2. OSCILLATORS
• Many electronic devices require a source of energy at a specific
frequency which may range from a few Hz to several MHz. This is
achieved by an electronic device called an oscillator.
• Oscillators are extensively used in electronic equipment. For
example, in radio and television receivers, oscillators are used to
generate high frequency wave (called carrier wave) in the tuning
stages.
• Audio frequency and radio frequency signals are required for the
repair of radio, television and other electronic equipment. Oscillators
are also widely used in radar, electronic computers and other
electronic devices.
• Oscillators can produce sinusoidal or non-sinusoidal (e.g. square
3. CLASSIFICATION OF OSCILLATORS:
• Different types of oscillators are used for different applications.
A) On the basis of frequency:
• Audio frequency oscillator.(up to 20 kHz)
• Radio frequency oscillator (up to 500 MHz)
• Microwave oscillator.(up to several GHz)
4. B) On the basis of active device used:
• Valve oscillator (triode or pentode)
• Transistor (BJT) oscillator
• Field effect transistor (FET) oscillator
• Uni junction transistor (UJT) oscillator
• Tunnel diode relaxation oscillator
• Integrated circuit oscillator
5. C) On the basis of wave shaped produced :
Sine wave oscillator : It generates sinusoidal waves.
Non sinusoidal oscillator : In this the wave shape produced is
not sine wave but it may be square wave or triangular or saw
tooth wave.
D) On the basis of variability of frequency :
Fixed frequency oscillator
Variable frequency oscillator
E) On the basis of method of generating oscillations :
LC oscillator
RC oscillator
6. SINUSOIDAL OSCILLATOR
• An electronic device that generates sinusoidal
oscillations of desired frequency is known as a
*sinusoidal oscillator.
• Although we speak of an oscillator as “generating” a
frequency, it should be noted that it does not create
energy, but merely acts as an energy converter.
• It receives D.C energy and changes it into A.C energy of
desired frequency.
7. OSCILLATORY CIRCUIT
• A circuit which produces electrical oscillations of any desired
frequency is known as an oscillatory circuit or tank circuit.
• A simple oscillatory circuit consists of a capacitor (C) and
inductance coil (L) in parallel as shown in Fig.3.2 (a) and a
switch is in position R .
• Now when the switch is brought to position P (fig. b) ,the
capacitor C charges so positive charge is accumulated on the
upper plate and negative charge is accumulated on the bottom
plate.
8.
9. • Voltage across capacitor increases slowly and energy is stored in electric
field.
• It is shown by oj in figure (f) .
• Now when the switch is brought to position Q from P (fig. c) capacitor gets
connected across inductor L.
• Current through inductor rises slowly due to the voltage of the capacitor.
• Energy is stored in magnetic field and capacitor discharges and voltage of
capacitor decreases (jk in fig. f )
• The current through inductor stops when the capacitor discharges
completely so emf induced as shown in figure (d).
• So capacitor charges in the reverse direction (kl) and the energy is now
stored in electric field.
10. • Capacitor now discharges in reverse direction and due to electric current
magnetic field now increases in reverse direction (lm).
• When capacitor discharges completely the magnetic field and current
through the inductor maximum.
• Then the whole process is repeated and oscillations are produced.
• From the figure it is seen that the magnitude of voltage is decreasing and
after some time it becomes zero and oscillations are stopped.
• This is called the damped oscillations .
• The oscillations damp out as there is loss of energy in inductor and capacitor.
• The voltage becomes zero when the energy is totally wasted.
11. SUSTAINED OR UNDAMPED OSCILLATIONS
• We saw above that damped oscillations are produced in tuned circuit
when the energy is given once.
• The oscillations produced are damped oscillations because at every
oscillation there is waste of energy in capacitor and inductor.
• But if energy equal to the loss is supplied at every oscillation there is
no decrease in voltage and sustained oscillations are produced.
12. FREQUENCY OF OSCILLATIONS:
• The frequency of oscillations in the tank circuit is determined by the
constants of the circuit viz L and C.
• The actual frequency of oscillations is the resonant frequency(or
natural frequency) of the tank circuit given by:
fr = 1/2π√LC
13. TYPES OF SINUSOIDAL OSCILLATIONS
• Sinusoidal electrical oscillations can be of two types viz damped
oscillations and undamped oscillations.
1) Damped oscillations.
• The electrical oscillations whose amplitude goes on decreasing with
time are called damped oscillations.
• Fig. Shows waveform of damped electrical
oscillations.
14. UNDAMPED OSCILLATIONS.
• The electrical oscillations whose amplitude remains constant with time are called
undamped oscillations.
• shows waveform of undamped electrical oscillations.