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Chapter 8 Oscillator and

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Presentation on theme: "Chapter 8 Oscillator and"— Presentation transcript:

1 Chapter 8 Oscillator and
Power Amplifier SJTU Zhou Lingling

2 Outline Oscillator Power amplifier SJTU Zhou Lingling

3 Oscillator Basic principles of sinusoidal oscillator.
The Wien-bridge oscillator SJTU Zhou Lingling

4 Basic Principles of Sinusoidal Oscillator
The oscillator feedback loop The basic structure of a sinusoidal oscillator. A positive-feedback loop is formed by an amplifier and a frequency-selective network. SJTU Zhou Lingling

5 Basic Principles of Sinusoidal Oscillator
Feedback signal xf is summed with a positive sign The gain-with-feedback is The oscillation criterion SJTU Zhou Lingling

6 Basic Principles of Sinusoidal Oscillator
Nonlinear amplitude control To ensure that oscillations will start, the Aβ is slightly greater than unity. As the power supply is turned on, oscillation will grown in amplitude. When the amplitude reaches the desired level, the nonlinear network comes into action and cause the Aβ to exactly unity. SJTU Zhou Lingling

7 A Popular Limiter Circuit for Amplitude Control
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8 A Popular Limiter Circuit for Amplitude Control
Transfer characteristic of the limiter circuit; When Rf is removed, the limiter turns into a comparator with the characteristic shown. SJTU Zhou Lingling

9 Oscillator Circuits Op Amp-RC Oscillator Circuits LC-Tuned Oscillator
The Wien-Bridge Oscillator The phase-Shift Oscillator LC-Tuned Oscillator Colpitts oscillator Hareley oscillator Crystal Oscillator SJTU Zhou Lingling

10 The Wien-Bridge Oscillator
A Wien-bridge oscillator without amplitude stabilization. SJTU Zhou Lingling

11 The Wien-Bridge Oscillator
The loop gain transfer function Oscillating frequency To obtain sustained oscillation SJTU Zhou Lingling

12 The Wien-Bridge Oscillator
A Wien-bridge oscillator with a limiter used for amplitude control. SJTU Zhou Lingling

13 The LC-Tuned oscillator
Colpitts Oscillator A parallel LC resonator connected between collector and base. Feedback is achieved by way of a capacitive divider Oscillating frequency is determined by the resonance frequency. SJTU Zhou Lingling

14 The LC-Tuned oscillator
Hartley Oscillator A parallel LC resonator connected between collector and base. Feedback is achieved by way of an inductive divider. Oscillating frequency is determined by the resonance frequency. SJTU Zhou Lingling

15 Crystal Oscillators A piezoelectric crystal. (a) Circuit symbol. (b) Equivalent circuit. SJTU Zhou Lingling

16 Crystal Oscillators Crystal reactance versus frequency (neglecting the small resistance r, ). A series resonance at A parallel resonance at SJTU Zhou Lingling

17 Crystal Oscillators A Pierce crystal oscillator utilizing a CMOS inverter as an amplifier. SJTU Zhou Lingling

18 Power Amplifier Small-signal approximation and models either are not applicable or must be used with care. Deliver the power to the load in efficient manner. Power dissipation is as low as possible. SJTU Zhou Lingling

19 Classification of Power Amplifier
Power amplifiers are classified according to the collector current waveform that results when an input signal is applied. Conducting angle. SJTU Zhou Lingling

20 Classification of Power Amplifier
Collector current waveforms for transistors operating in (a) class A, (b) class B SJTU Zhou Lingling

21 Classification of Power Amplifier
class AB class C SJTU Zhou Lingling

22 Class B Output Stage A class B output stage. Complementary circuits.
Push-pull operation Maximum power-conversion efficiency is 78.5% SJTU Zhou Lingling

23 Transfer Characteristic
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24 Crossover Distortion SJTU Zhou Lingling

25 Power Dissipation The load power Maximum load power SJTU Zhou Lingling

26 Power Dissipation Total supply power Maximum total supply power
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27 Power Dissipation Power-conversion efficiency
Maximum power-conversion efficiency SJTU Zhou Lingling

28 Power Dissipation Power dissipation Maximum Power dissipation
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29 Class AB Output Stage A bias voltage VBB is applied between the bases of QN and QP, giving rise to a bias current IQ . Thus, for small vI, both transistors conduct and crossover distortion is almost completely eliminated. SJTU Zhou Lingling

30 A Class AB Output Stage Utilizing Diodes for Biasing
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31 A Class AB Output Stage Utilizing A VBE Multiplier for Biasing
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