Electronics UNIT 1 PDF

Summary

This document provides a comprehensive introduction to electronics, covering fundamental concepts and components, including resistors, capacitors, and inductors.

Full Transcript

Electronics
UNIT 1
What is electronic devices?
An electronic devices are the circuits which is composed of
individual electronic components, such as resistors, transistors,
capacitors, inductors and diodes, connected by conductive wires
or traces through which electric current can flow.

It is a type of electrical circuit.
Examples of electronics devices
What is Electronic Components?
Electronic components are the elements of the circuit which
help in its functioning the electrical circuit.
Electronic components are the basic building blocks of an
electronic circuit any electronic system or any electronic device.
They can control the flow of electrons in an electronic system
or electronic circuit.
Electronic components vary from small to big.
So that they are easy to carry them from one place to another
place.
The cost of some electronic components is low and some of
them is high.
Conti…..
Electronic components consist of two or more terminals.
When a group of electronic components is connected together
in an electronic board such as a printed circuit board (PCB), a
useful electronic circuit is formed.
Each electronic component in a circuit performs a particular
task.
They can be classified into two types Active and Passive
Components.
Basics of Electrical circuit
Types of Electronic Components
An electrical circuit is an interconnection of Electronic
Components.
Based on their capability to generate energy these elements
are classified into active or passive electronic Components.

Electronic Components are classified into two groups:
Passive Components
Active components
Conti…
Passive Components
Passive components A passive element is an electrical
component that does not generate power, but instead
dissipates, stores, and/or releases it.
They mainly resist, store, or control the flow of electric current
or voltage in a circuit without actively amplifying or generating
signals.
These Passive components belongs to inactive functions of
components, these Passive components do not have capacity to
amplify the voltage or to rectify the supply.

Without these components assembly of electronic circuit is not
possible.
Conti…

Resistors, Capacitors, Inductors are called as passive
components.
Other Passive components include transformers, diodes,
thermistors, varactors, transducers, and many other common
components.
 Resistors
Resistors control the flow of current by offering resistance(The
property of a substance which opposes the flow of electric
current )
They are used to limit current, divide voltage, and set biasing
conditions in electronic circuits.
A resistor is a passive two-terminal electrical device that
resists the flow of current.
It is probably the simplest element in an electronic circuit.
It is also one of the most common components as resistance is
an inherent element of nearly all electronic circuits.
They are usually color-coded.
Resistor look like:::
Applications of Resistors
There won’t be any current flowing in the circuit if there is no
resistor present.
So, resistors are an essential component of electrical circuits.
Some applications and uses of resistor are listed below:
Circuit functions
Voltage dividers
Heating applications
Variable resistors
Frequency and timing
LEDs and transistor
Uses of Resistor in a Circuit
Resistors are used to control current flow in circuits.
This configuration is typically helpful for managing circuit tasks
like altering the motor’s speed, the pitch of a musical note, the
amplifier’s volume, etc.
In electronic circuits, resistors provide a range of functions, such
as reducing current flow,
regulating signal levels,
dividing voltages,
terminating transmission lines.
Basic terms
Voltage is the force that makes electrons flow.
Current: Current is the rate of the flow of electrons.
Conti….
Uses of Resistor in Voltage Dividers

As voltage dividers, resistors are utilised in electrical circuits.
A voltage divider is a simple circuit that is used to divide the input
voltage into smaller voltage.
It is made up of two resistors connected in series, with the output
voltage taken across one of the resistors.
A voltage divider distributes the source voltage among various
electrical circuit components and provides the required operating
voltage at the load terminal or output.
Conti….
Uses of Resistor in Heating Applications

Due to the high temperature, the filament of appliances like
heaters, toasters, electric stoves, microwaves, etc. glows.

This is because the metal filament acts as a resistor and
generates heat when current flows through it.
Conti….

Uses of Resistor in LEDs & Transistors
LEDs and transistors are examples of semiconductor devices
that are sensitive to input current values.
As a result, resistors are utilised in the circuit to control the input
current value.
Uses of Variable Resistor
Since the resistance of variable resistors can be adjusted to a
certain value, they are frequently employed in electrical circuits
to change the value of current or voltage.
With variable resistors, you may change the resistance while
maintaining a constant current to change the voltage value.
Uses of Resistor in Frequency and
Timing
Devices such as light flashers, electronic sirens, and blinking
lights on airplanes
or towers operate by storing electrical charge for a specific
duration and then releasing it as light.
In these cases, the resistor determines the amount of current
that flows based on the predetermined time.
By increasing the resistance, the discharge time of current in
the circuit is prolonged.
Uses of Resistor In Daily Life
The employment of resistors in heaters, toasters, microwaves,
electric stoves, and many other heating equipments is due to
the fact that they generate heat when conducting electricity.

In the evening, the street lights are automatically turned on, and
they are turned off in the daytime. This is because of
photoresistors, which allow them to detect light and darkness.

In the evening, the street lights are automatically turned on, and
they are turned off in the daytime.
This is because of photoresistors, which allow them to detect
light and darkness.
Photo resistor(LDR)
LDR (Light Dependent Resistor) as the name states is a
special type of resistor that works on the
photoconductivity principle means that resistance
changes according to the intensity of light.
Its resistance decreases with an increase in the intensity
of light.
It is often used as a light sensor, light meter, Automatic
street light, and in areas where we need to have light
sensitivity.
Look like
How are LDRs Made?
The Light-dependent resistors made with photosensitive
semiconductor materials like Cadmium Sulphides (CdS),
lead sulfide, lead selenide, indium antimonide, or
cadmium selenide and they are placed in a Zig-Zag
shape.
Two metal contacts are placed on both ends of the
Zig-Zag shape these metal contacts help in creating a
connection with the LDRs.
Now, a transparent coating is applied on the top so that
the zig-zag-shaped photosensitive material gets
protected and as the coating is transparent the LDR will
be able to capture light from the outer environment for
its working.
Look like
LDR Working Principle
It works on the principle of photoconductivity whenever
the light falls on its photoconductive material,
it absorbs its energy and the electrons of that
photoconductive material in the valence band (The
valence band is the band of electron orbitals that electrons can
jump out of, moving into the conduction band when excited. )get
excited and go to the conduction band
and thus increasing the conductivity as per the increase
in light intensity.
Types of Resistor
Conti…
Linear Resistors
The resistors whose value changes with the applied
temperature and voltage, are called linear resistors.
There are two basic types of resistors with linear
properties namely fixed resistors and variable resistors.
Fixed resistors
Fixed resistors are resistors with a specific value.
Fixed resistors one of the most widely used types of
resistor.
Fixed resistors are used in electronics circuits to set the
correct conditions in a circuit.
Conti….

Types of Fixed Resistors

1. Wire Wound Resistors

2. Carbon Film Resistors
Wire wound resistor
Wirewound resistors are constructed using a conductive wire.
The conductive wire is then wound around a non-conductive
core.
The conductive wire can be made of varying alloys and
thickness to control the resistance value.
Wirewound resistors are typically used in high power and
industrial applications such as circuit breakers and fuses.
Wire wound register
Carbon film resistor
A type of carbon resistor that uses carbon film to limit the flow of
electric current to a particular level is known as a carbon film
resistor.
These are fixed value type resistors that are designed out of a
ceramic carrier through a thin clean carbon film around it.
Here carbon film works like the resistive material.
The carbon film resistor symbol looks like a normal resistor
Carbon film resistor
Conti….
Variable Resistors
Variable Resistors consist of a slider which taps onto the
main resistor element and a fixed resistor element.
A variable resistor is a resistor of which the electric resistance
value can be adjusted.
Conti…..
Types of Variable Resistors
1. Potentiometer: A potentiometer is a three-terminal resistor
with a sliding or rotating contact that forms an adjustable
voltage divider.

2.Rheostat: A rheostat is a variable resistor that allows the
manual control of the flow of electric current by lowering or raising
the resistance.
3.Trimmer Resistor:Trimmers are mechanically driven, variable
resistors.
A wiper is moved across the resistance element, picking off an
intermediate voltage in the potentiometer mode
Trimmer resistor
How does resistor works?
A Resistor works by using this natural property of
resistivity/conductivity of any material.
It absorbs energy from the flow of electrons (electric energy)
and dissipates in the form of heat (thermal energy).
How does resistor works?
Resistor and Resistance || 3d Animated hindi explanation || Physics||
(youtube.com)
Non-Linear Resistor
Non-linear resistors are those types of resistors where the
electric current flowing through it changes with the
exchange in applied voltage or temperature
Thermistors
Thermistors are a type of variable resistor that notices
the change in temperature.
Photo Resistor or LDR (Light Dependent Resistors)
Photo Resistor or LDR (Light Dependent Resistors) or
Photo Conductive Cell is a light-controlled variable
resistor. The photo resistor resistance decreases with
increase in incident light intensity.
Capacitor
A capacitor is a two-terminal electrical device that can
store energy in the form of an electric charge.
It consists of two electrical conductors that are
separated by a distance.
The space between the conductors may be filled by
vacuum or with an insulating material known as a
dielectric.
The ability of the capacitor to store charges is known as
capacitance.
Capacitors store energy by holding apart pairs of
opposite charges
Look like
Conti….
An electric field appears across the capacitor.
The positive plate (plate I) accumulates positive
charges from the battery, and the negative plate (plate
II) accumulates negative charges from the battery.
After a point, the capacitor holds the maximum amount
of charge as per its capacitance with respect to this
voltage. This time span is called the charging time of
the capacitor.
When the battery is removed from the capacitor, the two
plates hold a negative and positive charge for a certain
time. Thus, the capacitor acts as a source of electrical
energy.
If these plates are connected to a load, the current flows to the
load from Plate I to Plate II until all the charges are dissipated from
both plates. This time span is known as the discharging time of
the capacitor.
What Are the Applications of Capacitors?

Capacitors for Energy Storage
Audio equipment
Camera Flashes
Power supplies
Magnetic coils
Lasers
Capacitors for Power Conditioning

Improve the quality of power
Capacitors allow only AC signals(exhibits both positive and
negative values) to pass when they are charged, blocking
DC signals(exhibits only positive values or only negative
values).
This capacitor effect is used in separating or decoupling
different parts of electrical circuits to reduce noise
as a result of improving efficiency.
What Is Alternating Current?
An alternating current can be defined as a current that
changes its magnitude and polarity at regular intervals of
time.
It can also be defined as an electrical current that
repeatedly changes or reverses its direction opposite to
that of Direct Current or DC, which always flows in a single
direction
Direct Current:In direct current, the voltage is always constant,
and the electricity flows in a certain direction.
Look like….
Capacitors as Sensors
Capacitors are used as sensors to measure a variety of
things including humidity, mechanical strain, and fuel
levels.
Two aspects of capacitor construction are used in the
sensing application – the distance between the parallel
plates and the material between them.
The former detects mechanical changes such as
acceleration and pressure,
and the latter is used in sensing air humidity.
Capacitors for Signal Processing
here are advanced applications of capacitors in
information technology.

Capacitors are used by Dynamic Random Access
Memory (DRAM) devices to represent binary information
as bits.
Look like
Types of Capacitors
According to structure:
1. Fixed Capacitors(fixed capacitance)
2. Variable Capacitors(variable capacitance)
3. Trimmer Capacitor(A trimmer capacitor differs from a regular
variable capacitor in that it's smaller, and its value is set initially
during production and is meant to be left there for some time
until an adjustment is needed.)
Fixed capacitor
Trimmer Capacitor
Variable capacitor
According to polarization:
According to polarization:
1. Polarized(capacitors are in use to accomplish high capacitive density)
2. A polarized capacitor is actually a capacitor that can only be
used in one voltage direction(DC)
3. Non-polarized capacitors are suitable for both AC and DC
supplies.
4. Non-polarized capacitors are capacitors without positive or
negative polarity.

Voltage is the force that makes electrons flow.
Current: Current is the rate of the flow of electrons.
Others types….
Ceramic Capacitors(The material in use within this capacitor type is
dielectric)
dielectric :insulating material or a very poor conductor of electric
current.

Film Capacitors
It consists polymer film, plastic film, or film dielectric.
Power Film Capacitors
Polypropylene film is in use as a dielectric in a capacitor.
Conti…..
Electrolytic Capacitors
In an electrolytic capacitor, a metallic anode covered with an oxidized layer.
It is in use as a dielectric.

Paper capacitors:
Paper capacitor is a fixed capacitor in which paper is in use as the dielectric
material.
How does capacitor works?
https://www.youtube.com/watch?v=R2QQ0yiqH_U
First, we can note that a metal typically has an equal amount of
positively and negatively charged particles, which means it’s
electrically neutral.
Conti….
If we connect a power source or a battery to the metal plates of
the capacitor, a current will try to flow,
or the electrons from the plate connected to the positive lead of
the battery will start moving to the plate connected to the negative
lead of the battery.
However, because of the dielectric between the plates, the
electrons won’t be able to pass through the capacitor, so they will
start accumulating on the plate.
Cont….
Conti….
After a certain number of electronics accumulated on the plate,
the battery will have insufficient energy to push any new
electronics to enter the plate
At this point, the capacitor is actually fully charged.
The first plate has developed a net negative charge,
and the second plate has developed an equal net positive
charge,
creating an electric field with an attractive force between them
which holds the charge of the capacitor.
Conti….
Capacitor Dielectric Working Principle
Let’s take a look how the dielectric can increase the capacitance
of the capacitor.
A dielectric contains molecules that are polar which means that
they can change their orientation based on the charges on the
two plates.
So the molecules align themselves with the electric field in such
a way enabling more electrons to be attracted to the negative
plate,
while repelling more electrons out of the positive plate.
So, once the it is fully charged, if we remove the battery, it will
hold the electric charge for a long time, acting as energy
storage.
Conti….
example
Connecting a new capacitor will increase the speed.
Capacitors are used to dump a burst of energy to give electric
motors a push to help them get spinning
Magnetic Field is the region around a magnetic material or a moving
electric charge within which the force of magnetism acts.
What is an inductor?
An inductor is a passive electronic component that temporarily
stores energy in a magnetic field when electric current flows
through the inductor's coil.
In its simplest form, an inductor consists of two terminals and an
insulated wire coil that either loops around air or surrounds a
core material that enhances the magnetic field.
Inductors help to handle fluctuations in an electric current
running through a circuit.
The inductor's ability to resist changes to the current is referred
to as its inductance, which is the ratio of voltage to the current's
rate of change within the coil.
Inductor look like
Conti….
When an electric current flows through a conductor such as
copper wire, the current generates a small magnetic field
around the wire.
If the wire is shaped into a coil, the magnetic field becomes
much stronger.
If the wire is coiled around a central core made up of a material
such as iron, the magnetic field grows stronger still -- this is
essentially how an electromagnet works. T
The magnetic field completely depends on the electric current.
Conti…
Inductors use the relationship between the electric current and
magnetic field to compensate for changes in the current's flow.
When the current begins to pass through the inductor's coil, the
magnetic field starts to expand until it finally stabilizes.
Until then, the coil inhibits the flow of current.
After the magnetic field stabilizes, the current flows through the
coil normally.
Conti…..
energy is stored in the magnetic field as long as the current
continues to run through the coil.
When the current stops flowing, the magnetic field starts to
collapse,
and the magnetic energy is converted back into electrical
energy,
which continues to flow into the circuit until the magnetic field
completely collapses.
Conti..
Inductance is a result of the induced magnetic field on
the coil.
It is also determined by several factors, such as
The shape of the coil.
The number of turns and layers of the wire.
The space that is given between the turns.
The size of the core.
How does inductor works?
https://www.youtube.com/watch?v=uW-M8eBHq9U
Different Types of Inductors
Depending on the type of material used, inductors can be
classified as follows:
1. Iron Core Inductor
2. Air Core Inductor
3. Iron Powder Inductor
4. Ferrite Core Inductor, which is divided into:
Soft Ferrite
Hard Ferrite
Iron Core Inductor

The core of this type of inductor is made of iron.
These inductors are low-space inductors that have high
power and high inductance value.
However, they are limited in high-frequency capacity.
These inductors are used in audio equipment.
Iron core conductor
Air Core Inductor

These inductors are used when the amount of
inductance required is low.
Since there is no core, it does not have a core loss.
But the number of turns the inductor must have is more
for this type when compared to the inductors with the
core.
This results in a high-quality factor.
Usually, ceramic inductors are often referred to as
air-core inductors.
Air Core Inductor
Iron Powder Inductor
In this type of inductor, the core is iron oxide.
They are formed by very fine and insulating particles of
pure iron powder.
High magnetic flux can be stored in it due to the air gap.
The permeability of the core of this type of inductor is
very less and is usually below 100.
They are mainly used in switching power supplies.
Iron Powder Inductor
Ferrite Core Inductor
In this type of inductor, ferrite materials are used as the
core.
Ferrites can be classified into two types: soft ferrites and
hard ferrites.
Soft Ferrite: These are materials that have the ability to
reverse their polarity without any external energy.
Hard Ferrite: These are permanent magnets, that is, their
polarity will not change even when the magnetic field is
removed.
Ferrite inductor
Functions of an Inductor

Inductors can be used for two primary functions:
1. To control signals.
2. To store energy.
Conti….
Controlling Signals
Coils in an inductor can be used to store energy.
The function of the inductor depends upon the
frequency of the current passing through it.
That is, higher frequency signals will be passed less
easily and vice versa.
This function tells that it blocks AC Current and passes
DC Current.
Hence, it can be used to block AC signals.
Storing Energy

Inductor stores energy in the form of magnetic energy.
Coils can store electrical energy in the form of magnetic
energy,
using the property that an electric current flowing
through a coil produces a magnetic field,
which in turn, produces an electric current.
In other words, coils offer a means of storing energy on
the basis of inductivity.
Semiconductors
Semiconductors are materials which have a conductivity
between conductors (generally metals) and nonconductors or
insulators (such as most ceramics).
Conductors are those substances through which electricity can
flow are called conductors.
Some common conductors are copper, aluminum, gold, and
silver.
Insulators are those substances through which electricity
cannot flow are called insulators.
Some common insulators are glass, plastic, rubber, and wood.
Why is called semiconductor?

A semiconductor is a material that has electrical resistance
more than conductors and less than insulators so that it can
conduct current not as fast as conductors but does not restrict
the flow of current as insulators.
So it kind of “semi” conducts the current.
Working of semiconductor through video

https://www.youtube.com/watch?v=8LUL2cBoJ48
How does semiconductor works?
Carbon, silicon and germanium (germanium, like silicon, is also
a semiconductor) have a unique property in their electron
structure -- each has four electrons in its outer orbital.
This allows them to form nice crystals.
The four electrons form perfect covalent bonds with four
neighboring atoms, creating a lattice.
A covalent bond is formed by the equal sharing of
electrons from both participating atoms. The pair of
electrons participating in this type of bonding is called a
shared pair or bonding pair. Covalent bonds are also
called molecular bonds.
Look like
Conti…
In a silicon lattice, all silicon atoms bond perfectly to four
neighbors, leaving no free electrons to conduct electric current.

This makes a silicon crystal an insulator rather than a
conductor.
Why metals are good conductors of
electricity?
Metals tend to be good conductors of electricity because they
usually have "free electrons" that can move easily between
atoms, and electricity involves the flow of electrons.
While silicon crystals look metallic, they are not, in fact, metals.
All of the outer electrons in a silicon crystal are involved
in perfect covalent bonds, so they can't move around.
A pure silicon crystal is nearly an insulator -- very little electricity
will flow through it.
But you can change all this through a process called doping.
Doping Silicon
You can change the behavior of silicon and turn it into a
conductor by doping it.
In doping, you mix a small amount of an impurity into the silicon
crystal.
There are two types of semiconductor materials on the basis of
impurities:
1.Intrinsic semiconductors
2.Extrinsic semiconductors
N-type
P-type
N-type
In N-type doping, phosphorus or arsenic is added to the silicon
in small quantities.
Phosphorus and arsenic each have five outer electrons, so
they're out of place when they get into the silicon lattice.
The fifth electron has nothing to bond to, so it's free to move
around.
It takes only a very small quantity of the impurity to create
enough free electrons to allow an electric current to flow
through the silicon.
N-type silicon is a good conductor.
Electrons have a negative charge, hence the name N-type.
P-Type
In P-type doping, boron or gallium is the dopant.
Boron and gallium each have only three outer electrons.
When mixed into the silicon lattice, they form "holes" in the
lattice where a silicon electron has nothing to bond to.
The absence of an electron creates the effect of a positive
charge, hence the name P-type.
P-type silicon is a good conductor.
Applications of semiconductor devices
They are used in the designing of logic gates and digital
circuits.
These are used in microprocessors.
They are also used in analog circuits such as oscillators
and amplifiers.
Used in high voltage applications.
diagram
Types of Semiconductor devices

Diode : Light Emiting Diode(LED)
Photo diode: Zener diode
LCD : solar cell
Diode
A diode is a semiconductor device that comprises a
single p-n junction.
P-n junctions are usually formed by joining up of p-type
and n-type semiconductor materials.
This formation is due to the reason that the n-type
region has a higher number of electron concentrations
whereas the p-type region has a higher number of hole
concentrations,
hence, the electrons get diffused from the n-type region
to the p-type region.
Hence, this phenomenon is used in generating light.
Diode, an electrical component that allows the flow of current in
only one direction. In circuit diagrams, a diode is represented
by a triangle with a line across one vertex.
Uses of diodes
Diodes help in performing digital logic.

They are used for isolating signals from a supply

They are also used in creating power supplies and
voltage doublers.

The light emitting diodes or LEDs are used in sensors and
also in laser devices any many other light illumination
devices.
Zener diodes are used as voltage regulators.
Working of diode
In the N-type region, the majority of charge carriers are
electrons and the minority of charge carriers are holes.
Whereas, In the P-type region, the majority of charge carriers
are holes and the minority of charge carriers are electrons.
Because of the concentration difference, the diffusion takes
place in majority charge carriers and they recombine with the
minority charge carriers which are then collected near the
junction and this region is known as the Depletion Region.
Unbiased pn junction
Video working of diode
https://www.youtube.com/watch?v=qu9reCzzrco
Reverse Bias condition
When the anode or p-type terminal of the diode is connected
with a negative terminal of the battery

and the n-type or cathode is connected with the positive
terminal of a battery, this type of connection is called a Reverse
Bias condition.
Look like
Importance of reverse bias
Positive terminal attracts the electrons away from the junction in
N side and negative terminal attracts the holes away from the
junction in P side.
As a result of it, the width of the potential barrier increases that
impedes(delay) the flow of majority carriers in N side and P side.
What is the importance of forward bias?
It decreases the potential barrier strength in the circuit.
Forward bias has a very thin depletion layer compared to
reverse bias.
It minimises the circuit resistance, increasing the current flow.
Forward Bias Condition
When the anode or p-type terminal of the diode is connected
with a positive terminal
and the n-type or cathode is connected with the negative
terminal of the battery,
this type of connection is called a Forward Bias condition.
Look like
LED
A light-emitting diode (LED) is a semiconductor device
that emits light when an electric current flows through it.
When current passes through an LED, the electrons
recombine with holes emitting light in the process.
LEDs allow the current to flow in the forward direction
and blocks the current in the reverse direction.
Look like
Conti…
Light-emitting diodes are heavily doped p-n junctions.
Based on the semiconductor material used and the
amount of doping, an LED will emit coloured light at a
particular spectral wavelength when forward biased.
As shown in the figure, an LED is encapsulated with a
transparent cover so that emitted light can come out
LED Symbol
Simple LED Circuit :The circuit consists of an LED, a voltage supply
and a resistor to regulate the current and voltage.
How does LED work?
https://www.youtube.com/watch?v=tPFI2_PdCYA
Valence band:The valence band is simply the outermost electron
orbital of an atom of any specific material that electrons actually
occupy
Conduction band:
The conduction band is the band of electron orbitals that
electrons can jump up into from the valence band when excited.
When the electrons are in these orbitals, they have enough
energy to move freely in the material.
This movement of electrons creates an electric current.
Working of LED
Conti…
EXPLANATION
IN THE FORWARD BIAS THE FLOW OF CURRENT in the battery will be
from +ve to –ve but the flow of electron will be from –ve to +ve.
Due to external voltage when the potencial barrier break the electron
will move from n type to p type(higher energy level to lower energy
level).

Due to this energy difference the light will be emit in the form of
photons.
At the end….
The energy is released in the form of photons on
recombination.
In standard diodes, the energy is released in the form of
heat.
But in light-emitting diodes, the energy is released in the
form of photons.
We call this phenomenon electroluminescence.
Electroluminescence is an optical phenomenon, and
electrical phenomenon where a material emits light in
response to an electric current passed through it.
As the forward voltage increases, the intensity of the
light increases and reaches a maximum.
Difference between depletion layer and forbidden
energy gap
1. The gap between the valence band and the conduction band is
referred to as the forbidden gap.
2. The difference in energy levels between the conduction band
and valence band is known as the forbidden energy gap.
3. No electron stays in the forbidden band.

The depletion region is a region near the junction of a
semiconductor device where there are no free charge carriers.
In this region, the forbidden energy gap plays a role in creating a
potential barrier that prevents the flow of current.
What is the difference between depletion layer and
barrier potential?
Potential barrier : The potential difference established across the
p-n junction due to diffusion of electrons from n-region to p-region
is called potential barrier.
Depletion region : It is a layer created around the p-n junction
which is devoid of free charge carriers and has immobile ions
only.
What determines the colour of an LED?
The colour of the light emitted by the LED depends on the
wavelength of the light which in turn depends on the
semiconductor material used in the diode while
manufacturing LED.
Aluminium alloys are used to obtain red, orange and
yellow light, and
indium alloys are used to get green, blue and white light.
Slight changes in the composition of these alloys change
the colour of the emitted light.
Alloys:
Photo diodes:
Photodiodes are a class of diodes that converts light energy to
electricity.
Their working is exactly the opposite of LEDs which are also
diodes but they convert electricity to light energy.
Photodiodes can also be used in detecting the brightness of the
light.
Photodiodes are designed to work in reverse bias condition.
Typical photodiode materials are Silicon, Germanium and Indium
gallium arsenide.
They are also called a photo-detector, a light detector, and a
photo-sensor
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Zener Diode
A Zener Diode, also referred to as a breakdown diode, is a
specially doped semiconductor device engineered to
function in the reverse direction.
When the voltage across a Zener diode’s terminals is
reversed and reaches the Zener Voltage (also known as the
knee voltage), the junction experiences a breakdown,
allowing current to flow in the opposite direction.
This phenomenon, known as the Zener Effect, is a key
characteristic of Zener diodes.
In this condition when the electric field increases to a high value it
enables the tunnelling of electrons from the valence band to the
conduction band of a semiconductor, which suddenly increases the
reverse current.

Why Zener diode?
Working of Zener diode
What is Zener Diode ? | Difference between Zener Diode and PN
junction Diode (youtube.com)

Zener Diodes: Characteristics & Working Principle (youtube.com)
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In reverse the voltage across Zener diode will remain constant even
though the current changes, due to this property it is used as voltage
regulator.
V-I characteristics
Look like
Applications and Uses of Zener Diode can be seen in the
following:
Zener diode acts as a voltage regulator
Zener diode protects from over voltage
When the input voltage increases and reaches the Zener
breakdown voltage, the current through the diode will
create a voltage drop across the resistor. This triggers a
short circuit to the ground.
Zener diode is used in clipping circuits
Clipper circuits are used to prevent the output signal
from going beyond a determined value without
changing anything of the input signal.
Zener diode can be used to shift voltage
Zener diode’s core uses include converting a signal from
one voltage to another.
What is the Full form of LCD?
The full form of LCD is Liquid Crystal Display.
it is a passive device, which means that it does not deliver any
light to display characters, animations, videos, etc.
LCD uses fluorescent tubes to lighten the picture.
It is a flat panel display technology, mainly used in TVs and
computer monitors, nowadays it is used for mobile phones also.
These LCDs are completely different from that
old CRT displays, it uses liquid crystals instead of cathode ray
in its primary form of operation.
LCD
In LCD display, it consists of millions of pixels made of crystal
and arranged in a rectangular grid.
In LCD it has backlights that provide light to each pixel.
Each pixel has a red, green, and blue (RGB) sub-pixel that can be
turned on or off.
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LCD is a combination of two states of matter, the solid and the
liquid.
The solid part is crystal and the liquid and crystal together
make the visible image.
LCD consists of two layers which are two polarized panels-
filters and electrodes.
LCD screen works by blocking the light rather than emitting the
light. There are two types of pixel grids in LCD:
Active Matrix Grid– It is a newer technology. In smartphone
with LCD display uses this technology.
Passive Matrix Grid– It is an older technology.
Characteristics of LCD
Resolution: LCD is made up of liquid crystal, which is neither
liquid nor solid, and this thing reflects the light in a well-formed
way, lights enter into the crystal and reflect very clearly. So the
image made with this liquid crystal is very accurate.
Brightness: Brightness means the light provided by the LCD,
which is nothing but the intensity of visible light,
Contrast Ratio: It is the ratio of the brightest color and the
darkest color for a particular position of the screen provided by
the display.
Response Rate: Response Rate is high in LCD, it means the time
required for changing colors of the pixels is very much less
Working principle of LCD
Polarized light and Unpolarized light
The light waves which travel only in a single plane are known as
polarized light waves.
The process of transforming unpolarized light waves to polarized
light waves is called the polarisation of light.
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Advantages of LCD :
The main advantage of LCD is, it has low in cost and energy
efficient and very less power consumption.
LCD is thinner and lighter and very flexible.
LCD provides excellent contrast, brightness and resolution, so
the picture quality is very clear like a crystal.
Radiation of LCD monitors are much less than CRT monitors.
It provides various conveniences like portability as compared to
previous technology based screens.
Solar cell
A photovoltaic (PV) cell, commonly called a solar cell, is a
nonmechanical device that converts sunlight directly into
electricity.
Some PV cells can convert artificial light into electricity.
It is defined as a device whose electrical characteristics,
such as current, voltage, or resistance, vary when
exposed to light.
Solar cells are the building blocks of photovoltaic
modules, otherwise known as solar panels.
Applications of solar cells
used as a photodetector.
Detect light or other electromagnetic radiation near the
visible range,
measure light intensity.
Solar cells are often bundled together to make larger units
called solar modules, themselves coupled into even bigger
units known as solar panels.
Just like the cells in a battery, the cells in a solar panel are
designed to generate electricity;
a battery’s cells make electricity from chemicals,
a solar panel’s cells generate power by capturing sunlight
How does a Solar Cells work?
A solar cell is a sandwich of n-type silicon and p-type silicon
It generates electricity by using sunlight to make electrons hop
across the junction between the different flavors of silicon
1. When sunlight shines on the cell, photons (light particles)
bombard the upper surface.
2. The photons carry their energy down through the cell.
3. The photons give up their energy to electrons in the lower,
p-type layer.
4. The electrons use this energy to jump across the barrier into
the upper, n-type layer and escape out into the circuit.
5. Flowing around the circuit, the electrons make the lamp light
up.
Video(how does solar cell works?)
How do Solar cells work? | #PNjunction solar cell | #solarenergy
Explain (youtube.com)
Advantages of solar panels
Solar energy is a renewable energy source and reduces carbon
emissions
Solar energy can reduce your home’s electricity bill
Solar panels have low maintenance costs
Solar energy can generate electricity in any climate