博士班資格考考試範圍製造組(乙組)

博士班資格考考試範圍

製造組(乙組)

高等機電工程學

1. Mechatronics System and Principle Introduction
2. Mechatronics Instrumentation Software and Hardware 
3. Mechatronics case study (1): Development of an Optical Particle Sizing 
System
4. Mechatronics case study (2): Development of an Auto Dropping Machine for 
Dental Burs
5. Mechatronics case study (3): Automatic Precision Machine Vision-Aided Three-
Axis Alignment System
6.Mechatronics case study (4): Development of The Automated Optical Inspection 
System of Magnetic Core Using Image Processing Technology
7.Mechatronics case study (5): Concentricity Alignment System for Rotary 
Encoder
8.Mechatronics case study (6): The Development of an Automatic PCB Concentric 
Circles Inspection System Using X-Ray Images
9. Mechatronics case study (7): The Development of Bio-Chip
 
 
塑性理論與應用 
1. Yield Criterion
2. Small Deformation Theory and Its Application
3. Large Deformation Theory and Its Application
4. Upper Bound & Low Bound Theorem and Its Application
 
 
高等精密量測學
▓  Principles for different precision length measurements
▓  Straightness measurement
▓  Flatness measurement    
▓  Precision angle measurement
▓  Roundness and sphereness measurement                                   
▓  Surface roughness measurement
▓  Automated measurement using a coordinate measuring machine
▓  Statistical process control
▓  Calibration of a machine tool                                                                     
▓  Composite curve measurement                                                                   
▓  Freeform surface measurement                                                                  
▓  Data processing for reverse engineering (RE)
▓  Image processing measurement                                                                  
▓  Optical metrology
▓  Nano-metrology
Reference textbooks
(1)           Galyer, J. F. W., Shotbolt, C. R., “Metrology for engineers”
(2)           Slocum, A. H., “Precision machine design”.
(3)           Faux, I. D., Pratt, M. J., “Computational geometry for design and 
manufacture”.
(4)           Rogers, D. F., Adams, J.A., “Mathematical elements for computer 
graphics”.
(5)           Mortenson, M. E., “Geometric modeling”.
(6)           Engeln-Muellges, G., “Numerical algorithms with C”.
(7)           Gonzalez, R. C., Woods, R.E., “Digital image processing”.
(8)           Related Journal papers.
 
  
製造分析 
Lecture 1 Introduction 
               .Background 
               .Course Schedule 
               .Manufacturing Processes or System 
               .Definition of Manufacturing Process 
 
Lecture 2 Process Modeling of Manufacturing Processes 
                .Classifying the Nature of Manufacturing Processes 
                .Variation versus Parameters 
                .Process Modeling Methods 
                .Modeling and Analysis for Control 
 
Lecture 3 Analysis of Manufacturing Processes 
                .Analytical Methods 
                .Numerical Methods 
                .Empirical Methods 
                .Optimization Methods 
 
Lecture 4 Material Removal Processes 
                .汹Modeling of Metal Cutting 
                .Feed or Force Control of Cutting Processes 
                .Geometric or Dynamic Modeling of Cutting 
                .Modeling of Grinding 
                .Control of Abrasive Machining Processes 
 
Lecture 5 Ultra-Precision Polishing Processes 
                .汹Modeling of Polishing Processes 
                .Control of Polishing Processes 
                .Modeling of CMP & SAP
                .Control of CMP & SAP 
 
Lecture 6 Precision Molding Processes 
                .Precision Molding Processes: Injection Molding (IM) 
                .Numerical Modeling of IM 
                .Precision Molding Processes: Hot Embossing 
 
Lecture 7 Empirical Modeling of Manufacturing Processes 
                .Trial-and-Error 
               .汹Operation Window 
                .Variations of Parameters or Statistical Methods 
 
Lecture 8 Statistical Modeling Methods 
               .Design of Experiments (DOE) 
               .Fractional Factorial Design 
               .Taguchi’s Method 
                .ANOVA 
                .Test of Random Error 
                .DOE and Empirical Model 
 
材料機械性質
Ⅰ. Materials: Structure, Properties, and Performance
1.            Strength of Materials—Basic Assumption
2.            Average Stress and Strain
3.            Stress–Strain Behaviors for Different Materials
 
Ⅱ. Stress and Strain Relationships for Elastic Behavior
1.            Description of Stress at a Point
2.            Stress Tensor
3.            Description of Strain at a Point
4.            Hydrostatic and Deviator Component of Stress
5.            Elastic Stress–Strain Relations
6.            Strain Energy
7.            Anisotropy of Elastic Behavior
 
Ⅲ. Elements of Theory of Plasticity
1.            The Flow Curve
2.            True Stress and True Strain
3.            Yielding Criteria for Ductile Metals
4.            Anisotropy in Yielding
5.            Yield Surface and Normality 
6.            Octahedral Shear Stress and Shear Strain
7.            Invariants of Stress and Strain
8.            Plastic Stress–Strain Relations
 
Ⅳ. Plastic Deformation of Single Crystals
1.            Concept of Crystal Geometry
2.            Lattice Defects
3.            Deformation by Slip
4.            Slip in Perfect Lattice
5.            Slip by Dislocation Movement
6.            Critical Resolved Shear Stress for Slip
7.            Deformation of Single Crystals
8.            Deformation of Face–Centered Cubic Crystals
9.            Deformation by Twinning
10.          Stacking Faults
11.          Microstrain Behavior
12.          Strain Hardening of Single Crystals
 
Ⅴ. Dislocation Theory
1.            Observation of Dislocations
2.            Burgers Vector and the Dislocation Loop
3.            Dislocation in the Face–Centered Cubic Lattice
4.            Dislocation in the Hexagonal Close–Packed Lattice
5.            Dislocation in the Body–Centered Cubic Lattice
6.            Stress Fields and Energies of Dislocations
7.            Forces on Dislocations
8.            Forces between Dislocations
9.            Dislocation Climb
10.          Intersection of Dislocations
11.          Dislocations Sources
12.          Multiplication of Dislocations
13.          Dislocation–Point Defect Interactions
14.          Dislocation Pile-Ups
 
Ⅵ. Strengthening Mechanisms
1.            Grain Boundaries and Deformation
2.            Strengthening from Grain Boundaries
3.            Low-Angle Grain Boundaries
4.            Yield –Point Phenomenon
5.            Strain Aging
6.            Solid-Solution Strengthening
7.            Deformation of Two-Phase Aggregates
8.            Strengthening from Fine Particles
9.            Fiber Strengthening
10.          Strengthening Due to Point Defects
11.          Martensite Strengthening
12.          Cold-Worked Structure
13.          Strain Hardening
14.          Annealing of Cold-Worked Metal
15.          Bauschinger Effect
16.          Preferred Orientation
 

 

微奈米製造技術

1.      Nanotechnology

Background and definition of nanotechnology

Why nano?

Lessons from nature

Nanofabrication and nanomaterials

Application in different fields

2.      Semiconductor manufacturing techniques

Lithography

Etching

Thin film process

Application in different fields

3.      LIGA process

Lithography

Electroformimg

Molding

Application in different fields

4.      Laser machining

Theory of laser

Excimer laser

Femtosecond laser

Application in different fields

5.      Nanoimprint and Micromolding

Design

Mold

Forming process

Inspection

Application in different fields

 

計算機輔助設計

1.  3D曲線之數學基礎

‧   Cubic spline curve

‧   Bezier curve

‧   B-spline curve

‧   Rational B-spline curve

‧   Non-uniform Rational B-spline (NURBS) curve

2.  3D曲面之數學基礎

‧   Ruled surface

‧   Linear Coons surface

‧   Coons bicubic surface

‧   Bezier surface

‧   B-spline surface

‧   NURBS surface