Download Basic Electronics

Basic Electronics
BHAVIN V KAKANI
ELECTRONICS & COMMUNICATION ENGINEERING, IT-NU
D-BLOCK, ROOM NO. 100, EXT. 421
EMAIL: [email protected]
Course Details:

Course Code : EC321
Course Title : Basic

Electronics
Teaching scheme : Lecture – 03 hours
Tutorial - 00 hours
Practical – 02 hours

Credit : 04
Course Instructors

Prof. Twinkle Bhavsar

Prof. Rachna Sharma
(Course Coordinator)

Prof. Bhavin Kakani
Course Objective:
“To learn fundamentals and all the aspects of the electronic
devices and circuits, starting from semiconductor diodes,
transistors to amplifiers, power supplies and design of
different types of electronics circuits.”
Course Learning Outcomes:
After successful completion of this course, student will be able to:
1. Understand the fundamentals of various basic semi-conductor
devices and principles of analog electronics
2. Apply the knowledge of basic semi-conductor devices to realize the
working of basic electronic circuits
3. Design basic electronic circuits
Course Syllabus
Semiconductor Diodes: Classification of semiconductors, conductivity of
semiconductors, Theory of PN-Junction Diode, Energy band structure, Diode
Resistance, Transition Capacitance, Diffusion Capacitance, Junction
Diode Switching Characteristics, Break-down in Junction diode, PN Diode
Applications, Zener diode, Varactor Diode, Schottky Diode, LED and Laser
Diode.
 Bipolar Junction Transistor: Construction, Biasing, NPN, PNP transistors, types
of configurations, Break-down in transistors, Bias stability, methods of
transistor biasing, bias compensation, heat sink
 Field Effect Transistor: Construction of FET, Operation of JFET, characteristic
parameters of JFET, Transfer characteristics of FET, comparison of JFET and
BJT, applications of JFET, MOSFET, enhanced MOSFET, depletion MOSFET,
comparison of MOSFET with JFET
 Amplifiers: small signal h-parameters, Classification, Single Stage Amplifier,
FET amplifier, classification based on biasing condition, multistage amplifier.


Operational Amplifier: Ideal Opamps, Opamp stages, parameters,
equivalent circuits, IF-opamp, opamp applications, Bandwidth with
feedback, noise, frequency response and compensation

Feedback Amplifiers: Basic concepts of feedback, effects of negative
feedback, type of negative feedback connections, stability of
feedback amplifiers

Principle of Oscillator: classification, condition per oscillation, RC
Oscillators, Wein-Bridge Oscillators, Crystal Oscillators, wave shaping
circuits

Power Supplies: Linear mode power supply, switch mode power supply

Design of electronics circuit: Design of rectifier, power supply, design of
amplifier, oscillator.
Text Book/ Reference Book:
Text Book:

Electronics devices & circuits by S. Salivahanan, N. Sureshkumar & A.
Valiavaraj-TMH publications.
Reference Books:
1. Electronics principles by Malvino-McGraw Hill
2. Electronics Devices & Circuits by Bell PHI publications.
3. Electronics Principle by V K Mehta S Chand Publications
4. Electronics Devices & Circuits by Boylested
E-book:

Science Ebook Basic Electronics Online Ebook with simulations and
troubleshooting. a science-ebooks.com publication
Course related web links
Hand-outs and Lecture notes
•
https://sites.google.com/a/nirmauni.ac.in/ec321-basic-electronics/
Blog
•
https://ec321vhd.wordpress.com
•
http://basic-electronic.blogspot.in/
NPTEL Lectures
•
http://nptel.ac.in/courses/117103063/
•
http://library/t/NPTEL/ECE_Basic_Electronics.htm
Virtual lab
•
www.vlab.co.in
Hobby Projects
1. http://101science.com/Radio.htm
2. http://www.101science.com/transistor.htm
3. http://www.101science.com/transistor.htm#Semiconductors
4. http://www.101science.com/transistor.htm#TUTORIALS
5. http://www.repairfaq.org/sam/electron/basicelectr.pdf
Useful Software
1. Multisim software
2. Circuit design tool
3. Ulti-board
4. Eagle
5. Proteus
A Cancer Cure Team
Khaled Barakat
Electrical Engineer
Hu Jintao
Hydraulic Engineer
Economist, Physician, Robotic
Engineer
Upcoming Engineering branches
and Master courses:

Astronautics Engineering

Optomechatronics Engineering

Aquaculture Engineering

Avionics

Biomechanical Engineering

IOT Engineering

Mechatronics Engineering

Rehabilitation Engineering

Biotechnical Engineering

Neural Engineering

Bioprocessing Engineering

Nanotechnology

Information and Electrical systems
Engineering

Health Technology

Clinical Engineering

Bioinstrumentation Engineering

Natural resources Engineering
Computer science specialization
(AMERICAN HIGHER EDUCATION INFORMATION CENTER)

Artificial Intelligence

Cognitive science

Computer Information systems (CIS)

Computer graphics

Computer Networks

Robotics

Telecommunication Engineering

Quantitative and Computational biology

Applied and computational mathematics
Chapter 1:
Semiconductor
Diodes
Chapter Objective

Aware about the general characteristics of 3 important semiconductor
materials: Si, Ge, GaAs.

Understand conduction using electron and hole theory

Realize n-type and p-type material

Develop clear understanding of operation and characteristics of a
diode in the different biasing conditions

Calculate ac, dc and average ac resistance of a diode from the
characteristics

Learning special diodes like Zener diode and LEDs.

Different applications of the diode
Semiconductors

Materials that permit flow of electrons are called conductors (e.g., gold, silver, copper,
etc.).

Materials that block flow of electrons are called insulators (e.g., rubber, glass, Teflon, mica,
etc.).

Materials whose conductivity falls between those of conductors and insulators are called
semiconductors.

Semiconductors are “part-time” conductors whose conductivity can be controlled.
Semiconductor Material
Silicon

Atomic density: 5 x 1022 atoms/cm3

Si has four valence electrons. Therefore, it can form covalent bonds
with four of its nearest neighbors.

When temperature goes up, electrons can become free to move
about the Si lattice.
Electronic Properties of Si
 Silicon is a semiconductor material.

Pure Si has a relatively high electrical resistivity at room temperature.
 There are 2 types of mobile charge-carriers in Si:


Conduction electrons are negatively charged;
Holes are positively charged.
 The concentration (#/cm3) of conduction electrons & holes in a
semiconductor can be modulated in several ways:
1.
2.
3.
4.
by adding special impurity atoms ( dopants )
by applying an electric field
by changing the temperature
by irradiation
Electron-Hole Pair Generation

When a conduction electron is thermally generated, a “hole” is also
generated.

A hole is associated with a positive charge, and is free to move
about the Si lattice as well.
Carrier Concentrations in Intrinsic Si

The “band-gap energy” Eg is the amount of energy needed to
remove an electron from a covalent bond.

The concentration of conduction electrons in intrinsic silicon, ni,
depends exponentially on Eg and the absolute temperature (T):
ni  5.2 10 T
15
3/ 2
exp
 Eg
2kT
electrons / cm3
ni  11010 electrons / cm3 at 300K
ni  11015 electrons / cm3 at 600K
Doping (N type)

Si can be “doped” with other elements to change its electrical
properties.

For example, if Si is doped with phosphorus (P), each P atom can
contribute a conduction electron, so that the Si lattice has more
electrons than holes, i.e. it becomes “N type”:
Notation:
n = conduction electron
concentration
Doping (P type)

If Si is doped with Boron (B), each B atom can contribute a hole, so
that the Si lattice has more holes than electrons, i.e. it becomes “P
type”:
Notation:
p = hole concentration
Summary of Charge Carriers
Electron and Hole Concentrations

Under thermal equilibrium conditions, the product
of the conduction-electron density and the hole
density is ALWAYS equal to the square of ni:
np  ni
N-type material
n  ND
2
n
p i
ND
2
P-type material
p  NA
2
n
n i
NA
Terminology

donor: impurity atom that increases n

acceptor: impurity atom that increases p

N-type material: contains more electrons than holes

P-type material: contains more holes than electrons

majority carrier: the most abundant carrier

minority carrier: the least abundant carrier

intrinsic semiconductor: n = p = ni

extrinsic semiconductor: doped semiconductor
Summary

The band gap energy is the energy required to free
an electron from a covalent bond.


Eg for Si at 300K = 1.12eV
In a pure Si crystal, conduction electrons and holes
are formed in pairs.
Holes can be considered as positively charged mobile
particles which exist inside a semiconductor.
 Both holes and electrons can conduct current.


Substitutional dopants in Si:
Group-V elements (donors) contribute conduction
electrons
 Group-III elements (acceptors) contribute holes
 Very low ionization energies (<50 meV)
