2-Filters.pptx

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FILTERS
Inductor Filter
Pros:
Filter Circuits 1.Noise Reduction: Inductor filters are
To remove the AC components or filter them effective at reducing high-frequency noise
out in a rectifier circuit, a filter circuit is and electromagnetic interference (EMI) from
used. A filter circuit is a device that is used electrical signals. They are often used in
to remove the AC components of the power supplies to eliminate or reduce
rectified output but allows the DC voltage spikes and ripple.
components to reach the load. 2.Improved Signal Quality: By removing
A filter circuit consists of passive circuit high-frequency noise and spikes, inductor
elements i.e., inductors, capacitors, filters can help improve the overall quality
resistors, and their combination. The filter and stability of electrical signals, making
action depends on the electrical properties them suitable for sensitive applications.
of passive circuit elements. 3.Energy Storage: Inductors store energy
in their magnetic fields, which can be
For example, an inductor allows the DC to beneficial in certain applications. They can
pass through it. But it blocks AC On the act as energy reservoirs, providing
other hand, a capacitor allows the AC to additional power during brief periods of high
pass through it. But it blocks the DC Some demand.
of the important filters are given below. 4.Simple Design: The basic design of an
1.Inductor Filter inductor filter is relatively simple, consisting
2.Capacitor Filter of only two passive components (an
3.T Filter inductor and a capacitor). This simplicity
Cons:
Capacitor Filter:
1.Size and Weight: Inductors tend to be
physically larger and heavier than other
Pros:
passive components, such as resistors and
1.High-Pass Filtering: Capacitor filters
capacitors. This can be a drawback in
are effective at blocking low-frequency
compact or lightweight electronic devices.
signals while allowing high-frequency
2.Limited Frequency Range: Inductor
signals to pass through. They are commonly
filters are most effective at filtering high-
used to eliminate ripple and provide DC
frequency noise, but their effectiveness
voltage in power supply applications.
decreases at very low or very high
2.Compact and Lightweight: Capacitors
frequencies. Choosing the right inductor and
are typically smaller and lighter than
capacitor values is crucial to target specific
inductors, making them suitable for
frequency ranges.
applications where space and weight
3.Energy Loss: Inductors have resistance
constraints are critical.
and can dissipate some energy as heat. This
3.Low Cost: Capacitors are relatively
can result in energy loss in the filter, which
inexpensive and readily available, which
may be a concern in energy-efficient
makes them a cost-effective choice for
applications.
filtering applications.
4.Complex Calculations: Designing
4.Simple Design: The basic design of a
inductor filters can be more complex than
capacitor filter is straightforward, with only
designing simple passive filters. Calculating
two passive components (a capacitor and a
the appropriate values for the inductor and
resistor). This simplicity facilitates easy
capacitor to achieve the desired filtering
integration into electronic circuits
effect can require expertise.
Cons: Cons:
1.Voltage Droop: In capacitor filters, the 5. Complex Ripple Reduction: Achieving
output voltage can experience a gradual a specific level of ripple reduction may
decrease over time due to the discharge of require careful selection of resistor and
the capacitor. This can be a limitation in capacitor values. Designing precise
applications requiring a constant voltage capacitor filters can be more complex than
output. it initially appears.
2.Limited Filtering Range: Capacitor
filters are most effective at filtering low-
frequency noise and ripple. They are less
effective at attenuating very high-frequency
noise. Additional filtering stages may be
required for comprehensive noise
suppression.
3.Energy Storage: Unlike inductors,
capacitors do not store energy. This means
that they cannot provide additional power
during brief periods of high demand, which
could be a drawback in certain applications.
4.Voltage Ratings: Capacitors have
voltage ratings, and exceeding these
ratings can lead to capacitor failure, which
may result in circuit damage or safety
T Filter: T Filter:

Pros: Cons:
1.Simplicity: T filters have a 1.Limited Bandwidth: T filters have a
straightforward design with only three limited bandwidth, meaning they are
passive components, making them cost- optimized for a specific range of
effective and easy to implement. frequencies. Achieving wideband filtering
2.Customizable Response: By choosing may require more complex filter designs.
specific resistor and capacitor values, you 2.Energy Loss: The resistors in T filters
can tailor the filter to meet your frequency introduce energy losses in the form of heat,
response requirements. which can be a concern in applications
3.Versatility: T filters can be used for both requiring high efficiency.
high-pass and low-pass filtering, offering 3.Component Values: Precisely designing
versatility for various applications. a T filter for specific cutoff frequencies may
require careful selection of resistor and
capacitor values. Component tolerances can
affect filter performance.
LC Filter
Cons:
Pros:
1.Component Sizing: Properly selecting
1.Effective Filtering: LC filters are highly
the values of the inductor and capacitor to
effective at filtering and shaping electrical
achieve the desired filtering effect can be
signals, allowing you to selectively pass
challenging, especially for complex filtering
desired frequencies while attenuating
requirements. Designing precise LC filters
unwanted ones. This is crucial in
can be complex.
applications where signal quality is
essential.
2.Limited Bandwidth: LC filters have
2.Low Power Dissipation: LC filters are
limited bandwidth and may not effectively
passive components, meaning they don't
filter signals with frequencies far from the
consume power themselves. This is
cutoff frequency. They are best suited for
beneficial for applications where power
applications within a specific frequency
efficiency is a concern.
range.
3.Simple Design: They have a relatively
simple design, consisting of just two passive
3. Losses: Both the inductor and capacitor
components—an inductor and a capacitor.
can introduce some losses into the circuit,
This simplicity makes them cost-effective
including resistive losses in the inductor and
and easy to implement in various circuits.
dielectric losses in the capacitor. This can
affect overall circuit efficiency.
Cons:

4. Size and Weight: Inductors can be relatively
large and heavy, which can be a limitation in
compact or portable electronic devices. Smaller
form-factor components may be preferred in
such cases.

5. Complexity for Multistage Filters: In
applications requiring multiple stages filtering,
managing the interaction between stages and
achieving the desired overall response can be
complex
Pi Filter Pi Filter

Pros: Cons:
1.Effective Filtering: CLC filters provide 1.Limited Bandwidth: π filters are
effective filtering by combining the optimized for either high-pass or low-pass
advantages of both inductive and capacitive operation, which means they are less
elements. They can offer good attenuation versatile compared to CLC filters in terms of
of both high and low frequencies. filtering frequency ranges.
2.Low Power Dissipation: Like other 2.Energy Loss: The resistors in π filters
passive filters, CLC filters do not consume introduce energy losses in the form of heat,
power themselves, which can be which can be a concern in applications
advantageous for power-efficient requiring high efficiency.
applications. 3.Component Values: Precisely designing
3.Simple Design: They have a relatively a π filter for specific cutoff frequencies may
simple design, consisting of three passive require careful selection of resistor and
components—an inductor and two capacitor values
capacitors. This simplicity makes them cost-
effective and easy to integrate.
 FILTERS

1 CAPACITOR FILTER:

A capacitor is connected at
the rectifier output, and dc
voltage is obtained across the
capacitor.
Output waveform The filtered voltage as shown in the figure below
shows the waveform to have a dc level and a ripple
The figure below shows the voltage as the capacitor charges and discharges.
waveform across a capacitor
filter. Time T1 is the time
during which diodes of the full-
wave rectifier conduct,
charging the capacitor up to
the peak rectifier voltage,.
Time T2 is the time interval
during which the rectifier
voltage drops below the peak
voltage, and the capacitor
discharges through the load. The ripple voltage can be calculated from

Where is in milliamperes
is in microfarads
is in kilo ohms
Example: Example:
Calculate the ripple voltage of the Calculate the ripple of a capacitor filter for a
full-wave rectifier with a 100 filter peak rectified voltage of 30 V, capacitor C=
capacitor connected to a load 100 uF, and a load current of 50 mA.
drawing 50.

Filter Capacitor Ripple

DC VOLTAGE
Diode Conduction Period and Peak Diode
Current

Recall that the diodes conduct during period
T1 , during which time interval, the larger
the amount of the charging current.
RC FILTER:

It is possible to further reduce the
amount of ripple across a filter FULL –WAVE RECTIFIER AND RC FILTER:
capacitor by using an additional RC
filter section. The purpose of the added The operation of the filter circuit can be
RC section is to pass most of the dc analyzed using superposition for the dc and
component while attenuating as much ac components of signal.
of the ac component as possible.
DC Operation of RC Filter Section AC Operation of RC Filter Section

The figure shows the equivalent circuit to The figure shows the equivalent circuit of
use in analyzing the RC filter circuit. Since the RC filter section. Due to the voltage –
both capacitors are open-circuit for dc divider action of the capacitor ac impedance
operation, the resulting output dc voltage is and the load resistor, the ac component of
the voltage resulting across the load is

For a full-wave rectifier with ripple at 120
Hz, the impedance of a capacitor can be
Example:
load for an filter section The dc voltage
across the initial filter capacitor is V.

Example:
Calculate the dc and ac components of the
output signal across load RL in the circuit.
Calculate the ripple of the output waveform.
Inductor Filter L-C Filter
As an inductor allows dc and vlocks ac, a A filter circuit can be constructed using both
filter called Series Inductor Filter can be inductor in order to obtain a better output
constructed by connecting the inductor in where the efficiencies of both inductor and
series, between the rectifier and the load. capacitor can be used.
The figure below shoes the circuit of a
series inductor filter.

The rectified output is when the inductor
allows dc components ta pass through it,
The rectified output when passed through blocking the AC components in the signal.
this filter, the inductor blocks the AC Now from the signal, few more AC
components that are present in the signal, components if any present are grounded so
in order to provide a pure dc. that we get a pure dc output.
The filter if also called as a Choke Input
Filter as the input signal first enters the
inductor. The output of this filter is better
than the previous ones.
Pi Filter () Pi Filter ()
Capacitor C1: This capacitor offers high
This is another type of filter circuit which is reactance to dc and low reactance to AC
very commonly used. It has a capacitor at signal. After grounding the AC components
its input and hence it is also called as a present in the signal, the signal passes to
Capacitor Input Filter. Here, two capacitors the inductor for further filtration.
and one inductor are connected in pi
shaped network. A capacitor in parallel, Inductor L: This inductor offers low
then an inductor in series, followed by reactance to dc components, while blocking
another capacitor in parallel makes this the AC components of any got managed to
circuit.. pass through the capacitor C1.

Capacitor C2: Now the signal is further
smoothened using this capacitor so that it
allows any AC component present in the
signal, which the inductor has failed to
block.

In this circuit, we have a capacitor in
parallel, then an inductor in series, followed
by another capacitor I parallel.
Diode Conduction Period and Peak Diode
Current

Recall that the diodes conduct during period
T1 , during which time interval, the larger
the amount of the charging current.
Diode Conduction Period and Peak Diode
Current

Recall that the diodes conduct during period
T1 , during which time interval, the larger
the amount of the charging current.
Diode Conduction Period and Peak Diode
Current

Recall that the diodes conduct during period
T1 , during which time interval, the larger
the amount of the charging current.