Introduction to Digital Electronics ( EE201)
數(shù)字電路基礎(chǔ) 視頻課程 ( Berkeley )
（28課時  ￥80）
Instructor: Bernhard Boser

        Introduction to Digital Electronics是UC Berkekey電子工程本科生必修課程，共28講，每講80分鐘左右， 該門課程是.rm格式的視頻課程，圖文并茂，清洗直觀。
        加州大學(xué)伯克萊分校（UC Berkeley）作為世界一流大學(xué)，有著世界頂級的大師，所設(shè)課程也都是精品中的精品，緊跟最新科技的進展。本站推出的美國一流大學(xué)精品視頻課程套裝，讓您足不出戶就能一睹世界一流大學(xué)大師教學(xué)的風(fēng)采；聆聽大師的聲音、拓展國際化的視野、與國際水平看齊、實現(xiàn)自我價值的提升。

        This course serves as an introduction to the principles of electrical engineering, starting from the basic concepts of voltage and current and circuit elements of resistors, capacitors, and inductors. Circuit analysis is taught using Kirchhoff's voltage and current laws with Thevenin and Norton equivalents. Operational amplifiers with feedback are introduced as basic building blocks for amplication and filtering. Semiconductor devices including diodes and MOSFETS and their IV characteristics are covered. Applications of diodes for rectification, and design of MOSFETs in common source amplifiers are taught. Digital logic gates and design using CMOS as well as simple flip-flops are introduced. Speed and scaling issues for CMOS are considered. The course includes as motivating examples designs of high level applications including logic circuits, amplifiers, power supplies, and communication links.
　

        Teach what problems electronic circuits can solve and how to realize these solutions.
　

        Nilsson & Riedel, “Electronic Circuits”, Prentice Hall, 8th edition
　

        1. Circuit abstraction:
        small number of simple elements to describe a wide variety of electronic circuits
        2. Time and frequency domain representations
        steady state analysis, energy storing elements
        3. Analog and digital signal representations
        amplitude quantization, dynamic range, electronic noise
        4. Engineering tradeoffs
        power, speed, accuracy
        Specific Subjects Learned:
        1. Electrical variables
        charge, voltage, current, power, energy, resistance, impedance, frequency
        2. Node-voltage analysis
        including controlled sources and ideal operational amplifiers, no floating voltage sources
        3. Operational amplifier based gain-stages
        ideal opamps, concept of negative feedback, no stability analysis
        4. Energy storing devices
        capacitors and inductors
        5. Time-domain analysis
        1st order RC and RL response
        6. Steady state frequency domain analysis
        phasors, Laplace transform notation – without the math, transfer functions, Bode plots
        7. Analog / Digital signals
        signal representations, ADC, DAC, digital circuits, sampling not covered)
        8. Circuit simulation
        SPICE / Multisim, dc, ac, transient analysis
　

        Lecture 1:   Introduction
        Lecture 2:   Electronic Circuits
        Lecture 3:   Circuit Elements
        Lecture 4:   Circuit Analysis
        Lecture 5:   Node Voltage Analysis (NVA)
        Lecture 6:   Source Transforms, Superposition
        Lecture 7:   Operational Amplifiers
        Lecture 8:   Input/Output Resistance
        Lecture 9:   Review
        Lecture 10:   Capacitance and Inductance
        Lecture 11:   Capacitor and Inductor Examples
        Lecture 12:   NVA with L and C
        Lecture 13:   Frequency Domain
        Lecture 14:   Phasors
        Lecture 15:   Phasor Calculations
        Lecture 16:   Bode Diagrams
        Lecture 17:   Filters
        Lecture 18:   Review
        Lecture 19:   Boolean Algebra
        Lecture 20:   Transistors, CMOS Gates
        Lecture 21:   Memory, Sequential Circuits
        Lecture 22:   Microcontroller
        Lecture 23:   Microcontroller I/O, ADC, DAC
        Lecture 24:   Amplitude Quantization
        Lecture 25:   Dynamic Range
        Lecture 26:   Thermal Noise
        Lecture 27:   Speed / Power Accuracy Tradeoff
        Lecture 28:   Review
 

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