F. Nye, 1957 and 1985, Oxford University Press.
9. Vectors, tensors, and the basic equations of fluid mechanics, R. Aris, 1962. ./Rutherford Aris
(1). Home Works and Quizes40 %
(2). Midterm #120 %
(3). Midterm #220 %
(4). Final20 %
140.116.155.46
, Room 91A08, Ext.62159-28, or (06)2389131
98
1
PRECISION MEASUREMENTS BY OPTICAL METHODS
:
3
(06)2757575-62123
Office Hours
Any Time
.
1.
2.
3.
4.
5.
6.
1.Optics Hecht, Addison Wesley
2. ,
3. , ,
()20%25%25%30%
()
98
1
()
LABORATORY EXPERIMENTS ON ELECTRONIC DEVICES (1)
N165510
1A 1B
3
62177
Office Hours
Monday 11:00 ~12:00
(Analog)(Digital)13
(Analog)(Digital)
R-L-C
R-L-C(SPICE and EWB)
(BJT)(1/2)
(BJT)(2/2)
(FET)
(1/3)-
(2/3)-
(3/3)-
555 Timer
RS232IEEE-488 (GPIB)
10. Albert P. Malvino, Electronic Principles, 7th Edition, 2007, McGraw-Hill.
11. Thomas L. Floyd, Electronic Devices, 6th Edition, 2002, Prentice Hall.
12. - 8th Edition 2002 Robert L. Boylestad and Louis Nashelsky, Electronic Devices and Circuit Theory, 8Th Edition, 2001, Prentice Hall.
13. Paul Horowitz and Winfield Hill, The Art of Electronics, 2nd Edition, 1989, Cambridge University Press.
14. Thomas C. Hayes and Paul Horowitz, Student Manual for the Art of Electronics, 1989, Cambridge University Press.
15. Adel S. Sedra and Kenneth C. Smith, Microelectronic Circuits, 4th Edition, 1998, Oxford University Press.
1. (Lab.)(13:10 pm)
2. (13:10 pm)
3.
4.
1. Midterm #1
15 %
2. Midterm #2
15 %
3. Final
15 %
4. Pre-Study Home Work15 %
5. Lab. Report
30 %
6. Lab. Hand-On Exam
10 %
140.116.155.46
Teaching AssistantsRoom 91A08, Ext.62159-28 or (06)2389131
98
1
RESEARCH METHODOLOGY AND TECHNICAL WRITING
N166900
3
Office Hours
,,,,,,,,,,,!!
[] ,
[ ] ,
[]
[]
[ ] ,
, R.A. Day , 2002, ,
Philip C. Kolin, 2009(v2), Successful Writing at Work, Houghton Mifflin Co.
Michael Alley, 1996, The Craft of Scientific Writing, Springer-Verlag.
, 2007, ,
, 1996, ,
, 2000, , ,
, 2002, ;
,2005, ,
,2006, ,
(Conference Paper) 50%; (Diploma Thesis) 50%
word(.doc),[email protected]
()
98
1
()
FUNDAMENTAL SOLID MECHANICS (1)
N188110
3
Office Hours
1.
2.
3.
4.
5.
6.
98
1
THEORY OF GEARING
N170400
()
3
(06)275-7575 ext. 62190
Office Hours
To be announced
1.
2.
3.
4.
5.
6.
7.
Litvin, F. L., 1989, Theory of Gearing, NASA, Reference Publication 1212
Litvin, F. L., 1994, Gear Geometry and Applied Theory, PTR Prentice Hall, Englewood Cliffs.
(50%)(50%)
98
1
Mechanical Design of Robotic System
N155400
Basic concept of mechanical design
3
06-2757575 Ext. 62161
Office Hours
By appointment
Enable students to design a robotic system
1. Introduction
-Introduction to Robotic System
2. Geometry Design and Optimal Working Space
(a). Regional Structure
(b). Orientation structure
(c). Normalized Volume Index.
3. Structural Design of Manipulators
(a). Structural Compliance, Actuator Compliance
(b). Static Deflection
(c). Dynamic Compliance and Natural Frequencies.
4. Power Actuation, Transmission, and Instrumentation
(a). Power actuation,
(b).Transmission
(c). Sensing and Instrumentation.
5. Robotic Forward Position Analysis
(a). forward problem
(b) Homogeneous Coordinates
(c) Homogeneous Transformation
(d) Rotation Matrix and Representations
6. Robotic Inverse Position Analysis
(a). inverse problem
(b) Straight line motion
7. Robotic Velocity Analysis
(a). forward Jacobian formulation.
(b). inverse Jacobian problem
(c). Dulity between static & instantaneous kinematics
8. Robotic Dynamics Analysis
(a). Lagrange Method
(b). Newton Euler Method
9. Programming and Trajectory Planning
(a) Programming method
(b) Cubic spline trajectory
(c) 1-4-1 spline trajectory
(d) Other blended and mixed trajectories
10. Design/Research and system Integration Project
Ming J. Tsai, Mechanical Design of Robotics System, Class Note.
3-4 home works, @10-15%
1 midterm exam, 20%
1 final project (include a proposal and a final presentation) 20-25%
98
1
Reliability in Mechanical Design
N15B100
3
[email protected] (with mail title : Reliability Class ... )
62149
Office Hours
10:00 am - noon, Wednesdays, or by appointments
- Provide examples to show the significance of reliability in engineering applications
- Review fundamental probability theory and statistics
- Compare various uncertainty models
- Understand some commonly used probability distributions and their physical meanings
- Determine distributions and parameters from observed data
- Determine reliability of serial and parallel systems
- Introduce various reliability analysis techniques
- Advanced topics : system reliability, variance reduction techniques, design for six sigma
Develop fundamental reliability backgrounds for mechanical engineers. Students are expected to have basic knowledge about probability and statistics including set theory prior to this class.
course slides and handouts
Probability, Reliability, and Statistical Methods in Engineering Designby A. Haldar and S. Mahadevan, John Wiley & Sons, 2000, ISBM:0-471-33119-8
Homework 30% (5% each)
Project 25% (5%, 8%, 12%)
Attendance and Participation 15%
Midterm Exam #1 15%
Midterm Exam #2 15%
http://iteach.ncku.edu.tw (Email)
98
1
Flexure-based Mechatronics System
N171400
3
06-2757575ext62274
Office Hours
,,.:
1. Introduction
2. Review of rigid-body mechanism
3. Deflections and failure
4. Elliptic integral equations and Pseudo-rigid-body model
5. Generalized shooting method
6. Global coordinate model and incremental linearization approach
7. Compliant mechanism synthesis
8. Compliant actuators
9. Special topics
1. Compliant Mechanisms, Howell, L. L., 2001, John Wiley & Sons.
2. Flexures : elements of elastic mechanisms, Stuart T. Smith, 2002, Gordon & Breach
3. Compliant Mechanisms: Design of Flexure Hinges, Nicolae Lobontiu, 2000, CRC Press
Homework (45%)
Midterm exam (25%)
Final exam (25%)
Reading assignment (5%)
http://myweb.ncku.edu.tw/~cclan/CM2009F/
98
1
Fundamentals of Automotive Crashworthiness
N167000
3
Office Hours
Introduction
Crash Signature and Typical Testing Method
Coordinate System
Sensor
Digital Filter
Crash Pulse and Kinematics
Analysis of Crash Test Data
Impulse, Momentum, and Energy
Vehicle Inertia Properties
Vehicle and Occupant Responses
Critical Sliding Velocity
Vehicle Rollover
Crash Severity Assessment
Regulations
Injury Index
1. Huang, Matthew (2002) Vehicle Crash Mechanics, CRC Press.
2. SAE (2003) Accident Reconstruction.
3. Seiffert and Wech , Automotive Safety Handbook
40% Homework assignments and literature studies
20% Project and Presentation
40% Exam
98
1
Viscoelasticity
N15A700
3
62181
Office Hours
(Constitutive Model)
1. Mechanical models for linear viscoelastic materials
2. creep and relaxation functions
3. correspondence principle
4. quasi-static analysis
5. wave propagation
6. nonlinear material behavior
7. uniaxial creep laws and multiaxial generations
8. creep damage and failure
1. Theory of viscoelasticity An introduction,R. M. Christensen, Academic Press
2. Lectures on viscoelasticity theory,A. C. Pipkin, Springer-Verlag
()30%30%40%
98
1
METAL PHYSICS
N152700
3
(06) 275-7575#62154
Office Hours
1.
2.
3.
4. X
5.
6.
7.
8.
98
1
MACHINE TOOL DYNAMICS
N153100
3
Office Hours
1. (3 Hours)
2. (3)
3. : (9)
4. (9)
5. (3)
6. (3)
7. : (3)(3)(3)(3)
40% 40% 20%
98
1
Computer Integrated Manufacturing
N163900
3
Ext. 62147
Office Hours
3,4,6
21
1.
2. CIM
3.
4.
5. CADCIM
6.
7.
8. CAM
9.
10.
1. P. K. Wright, 21st Century Manufacturing, Prentice Hall, New Jersey, 2001.
2. U. Rembold, B. O. Nnaji, A. Storr, Computer Integrated Manufacturing and Engineering, Addison-Wesley, 1993.
3. Kim and Mauborgne,2005
1. 30%
2. 40%
3. 30%
140.116.71.181
91902
98
1
INTEGRATION OF MEMS TECHNOLOGY
N165400
3
62111
Office Hours
CMOSLIGALIGA-like
1.
2. (Introduction to MEMS/MST)
2.1 (Basic semiconductor/IC process)MOS
2.2 (Bulk micromachining)
2.3 (Surface micromachining)
2.4 LIGALIGA-like (LIGA/LIGA-like technology)
2.5 CMOS (CMOS micromachining)
3. (Integration and case study of MEMS technology)
3.1 (Material, interface and process issue)
3.2(-structure) (-sensor) (-actuator)
1. Marc Madou, Fundamentals of Microfabrication, 2nd ed., CRC press, 2002
2. Gregory T.A. Kovacs, Micromachined Transducers Sourcebook, WCB/McGraw-Hill, 1998.
3. 2003.
4. MEMS/NEMS related website/lectures
()30%
30%
()40%
98
1
The technology and application of diamond coating
N170700
Office Hours
1.
2.
3.
4.
5.
6.
7.
CVD
CVD
CVD
CVD
8.
9.CVD
SEM
X
TEM
a)M.A. Prelas, G. Popovici and L.K. Bigelow, Handbook of Industrial Diamonds and Diamond Films. (1998).
b)Davids, R.F., Diamond films and coatings, Noyes publications, (1992)
c)Liu, H.; Dandy, D. S., Diamond Chemical Vapor Deposition: Nucleation and Early Growth Stages., (1995).
d)Bakon, A.; Szymanski, A., Practical uses of Diamond, Ellis Horwood Ltd, (1993).
98
1
()
ROBUST CONTROL
N110100
3
886-6-2757575-62173
Office Hours
(Chain Scattering Matrix Description, CSD)CSDCSDHH
H80/H
1.
2. (Chain Scattering Matrix Description, CSD)
3. J-lossless
4.
5.
6. J-lossless
7. H
8. H
1. K. Zhou, J.C. Doyle and K. Glover, Robust and optimal control. Prentice Hall
2. H. Kimura, Chain Scattering Approach to H control. Birkhauser.
3. Michael Green, David J.N. Limebeer, Linear Robust Control. Prentice Hall
4. Jeffery C. Allen.H-infinity Engineering and Amplifier Optimization. Birkhauser
3.
4.
1. 25%
2. 25%
3. 40%
4. 10%
http://emotors.ncku.edu.tw/script/teach/
62271
98
1
RANDOM DYNAMIC DATA ANALYSIS AND PROCESSING
N151400
3
06-2757575-62152
Office Hours
0
:
1
:
2
:
3
:
4
:
5
:
J. S. Bendat, A. G. Piersol, Random data- analysis and measurement procedures, 3rd, Wisley.
40% 30% 30%
http://rjchang.me.ncku.edu.tw/rj/class3/
98
()
()
Anatomy & Physiology for Engineering
Q550200
Non
3
72692
Office Hours
9-5
to provide students a general sense of biological systems and their anatomy and physiology, from subcellular level, through the tissue, system and individual levels, to the society and ecology levels, on different temporal scales. In addition, the efficiency and functions of biological systems are discussed from the engineering perspective.
1. Subcellular structure
2. Cell structure and function
3. Major systems of human body
4. General physiology and pathophysiology
5. Genetics
6. Evolution & Ecology
98
1
SYSTEM MODELING AND CONTROL
N15A100
(1), (2)
3
62137
Office Hours
1.
2.
Chapter 0: Background: Concept of Closed-loop Control Systems
Chapter 1: ME System Modeling Chapter 2: EE System Modeling
Chapter 3: Bond Graph
Chapter 4: System Identification
Chapter 5: Developing Models from Experimental Data
Chapter 6: Lead/Lag Compensator
Chapter 7: Digital Systems and PID Controller Design
Chapter 8: Pole Placement and State Feedback Controller
Chapter 9: Optimal Control
Chapter 10: More on System Modeling Technique
1. Modeling, Analysis, and Control of Dynamic Systems by William J. Palm ,
2. System Dynamics and Control by Eronini Umez-Eronini, ITP.
3. Modern Control Engineering, 3nd Edition, by Katsuhiko Ogata;
1. (Take-home) Mid-term Exam: 40%
2. (Written) Term Project (Electronic Report): 40%
3. Project Proposal: 5 %
4. Term Project Presentation: 15 %
http://myweb.ncku.edu.tw/~n1894127/web/index.html
Email: [email protected]
98
1
ROBOT ANALYSIS & CONTROL
N162400
3
62175
Office Hours
1.
2.
3.
4.
5.
6.
7.
H. Asada and J.-J. E. Slotine, Robot Analysis and Control, John Wiley and Sons, Inc..
: 30%
: 30%
: 40%
98
2
Transport Phenomena in Manufacturing Processes
N167900
3
62169
Office Hours
1.
2.
3.
4.
5.
6.
7.
S. Kuo, Transport Phenomena an