ee.pccu.edu.twee.pccu.edu.tw/ezfiles/126/1126/img/260/2013-ieet-d---.doc · web...

PAGE

20

21-1

51-2 104101

151-3 101

192-1

203-1 (91)

214-1

414-2 101

1344-3

1374-4

1495-1

1-1

101

-Gamelan

100

Quad-Theremin()

()

Android

FPGADE2-70

99

Zigbee()

PSoC

98

8051Microcontroller()

FLASH

High-k

()

CANbus

1-2 104101

-

Total

59

100.0%

/

2

3.4%

36

61.0%

7

11.9%

14

23.7%

Q1. /

Total

21

100.0%

8

38.1%

13

61.9%

0

.0%

Q2.

Total

38

100.0%

9

23.7%

29

76.3%

0

.0%

Q3. (10

Total

59

100.0%

31

52.5%

41

69.5%

38

64.4%

37

62.7%

16

27.1%

30

50.8%

9

15.3%

15

25.4%

5

8.5%

4

6.8%

25

42.4%

9

15.3%

32

54.2%

19

32.2%

4

6.8%

11

18.6%

3

5.1%

16

27.1%

3

5.1%

4

6.8%

13

22.0%

18

30.5%

13

22.0%

2

3.4%

4

6.8%

0

.0%

Q4. /?

Total

Q4_1.

59

6

21

17

15

0

0

0

100.0%

10.2%

35.6%

28.8%

25.4%

.0%

.0%

.0%

Q4_2.

59

3

22

21

11

2

0

0

100.0%

5.1%

37.3%

35.6%

18.6%

3.4%

.0%

.0%

Q4_3.

59

7

19

18

14

1

0

0

100.0%

11.9%

32.2%

30.5%

23.7%

1.7%

.0%

.0%

Q4_4.

59

5

17

18

17

2

0

0

100.0%

8.5%

28.8%

30.5%

28.8%

3.4%

.0%

.0%

Q4_5.

59

4

15

18

20

2

0

0

100.0%

6.8%

25.4%

30.5%

33.9%

3.4%

.0%

.0%

Q4_6.

59

5

12

17

21

3

1

0

100.0%

8.5%

20.3%

28.8%

35.6%

5.1%

1.7%

.0%

Q4_7.

59

4

17

21

14

2

1

0

100.0%

6.8%

28.8%

35.6%

23.7%

3.4%

1.7%

.0%

Q4_8.

59

4

19

21

13

1

1

0

100.0%

6.8%

32.2%

35.6%

22.0%

1.7%

1.7%

.0%

Q4_9.

59

4

19

23

11

1

1

0

100.0%

6.8%

32.2%

39.0%

18.6%

1.7%

1.7%

.0%

Q5. /()

Total

59

100.0%

36.

59

100.0%

36.

Q6. /?

Total

59

100.0%

45

76.3%

10

16.9%

4

6.8%

36.

Q7. /?

Total

59

100.0%

0

.0%

0

.0%

0

.0%

2

3.4%

1

1.7%

0

.0%

MIS

7

11.9%

24

40.7%

5

8.5%

15

25.4%

1

1.7%

4

6.8%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

36.

Q8. /?

Total

59

100.0%

20,000

0

.0%

20,001-22,000

0

.0%

22,001-25,000

4

6.8%

25,001-28,000

3

5.1%

28,001-30,000

7

11.9%

30,001-35,000

19

32.2%

35,001-40,000

16

27.1%

40,001-45,000

9

15.3%

45,001-50,000

1

1.7%

50,001-55,000

0

.0%

55,001-60,000

0

.0%

60,001

0

.0%

36.

Q9. /?

Total

59

100.0%

28

47.5%

15

25.4%

24

40.7%

27

45.8%

11

18.6%

28

47.5%

3

5.1%

1

1.7%

Q10-Q23.()

36.

Q10.

Q11.

Q12.

Q13.

Q14.

Q15.

Q16.

Q17.

Q18.

Q19.

Q20.

Q21.

Q22.

Q23.

Q10-Q23.()

Total

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

59

100.0%

3

5.1%

4

6.8%

4

6.8%

6

10.2%

3

5.1%

2

3.4%

4

6.8%

5

8.5%

4

6.8%

4

6.8%

8

13.6%

2

3.4%

4

6.8%

4

6.8%

30

50.8%

29

49.2%

25

42.4%

19

32.2%

26

44.1%

21

35.6%

21

35.6%

24

40.7%

21

35.6%

26

44.1%

22

37.3%

25

42.4%

27

45.8%

27

45.8%

17

28.8%

15

25.4%

16

27.1%

15

25.4%

16

27.1%

17

28.8%

21

35.6%

15

25.4%

17

28.8%

18

30.5%

16

27.1%

17

28.8%

16

27.1%

15

25.4%

8

13.6%

9

15.3%

12

20.3%

15

25.4%

10

16.9%

14

23.7%

8

13.6%

13

22.0%

15

25.4%

7

11.9%

11

18.6%

11

18.6%

10

16.9%

13

22.0%

1

1.7%

1

1.7%

2

3.4%

3

5.1%

3

5.1%

3

5.1%

3

5.1%

2

3.4%

2

3.4%

4

6.8%

2

3.4%

4

6.8%

2

3.4%

0

.0%

0

.0%

1

1.7%

0

.0%

0

.0%

1

1.7%

2

3.4%

2

3.4%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

1

1.7%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

0

.0%

Q24. /

Total

59

100.0%

5

8.5%

37

62.7%

17

28.8%

0

.0%

0

.0%

/

0

.0%

Q25. ///

Total

59

100.0%

53

89.8%

6

10.2%

/

Total

59

100.0%

6

10.2%

14

23.7%

12

20.3%

0

.0%

0

.0%

1

1.7%

1

1.7%

21

35.6%

0

.0%

1

1.7%

0

.0%

0

.0%

2

3.4%

1

1.7%

0

.0%

0

.0%

0

.0%

/

Total

59

100.0%

0

.0%

()

23

39.0%

9

15.3%

7

11.9%

3

5.1%

10

16.9%

1

1.7%

0

.0%

0

.0%

1

1.7%

3

5.1%

1

1.7%

1

1.7%

0

.0%

0

.0%

0

.0%

0

.0%

/

Total

59

100.0%

1-29

8

13.6%

30-99

5

8.5%

100-249

17

28.8%

250-499

6

10.2%

500

23

39.0%

-

Total

59

100.0%

51

86.4%

8

13.6%

-

Total

59

100.0%

()

1

1.7%

11

18.6%

/

31

52.5%

()

16

27.1%

-

Total

59

100.0%

20

0

.0%

21-30

3

5.1%

31-40

39

66.1%

41-50

12

20.3%

51-60

5

8.5%

61

0

.0%

- /

Total

59

100.0%

1()

1

1.7%

1-3()

14

23.7%

3-5()

12

20.3%

5-10()

19

32.2%

10

13

22.0%

1-3 101

(101)

1. Windows(prototype)WindowsIEET 2014

2. APPIEET 2014

3. (GPU)IEET 2014

4.

5. -Gamelan

102

1. 2014IEET102/

2. ()

3. ()

4.

5. /

1. /APP/

(a) KinectWin7Kinect

(b) /

(c) /

2. /()(//)

(a) Electrical dipole(pattern)

(b) /(photonic crystal)90/60

(c) diodeI-V curveMOSFETC-V curve

3. ///

2-1

101

98244591

100

97244180

97244384

97244368

97244554

99

96244224

96244569

96244542

98

95245529

95245049

95245120

97

94245509

3-1 (91)

91

91

SOC

94

95

95

95

95

96

96

IC

97

98

2009

98

98

99

99

100

100

101

LED

101

IC

102

4-1

384()

/

(V)

1

3

2

3

3

1

3

3

1

2

3

2

3

3

1

3

3

3

1

2

1

3

3

3

3

1

V

2

2

2

2

2

2

1

3

3

3

1

V

3

3

3

3

3

3

1

V

3

3

3

3

3

2

1

V

2

3

3

3

3

1

V

3

1

V

3

1

V

2

2

(7)

0

A

37

70

34

B

128()

A/B

28.9%

54.7%

26.6%

IEET4

32(25)

48

(37.5)

121()

/

(V)

1

3

2

0

3

3

1

3

3

1

2

0

3

2

3

3

1

3

3

3

0

1

1

2

3

3

3

3

2

1

V

1

2

3

3

3

3

3

3

1

V

2

0

3

3

3

3

3

3

2

1

V

2

0

3

3

3

1

V

1

(6)

0

3

2

2

0

3

1

V

(7)

0

0

2

0

3

3

(8)

0

A

40

67

32

B

128()

A/B

31.25%

52.3%

25%

IEET4

32(25)

48

(37.5)

333()

/

(V)

1

3

2

0

3

3

1

3

3

1

2

0

3

2

3

3

1

3

3

3

0

1

2

0

3

3

3

3

2

1

V

2

0

3

3

1

V

3

3

3

3

3

2

2

0

3

3

3

3

1

V

3

3

3

1

V

(6)

0

3

2

3

1

V

3

3

3

1

V

1

V

2

(7)

0

0

3

3

(8)

0

A

41

71

28

B

128()

A/B

32%

55.5%

21.9%

IEET4

32(25)

48

(37.5)

317()

/

(V)

1

3

2

3

3

1

3

1

3

2

3

2

3

3

1

3

3

2

3

2

3

3

3

3

3

2

1

V

1

2

3

3

3

3

3

3

1

V

2

3

3

3

3

3

3

1

2

1

2

2

3

3

3

1

3

2

3

3

3

1

V

1

V

2

1

3

3

3

A

38

72

36

B

128()

A/B

29.7%

56.3%

28.1%

IEET4

32(25)

48

(37.5)

082()

/

(V)

1

3

2

3

3

1

3

3

1

2

3

2

3

3

1

3

3

3

1

1

3

3

3

3

1

V

2

2

2

2

1

3

3

3

1

V

3

3

3

3

3

1

V

3

3

3

3

3

2

2

3

1

3

1

3

3

3

3

2

3

3

3

1

V

3

3

3

A

37

88

28

B

128()

A/B

28.9%

68.8%

22.4%

IEET4

32(25)

48

(37.5)

4-2 101

()

Engineering Mathematics (II)

6003

3

/

()

1

2008 (http://faculty.pccu.edu.tw/~meng/Mathjiangyi.htm)

(Theories of Systems)

1. Laplace transform solutions of linear systems

2. Matrix Solutions of Linear Systems

3. Nonlinear Systems and Phase Planes

4. Sturm-Liouville Theory

124

1

A.

B.

2

4

(Complex Numbers, Functions, and Operators)

1. Complex Numbers and Complex Functions

2. Complex Operators

3. Elementary Complex Functions

124

(Integration in the Complex Plane)

1. Complex Line Integrals and Some Integral Theorems

2. Laurents Theorem & the Residue Theorem

3. Evaluation of Real Integrals in the Complex Plane

124

(Complex Sequence and Series)

1. Sequence and Series

2. Complex Taylors Series & Laurents Series

3. Summation of Series by the Residue Theorem

4. Infinite products

124

(Conformal Mapping)

1. Introduction

2. Conformal Mapping

124

(Special Functions)

1. Gamma & Beta Functions

2. Bessel Differential Equations and Bessel Functions

3. Legendre Differential Equations and Legendre Polynomials

4. Applications of Bessel and Legendre Functions

124

2

1. http://faculty.pccu.edu.tw/~meng/Mathjiangyi.htm

2.

3. 2()

4. 9697

Linear Algebra

2184

3

/

1

Gareth WilliamsLinear Algebra with Applications7th edition, Jones and Bartlett, 2011.

Linear Equations, Vectors, and Matrices

(,)

1. Linear Equations and Vectors

2. Matrices and Linear Transformations

3. Determinants and Eigenvectors

124

1

2

/////

4

Vector Spaces

()

1. General Vector Spaces

2. Coordinate Representations

3. Inner Product Spaces

124

Numerical Linear Algebra()

1. Numerical Methods

2. Linear Programming

124

2:1. Gilbert Strang , Introduction to Linear Algebra, 4th Edition Publication 2009. 2. Otto Bretscher, Linear Algebra With Applications, 4th Edition,Prentice Hall, 2009.

Electro-optic Engineering

F716

: 3

3

/

: Basic Physics

1

()

Nature of light()

1. Historical theories about light

2. Electromagnetic spectrum

3. visible light

4. Particle theory

5. Wave theory

6. Quantum theory

124

1

2

4

Radiometry and Photometry()

1. Radiometry

2. Photometry

3. Colorimetry

124

Geometric Optics

()

1. Ray optics

2. Reflection of light

3. Law of reflection

4. Refraction of light

5. Law of refraction

6. Total internal reflection

7. Dispersion

124

Optical devices

()

1. Plane mirror, Parabolic mirror, Spherical mirror, Lens.

2. Grating, Zone plate

3. Lasers, Beam splitter, Prisms

4. Waveplate, Polarizer

5. Optical fiber

124

Wave Optics

()

1. Polarization

2. Diffraction

3. Interference

4. Coherence

5. Fourier Optics

124

2

1)S. O. Kasap, "Optoelectronics and Photonics" Prentice Hall, 2001.

2)E. Hecht, Optics, 4th Edition, Addison Wesley, New York, 2002.

3)F. T. S. Yu and X. Yang, Introduction to Optical Engineering, Cambridge Univ. Press, United Kingdom, 1997.

4)J. W. Goodman, Introduction to Fourier Optics, 3rd Edition, Roberts & Company, Colorado, 2005.

5)U. Schnars and W. Jueptner, Digital Holography, Springer-Verlag, Berlin Heideberg, 2005.

6)-

7)

Electromagnetism

2304

3

/

MaxwellMaxwell

1

2008 (http://faculty.pccu.edu.tw/~meng/EMJiangyi.htm)

(Electromagnetic Field Theory)

1. Electric Fields and Electric Dipoles

2. Static Electric Potentials

3. Magnetic Fields

4. Electromagnetic Forces

5. Faradays Law and Magnetic Dipoles

124

1

2

4

Maxwell(Maxwells Equations and Plane EM Waves)

1. Dielectric and Conductor

2. Boundary Conditions of Electromagnetic Fields

3. Steady-state Currents

4. Maxwells Equations and Plane EM Waves

5. Plane EM waves in a Simple region and a Lossy Media

124

(Plane EM Waves and Lasers in Distinct Media)

1. Normal & Oblique Incidences at a Plane Conducting Boundary

2. Normal & Oblique Incidences at a Plane Dielectric Boundary

3. Total Reflection and Critical Angle

4. Normal Incidence at Three-layer Dielectric Interfaces

5. Optical Theory of Multi-Layer Films and Fabry-Perot Resonators

6. Lasers and General Optical Resonators and Laser Modes

7. Gratings and Photonic Crystals

124

(Selected Topics for Circuits and Systems)

1. Poissons and Laplaces Equations

2. Boundary-Value Problems in Various Coordinates

3. Capacitors and Capacitances

4. Electrostatic Energy, Forces and Torques

5. Resistors and Resistances

6. Inductors and Inductances

7. Magnetic Energy, Forces and Torques

8. Magnetic Circuits

124

2

1. http://faculty.pccu.edu.tw/~meng/EMJiangyi.htm

2.

3.

Electromagnetic Waves

6088

3

/

1

2008 (http://faculty.pccu.edu.tw/~meng/EMJiangyi.htm)

(Transmission Lines)

1. Characteristics of Transmission Lines

2. Wave Characteristics of Finite Transmission Lines

3. Introduction to Smith Chart

1234

1

2

3

4

(Metallic Waveguide and Cavity Resonators)

1. General Metallic Waveguides

2. ParallelPlate Waveguides

3. Rectangular & Circular Metallic Waveguides

4. Rectangular & Circular Cavity Resonators

5. Excitations of Metallic Waveguides

124

1

2

4

(Dielectric Waveguides and Some Selected Topics for Photonics)

1. Introduction to Integrated Optics

2. Basic Integrated Optoelectronic Devices

3. Dielectric Slab Waveguides in the Free Space

4. Optical Fibers

5. Planar Optical Waveguides

6. Rectangular Optical Waveguides

7. Diffused Waveguides

8. Direct Coupling from Laser to Waveguide

9. Theory of Crystals

10. Theory of Photonic Crystals

124

(Antenna Theory)

1. Calculation of EM Fields of Antennas

2. Radiation Patterns of Antennas

3. Linear Dipole Antennas and Effective Lengths

4. Travelingwave Antennas

5. Helical Antennas

6. Antenna Arrays

7. Effective Areas of Antennas and Gains

8. Friis Transmission Formula and Radar Equation

9. Wave Propagation near Earths Surface

10. Broadband Antennas

11. Waveguide Antennas

12. Reflector Antennas

13. Aperture Antennas

1234

1

2

3

4

2

1. http://faculty.pccu.edu.tw/~meng/EMJiangyi.htm

2.

3. 10

Modern Physics

2134

3

/

Basic Physics

1

Arthur Beiser, Concepts of Modern Physics, 6th Ed. 2010.

Relativity()

1. Einstein's Postulates

2. Time Dilation

3. Length Contraction

4. Doppler Effect

5. Twin Paradox

6. Relativistic Momentum

7. Relativistic Energy

124

1

2

4

Quantization()

1. Quantization

2. Blackbody Radiation

3. Photoelectric Effect

4. Compton Effect

124

Wavelike Properties of Particles()

1. The de Broglie Hypothesis

2. Particle Wavelength

3. Wave Packets

4. The Uncertainty Priciple

5. Wave-Particle Duality

124

Atom Model()

1. Atom Spectra

2. Rutherford Nuclear Mode

3. Bohr H Atom Model

4. X-ray Spectrum

5. Franck-Hertz Experiment

124

Schrodinger Equation()

1. 1-D Schrodinger Equation

2. Square Well

3. Expectation Values and Operators

4. The Simple Harmonic Oscillator

5. Reflection and Transmission of wave

124

Atomic Physics()

1. 3-D Schrodinger Equation

2. Angular Momentum, Energy Wave Functions in H Atom

3. Electron Spin

4. Angular Momentum

5. Spin-Orbit Interaction

6. Ground States of Atoms and Periodic Table

7. Excited States

8. Spectra of Atoms

124

Molecular Structure and Spectra()

1. Bonding Mechanism

2. Molecule Energy Levels

3. Spectra

4. Scattering, Absorption and Stimulated Emission

5. Laser

124

2:1. Thornton and Rex, Modern Physics for Scientists and Engineers, 4th Ed.2012. 2. J.R.Taylor, C.D. Zafiratos & M.A. Dubson, Modern Physics for scientists and engineers, second edition, Prentice Hall, Inc.2004.

Signals and Systems

3522

3

/

:(1) (2) (3) (4)Z (5) (6)

1

Signal and System Analysis Simon Haykin & Barry VanVeen 2003 John Wiley & Sons, Inc.

-

1.

2.

3.

124

1

2

4

(LTI)

1.

2.

3.

4.

124

1. ((FS,DTFS), (DTFT,FT))

2.

3. Convolution

124

Z

1. Z

2. Z

3. Z

124

1. :

2. :

3. Various Matrices

4. Special Characteristics of Matrices

5. Bilinear Forms

124

1. Matlab

2.

124

2

1. PowerPoint

2.

3.

Probability and Statistics

6277

3

/

Axioms,,,,Moment,,,,.(),

1

Peyton Z.Peebles, JR.Probability,Random Variables and Rrandom Singal Principles McGraw-Hill International Edit 2001 Mcgraw-Hill

Probability:Introduction

1. Sets and algebra

2. 3 Axioms and their corollaries

3. Bayes thm

124

1

2

4

Random Variables

1. Definition

2. Distribution function and density function

3. Gaussian random variable

4. Other density functions

124

Operations on One Random Variables

1. Mean,variance and moments of random variable

2. Inequality-Chebycheves, Markovss

3. Transformation of rvs.

4. Computer generation of rvs

124

Multiple Random Variables

1. Vector rvs

2. Joint and conditional distribution

3. Statistical Independence

4. Central-limit-thm

124

Opertions on Multiple Random Variables

1. Function of rvs

2. Linear transformation of Gaussian rv.s

3.

124

Random Processces:General

1. Random process concept

2. Stationarity and Independence

3. Correlation function

124

Gaussian and Poissons Processes

1. Their distribution functions and relative moments and indpendece properties

124

Spectral Characteristics of Random Processes and Linear Systems With Random Inputs

1. Power spectrum density and autocorrelation function

2. System operated on input power spectrum

124

Estimation-Point Estimation

Maximum Likelihood estimate, Estimate using moments

124

Estimation-confidence interval and sample size

1. Confidence interval for mean and variance

2. F distribution and t-distribution

124

Test of Statistical Hypotheses and Applications: Detection (False Alarm Prob and Threshold)

1. Test about proportion

2. Test about mean and variance

3. Application on detector of signal

124

2

1.

2. 982()

3.

Communication System

6438

3

/

:,

1

Ziemer and Tranter "Principles of Communications"2002 John Wiley & Sons, Inc

-

1.

2.

3.

124

1

2

4

1.

2.

3.

4. convolution

5. Hilbert

124

-DSB, AM, SSB, VSB

1. (DSB)

2. (AM)

3. (SSB)

4. (VSB)

124

(FM)

1. FM(NBMF)

2. FM(WBFM)

3. FM

4. NBFMWBFM

5. FM

6. PLL FM

124

PCM

1.

2.

3. T1 ~T4

4. TDMA

124

1.

2. DSB,SSB,AM,FM(SNR)

124

PSTN

1. PSTN

2.

124

2

1. class notes

2.

Digital Communications

9905

3

/

Lab 6-1(), Lab 6-2:

(Shannon-),Huffman coding,Delta,CVSD DM, PCM, ADPCM, CELP, VSELP,,,,,,Turbo, (ASK, FSK, PSK, MSK),,.

1

Class notes by Dr. Liu

Bernard Sklar "Digital Communications-Fundamental and Applications" 2001 Prentice Hall

Digital Communication system (Introduction

Easy-Kit Lite (ADSP-2181)

[module]

124

1

2

4

Information Theory Intro.

Entropy- Shannons First Coding Thm. (Source Coding Thm),Huffman Code Mutual Information-Shannons second Coding Thm(Channel Coding Thm)

Hartley-Shannon Thm.

124

PCM, ADPCM, DM, CVSD- DM,CELP,VSELP,MP3

Source Coding

124

Digital Signaling Technique

Baseband SignalingBi-Phase Coding

124

Detection of Binary Signals in Noise

Detection and ClassificationLRT (Likelihood Ratio Test)RZ and NRZ

124

Match Filtering

Match filterSNRcorrelator

124

Modulation:ASK, FSK, PSK, QPSK

124

Modulation:MSK, pi/4 shiftQPSK,OFDM

blue-tooth

124

Error-Control Coding Cyclic Code

Channel CodingHamming code, BCH code

124

Convolution Code

CodingViterbi

124

Trellis code, Space Time Code, Turbo Code)

Three modern coding techniques currently used

124

Bit/ Frame, Carrier Synchronization Techniques, Fading and Diversity

Clock synchronization, square and PLL, Fading \Multi-antenna system,

124

PSTN ,Mobile Communication Intro.,

frequency reuse in Mobile system,

124

2

1.

2. ProakisContemporary Communication System using MatlabMatlab Program code

3.

Digital Signal Processing

6281

3

/

:(FFT)Z-FIRIIR:DTMFDelta-Sigma A/D, D/AMatlab

1

+Sophocles OrfanidisIntroduction to Signal processing1996 Prentice-Hall, Inc

-

1.

2.

3.

124

1

2

4

DTFT

1.

2. Power meter

3. DTFT

124

Z

1. Z

2. (SFG)

3. :Direct FormIndirect FormFIR Lattice structure

124

DFTFFT

1. ZDFT

2. FFTdecimation in Time

3. FFTBit-Reversalzero-Pedding

4. Picket fence effect

5. Chirp Transform

124

IIRFIR

1. IIR(Design by Transform methods:Impulse Invariant,umerical,Bilinear)

2. FIR(Fourier Approximation)

3. WindowingKaiser Window

4. Proto-type IIR FilterConformalapping

124

Comb and string Filters

1. Comb filter

2. allpass filter

124

CD

1. Oversamplingdecimation filter

2. Multi-stage decimation filter

3. Poly-phasedecimation Filter

124

Delta-Sigma A/D,D/A

1. noise shaping

2. Noise shaping filter

124

2

1. Homework projects

2.

Digital Control

2971

3

/

Lab 6-1(), Lab 6-2:

,,Matlab Control Tool BoxSIMULINKDSP,,Z-.

1

Digital Control Using Digital Signal Processing, Farzad Nekoogar , Gene Moriarty Prentice Hall International. 1999 Prentice Hall.

Introduction to Digital Control using Digital Signal Processing

Digital vs. Analog Control, Classical vs Modern control, Design process overview

124

1

2

4

Mathematical Methods of Discrete Systems-time domain

Difference equations and their solution

124

Mathematical Methods of Discrete Systems-Frequency domain

z-transform and frequency response

124

Analysis of Discrete System- Sampled-data system, state-variable system

Open(closed)-loop sample-data structure, A/D, D/A, State-variable representation of system and its conversion between transfer function

124

Analysis of Discrete System-stability

Routh-Hurwitz stability method, Liapunnov method

124

Design of Digital Control Systems

Dynamic resonse parameters, Steady -state parameters, Root-locus method, Bode plots, Phase lead, lag compensator, PID compensator, Deadbeat controller

124

DSPs in Control System

DSPDSP chip

124

Modern Design Techniques and their Applications

Controbility and pole-placement controbility-Ackermanns Formula, Observability and state estimation, Linear quadratic optimal design

124

2

1.

2. Matlab

3.

Communication and DSP Lab

6511

3

/

Lab 6-1(), Lab 6-2:

:

1. ED-297010

2.ADSP-2181 Easy Kit Lite16

1

Lab Manual "Digital Communication ED-2790"

Rotgers University

DSP Board Guidance and Install [General Guidance]

Easy-Kit Lite (ADSP-2181)

[module]

1234

1

2

3

4

Assembler Dir. and Macro [Ex-1 Intro. signalling ]

ADSP-2181(Assembler directive, Module, Macro, Command instruction set)

[]

1234

Sampling and Quantization [Ex-2 Noise in System]

Aliasing

[]

1234

Delays [Ex-3 Clock Gen.]

[]

1234

FIR Filters [Ex-4 ASK]

FIR

[]

1234

Comb Filter [Ex-5 Clock Regen.]

Comb Filter

[Bi-Phase Code]

1234

Plain Reverb Filter [Ex-6 FSK]

[:PLL]

1234

AllPass Reverb Filter [Ex-6 FSK]

[:PLL]

1234

LowPass Reverb Filter [Ex-7 PSK]

[]

1234

Schroeder's Reverb Filter [Ex-7 PSK]

Schroeder

[]

1234

Stereo Reverb [Ex-8 PSK/DSBSC]

[PSK]

1234

Reverberating Delay [Ex-8 PSK/DSBSC]

[PSK]

1234

Karplus-Strong String Algorithm [Ex-9 QPSK Gen.]

[]

1234

Wavetable Gen. [Ex-9 QPSK Gen.]

WavetableAM FM

[]

1234

Notch Filter [Ex-10 QPSK Rec.]

Notch

[]

1234

Flangers and Phasers [Ex-10 QPSK Rec.]

[]

1234

2

1.

2. Report progress each week (DSP Lab Lab)

Electrical Circuitry Lab

D601

1

/

N/A

Understand the basic concepts of circuits

1

2008 (http://www.pccu.edu.tw/)

Introduction to Laboratory Equipment

1. Power Supply

2. VOM meter

3. other laboratory equipments

1 2 3 4

1

2

3

4

Resistors: Parallel & Serial Connection

1. Recognize the resistors

2. Parallel connection of resistors

3. Series connection of resistors

1 2 3 4

Measurements of Current and Voltage

1. Understand how to measure current and voltage of electronic components

1 2 3 4

Serial Parallel Circuit

1. Measure the resistance of more complex circuits

1 2 3 4

Superposition Analysis

1. To study & verify the superposition of a linear circuit

1 2 3 4

Nodal Voltage & Mesh Current Analysis

1. Analyze & Verify the Nodal Voltage

2. Analyze & Verify the Mesh Current methods

1 2 3 4

Thevenin and Norton Equivalent Circuit

1. Analyze & Verify the Thevenin Equivalent Circuit

2. Analyze & Verify the Norton Equivalent Circuit

1 2 3 4

Introduction to Functional Generator and Oscilloscope (1)

1. To learn how to the concepts and operations of Functional Generator

1 2 3 4

Introduction to Functional Generator and Oscilloscope (2)

1. To learn how to the concepts and operations of Oscilloscope

1 2 3 4

RC Circuit Analysis

1. The transient response of RC circuit

1 2 3 4

Frequency Response

1. To learn how to measure the frequency response of AC circuit

1 2 3 4

Introduction to Inductance

1. Learn how to recognize the inductors

2. Learn how to measure the inductance

1 2 3 4

RLC circuit

1. Test a RLC circuit

2. Measure the frequency respose

1 2 3 4

2

1.

2.

3.

4. 9697

Electric Machines

6058

2

/

Basic Circuit Theory and Physics

1

S. Chapman, Essentials of Electric Machinery Fundamentals, 1st Eds, McGraw-Hill, 2005.

1.

2.

1 2 4

1

2

/////

4

1.

1 2

1

2

/////

1.

2.

1 2 3 4

1

2

/////

3

4

2

1.

2.

Design of Digital Systems

6276

3

/

Basic Logic Theorems, including Boolean algebra, logic gates, etc.

1

Donald D. Givone, Digital Principles and Design, International Edition McGraw-Hill, 2003.

Introduction to Basic Logic Devices

1. the properties of TTL & CMOS

2. Boolean Algebra

1 2 3 4

1

2

3

4

Intro. to Combinational Circuit

1. multiplexers, decoders, BCD decoder

2. comparator, even/odd parity generator,

3. half and full adder, etc

1 2

1

2

Latch and Flip-Flop

1. Latch

2. Flip-flop

1 2

Sequential Circuit

1. Analysis of Sequential circuit

2. Synthesis of sequential circuit

1 2

Applications of Logic Circuit

1. Counter

2. Practical logic circuit

1 2 3 4

1

2

3

4

2

1.

2.

3. FPGA

4. 9697

Digital Image Processing

6788

3

/

Signal Processing and Computer Language Skills

This course explores the digital image processing theorems

1

Introduction to Digital Image Processing with Matlab, Alasdair McAndrew, Thomson Learning, Inc, 2004.

1. Basic Concepts of Digital Image Processing

1

1

Matlab

1. Intro. to Matlab

2. How to use Matlab to process image

1 2

1

2

&

1. Intro. to Point Processing

2. Neighboring Process for Digital Image

1

1

1. Geometry for Image Processing

1 4

1

4

1. Intro to Different Color Spaces

2. The conversion between different color spaces.

1 4

1

4

1. Topology of Digital Image

1

1

1. The frequency analysis of digital image

1 3 4

1

3

4

1. The shape of objects in an image

2. The boundary detection of objects

1

1

2

1.

2.

3. Matlab

4. 9697

Electronic Circuitry Lab

6005

1

/

Basic Circuit Concept and Electronic Components

Learn the properties of electronic componetns

1

2008 (http://www.pccu.edu.tw/)

PN Diode

1. Intro. to PN Diode

2. Analysis of IV chart

1 2 3 4

1

2

3

4

Rectifier Circuit and DC Power Supply

1. Intro. to Rectifier circuit

2. By using PN diode to do the rectifier circuit

1 2 3 4

Introduction to BJT Transistor

1. Intro. to BJT transistors


1 2 3 4

Common Emitter Amplifier

1. Use BJT circuit to do CE amplifier

2. Measure the amplification rate

1 2 3 4

Common Collector Amplifier

1. Use BJT circuit to do CB amplifier

2. Measure the amplification rate

1 2 3 4

Operational Amplifier

1. Intro. to OP AMP

2. Analysis of different OP AMP circuits

1 2 3 4

Introduction and Application of FET

1. Intro. to FET


1 2 3 4

Miscellaneous Circuit Using TTL or Operational Amplifier, etc

1. Analysis of different amplification circuits

1 2 3 4

2

1.

2.

3.

4. 9697

Multimedia Engineering

A567

3

/

Linear Algebra and Calculus

To learn basic concepts of multimedia system

1

Fundamentals of Multimedia, Ze-Nian Li and Mark S. Drew, Prentice Hall, 2004.

Introduction

()

1. Introduction to Multimedia Concepts

2. Applications of Multimedia

1 2

1

2

Image Representations ()

1. Graphic and Image Data Representation

2. Intro. to some popular image file types, such as BMP, JPEG.

1

1

Color of Still Image and Video ()

1. Color Image and Video

2. Intro. to Different Color Spaces

3. Explain the way of human seeing colors

1

Video ()

1. Fundamental Concepts of Video

1

Lossles Compression ()

1. Lossless Compression Algorithm

2. Basic concepts of compression

1 4

1

4

Lossy Compression()

1. Image Compression Standard

2. Intro. to Different codec

1

1

Video Compression ()

1. Basic Video Compression

2. The process of video compression

1 2 3 4

1

2

3

4

MPEG (MPEG)

1. MPEG Standard

1 2 4

1

2

4

2

1.

2.

3. 9697

Control System

6010

3

/

Basic Circuit Theory and Engineering Mathematics

Learn the Control Systems and Mathematical Models

1

Benjamin C. Kuo and Farid Golnaraghi, Automatic Control Systems, 8th Eds., John Wiley & Sons, Inc., 2003

1. Introduction to Control System

2. Applications of Control System

1 2 4

1

2

4

1. Mathematical Foundation

2. Laplace Transform

3. Linear Algebra

1

1

1. Transfer Function, Block Diagrams, Signal-Flow Graphs

1

1. Mathematical Modeling of Physical Systems

1

1. State-Variable analysis

1 4

1

4

1. Stability of Linear Cntrol Systems

1

1

1. Time-Domain analysis of Control Systems

1 2 4

1

2

4

1. Root-Locus Technique

1 2 3 4

1

2

3

4

2

1.

2.

3. 96, 9798

Logic Design

6249

3

/

N/A

Learn and handle Boolean Algebra and Basic Logic Operations

1

Donald D. Givone, Digital Principles and Design, International Edition McGraw-Hill, 2003.

1. Intro. to Logic Design

2. The applications of logic circuit

1

1

1. convert different number system

2. binary, octal, decimal, hexadecimal

3. Complement number

4. Operations of numbers

5. Coded number, i.e. BCD

1

1. Intro. to Boolean Algebra

2. The operations of Boolean Algebra

1

1. Intro. to Karnaugh map

2. How to use Karnaugh map to simplify a Logic circuit

1 2 4

1

2

4

1. Use tabular method to simplify a logic cirucit

1 2

1

2

1. The basic combinational circuit

2. Intro. to basic combinational circuit

3. Intro. to Half Adder, Full Adder, Comparator, and other useful logic circuits

1 2 3 4

1

2

3

4

2

1.

2.

3. 96, 9798

Introduction to Computer

7236

3

/

CCFortranCCCMicrosoft Word, Excel, Power Point, Front Page,

1

C, , ,

1.

2. CPU

3.

4.

4

4

1.

2. ASCII code

3.

4.

5. 2s complement

24

2

4

MS-DOS/WinXpWinXp

1. Window XP

2. DOS

124

1

2

4

TurboC

1. TurboC

2. TurboC editor

3. TurboC compiler

4. Program execution

124

1.

2.

3.

4.

5.

6.

124

1. printf()

2. scanf(), getch(), gets()

124

1. Arithmetic operators

2. Logic operators

3. Results assignments

124

1. For loop

2. While

3. Do while

4. Break

5. Continue

124

1. If else

2. Switch

3. Go to

124

2

1. ap1.pccu.edu.tw/newAp/frame/apMain.asp?ApGUID={B0D96431-819E-42D5-AAA0-C1398729D01B}

2.

3.

Programming Language and Lab

D391

3

/

CC

1

C, , ,

Array and pointer

1. Array

2. Pointer

3. N-dimensional array

1234

1

2

3

4

Function

1. Function type

2. Parameter passing

3. Math lib

1234

Preprocessor

1. #if

2. #define

3. macro

1234

character and string function

1. character functions

2. string functions

1234

File input/output

1. fopen, fclose

2. fscanf, fprint

1234

Command line argument

1. parameter count

2. parameter access

1234

Final Project

1. optimization problems

2. simulation problems

1234

2

1. http://ap1.pccu.edu.tw/newAp/frame/apMain.asp?ApGUID={B0D96431-819E-42D5-AAA0-C1398729D01B}

2.

3.

Data Structure

2314

3

/

Stacks, Queues, Linked Lists, Trees, Hashing(Complexity)

1

C.

Fundamentals of Data Structures in C, Horowitz, Sahni, Anderson-Freed, 2nd ed.,

Data structure and algorithm

1.

2. (Algorithm)

3. (program)(programming)

124

1

2

4

Complexities

1. Space Complexity

2. Time Complexity

3. Asymptotic Notations

4. trade-off between program space and execution time

124

Arrays

1. Storage

2. References

3. Common operations

4. N-dimensional array

124

Stack

1. Basic operations

2. Stack applications

124

Queue

1. Basic operations

2. Circular queue

3. Queue application

124

Linked list

1. Linked list

2. Singly Linked List

3. S.L.L. operations

4. S.L.L. applications

124

Double Linked list

1. Double Linked List

2. D.L.L. operations

3. Memory allocation strategy

4.

124

Tree

1. Tree

2. Binary tree

3. Binary Tree Traversal

4. Binary Search Tree

5. Heap

124

Hashing

1. Hash function

2. Linear probing

3. Linked list hashing

124

Sorting

1. Bubble Sort

2. Selection Sort

3. Insertion Sort

4. Quick Sort

5. Heap Sort

124

Project 1. poker

13-card Chinese poker optimization

1234

1

2

3

4

Project 2. State machine simulator

Moore machine simulation

1234

2

1. http://ap1.pccu.edu.tw/newAp/frame/apMain.asp?ApGUID={B0D96431-819E-42D5-AAA0-C1398729D01B}

2.

3.

Microprocessors

6090

3

/

programmerIntel 80x86MASM DOS calls BIOS calls

1

The 80x86 Family, Design, Programming, and Interfacing, 3rd. ed.by John Uffenbeck,Prentice Hall, 2002

Basic Computer System Architecture and Microprocessor

1. Intel microprocessor families

2. Basic Microprocessor

3. Computer System Architecture

4. Byte ordering

4

4

Registers and Flags

1. Programmers model

2. Registers

3. Address translation

4. Processor Status Word (PSW or flags )

124

1

2

4

Addressing Modes

Various ddressing modes

124

debugger

Various debugger commands

124

Instruction Set

1. Data Transfer

2. Arithmetic Operations

3. BCD Arithmetic

124

Instruction Format and Encoding

1. Instruction Formats

2. Instruction Encoding

124

Branches and jumps

1. Conditional branches

2. Unconditional Jumps

3. Flag Manipulation Instructions

124

Logical Instructions

1. Logical Instructions

2. Shift and Rotate Instructions

124

Assembler, Linker and Directives

1. Editor

2. Assembler

3. Linker

4. Skelton and Examples

124

Call/Return and Push/Pop

1. Stack

2. Calls

3. Returns

124

Interrupts, BIOS Calls, and DOS Function Calls

1. Interrupts

2. Vector Table

3. BIOS Calls

4. DOS function Calls

124

2

1. http://icas.pccu.edu.tw/cfp/?ccode=161791#matepage

2.

3.

Microcontroller Applications

A910

3

/

80518051

1

The 8051 Microcontroller, 3rd ed., Scott Mackenzie, Prentice Hall,

Introduction to Microcontroller

1. Microcomputer system overview

2. Microcomputer vs. microcontroller

4

4

8051 Hardware Organization

1. Pin description

2. I/O ports

3. Memory organization

4. Special function registers

5. External memory

124

1

2

4

Instruction Set

1. Addressing modes

2. Instruction types

124

Timer

1. Registers

2. Clocking

3. Examples

124

Serial Port

1. Registers

2. Examples

124

Interrupts

1. Interrupt organization

2. Examples

124

Assembly Programming

1. Instruction Format

2. Expression Evaluations

3. Assembler Directives

4. Macros

5. Program structures

124

2


2.

3.

Computer Organization and Architecture

6419

3

/

(DLX)Verilog HDL

1

Computer Architecture, A Quantitative Approach, 3rd ed. by John L. Hennessy and David A. Patterson

Performance Measurement

1. Performance Metrics

2. benchmark suits

3. Quantitative Principles of Computer Design

4. The CPU performance equation

1234

1

2

3

4

Instruction Set Principles

1. Instruction Set Architecture (ISA)

2. Classifying ISA

3. Classifying GPR machine

124

1

2

4

DLX ISA

1. DLX ISA

2. DLX Instruction format

3. RISC v.s. CISC

124

DLX Data Path

1. A 5-stage data path in RTL

2. The 5-stage data path in diagram

3. Pipeline operations

124

Hazards and Improvement

1. Structure hazard

2. Data hazard

3. Control hazard

4. The improvements

124

Verilog HDL

1. Hardware description module

2. Test fixture

3. Test planning

4. Timing diagram

5. Text output

124

A Simple CPU Design

1. Multiplexers

2. Registers

3. ALU

4. Timing planning

5. Implementations

1234

1

2

3

4

Cache Memory Management

1. Memory hierarchy

2. Block Placement

3. Block Identification

4. Block Replacement

5. Write Strategy

124

1

2

4

Cache Memory Performance Improvement

1. Cache performance measurement

2. Three Causes of Cache Misses

3. Ways of reducing miss rate

4. Ways of reducing cache miss penalty

1234

1

2

3

4

2


2.

3.

Circuitry1

6002

3

/

1 234 56

1

"Fundamentals of Electric Circuits 4/e", Alexander, McGraw-Hill

1. Current & Voltage

2. Power & Energy

3. Circuit elements

124

1

2

4

1. Resistors

2. Capacitors

3. Inductors

124

1. Ohms low

2. Kirchhoffs lows

3. Wye-Delta transformations

124

1. Nodal analysis

2. Mesh analysis

124

1. Thevenins theorem

2. Nortons theorem

3. Superposition

124

1. Inverting\Noninverting Amplifier

2. Summing\Difference Amplifier

3. Cascaded Op Amp circuit

124

2

1.

2.

Microcontroller Lab

6187

1

/

()

80512~3/timerreal time clockserial port internal loopbackserial port transmit/receivetimer/serial port

1

The 8051 Microcontroller, 3rd ed., Scott Mackenzie, Prentice Hall,

/

8051 pin descriptions

Oscillator, LED, and other components.

1234

1

2

3

4

Instruction execution clock cycle, looping, time estimation.

1234

timer

Timer

1234

real time clock

7-segment display, common anode/cathode,

/

1234

serial port internal loopback

serial port, parity check,

/

1234

serial port transmit/receive

1234

timer/serial port

Interrupts,

Interrupt vector,

Interrupt priority

/

1234

1234

2


2.

3.

Circuitry2

3700

3

/

12345678

1

"Fundamentals of Electric Circuits 4/e", Alexander, McGraw-Hill

1. The source-free RC\RL circuit

2. Singularity functions

3. Step response of RC\RL circuit

124

1

2

4

1. The source-free RLC circuit

2. Step response of RLC circuit

3. General second-order circuit

124

1. Sinusoid & phasors

2. Impedance & admittance

124

1. Nodal analysis

2. Mesh analysis

3. Thevenin & Norton equivalent circuit

124

1. Balanced three-phase voltage

2. Balanced Wye-Delta connection

124

1. Transer function

2. Bode plots

3. Filters

124

1. Definition of the Laplace transform

2. Properties of the Laplace transform

124

1. Hybrid parameters

2. Interconnection of Networks

124

2

1.

2.

Biomedical electronics

3693

3

/

() ()

1

"INTRODUCTION TO BIOMEDICAL EQUIPMENT TECHNOLOGY", Carr, Joseph J. & Brown, John M.

Introduction to biomedical instrumentation and measurement

1. Biomedical instrumentation

2. Biomedical measurement

234

2

3

4

Basic theories of measurement

1. Measurement error

2. Error contribution analysis

234

Signals and noise

1. Fourier series

2. Transient signals

3. Noise

234

Electrodes, sensors and transducers

1. Medical surface electrodes

2. Sensors

3. Capacitive & temperature Transducers

234

Bioelectrical amplifiers

1. Bioelectric amplifiers

2. Isolation amplifiers

234

The human respiratory system and its measurement

1. The human respiratory system

2. Gas Laws

3. Respiratory system measurement

234

Medical Laboratory instrumentation

1. Blood tests

2. Autoanalyzer

3. Electrical safety precautions

234

Biosensors and cell trapping device & Bioimpedance

1. Bio-chip

2. Cell model

234

2

1.

2.

Electronics(1)

6007

3

/

3LEDMOSFETFETNMOSCMOS

1

"Microelectronics Circuit Analysis & Design 4/e", D.A.Neamen, McGraw-Hill

Semiconductor Materials and Diodes

1. Intrinsic Semiconductors

2. The pn junction

3. Diode circuits

124

1

2

4

Diode Circuits

1. Rectifier circuits

2. Zener diode circuits

3. Clipper and clamper circuits

4. Multiple-diode circuits

5. Photodiode and LED circuits

124

The Field-Effect Transistor

1. MOS field-effect transistor

2. Basic MOSFET application: Switch, digital logic gate, and amplifier

3. Junction field-effect transistor

4. Design Application: Diode thermometer with MOSFET

124

Basic FET Amplifiers

1. MOSFET Amplifier

2. Basic Transistor Amplifier Configurations

3. Three Basic Amplifier Configuration:

4. Single-Stage Integrated Circuit MOSFET

5. Multistage Amplifiers

6. Basic JEFT Amplifiers

124

2

1. .

2.

Electronics(2)

6008

3

/

32BJTBJT

1


The Bipolar Junction Transistor

1. Basic Bipolar Junction Transistor (BJT)

2. DC Analysis of Transistor Circuits

3. Basic Transistor Applications

4. Bipolar transistor Biasing

5. Multistage Circuits

6. Design Application : Diode Thermometer with a Bipolar Transistor

124

1

2

4

Basic BJT Amplifiers

1. Analog Signals and Linear Amplifiers

2. The Bipolar Linear Amplifier

3. Basic Transistor Amplifier Configurations

4. Common-Emitter Amplifiers

5. AC Load Line Analysis

6. Common-Collector Amplifier

7. Common-Base Amplifier

8. Summary & ComparisonThree Basic Amplifiers

9. Multistage Amplifiers

10. Power Considerations

124

Frequency Response

1. Amplifier Frequency Response

2. System Transfer Functions

3. Frequency Response

4. Frequency Response => Bipolar Transistor

5. Frequency Response => The FET

6. High-Frequency Response of Transistor Circuits

7. Design Application

124

2

1.

2.

()

Electronics(3)

6009

3

/

() ()

33A B ABBJT FET BiCMOSNMOS \ CMOS \\

1


Output Stages and Power Amplifiers

1. Power amplifiers

2. Power transistors

3. Classes of amplifiers

4. Class-A power amplifiers

5. Class-AB push-pull complementary output stages

6. Design application: an output stage using MOSFETs

124

1

2

4

Differential and Multistage Amplifiers

1. Ideal differential amplifier

2. Basic bipolar differential amplifier

3. Basic FET differential amplifier

4. FET differential amplifiers with active loads

5. Multistage amplifiers

6. Frequency response of the differential amplifier

124

Feedback and Stability

1. The ideal feedback system

2. Seriesshunt feedback amplifiers

3. Shuntseries feedback amplifiers

4. Series-series feedback amplifiers

5. Shuntshunt feedback amplifiers

6. Loop-gain of ideal and practical feedback circuits

124

MOSFET Digital Circuits

1. NMOS inverters and logic gates

2. CMOS inverters and logic gates

3. clocked CMOS logic gates

4. NMOS and CMOS transmission gates

124

2

1.

2.

Semiconductor Engineering

6658

3

/

Providing a comprehensive knowledge in semiconductor manufacturing, and present some of the many challenges in microchip fabrication. This course attempts to provide the manufacturing practice associated with the technologies used in advanced CMOS device applications. Topics such as crystal growth, cleanroom technology, wafer-cleaning technology, manufacturing technology, lithography, etching, metallization, dopant diffusion, Ion Implantation, and process integration will be covered in this course.,. CMOS.: crystal growth, cleanroom technology, wafer-cleaning technology, manufacturing technology, lithography, etching, metallization, dopant diffusion, Ion Implantation, and process integration. , .

1

Semiconductor Manufacturing Technology, by Michale Quirk, Julian Serda, Pearson Education, 2005, ISBN-986-154-117-9

Introduction to the Semiconductor Industry

Introduction

1, 2, 3, 4

1

2

3

4

Characteristics of Semiconductor Materials

Semiconductor Materials

1, 2, 4

1

2

4

Device Technology

Device Technology

1, 2, 4

Silicon and Wafer Preparation

Silicon and Wafer Preparation

1, 2, 4

Chemicals in Semiconductor Fabrication

Chemicals in Semiconductor Fabrication

1, 2, 4

Contamination Control in Wafer Fabs

Contamination Control in Wafer Fabrication

1, 2, 4

Metrology and Defect Inspection

1. Metrology

2. Defect Inspection

1, 2, 4

IC Fabrication Process Overview

IC Fabrication Process

1, 2, 4

Oxidation

Oxidation

1, 2, 4

Deposition

Deposition

1, 2, 4

Metallization

Metallization

1, 2, 4

Etch

Etch

1, 2, 4

Photolithography

Photolithography

1, 2, 4

Ion Implant

Ion Implant

1, 2, 4

Chemical Mechanical Planarization

Chemical Mechanical Planarization

1, 2, 4

2

1. The assignments are designed to help students to understand the covered subjects better. Discussion with other students is encouraged, but the assignments should be done individually.

2. Term Project and its Presentation

The student will need to decide an electronic devices related topic, researching the latest publication and summarized it in a project report, and present it during the last meeting of the course. The project report should not be longer than 5 single-spaced pages. In addition, you may provide supporting figures. The project is due at the beginning of the last class

Semiconductor Devices

6280

3

/

This course is an introduction to semiconductor devices for undergraduates. It will bring students with a background in physics and electronic devices. The goal of this course is to bring together quantum mechanics, the quantum theory of solids, semiconductor material physics, and semiconductor devices physics. All of these components are vital to the understanding of both the operation of present day devices and any future development in the field..,., , . , .

1

Fundamentals of Semiconductor Physics and Devices (First Edition), by Donald A. Neamen, McGraw Hill, 2003, ISBN: 007-123461-6

The Crystal Structure of Solids

Crystal Structure

1, 2, 3, 4

1

2

3

4

Introduction to Quantum Mechanics

Quantum Mechanics

1, 2, 4

1

2

4

Introduction to the Quantum Theory of Solids

Quantum Theory of Solids

1, 2, 4

The Semiconductor in Equilibrium

Semiconductor in Equilibrium

1, 2, 4

Carrier Transport Phenomena

Carrier Transport Phenomena

1, 2, 4

Nonequilibrium Excess Carriers in Semiconductor

Nonequilibrium Excess Carriers

1, 2, 4

The pn Junction

The pn Junction

1, 2, 4

Metal-Semiconductor and Semiconductor Heterojunctions

1. Metal-Semiconductor

2. Semiconductor Heterojunctions

1, 2, 4

The Bipolar Transistor

The Bipolar Transistor

1, 2, 4

Fundamentals of the Metal-Oxide-Semiconductor Field-Effect Transistor

MOS Field-Effect Transistor

1, 2, 4

Optical Device

Optical Device

1, 2, 4

2

1. The assignments are designed to help students to understand the covered subjects better. Discussion with other students is encouraged, but the assignments should be done individually.

2. Term Project and its Presentation

The student will need to decide an electronic devices related topic, researching the latest publication and summarized it in a project report, and present it during the last meeting of the course. The project report should not be longer than 5 single-spaced pages. In addition, you may provide supporting figures. The project is due at the beginning of the last class

Solid State Physics and nano Technology

C240

3

/

In recent years, nanocomposites have captured and held the attention and imagination of scientists and engineers alike. Based on the simple premise that by using a wide range of building blocks with dimensions in the nanosize region, it is possible to design and create new materials with unprecedented flexibility and improvements in their physical properties. This course contains the essence of this emerging technology, the underlying science and motivation behind the design of these structures and the future, particularly from the perspective of applications. ,, :Background to Nanotechnology, Molecular nanotechnology, Nanopowders and nanomaterials, The carbon age, Molecular mimics, Nanobiometrics, Optics, photonics and solar energy, Nanoelectronics, and Future applications.

1

1. NanoTechnology basic science and emerging technologies, by Mick Wilson, UNSW Press, 2002ISBN: 0-86840-437-3 2. Introduction to Solid State Physics, by Charles Kittel, Wiley, 2006 ISBN:0-471-41526-X

Background to Nanotechnology

Background

1, 2, 3, 4

1

2

3

4

Molecular nanotechnology

Molecular nanotechnology

1, 2, 4

1

2

4

Nanopowders and nanomaterials

1. Nanopowders

2. Nanomaterials

1, 2, 4

The carbon age

The carbon age

1, 2, 4

Molecular mimics

Molecular mimics

1, 2, 4

Nanobiometrics

Nanobiometrics

1, 2, 4

Optics, photonics and solar energy

Optics, photonics and solar energy

1, 2, 4

Nanoelectronics

Nanoelectronics

1, 2, 4

Future applications

Future applications

1, 2, 4

Crystal Structure

Crystal Structure

1, 2, 4

Wave Diffraction and The Reciprocal Lattice

1. Wave Diffraction

2. The Reciprocal Lattice

1, 2, 4

Crystal Binding and elastic constants

1. Crystal Binding

2. Elastic constants

1, 2, 4

Phonons I: Crystal Vibrations

Crystal Vibrations

1, 2, 4

Phonons II: Thermal Properties

Thermal Properties

1, 2, 4

Free Electron Fermi Gas

Free Electron Fermi Gas

1, 2, 4

2

There will be two tests during the semester. The tests will evaluate students understanding of the subjects covered in the lectures, and students knowledge acquired from assignments. The test will be closed-book exam

CMOS

CMOS Integrated Circuits

3524

3

/

Providing a comprehensive knowledge of a specific aspect of CMOS logic, circuit, design and processing technology. This course is divided into three main sections. The first deals with silicon integrated circuit technology. The second section deals with logic design in a CMOS technology and electronic aspects of CMOS. The final section describes the design of VLSI systems. It will link logic networks, physical design, and electronics together into the single discipline of VLSI systems design. CMOS logic, circuit, design and processing technology. - (1) silicon integrated circuit technology (2)logic design in a CMOS technology and electronic aspects of CMOS (3) the design of VLSI systems. , .: Modern CMOS Technology, Crystal Growth, Wafer Fabrication and Basic Properties of Silicon Wafers,Thermal Oxidation and the Si/SiO2 Interface,Doping,Logic Design with MOSFETs,Physical Structure of CMOS Integrated Circuits,Elements of Physical Design, Electrical Characteristics of MOSFETs,Electronic Analysis of CMOS Logic Gates, Advanced Techniques in CMOS Logic Circuits,General VLSI Systems Components, and System-Level Physical Design.

1

1. INTRODUCTION TO VLSI CIRCUITS AND SYSTEMS, BY JOHN P. UYEMURA, JOHN WILEY & SONS, 2002. ISBN 0471127043

2. Silicon VLSI Technology, by James D. Plummer, Michael D. deal and peter B. Griffin, Prentice Hall, 2000. ISBN 0130850373

Introduction and Historical Perspective

1. Introduction

2. Historical Perspective

1, 2, 3, 4

1

CMOS

2

CMOS

3

CMOS

4

CMOS

Modern CMOS Technology

Modern CMOS Technology

1, 2, 4

1

CMOS

2

CMOS

4

CMOS

Crystal Growth, Wafer Fabrication and Basic Properties of Silicon Wafers

1. Crystal Growth

2. Wafer Fabrication

3. Basic Properties of Silicon Wafers

1, 2, 4

Lithography

Lithography

1, 2, 4

Thermal Oxidation and the Si/SiO2 Interface

1. Thermal Oxidation

2. Si/SiO2 Interface

1, 2, 4

Doping

Doping

1, 2, 4

Logic Design with MOSFETs

Logic Design with MOSFETs

1, 2, 4

Physical Structure of CMOS Integrated Circuits

Physical Structure of CMOS Integrated Circuits

1, 2, 4

Elements of Physical Design

Elements of Physical Design

1, 2, 4

Electrical Characteristics of MOSFETs

Electrical Characteristics of MOSFETs

1, 2, 4

Electronic Analysis of CMOS Logic Gates

Electronic Analysis of CMOS Logic Gates

1, 2, 4

Advanced Techniques in CMOS Logic Circuits

Advanced Techniques

1, 2, 4

System Specification Using Verilog HDL

Verilog HDL

1, 2, 4

General VLSI Systems Components

General VLSI Systems Components

1, 2, 4

2

There will be two tests during the semester. The tests will evaluate students understanding of the subjects covered in the lectures, and students knowledge acquired from assignments. The test will be closed-book exam

Control Laboratory

E778

1

/

PID

1

()

1.

2.

124

1

2

4

PID

1.

2.

124

1.

2. -

124

2

1.

2.

3. 2~3

4-3

2010

714()

1210()

2011

127()

2012

511()

1119()

2013

412()

419()

510 ()

4-4

2008.05.022008

(OSA, SPIE Fellow)

(2008)

2009.03.06

(IEEE Fellow)

2009.05.012009

(IEEE Fellow)

(IEEE Fellow)

2009.09.30

FPGA

2009.10.29

/

2009.12.03

/

2010.03.31

/(IEEE Fellow)

2010.05.072010()

(IEEE Fellow)

/

2010.05.082010()

()

()

2010.05.25

/(IEEE Fellow)

2010.06.03

2010.10.05

2010.11.01

2010.12.01

(IEEE Fellow)(LED)

2010.12.13

Real-Time Task Scheduling for Dual-Core Embedded Systems

2011.03.09

/(IEEE Fellow)(Fuzzy Theory and Fuzzy Reasoning)

2011.05.062011

/(IEEE Fellow)

/Innovative Time-Domain Smart Temperature Sensor Design

Power-Aware High-Speed ADC in Deep Submicron CMOS

/

2011.09.22

2011.09.29

2011.10.06

2011.10.13

RFID

2011.10.20

/(Specific Absorption Rate, SAR)

2011.10.27

2011.11.03

2011.11.10

2011.11.17

2011.11.24

(Microgrids)

2011.12.15

/(IEEE Fellow)Ultrasound Applications in Future Healthcare

2011.12.29

2012.05.042012

/(Fiber optics devices for photonic communication and network)

Photonic Crystal Cavities for Nanolasers and Sensors

Organic Semiconductors and Optoelectronic Device Applications

2012.05.09

(IEEE Fellow)(Body Sensing: Some Data Processing Techniques)

2012.05.14

Dr. Daniel S. Yeung (IEEE Fellow, President of IEEE SMC Society)Artificial Intelligence

2012.09.19

2012.09.27

Math Actually

2012.10.25

2012.11.15

Gigabit Wi-Fi

2012.12.13

2012.12.20

-

2012.12.27

(STB)

2013.01.03

2013.05.032013

(IEEE Fellow)

2009.04.22

2009.11.24

2009.11.25

yes123+=

2010.04.26

2010.04.27

2010.04.28

2010.05.31

/

2010.10.13

2010.10.20

2011.03.20

2011.06.08

2011.09.14

()

2011.10.15

/

2011.12.01

2011.12.22

2012.04.25

2012.10.11

123

2012.10.18

2012.11.08

CURTIS TOLEDO, INC -/

2012.11.29

2013.03.20

2013.04.10

2009.05.16

2009.11.07

2010.03.10

2010.03.17

2010.04.07

2010.05.19

2010.06.02

2010.11.03

2010.11.17

2010.12.30

2011.04.06

2011.05.04

2011.05.25

2011.12.01

2012.04.11

2012.10.04

2012.11.01

2012.11.10

2012.11.22

2012.12.06

2013.05.31

5-1

PAGE

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