This document discusses different types of power supplies and electronic device testing. It describes various rectifier circuits including half wave, full wave, and bridge rectifiers. It discusses important rectifier characteristics such as ripple factor, efficiency, and peak inverse voltage. It also covers full wave and bridge rectifier operation, waveforms, and advantages/disadvantages. The document concludes by discussing voltage regulators including series, shunt, and switching types as well as their basic configurations and operations.
4. Rectifier
• A circuit that converts ac voltage of main supply
into pulsating dc voltage using one or more pn
junction diodes.
• Half Wave Rectifier
• Full Wave Rectifier
• Center Tap Rectifier
• Bridge Rectifier
5. Important Characteristics of Rectifier
• Waveform of the load current
• Regulation of output voltage
• Rectifier efficiency
• Peak value of current in the rectifier circuit
• Peak value of voltage across the rectifier
element in the reverse direction ( PIV)
• Ripple factor
14. How effectively a rectifier converts
ac into dc:
• Rectifier Efficiency (η)
• Ripple Factor (r)
15. Rectifier Efficiency (η)
Tells us the percentage of total input ac power
that is converted into useful dc output power.
η = 40.6 %
Under best conditions (no diode loss) only 40.6% of the
ac input power is converted into dc power.
The rest remains as the ac power in the load
16. Ripple Factor
Measure of purity of the dc output of a rectifier
Defined as the ratio of ac component of the output
wave to the dc component in the wave
17. Ripple Factor
This indicates that the ripple content in the output are 1.211 times the dc component.
i.e. 121.1 % of dc component.
The ripple factor is very high.
Therefore a half wave rectifier is a poor converter of ac to dc.
The ripple factor is minimized using filter circuits along with the rectifier.
18. Peak Inverse Voltage (PIV)
PIV = Em
Diode must be selected based on the PIV rating and
the circuit specification.
19. Disadvantage of HWR
•The ripple factor of half wave rectifier is 1.21,
which is quite high.
•The output contains lot of ripples
•The maximum theoretical efficiency is 40%.
•The practical value will be quite less than this.
•This indicates that HWR is quite inefficient.
27. Ripple Factor
This indicates that the ripple contents in the output are 48%
of the dc component which is much less than that for the
half wave rectifier.
29. Advantages of Full Wave Rectifier
• Efficiency is higher.
• The large dc power output
• The ripple factor is less
Disadvantages of Full Wave Rectifier
• PIV rating of diode is higher.
• Higher PIV diodes are larger in size and costlier.
• The cost of center tap transformer is high.
34. Advantages of Bridge Rectifier
• It does not need center tap transformer secondary.
• The transformer secondary voltage of CT rectifier is
2Vm, where as in Bridge the transformer secondary
must have a peak voltage of Vm. That is the
transformer secondary of CT rectifier must have double
the number of turns. Such transformers are costlier.
• If stepping up or stepping down of voltage is not
needed, we may even do away without transformer.
• Each diode in center tap has a PIV rating of 2Vm,
whereas diodes in bridge rectifier needs a PIV rating of
Vm. Hence the diodes for use in center tap rectifier are
costlier than meant for bridge rectifier.
35. Disadvantages of Bridge Rectifier
• It requires four diodes, two of which conduct
in alternate half cycles. This creates a total
voltage drop of 1.4V (if Si diodes are used).
• Therefore this creates a problem if low dc
voltage is required.
• The secondary voltage is low and two diode
voltage drop of 1.4V becomes significant.
36. Rectifiers with filter
• Pulsating DC not constant (fluctuates w.r.t time)
• This is not applicable to electronic components
• Solution – smoothing the fluctuating DC (with
filter)
• It consists of
– A transformer
– Diode
– Capacitor
41. Voltage Regulators
• Delivers constant power to the load
• Vo controlled by internal circuitry
• Avoids unnecessary change in load
• Figure shows role of a regulator
42. Continued..
• Basic diagram is as follows
• Has 3 parts
– Reference voltage circuit
– Feedback circuit (error amplifier)
– Current amplifier
• Figure of merit for voltage regulator
– Line regulation
– Load regulation
43. Output resistance
• Relates output voltage and current
• Ideal case – Vo independent of Io
• Practical case - Vo is a function of Io
• This relation is Ro
Ro = change in Vo / change in Io
44. Types of voltage regulator
• Series regulator
• Shunt regulator
– based on configuration between transistor (with
load) and control element
• Switching regulator
46. Continued..
• Series regulator consists of the following
– Control element
– Reference voltage
– Sampling circuit
– Comparator circuit
• Input is unregulated power supply
• Functions of each block
47. Continued..
• Circuit diagram of series regulator is
• It consists of the following
– Source resistance R
– Transistor Q1
– Zener diode
– Load
49. Shunt regulator
• Shunt configuration between control element
and the load
• Shunts current from the load
• The block diagram is as follows
50. Continued..
• Circuit diagram of series regulator is
• It consists of the following
– Source resistance R
– Transistor Q1
– Zener diode
– Load
• The Zener diode, Transistor and Load are parallel
to each other
51. Switching regulator
• Completely different from series and shunt
• More efficient power transfer to load
• Added circuit complexity
• It consists of a V-source, Transistor, Pulse
generator and Filter
52. Continued..
• The basic circuit diagram is as follows
• It consists of
– Voltage reference - Diodes
– Error amplifier - R and L components
– Pulse wave generator
53. Types of switching regulators
• Step down switching regulator
• Step up switching regulator
• Inverting type switching regulator
54. Step down switching regulator
• It consists of a transistor (Q), inductor,
capacitor, comparator, oscillator, zener diode
• Reference voltage – zener diode
• Oscillator controls Q for switching
• L and C acts as filter
55. Step up switching regulator
• Basic elements identical to step down type
56. Inverting type switching regulator
• Identical elements to previous types
• But connections different
• Output - opposite polarity to input
58. Over voltage protection
• Switching regulator used (step down)
• Excessive input voltage identified by peak
current of regulator
• External transistor biased using RB