Circuits and Electronics. Hands-on Learning with Analog Discovery

Content: Chapter 1: Virtual Instruments of the Analog Discovery Board1.1 Analog Discovery Board1.2 WaveForms Software1.3 Power Supplies1.4 Voltmeters1.5 Arbitrary Waveform Generators1.6 Oscilloscope1.7 Network Analyzer1.8 Spectrum AnalyzerProblemsChapter 2: Basic Circuit Laws2.1 Ohm's Law2.2 Kirchhoff's Voltage Law2.3 Kirchhoff's Current Law2.4 Linearity Property2.5 Thevenin and Norton TheoremsProblemsChapter 3: Transient Analysis3.1 RC Circuits3.2 RL Circuits3.3 RLC CircuitsProblemsChapter 4: Impedance, Power Calculation and Frequency Response4.1 Impedance Measurements4.2 RMS Values4.3 Complex Power4.4 Frequency ResponseProblemsChapter 5: Operational Amplifiers5.1 Properties of the Op Amp5.2 Inverting Amplifier5.3 Non-inverting Amplifier5.4 Weighted Summer5.5 Integrator and Differentiator5.6 Active Filter CircuitProblemsChapter 6: Diodes6.1 Diode Characteristics6.2 Half-Wave Rectification6.3 Peak Detector6.4 Full-Wave Rectification6.5 Full-Wave Rectification with Smoothing FilterProblemsChapter 7: Transistors7.1 Bipolar Junction Transistors7.2 Mosfet Characteristics7.3 Biasing of BJT Amplifiers7.4 Biasing of MOSFET Amplifiers7.5 Frequency Response of BJT Amplifiers7.6 Frequency Response of MOSFET AmplifiersProblemsBibliographyIndexExamplesExample 1.1 Use of the Analog Discovery Power Supply and VoltmeterExample 1.2 Resistor-LED CircuitsExample 1.3 Arbitrary Waveform Generator Signal Displayed on ADB ScopeExample 1.4 Magnitude and Phase Characteristics of a RLC CircuitExample 1.5 Frequency Response of a Square WaveExample 2.1 Ohm's LawExample 2.2 Kirchhoff's Voltage LawExample 2.3 Kirchhoff's Current LawExample 2.4 Homogeneity Property of Linear CircuitExample 2.5 Thevenin's and Norton's Equivalent CircuitExample 3.1 Charging and Discharging of a CapacitorExample 3.2 Charging and Discharging of an InductorExample 3.3 Transient Response of RLC CircuitExample 4.1 Determining the Impedance of a CircuitExample 4.2 RMS Values of Two Periodic SignalsExample 4.3 Determining the Complex Power of a CircuitExample 4.4 Frequency Response of a RLC Resonant CircuitExample 5.1 Inverting AmplifierExample 5.2 Non-inverting AmplifierExample 5.3 Summer AmplifierExample 5.4 Converting Square Wave to Triangular WaveformExample 5.5 Frequency Response of a Notched FilterExample 6.1 Diode CharacteristicsExample 6.2 Half-Wave RectificationExample 6.3 Battery Charging CircuitExample 6.4 Ripple Voltage of Half-wave RectifierExample 6.5 Full-wave Bridge RectifierExample 6.6 Full-wave Rectification with Smoothing FilterExample 7.1 BJT Output CharacteristicsExample 7.2 BJT Input CharacteristicsExample 7.3 Output Characteristics of N-channel MOSFETExample 7.4 Input Characteristics of N-channel MOSFETExample 7.5 Bias Point of BJT Amplifier CircuitExample 7.6 Bias Point of MOSFET Amplifier CircuitExample 7.7 Frequency Response of Common Emitter AmplifierExample 7.8 Characteristics of Emitter Follower CircuitExample 7.9 Frequency Response of Common Source AmplifierExample 7.10 Frequency Response of Common Drain Amplifier