Electronics Spectra - SMS Lucknow

an ece publication
VOL. I 2010
spectra
electronics
Claytronics CAM Green Laser MEMS
ASIC
SED
virtually redefined
Sixth Sense Technology
Bio-Metrices
securing future
Project
DTMF Controlled Robot
Counselling Arena
IES
CAT 2011
GATE 2011
Campus Interview
Retina based
Security System
E lectronics Unborn
Deptt. of electronics & Communication Engg.
SMS-IT, Lucknow

DEPARTMENT OF
ELECTRONICS & COMMUNICATION
Electronics and Communication Engineering is one of the most upcoming area of Research & Engineering
among all other branches of engineering. As of today, Electronics and Communication Engineers are
working in all spheres of modern industry. The goal of this course is to impart all around technical education
to the students to fulfill requirements of new challenges of industries as well as to find new ways to solve the
practical problems of our daily life.
The Department of Electronics and Communication Engineering was established in the year 2008 in SMS
INSTITUTE OF TECHNOLOGY, LUCKNOW. The department has well equipped Labs as :
Electronic Workshop & PCB Lab
Electronics circuit Lab
Digital Electronics lab
Measurement Lab
Integrated Circuit Lab
Advanced Communication lab
Microprocessor Lab
Control System Lab
Micro-wave & Research Lab
Design & Simulation Lab
The department has prominent Faculty members having a vast experience in their field.
Industrial visits and practical projects are also encouraged by the department in various sectors. Students
are also taken out to industries for practical understanding of the new technologies. Recently we had an
Industrial Tour to NEDA, Lucknow and a Seminar on Embedded Technology.

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
MESSAGE
Dear Students,
This gives me immense pleasure to say few words for the intellectual initiative
taken by the students of Electronics & Communication Engineering, in bringing out
the first issue of “Electronics Spectra”.
I am confident that the initiative will not only bring laurels to the student community
but will also open new vista for further innovations.
Sustaining the professional impeccability of a new age “Technology Magazine” is a
daunting challenge and we must be armed to face it.
The passage of time will ensure the acceptability of the contributions of the writers.
The critical feedback of the readers shall build a continuous improvement system that will lead the Electronics
Spectra towards excellence.
Wishing Electronics Spectra a grand success in the future.
With best wishes!!
Sharad Singh
Chief Executive Officer
SMS Group of Institutions, Lucknow
I am pleased to know that the Department of Electronics & Communication Engineering
of SMS Institute of Technology, Lucknow is bringing out its first issue of
"Electronics Spectra" . I extend my best wishes on the occasion of the publication of the
first issue of the technical magazine.
I hope this magazine will be a treasure for those associated with Electronics &
Communication Engineering and will help in providing a platform for sharing experiences
& learning in this area.
I once again congratulate the Electronics & Communication Engineering Department
and the entire team on this endeavour and wish the Technical Magazine all success.
Dr. G.D. Singh
Director
SMS Institute of Technology, Lucknow
It is a matter of great pleasure to know that Electronics and Communication Engineering
Department of SMS Institute of Technology Lucknow is releasing its first Departmental
Magazine - “Electronics Spectra” in the month of October 2010, with participation
of students and faculty members. It would definitely provide a platform to
enhance the talent of students as well as faculty members and create good academic
environment.
I trust this will prove a very successful endeavour in future to evolve a team of
intellectuals who will share their views with such magazine for the growth of Institute
and development of nation as a whole.
I congratulate to Mr. Rahul Mishra, HOD, EC, faculty members and team of students, who are contributing
in the publication of first Departmental Magazine and wishing for its long way success.
Prof. B.R. Singh
Associate Director
SMS Group of Institutions, Lucknow
3 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
It’s a matter of delight to know about the 'Electronics Spectra' a magazine by department
of Electronics & Communication Engineering. As the magazine is going to
be a profound source of information and knowledge in the field of electronics and
communication, I expect from the readers to enjoy it to its fullest.
The moves like this generate a positive and creative current in the campus and I
appreciate the enthusiasm shown by the students in making it to happen.
At last, I congratulate Mr. Rahul Mishra, chief editor of the magazine for his constructive
initiation. I would also like to congratulate the students for their vibrant and dynamic endeavours.
I wish the magazine a grand success with best compliments.
Dr. Dharmendra Singh
Dean Academic
SMS Institute of Technology, Lucknow
Dear students,
Every achievement is rooted deep in hard work, determination and dedication. The
best of learning's get tested through the journey of life. In that sense we all are studen ts
of life. At the end I would like to share with you a success formula-
"Desire + Stability = Resolution + Hard work = Success"
I am sure each one of you is capable of contributing to the bright future. Best
wishes to all my student friends.
R S Bajpai
Reader, EN Department,
SMS Institute of Technology, Lucknow
It is our great pleasure that Department of Electronics & Communication Engineering,
SMS Institute of Technology has taken a step forward to start a compiled
informative magazine named "ELECTRONICS SPECTRA". This will provide a platform
to the students, faculty members as well as professionals to express their knowledge.
I congratulate Mr. Rahul Mishra, Chief Editor of the magazine on behalf
of Computer Science & Engineering Department for his initiative.
I wish a grand success, to growth and utility of the magazine.
Sudhakar Tripathi
HOD
Computer Science & Engineering Department
SMS Institute of Technology,Lucknow
4 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Contents
Department of Electronics & Co mmunication
5 Sixth sense technology
7 Biometrics
11 Retina based security system
13 Claytronics : Turning dream into real
16 CAM: Memory faster than RAM
20 Application specific integrated circuit
22 Smart dust
24 Genetic algorithms
26 Junctionless transistor
27 Green laser
29 IPTV: The future TV
31 MEMS
34 NN Power Planner
36 Plasmonics
39 Ground Penetrating Radar
40 Surface-conduction electron-emitter
display
Regular Columns
10 GATE - The way of success
18 Indian Engineering Services (IES)
28 Campus interview
33 Electronics unborn
38 Common Admission Test (CAT)
43 Tech-Buzz-Arena
44 Project : Mobile phone operated
robot
46 Campus interview paper
41 E -Waste
5 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Month : October Year : 2010
Volume : 1
“Electronics Spectra”
CHIEF EDITOR
Mr. Rahul Mishra
EDITORIAL BOARD
Faculty
Mr. Nikhil Jaiswal
Ms. Neha Srivastava
Mr. Kamran Akhtar
Mr. Rakesh Seth
Ms. Sadaf Rizvi
Students
Mr. Sudhanshu Shekhar Singh
Mr. Jaikar Sahai
Mr. Ashutosh Vikram Singh
Mr. Gaurav Mishra
SPECIAL THANKS TO :
Mr. Saurabh Shukla (Lecturer)
Mr. S.S. Rawat (DTP-cum-S.O.A.)
Mr. Mahesh Kr. Yadav (DTP)
Mr. Prabhat Singh (LI)
Mr. Aman Srivastava
Mr. Kislaya Srivastava
Mr. Prashant Mathur
Ms. Ritu Gupta
Mr. Parama Hans
Mr. Arvind Kr. Chaubey
From the Editor’s Desk.......
Department of Electronics & Co mmunication
It brings me a lot of pleasure in bringing
up the first Edition of Electronics
Spectra , the departmental magazine
of Electronics & Communi cation
Engineering. The magazine consist of
articles and columns related t o Projects,
Future of electronics, Career counseling
and various horizons of the field of electronics and
communication engineering.
The magazine is an outcome of students audent efforts as
well as sincere guidance of th e faculty of the Department.
As an editor, I am pleased to see the quality of the article s
submitted by the students and I expect this movement
will help them in developing their research and presentation
skills.
I also feel that the magazine will provide proper guidance
and information about the Covered field to the readers .
At last, I congratulate the students for their efforts and
endeavours. I am also thankful to the Management of the
Institution for providing me s uch an atmosphere and their
continuous support.
With Best Wishes
Rahul Mishra
Chief Editor &
HOD of ECE
mail us at
electronics.spectra@gmail.com
6 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Sixth sense technology
Department of Electronics & Co mmunication
Arvind, Param Hans & Ritesh
EC -III year
INTRODDUCTION
MANY of us might have heard
about the sixth sense in Hollywood
movies, but ever thought that
you will be able to use it as a technology?
If you are from those who just
believe that there are only five senses
then I must say you are wrong. Because,
those five senses are provided
by nature. Now technology is going
to provide you an additional s ense
named as sixth sense. It’s an exciting
new research from MIT students
which have been experimented successfully,
and soon we will find it in
the market as a wearable gestural interface.
Ever since computers began to be
a part of mankind, their evolution has
been taking place at break nec k
speed. And now we are about to
witness the power of computing and
on demand information just like the
Sci-fi thrillers of Hollywood have portrayed
for many years. Sixth S ense
Technology is one such recent invention
which aims to blend in the boundaries
between the virtual and the real
world. The mastermind behind t his
futuristic technology is Pranav Mistry,
a designer whiz kid.
WHAT IS SIXTH SENSE
TECHNOLOGY?
Pranav Mistry, a student at th e
Media Lab of Massachusetts Institute
of Technology (MIT), has developed
a gestural interface device which enables
enrichment of the physical world
with knowledge that is digital and allows
a person to use natural motions
to act together with this information
so received. This device, tent atively
named as the Sixth Sense, is a wearable
machine that assists unexplored
interactions between the real and the
virtual sphere of data. It consists of
certain commonly available com ponents,
which are intrinsic to its functioning.
These include a camer a, a
portable battery-powered projection
system coupled with a mirror a nd a
cell phone. All these componen ts
communicate to the cell phone, which
acts as the communication
and computation
device. The entire hardware
apparatus is encompassed
in a pendantshaped
mobile wearable
device. Basically the camera
recognises individuals,
images, pictures, gestures
one makes with
their hands and the projector
assists in projecting
any information on whatever
type of surface is
present in front of the
person. The usage of the
mirror is significant as the
projector angles pointing
downwards from the neck. To br ing
out variations on a much higher plane,
in the demo video which was broadcasted
to showcase the prototype to
the world, Mistry uses coloured caps
on his fingers so that it becomes simpler
for the software to diffe rentiate
between the fingers, demanding various
applications. The software program
analyses the video data caught
by the camera and also tracks down
the locations of the coloured markers
by utilising single computer vision techniques.
One can have any number of
hand gestures and movements as long
as they are all reasonably ide ntified
and differentiated for the sys tem to
interpret it, preferably through unique
and varied fiducials. This is possible only
because the ‘Sixth Sense’ device supports
multi-touch and multi-user interaction.
DEVELOPMENTAL
STAGES
The idea behind this technolog y
is to simplify day-to-day tasks and integrate
them with the virtual world.
This technology was born with the
simple modification of a ball mouse into
a motion sensing device. The a xial
rollers found in the ball mouse were
used to replicate the gestures made
with hand on the computer. The
much-loved sticky notes were a lso
implemented with this, one exception
being that our scribble work on them
would be directly synchronized with
the computer or a scheduling device
which can also be organized ef fortlessly.
With the virtual interaction in place,
the next obvious step was to bring in
instant information to the user. Sixth
sense technology is set to red efine
the way information can be searched
for. The information could be accessed
by merely placing the object of interest
on the interactive plane w ithout
even having to GOOGLE it! So t o
check your flight schedule, all that you
have to do is place your ticket on the
interactive surface and watch in awe
as you are flooded with the details.
DEVICE SET UP
The Sixth sense device is a complete
surprise package when it comes
to its functionality and hardware. Just
as the device simplifies human craving
for information, it simplifies the way
you interact with it. You don’ t have
to be a rocket scientist to be absolutely
at ease operating it. T he device
has a portable camera, projector
and few color markers stuck onto the
fingers for gesture tracking.
The big plus of this device is that
you need not to carry a monitor display
with you wherever you go.
Rather you can magically turn any surface
of your choice into a vir tual
screen and start interacting with the
7 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
projected information. The dev ice is
a network enabled module which allows
you to access the internet, cruise
through maps when you are stuck in
a tour, check your mails and a lso
doubles up as your virtual mob ile
phone.
HOW IT WORKS
The technology in itself is nothing
more than the combination of s ome
stunning technologies, but the idea
of combining those technologie s is
really great. The technology is mainly
based on hand gesture recognit ion,
image capturing, processing, and manipulation,
etc. The camera is used
to recognize and track user’s hand
gestures and physical objects using
computer-vision based techniqu es,
while the projector is used to project
visual information on walls or on any
physical thing around us. Other hardware
includes mirror and colored caps
to be used for fingers
The software of the technology
uses stream, which is captured by the
camera, and also tracks the location
This device, which can only be
found in Think Geek, is a kind of mobile
phone charger that can power up
your phones via induction. It also
works easy enough. You only have to
slide your phone into the included receiver
case and watch as your phones
get juiced up. Once your phone is completely
charged, this Air Volt Wireless
Phone Charger will automatically turn
off.
Here are the features of this
AirVolt Wireless Phone Charger:
* Compatible with I Phone 3G/3G.
* Works via induction - Tesla would
be so proud of us.
* Dimensions: 5.5 x 4.5
(14 x 11.5cm).
* A/C Power: 100-240VAC, 50/
60Hz, .5A (Input); 9VDC, 1A
(Output)
* Includes: charging tray, receiver,
A/C power supply, instruction.
of the tips of the fingers to recognize
the gestures. This process is done
using some techniques of compu ter
vision.
SIXTH SENSE VS
MICROSOFT DIGITAL
SURFACE
The other recent development
which introduced the multi-tou ch
functionality and gesture inte rpretation
technology is the Microsoft Surface
from the computer technol ogy
giants, the Microsoft Corporation. But
Pranav Mistry’s invention wins hands
down with respect to the Micro soft
Surface because of its down to earth
price, portability, and mass popularity.
Pranav Mistry and his mentor P attie
Maes got rave reviews for their presentations
in the Ted conferences held
at India and USA respectively. Moreover
the Microsoft Surface is aimed at
the commercial market with only a few
ready to experiment with it considering
the huge investment involved.
Thus Sixth Sense Technology is
Air volt wireless phone charger
A revolutionary charger for your
mobile phones
* Charger similar to other phones.
Although not officially licensed by
Apple Inc., the AirVolt Wireless Phone
Charger is worth about $49.99.
Udit Narayan
EC - II year
one fuss free device which is set to
bless mankind with an extra sense in
spite of the individual’s spiritual status.
So let us all gear up to explore
the world around us Virtually the video.
SIXTH SENSE
APPLICATIONS
The sixth sense also implement s
map which let the user to display the
map on any physical surface and find
his destination by just using his gestures.
The device is cool enough that
it can display current time on your
wrist as well as recognize people by
projecting information related to
them.The important thing is that the
device is a mobile device. Means, it is
so light that we can take it w ith us
where ever we want to. It is as small
as a cell phone and is so simple to use.
AVAILABILITY
it would come as cheap as $350
in its compact and stylish pen dant
avatar. Just put together your own
sixth sense device and experience the
power of the digital world on the go.
Digital photo frame
Now in this era, electronics h as
launched a digital photo frame to make
the living rooms more attractive with
special memories. It comprises of a
wide 8 inch screen which makes it perfect
for users to view.
Also it looks glossy & stylish . It
helps the viewer to
view full screen images.
It is equipped
with multiple options
such as storage folders,
image
b r o w s i n g ,
multi slide
show, image pause/zoom,
digital clock, calendar and alarm. These
all options make it multipurpose and
reasonable. It also gives user the convenience
of changing images from a
distance. The remote control with the
frame facilitates easy image transition.
The picture clarity is superb as it has
the resolution of 800 x 600. I t also
consists of 2GB internal capac ity so
that it can store sample images & create
an album for everlasting m emories.
Using the inbuilt USB po rt, we
can directly transmit photos o f the
digital camera to the photo frame.
8 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Biometrics
HUMAN body is a precious and
unique gift to all of us. Have you
ever imagine that our human bo dy
can be used as a security lock or to
identify someone. But now, at this
time, this dream has turned in to a
vast era of technology. This real part
of life is known as Biometrics .Biometrics
is all about using this unique feature
of human body for security purpose
or for other applications. for Biometrics
refers to use of unique physiological
characteristics to identify an
individual. While it is mainly concerned
with security, it also has some another
useful applications.
INTRODUCTION
Biometrics is defined as the science
and technology of measuring and analyzing
biological data. In information
technology, biometrics refers to technologies
that measure and analyze human
body characteristics such as DNA,
fingerprints, eye retinas and irises,
voice patterns, facial pattern s and
hand measurements, for authentication
purposes. A number of biometric
traits have been developed and are
used to authenticate the perso n's
identity. The idea is to use the special
characteristics of a person to identify
him. By using special characteristics we
mean the using the features such as
face, iris, fingerprint, signature etc.
WHY BIOMETRICS?
The biometrics techniques are
preferred over traditional pas swords
and PIN based methods for vari ous
reasons such as: The person t o be
identified is required to be physically
Department of Electronics & Co mmunication
Preeti Singh
EC - II year
present at the time-of-identif ication.
Identification based on biometric techniques
obviates the need to remember
a password or carry a toke n. A
biometric system is essentially a pattern
recognition system which makes
a personal identification by determining
the authenticity of a specific physiological
or behavioral charact eristic
possessed by the user.
TYPES OF BIOMETRICS
SYSTEM
Based on the application, Biometrics
system can be broadly classified
into two categories that are:
IDENTIFICATION
SYSTEM
Category of applications in which
Biometrics can be used to determine
9 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
a person's identity even witho ut his
knowledge or consent. For example,
scanning a crowd with a camera and
using face recognition technol ogy,
one can determine matches against a
known database.
VERIFICATION SYSTEM
These are application in which Biometrics
can be used to verify a
person's identity. For example, one can
grant physical access to a secure area
in a building by using finger scans or
can grant access to a bank acc ount
at an ATM by using retinal scan.
HOW IT WORKS?
Biometrics Security systems in -
volves comparison of a registered or
enrolled biometric sample (Previously
recorded sample or identifier) against
a newly captured biometric sam ple
(captured at the time of log in). Biometrics
authentication (verification) is
a three step process which inv olve
Capture, Process, Enroll followed by
a Verification or Identification process.
During Capture process, Sample or raw
biometric is captured by a sen sing
device such as a fingerprint s canner
or video camera. The second ph ase
of processing is to extract the distinguishing
characteristics from the raw
biometric sample and convert it into
a processed biometric identifier record
(sometimes called biometric sample or
biometric template). Next phase does
the process of enrollment. Her e the
processed sample (a mathematic al
representation of the biometric - not
the original biometric sample) is stored
/ registered in a storage medium for
future comparison during an authentication.
In many commercial applications,
there is a need to stor e the
processed biometric sample only. The
original biometric sample cann ot be
reconstructed from this identifier.
PARAMETERS
The importance or usefulness o f
any biometrics system used, is assessed
on basis of various parameters
which are as follows:
1. Universal: Every person must possess
the characteristic/attribute.
The attribute must be one that
is universal and seldom.
2. Invariance of properties: They
should be constant over a long
period of time. The attribute
should not be subject to signi ficant
differences based on age
either episodic or chronic disease.
3. Measurability: The properties
should be suitable for capture
without waiting time and must be
easy to gather the attribute data
passively.
4. Singularity: Each expression of
the attribute must be unique t o
the individual. The characteristics
should have sufficient unique
properties to distinguish one person
from any other. Height,
weight, hair and eye color are all
attributes that are unique assuming
a particularly precise measure,
but do not offer enough points
of differentiation to be useful for
more than categorizing.
5. Acceptance: The capturing
should be possible in a way ac -
ceptable to a large percentage of
the population. Excluded are particularly
invasive technologies, i.e.
technologies which requires a part
of the human body to be taken
or which (apparently) impair the
human body.
6. Reducibility: The captured data
should be capable of being reduced
to a file which is easy to
handle.
7. Reliability and tamper-resistance:
The attribute should be
impractical to mask or manipulate.
The process should ensure high
reliability and reproducibility.
8. Privacy: The process should not
violate the privacy of the person.
9. Comparable: Should be able to
reduce the attribute to a stat e
that makes it digitally comparable
to others. The less probabilis tic
the matching involved, the more
authoritative the identification.
10. Inimitable: The attribute must
be irreproducible by other means.
The less reproducible the attribute,
the more likely it will be
authoritative.
MEASURES OF A
BIOMETRIC SYSTEM
‣ FAR or FMR - It is an acronym
for False accept rate or false match
rate. It is defined as the pr obability
that the system incorrectly
matches the input pattern to a
non-matching template in the
database. It measures the percent
of invalid inputs which a re
incorrectly accepted.
‣ FRR or FNMR - It is an acronym
for false reject rate or false nonmatch
rate the probability tha t
the system fails to detect a match
between the input pattern and
a matching template in the database.
It measures the percent of
valid inputs which are incorrectly
rejected.
‣ ROC - It is an acronym for relative
operating characteristic. The
ROC plot is a visual characterization
of the trade-off between the
FAR and the FRR. In general, the
matching algorithm performs a
decision based on a threshold
which determines how close to a
template the input needs to be
considered a match. If the
threshold is reduced, there will be
less false non-matches but more
false accepts. Correspondingly, a
higher threshold will reduce the
FAR but increase the FRR. A common
variation is the Detection
Error Trade-off (DET), which i s
obtained using normal deviate
scales on both axes. This more
linear graph illuminates the differences
for higher performances
(rarer errors).
‣ EER or CER - It is an acronym
for the Equal Error Rate or crossover
Error Rate. It is defined as
the rate at which both accept and
reject errors are equal. The value
of the EER can be easily obtained
from the ROC curve. The EER is a
quick way to compare the accuracy
of devices with different ROC
curves. In general, the device
with the lowest EER is most ac -
curate. Obtained from the ROC
plot by taking the point where
FAR and FRR have the same value.
The lower the EER, the more
accurate the system is considered
to be.
‣ FTE or FER - It is an acronym for
the Failure to Enroll Rate. It is defined
as the rate at which at -
tempts to create a template from
an input is unsuccessful. This is
most commonly caused by low
10 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Kind of Biometric Technique Applications
Iris
Information security access co ntrol, Physical access control , ATMs etc.
Fingerprint
Access control, attendance Facility, physical access control etc.
Voice
Mobile phones, Telephone banking and other automated call ce ntre
Face
Physical access control. Ident ification of individual and se arching
population
Hand
Physical access control, time and attendance facility
Retina
Access control for high security agencies, Physical access c ontrol
quality inputs.
‣ FTC - It is an acronym for failure
to capture rate. It is defined as
the probability that the syste m
fails to detect a biometric in put
when presented correctly.
‣ Template Capacity - the maximum
number of sets of data which
can be stored in the system
SOME IMPORTANT
BIOMETRICS
TECHNIQUES
Face Recognition is a biometric
technique for automatic identification
or verification of a person from a digital
image or a video frame from a video
source. One of the ways to do this is
by comparing selected facial features
from the image and a facial database.
Face Recognition System is typ ically
used in security systems and c an be
compared to other biometrics such as
fingerprint or eye iris recognition systems.
Iris Recognition is another biometric
authentication method t hat
uses pattern recognition techn iques
based on high-resolution images of the
irises of an individual's eyes. Converted
into digital templates, these images
provide mathematical representations
of the iris that yield unambiguous positive
identification of an individual. Iris
recognition technology has bec ome
popular in security applicatio ns because
of its ease of use, accuracy, and
safety. Its most common use is controlling
access to high-security areas.
Iris recognition technology is currently
used at physical access points demanding
high security, such as airports,
government buildings, and research
laboratories.
Voice Recognition or Speaker
Recognition is a biometric process
of of validating a user's claimed identity
using characteristics ext racted
from their voices. Thus voice recognition
can be an effective technique in
user authentication and identification.
Smart Cards are digital security
pocket-sized cards with embedd ed
integrated circuits which can process
data. Thus smart cards can be used
for identification, authentication, and
data storage. It can also be used as a
medium to provide a means of effecting
business transactions in a flexible,
secure, standard way with mini mal
human intervention. Smart card can
provide strong authentication for
single sign-on or enterprise single signon
to computers, laptops, data with
encryption, enterprise resource planning
platforms such as SAP, etc...
Encryption Systems on the
other hand, use an encryption technique
for transforming information (referred
to as plaintext) using an algorithm
(called cipher) to make it unreadable
to anyone except those possessing
special knowledge, usually referred
to as a key. The result of the
process is encrypted informati on (in
cryptography, referred to as c ipher
text). Encryption Systems can be
used to protect data in transi t, for
example data being transferred via
networks (e.g. the Internet, e -commerce),
mobile telephones, wir eless
microphones, wireless intercom systems,
Bluetooth devices and ba nk
automatic teller machines ATMs. Encryption
has been used by mili taries
and governments to facilitate secret
communication. Encryption is n ow
commonly used in protecting information
within many kinds of civilian systems.
Security Tokens (or sometimes
a hardware token, hard token, authentication
token, USB token, cryptographic
token, or key fob) are biometric
devices which eases authentication
for authorized user of computer
services. These tokens are also known
as Software Tokens. Security t okens
are used to prove one's identity electronically
(as in the case of a customer
trying to access their bank account).
The token is used in addition to or in
place of a password to prove that the
customer is who they claim to be. The
token acts like an electronic key to
access something.
MULTIMODAL
BIOMETRICS SYSTEM
A Multimodal biometrics system
consists of various biometric techniques
embedded into it. It is fusion
of various biometric techniques which
provide us a better way to sta y secure.
It utilizes more than one physiological
or behavioral characteristic for
enrollment, verification, or identification.
In applications of higher priority
such as border entry/exit, access control,
civil identification, an d network
security, multi-modal biometri c systems
is highly recommended.
APPLICATIONS
Biometrics is mainly concerned with
security purpose. Since every human
body has unique Identification, so it
may be used as a unbreakable p ass
key to access. The main applications
of biometrics are entry control, ATMs,
Internet banking, Networking etc. It
also provides time and attenda nce
facility for a company.
11 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
GATE - The way of success
Department of Electronics & Co mmunication
Amit Mishra
EC - III year
INTRODUCTION
The graduate aptitude test in engineering
(GATE) is an all India examination
conducted by Indian institutes
of technology and the Indian institute
of science, Bangalore on behalf of the
national coordinating board GA TE,
Department of education ministry of
human resources development
(MHRD) government of India.
Many students may not be
aware that there are several i nstitutions
in this country, offering specialized
post-graduate programmes in
various disciplines, attractive scholarships,
assistant-ship for post graduate
course in engineering technolo gy at
engineering collages / institutes in the
country are available to those who
qualify through GATE. The candidate
is required to find the proced ure of
final selection and award of s cholarship
/ assistant-ship from the respective
institutions to which the candidate
seeks admission. GATE qualified
candidates will also be eligible for the
junior research fellowship in CSIR laboratories.
WHAT IS GATE
The graduate aptitude test in engineering
(GATE) is an all India examination
administrated and condu cted
by different zones across the country
by the GATE committee comprisi ng
faculty from Indian institute of science,
Bangalore collages / ins titutes
specifying GATE and seven Indian institutes
of technology on beha lf of
national coordinating board GA TE.
Department of education, min istry
of human resources development
(MHRD), government of India.
OBJECTIVE
The objective of GATE is to identify
meritorious and motivated candidates
for admission in post graduate
programmes in engineering tech nology,
architecture and applied sciences
at the national level, to serv e as
benchmark for normalization of the
under-graduate engineering edu cation
in the country.
WHY GATE?
M.Tech degree leads to a specialization
and furthering of interest in a
certain area which may lead to Ph.D/
M.Tech degree is best for those wishing
to apply for faculty / res earch
positions in educational insti tutes /
R & D centers.
EXAMINATION DETAIL
The examination is a single paper
of 3 hours duration.
‣ You have to choose the subject
and study as per the syllabus mentioned
in the GATE brochure.
‣ Results of qualified candidate in
GATE will all India rank and indicate
percentile score: for example-
a percentile score of 9 9
means you are in top 1% category
of the candidates who appeared
for GATE.
‣ Percentile cut-off depends num -
bers of the candidates appearing
in the exam.
‣ GATE scores are valid for 1 year.
You may reappear in the GATE
exam if you are not satisfied with
the earlier and the new score will
be used for admission purposes.
AFTER EXAM
‣ After declaration of GATE results,
student must apply to individual
institutes to get their application
forms.
‣ Institutes advertise M-Tech admission
in leading newspapers from
April till end July. However some
institutes do not advertise an d
therefore students have to get
the forms themselves.
‣ In the applications forms you have
to mention your GATE score
along with others details.
‣ The concerned institute may conduct
written test or interview for
the purpose of admission.
‣ If your GATE score is 90+ percentile
you can try for IIT’S, if between
80 to90 then can apply
for top NIT’S otherwise you can
look for appropriate institutes.
SCHOLARSHIP
During the pursuit of M-Tech, you
are paid a scholarship of Rs 1 2000-
16000 per month by the Government
of India, according to your in stitute.
This amount of scholarship is paid for
the entire 18 months M-TECH period.
The score card of the qualified
candidates will given per centile
score for that discipline and the performance
index. The percentile score
in each discipline is calculated as follows
:
N
r
c
1
N
nc
The performance index can be calculated
as-
Where, M= marks obtained by a
candidate in a paper
A=average marks in the paper
S=standard deviation in the paper
K 1
& K 2
=constants which are same
for all disciplines
ELECTRONICS AND
COMMUNICATION
ENGINEERING SYLLABUS
General aptitude (GA)
o Verbal ability o Numerical ability
ENGINEERING MATHEMATICS
It consists of linear algebra, calculus,
differential equations, c omplex
variables, probability, matrix and transform
theory.
(and whatever you have studied
in 1 st , 2 nd ,3 rd sem.)
CORE SUBJECTS
Networks, analog & digital electronics,
signals and systems, control systems,
communication (analog & digital)
& electromagnetic.
IMPORTANT DATES
Availability of GATE forms- September
last week.
Last date for submitting of forms-
October last week.
Examination date-2 nd Sunday of
February.
Result-Till last of March.
Useful sites (for previcious papers &
further enquiries):-
1-Gateforum.com 2-fresherworld.com
3-Onestopgate.com
NOTE : GATE 2011 form is available in
Union Bank of India. Last date for
submission of form is 30 th October,
2010.
12 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Retina based security system
Department of Electronics & Co mmunication
Jaikar Sahai
EC - III year
Retina scanning is mainly used for places that a high level
of security, for instance power plants, military installations
& other secure government sites.
RETINA scanning is a form of security
where people are identi -
fied by a scan that analyse the blood
vessels at the back of the eye. Retina
scan security usually involves a lowintensity
light source & optic al coupler,
which can read the blood vessels
with accuracy.
Retina scanning is one of the most
accurate biometric security measures
available because the retina patterns
are difficult to fake & even t he retinas
of a dead person do not ch ange
soon after they have died…
HOW DOES RETINA
SCANNING WORK?
Retina scanning technology involves
the use of a small green light
to record the retina patterns of a person
& ensure that they match up with
the patterns of those people who are
allowed access. This green light contains
a low-intensity light source. The
user needs to keep their head still &
keep their eyes focused on the green
light for about 10 seconds. If they
wear glasses, they must remove them
before focusing on the light. During
this time, the retina scanner will read
the patterns of the retina.
HOW DOES RETINA
SCANNING DIFFER
FROM IRIS SCANNING?
A retina scanner is similar to an IRIS
scanner, as both uses eyes as a form
of identification for security purpose.
However, retina scanning looks at the
patterns of the retina for identity purpose
& IRIS for identification (i.e. the
visible colored part of the eye). There
is also a difference in the way the IRIS
or retina is read. In retina scanning, a
green light reads the blood vessel at
the back of the eye. IRIS scanning, a
video image is taken of eye to produce
a record. A camera affirms the
identity of the person.
BENEFITS OF RETINA
SCANNING IN
SECURITY
Retina scanners for security h ave
many benefits that have been widely
used by top-end security place s. As
yet, they have not been widely used
in offices or places that do not require
a high level of security. However, there
are some benefits of using retina scan
security in an office environment. Here
are some of them:-
i. Retina scans are very difficult to
fake.
ii. Retina scans provide a unique way
of identifying people.
iii. Retina scans eliminate the nee d
for identification cards or ot her
portable identification method s
that may be stolen, lost are given
to other people.
iv. Retina scans provide a high level
of security.
v. A deal person can’t be used to
obtain access to a place through
their retina (unlike finger pr int
scanning).
DISADVANTAGES OF
RETINA SCANNING
Unfortunately, there are also a few
disadvantages to retina scanning. Many
cases, people feel that the disadvantages
of retina scanning outweigh any
benefits. It is also the why retina scan
technology has mainly been used for
high-risk security places, where it is
believed the extra security pr ovided
by the retina scanner is needed. Here
are some of the disadvantages:-
i. It can be quite expensive to i n-
stall.
ii. It can be considered as invasion
of privacy as a retina may indicate
an health problem.
iii. It is considered intrusive.
iv. It can’t be convenient.
DECIDING WHETHER TO
USE RETINA SCANNING
IN YOUR OFFICE
Making the decisions on whether
or not to use retina scanning is a difficult
one & one that should not be
taken lightly. Before installing retina
scanning technology, you shoul d
spend some time considering the advantages
& disadvantages of re tina
scanning for your company. The main
advantage is the high security that
retina scanning provides.
The main disadvantages are the
privacy & intrusiveness issues that
employees may have. Consider b oth
of these aspects in light of your company.
Does your company need such
a high level of security? Will another
security measures be adequate for
your needs? How will your employees
13 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
feel about retina scanning sec urity
measures being used? Consider these
factors carefully before your decision.
WHERE IS RETINA
SCANNING USED?
Retina scanning is mainly used for
places that require a high level of security,
for instance power plants, military
installations & other secure government
sites. Retina scan computer
access is sometimes used for computers
that have top-level security informations.
A number of other com panies
are starting to use the t echnology,
including banks (this pla ce the
technology in ATMs) & prisons.
THE FUTURE OF RETINA
SCANNING
The future impact of retina scanning
is likely to be felt mostly in the
medical field, rather than the security
field. Retina scanning can hel p doctors
diagnose a number of diseases &
may help many diseases be diagnosed
much earlier than they otherwi se
would be. Scientists are currently researching
ways in which retina scanning
can help medical professionals &
there is likely to be some breakthrough
in the future. There is also talk of having
nationwide screening services.
In term of security, there will also
be improvement in retina scan technology.
These improvements are likely
to achieve a quicker reading t ime if
the retina & making the retina scanner
more user-friendly. Retina scanning
will probably start to be used by a
wider range of companies & corporation
that do not necessary have high
security needs. However, this will probably
bring up issues of privac y &
intrussiveness and as retina scan security
becomes more prevalent.
Hyper threading technology in core processors
Modern processors can handle only
one instruction from one program at
any given point of time. Each instruction
that is sent to the proce ssor is
called a thread.
Today's Intel Hyper-Threading
Technology (Intel HT Technolog y)
delivers thread-level parallelism on each
processor, resulting in more efficient
use of processor resources, hi gher
processing output and improved performance
on multi-threaded software.
An Intel processor and chipset
combined with an OS and BIOS supporting
Intel HT Technology allows us
to:
‣ Run demanding applications simultaneously
while maintaining system
responsiveness to the opti -
mum.
‣ Keep systems more secure, efficient,
and manageable while minimizing
impact on productivity.
‣ Provide room for future business
growth and new solution capabilities.
The figure 1 above tells us about
the usage of different cores o f the
processor that take up multipl e
threads or instructions at one go and
operate upon them producing th e
required output. This is a pro minent
feature of Intel Core-i3 processor.
The figure 2 tells us about th e
usage of the same 4 cores of t he
single processor but this time each
core can access multiple threads, thus
having an advantage over the C orei3
processor. A typical feature of Corei5
& i7 processors.
TURBO BOOST
TECHNOLOGY
The new Intel's Turbo Boost Technology
covers all our problems related
to Fast System Booting, Processing &
Termination. This new technical complexity
developed by Electroni cs &
Micro processing Engineers at the Intel
Corporations, has revolutionized the
modern Tech Era and has helped a
lot with Speedy and Reliable
Multitasking Processing.
TDP- THERMAL DESIGN
POWER
Thermal Design Power merely indicates
the power limit or percentage
usage of core(s) of a processo r that
are currently into operational state in
form of bars as shown above.
By the figure, it's quite clear that
in the Previous Generations of Processing
the Active Cores had n o advantage
of having the Processi ng
Power Sharing from the Idle Co res.
But in the Core-i5 &i7 process ors, if
Aman Srivastava
EC - III year
the Active Cores are operating then
the Idle Cores provide a Shari ng of
the Processing Power to them resulting
in ULTRA HIGH SPEED COMPUTA-
TION, QUANTIZATION, PROCESSING
AND LOTS MORE!!
ADVANTAGES
The major advantage of Hyper
threading moulded or amalgamat ed
with the Turbo Boost Technolog y is
that the performance of the sy stem
increases to about five to ten times
yet with a negligible increase in the
power or energy consumption due to
the use of Nanotechnology that allows
the fabricators to hang over with
millions of transistors on just a 45nm
chip. Rest is the fact that takes care
of the performance that at Nanoscale,
the behaviour of the materials abruptly
changes and thus at the stake of
Maximum Performance and Energy
Efficiency along with the Mini mum
Heat Dissipation the new Core processors
are not just Faster, t hey are
Smarter too!!
14 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Claytronics : Turning dream into real
Department of Electronics & Co mmunication
Sudhanshu Singh
EC - III year
Transmission and reception of sound energy by telephone was followed by a revolution in electronics
and its digitalization. Pictures along with sound were then transported successfully from
one place to another along with miniaturization of electronics. Such developments inspire scientists
and engineers to think about human teleportation. Teleportation is the transfer of matter
from one place to another instantaneously, either by paranormal means or through technological
artifice. Matter teleportation, however, is still a day dream, but along these lines researcher have
come up with a new science called Claytronics. The idea is to create a small robot of a few
millimeters which can organise itself into a shape that is determined remotely.
Claytronics is an emerging field of engineering, drawing on nano technology and computer engineering.
Claytronics or programmable matter refers to an assembly of tiny components called
claytronic atoms or catoms, which could assume the form of any object, depending on the
programs controlling the Claytronics. This term also refers to the art of making clay caricatures of
public figures, begun in 1996 by an Indian Charuvi Agrawal.
CLAYTRONICS is a concept that
combines nanotechnology and
modular programmable robotics to create
what is also called programmable
matter, programmable grit, dyn amic
physical rendering or synthetic reality.
Very small components, called
claytronic atoms or catoms, have the
ability to move and morph into shapes
controlled by a communication network.
Claytronics is a form a progra m-
mable matter that takes the concept
of modular robots to a new extreme.
One of the primary goals of Claytronics
is to form the basis for a new media
type, pario. Pario, a logical extension
of audio and video is a media type used
to reproduce moving 3D objects in
the real world.
Claytronics is a name for an instance
of programmable matter whose p rimary
function is to organize itself into
the shape of an object and render its
outer surface to match the visual appearance
of that object. Clayt ronics
is made up of individual components,
called catoms—for Claytronic atoms—
that can move in three dimensions (in
relation to other catoms), adhere to
other catoms to maintain a 3D shape,
and compute state information (with
possible assistance from other catoms
in the ensemble). Each catom is a selfcontained
unit with a CPU, an energy
store, a network device, a video output
device, one or more sensor s, a
means of locomotion, and a mec hanism
for adhering to other catoms.
A Claytronics system forms a shape
through the interaction of the individual
catoms. For example, suppose
we wish to synthesize a physic al
“copy” of a person. The catoms would
first localize themselves with respect
to the ensemble. Once localized, they
would form an hierarical network in a
distributed fashion. The hiera rical
structure is necessary to deal with
the scale of the ensemble; it helps to
improve locality and to facili tate the
planning and coordination tasks. The
goal (in this case, mimicking a human
form) would then be specified abstractly,
perhaps as a series of “snapshots”.
or as a collection of virtual deforming
“forces”, and then broadcast
to the catoms. Compilation of the
specification into local actions would
then provide each catom with a local
plan for achieving the desired
global shape. At this
point, the Catoms would
start to move around each
other using forces generated
on-board, either
magnetically or electrostatically,
and adhere to
each other using, for example,
a nanofiber-adhesive
mechanism. Finally,
the catoms on the surface
would display an image,
rendering the color and
texture characteristics of
the source object. If the
source object begins to move, a
concise description of the movements
would be broadcast allow ing
the catoms to update their pos itions
by moving around each other. T he
end result is the global effec t of a
single coordinated system.
The core concepts in Claytronics
are hardly new; from science f iction
to realized reconfigurable rob ots to
proposed modular robots, scien tists
and writers have contemplated the
automatic synthesis of 3D objects.
However, technology has finall y
reached a point where we can for the
first time realistically build a system
guided by design principles which will
allow it to ultimately scale to millions
of sub-millimeter catoms. The resulting
ensemble can be viewed as either
a form of programmable matter suited
for implementing pario or as a swarm
Fig. 1
15 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
of modular Robots.
SCALING AND DESIGN
PRINCIPLES
A fundamental requirement of
Claytronics is that the system must
scale to very large numbers of interacting
catoms. We have the fol lowing
four design principles:
1. Each catom should be self-contained,
in the sense of posses s-
ing everything necessary for performing
its own computation,
communication, sensing, actuation,
locomotion, and adhesion.
2. To support efficient routing o f
power and avoid excessive heat
dissipation, no static power
3. The coordination of the catoms
should be performed via local control.
In particular, no computation
external to the ensemble should
be necessary for individual catom
execution.
4. For economic viability,
manufacturability, and reliability,
catoms should contain no moving
parts.
HARDWARE
At the macro-scale, catoms
have a diameter > 1cm and weigh
many tens of grams. In light o f the
design principles stated above , the
only viable force that can be used to
move and adhere catoms is magnetic;
which sets a lower limit on th e size
and weight of a catom as the m agnets
have considerable weight and volume.
Furthermore, the circuitr y
needed for the high currents n ecessary
to switch the magnets increases
the weight. At this scale, it may not
be possible to adhere to the “no static
power” design principle. Our current
prototype, as shown in Figure 2, is a
system composed of catoms that only
operate in two dimensions. In this
case gravity holds the individual catoms
to a surface and we do not hav e to
deal with the adhesion problem.
Much of the weight and size in a
macro-scale catom comes from packaging,
e.g., chip packages, pins, wires,
PCBs, etc..
In fact, in our planer prototy pe
currently under construction we estimate
that more than 20% of the
weight is packaging and more t han
77% goes to the magnets and th eir
support circuits. This is partly because
we are hand-assembling the catoms.
Our next version will use machine assembly
which will allow us to shrink
the packaging, resulting in an estimated
savings of twofold in we ight
and fivefold in volume.
Micro-scale catoms have diameters
between 1mm and 1cm and weightless
than 1 gram. Almost all packaging
is eliminated and the catom is co n-
structed by bonding VLSI dies directly
to MEMS-based sensor and actuation
dies.
THE SIDE AND TOP
VIEWS OF A
PARTIALLY
ASSEMBLED PLANAR
PROTOTYPE CATOM
The forces necessary to move a
catom are now sufficiently small that
electrostatic forces become an option.
Fig. 2
Macro-scale catoms would requi re
electric field strengths in excess of the
dielectric breakdown of air. Programmable
nanofiber adhesives (PNA), can
be combined with electrostatic actuation
to attach catoms without using
any static power. PNA is the next step
in bio-mimetic adhesives which mainly
use vander waals effects similar to that
of the Gecko. The active components
for micro-scale catoms are within the
realm of current engineering practices
using micro and nanoscale fabrication
techniques. The container coul d be
manufactured by casting a sphe rical
transparent polymer film and sputtering
indium-tin-oxide (ITO) ele ctrode
patches on the film. The patch es of
ITO would be used both to conn ect
catoms for distributing power as well
as used to create capacitive coupling
between catoms in order to con trol
their movement.
The next discontinuity occurs
when catoms are manufactured u s-
ing nanotechnology, e.g., as in chemically
assembled electronic nano-technology.
In this regime, the catoms are
small enough, e.g., < 10 microns in
diameter, that they are aerosol. While
this is currently beyond the state-ofthe-art
in manufacturing further scaling
of lithographic features in VLSI ,
and advances in MEMS capabilities combined
with advances in Nano-technology
will enable the integrate d construction
of such catoms.
In addition to capabilities, the different
regimes (macro, micro, and
nano) have significantly different economics.
Macro-scale catoms require the assembly
of multiple parts into a single
unit. We expect that this will make
the realization of life-size s ynthetic
reality prohibitive due to the cost per
catom. The micro-scale catoms may
also require assembly, but with many
fewer parts, e.g., no boards and the
elimination of magnets in favor of electrostatics.
At this scale the entire
catom will be constructed using a parallel
process, e.g., photolithography.
Just as VLSI-based computers are
commonplace (as opposed to vacuum
tube based computers), in this regime,
catoms are inexpensive enough
that synthetic reality, though expensive,
becomes viable. For exam ple,
assume a 2mm catom controlled by
3mm of silicon. If half the cost is in
the silicon, then, to construc t a human
sized form with an average depth
of 10 catoms would require app roximately
1.25x10.7 catoms or less than
one million dollars. In the nano regime
they will become sufficiently inexpensive
that synthetic reality co uld be
used not only for applications such as
telepario, but could be as ubiquitous
as embedded processors are today.
SOFTWARE
The essence of claytronics—a massively
distributed system composed of
numerous resource-limited catoms—
16 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
raises significant software issues: specifying
functionality, managing
concurrency, handling failure robustly,
dealing with uncertain informa tion,
and controlling resource usage. The
software used to control clayt ronics
must also scale to millions of catoms.
Thus, current software enginee ring
practices, even as applied to distributed
systems, may not be suita ble.
We are just beginning to explore the
software design principles needed.
I have broken down the software
issues into three main categor ies:
specification, compilation, and runtime
support.
Our goal is to specify the glo bal
behavior of the system in a direct and
descriptive manner. The simple st
model we are investigating with respect
to specification is what we call
the Wood Sculpting model. In t his
model, a static goal shape is specified.
We are investigating two alternative
compilation methodologies, bot h of
which fit into the general category of
single-program-multiple data (SPMD)
programming models. In the first, we
are compiling the specification into a
planning problem. In this approach we
are inspired by work done in communicating
soccer robots and in the context
of reconfigurable robots, by the
constraint-based control framework in
The wimax technology
Wimax is a telecommunication
technology that provide data over long
distances to full mobile cellu lar type
access. The word "wimax" means
Worldwide Interoperability for Microwave
Access. It is based on the wireless
MAN (IEEE 802.16) standar d.
Wimax is a highly scalable, long-range
system, covering many km using licensed
spectrum to connect internet
from an ISP to an end user.
The speed of Wimax devices are
10 mb/s at 10 km distance. There is
no uniform global licensed spe ctrum
for wimax although three licen sed
spectrum profiles are being used generally
- 2.3 GHz, 2.5 GHz and 3.5 GHz.
Wimax Wireless Network
Wimax system have to parts :
Wimax Tower : A Wimax tower
can provide coverage to a very large
area as 3000 m2 (8000 km2).
Wimax Receiver : The receiver
and antenna could be a small box are
PCMCIA card or they could be b uilt
into a laptop the way wifi acc ess is
which a high-level description such as
a particular gait which is translated to
a distributed, constraint-base d controller.
Our second approach is based
on emergent behavior. Prior work by
seems particularly appropriate in this
latter approach with respect t o
claytronics.
At the highest level of abstraction
a shape is specified in terms of Origami
folding directives. Through a process
of planning, these folding dir ectives
are translated into low-level programs
for autonomous agents; achieving the
shape by local communication a nd
deformation only.
Underlying the user-level software
is a distributed runtime system. This
system needs to shield the user from
the details of using and managing the
massive number of catoms. Our initial
steps in this direction use em ergent
behavior to determine a catoms location
and orientation with resp ect to
all catoms as well as to build a hierarchical
network for communicati on
between catoms. Efficient localization
is achieved by having the catoms determine
their relative location and orientation
in a distributed fashion. Then
as regions of localized catoms join up
they unify their coordinate sy stems.
Once catoms are localized we form a
hierarchical communication network,
today.
The Wimax can provide wireless
services in two forms :
‣ The Wimax uses a lower frequency
range - 2 GHz to 11 GHz
similar as wifi. Lower wave length
transmissions are not as easily disrupted
by physical obstructions -
they are better able to diffract or
bend, around obstacles.
‣ There is line - of - sight service,
where a fix dish antenna point s
straight at the Wimax tower from
a pole. The connection is stro n-
ger and more stable, so its ab le
to send a lot of data with fewer
errors.
Coverage and speed
Wimax operates on the same general
principle as wifi. It sends data from
one computer to another using radio
signals. The wimax connection can
transmit upto 70 mb/second.
The range of Wimax is 50 km radius.
The increased range is d ue to
the frequencies used and the p ower
again using simple local programs on
each catom. A tree is formed in parallel
by having nodes join with their
neighbors until all the nodes are in a
single tree. This simple algorithm produces
a surprisingly efficient tree from
which can then be further optimized.
FUTURE OF
CLAYTRONICS
Claytronics is one instance of programmable
matter, a system whi ch
can be used to realize 3D dyna mic
objects in the physical world.
While our original motivation was
to create the technology neces sary
to realize pario and synthetic reality, it
should also serve as the basis for a
large scale modular robotic system. At
this point we have constructed a
planer version of claytronics that obeys
our design principles.
We are using the planer prototype
in combination with our simulator to
begin the design of 3D claytro nics
which will allow us to experiment with
hardware and software solutions that
realize full-scale programmable matter,
e.g., a system of millions of catoms
which appear to act as a single entity,
in spite of being composed of millions
of individually acting units.
Sadhana Gautam
EC - II year
of the transmitter.
IEEE 802.16 specifications
Range - 30 mile (50 km) radious
from base station.
Speed - 70 megabits per second.
Line - of - sight not needed b e-
tween user and base station.
Frequency bands 2 to 11 GHz and
10 to 60 GHz.
Applications
‣ Metropolitan area network (MAN)
that allows areas of cities to be
connected.
‣ The Wimax protocol is designed
to accommodate several different
methods of data transmission,
one of which is voice over
Internet Protocol (VOIP). VOIP
always people to make local, long
distance and even internationa l
calls through a broad band
internet connection, bypassing
phone companies entirely.
17 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
CAM: Memory faster than RAM
CAMS (CONTENT
ADDRESSABLE
MEMORIES)
In their most trivial form, work in a
way opposite to conventional
memory. Effectively a cam is a searching
tool that looks for the data in question
within a database. A CAM commonly
work as hardware search engines
in routers and switches to accelerate
forwarding of packet on the
destination root.CAM i.e. Cont ent-
Addressable Memory stores data in a
similar fashion to a conventional RAM.
However, “reading” the CAM involves
providing input data to be mat ched,
then searching the CAM for a m atch
so that the address of the match can
be provided to output. Typical applications
of CAM are networking,
telecom (e.g., ATM cells), and consumer.
CAM ARCHITECTURE
Writing to a CAM is exactly li ke
writing to a conventional RAM. However,
the “read” operation is actually
a search of the CAM for a match to
an input “tag.” In addition to storage
cells, the CAM requires on e or
more comparators Architectures can
also include an input address bus. Another
common scheme involves writing
to consecutive locations of the CAM
as new data is added. The outp uts
are a MATCH signal and either an encoded
N-bit value or a one-hot -encoded
bus with one match bit corresponding
to each CAM cell.
The multi-cycle CAM architecture
tries to find a match to the input data
word by simply sequencing thro ugh
all memory locations – reading the
contents of each location, comparing
the contents to the input valu e, and
stopping when a match is found . At
that point, MATCH and MATCH_VALID
are asserted. If no match is f ound,
MATCH is not asserted, but
MATCH_VALID is asserted after all
addresses are compared. MATCH_
VALID indicates the end of the read
cycle. In other words, MATCH_VALID
asserted and MATCH not asserted indicate
that all the addresses have
been compared during a read operation
and no matches were found .
When a match is found, the address
of the matching data is provid ed as
an output and the MATCH signal is asserted.
It is possible that multiple locations
might contain matching data,
but no checking is done for this. Storage
for the multi-cycle CAM ca n be
either in distributed RAM (registers)
or block RAM. In the single-cycle CAM
architecture, there is a comparator for
each storage Location. If there are N
CAM locations, the output is a single
N-bit MATCH signal, which represents
the one-hot encoding of the comparator
results at each location. A ‘1’ indicates
a match and a ‘0’ represents no
match. Note that a match at an y location
triggers assertion of the MATCH
signal; no checking is done vis-à-vis
multiple addresses, which cont ain
matching data. The storage cells are
implemented as distributed registers.
For the Actel, single-cycle CAM generators,
you can choose to hav e a
single MATCH output, which is the
logical OR of all of the MATCH bit.
FUNCTIONS OF CAMS
In order to get a true understanding
of the functionality cam ,you need
to dig a little deeper into the domain
these works .if you look at either the
OSI reference model or the TCP /IP
stack ,you will find that the lowers
three layers are the ones that are
concern with the packet delive ry to
its peer, while all other layers are more
concerned with the content, its presentation
and formatting another importance
task that needs to be performed
by these upper layers i s to
ensure delivery of the packet to its
correct recipient .
This is done in two ways1-usin g
Department of Electronics & Co mmunication
Param Hans
EC - III year
MAC (media access control)address2-
using IP address
TYPES OF CAMS
Fundamentally, CAMs are of two
types: binary and ternary. As it indicates,
a binary CAM has two bit states,
while a ternary CAMs has 1, 0 and a
third state called “don’t care .” So
search-hit on a binary CAM could be
an exact match or a parital ma tch.
Currently ternary CAMs are de-facto
in the industry. These bring the possibility
of multiple match in a look up
table. All the access list (ACI) tables
for packet forwarding use a po pular
address resolution algorithm called the
longest prefix match where the addresses
are placed in the CAM based
on certain priorities and the CAM by
itself has a priority encoder that helps
in resolving the winning address.
WORKING OF CAMS
Let us see how a CAM works in
hardware. A CAM can be either binary
or ternary.
Binary CAM cell: CAM logic will
simply have the storage circuitary and
comparator logic to provide the match
information for the searches p erformed.
In this case a XOR gat e is
used to compare between the stored
data and the searched data.
Ternary CAM cell: A ternary CAM,
as the name indicates, has thr ee
states 0, 1, ‘X’. A don’t-care condition
exist in a ternary CAM to mask
off certain bits of partial match. In the
context two sets of data world appear
fo a single entry in the table. One
referring to the data to be looked up
for and the the other referring to the
mask that is to be applied on every
bit during look up. The conven tion
used with respect to the mask in this
context is “A’1’ refers to data masked
and a ‘0’ refers to data not b eing
masked”. The possibility of masking off
of certain bits of the data opens up a
wide range of applications were partial
match is necessary for in stance,
at the edge of a router, where the
router only worries about the destination
network address and not the
host ID.
18 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
IMPLEMENTATION AND
PERFORMANCE/
UTILIZATION
The implementation is mostly behavioral,
but key blocks are i mplemented
structurally to target features
of Actel devices. Both archite ctures
are implemented in VHDL. Gener ics
allow setting the number of address
bits, the memory depth and wid th,
and the degree of parallelism. To make
the simulation easier to follo w, the
data written to a given address is the
address itself. Four writes occur
APPLICATIONS OF CAM
1-implemation of ARP-when a new
host gets associated with a ne twork
the foremost thing that the ne twork
processor does is to update it s network
database with the MAC and IP
address of the new host.This u pdate
taken place in CAM table.
2-signature recognition-with t he
performance and speeds that current
technologies are achieving in communication,
the performance of C AM is
extremely important. One of the foremost
applications that the Int ernet
needs is data protection. With new
ways coming in vogue to hack an end
point, the need for protection from
such attacks, be it through a virus or
a spam, is necessary. If such a process
can be achieved in hardware, it
New Lithium metal phosphate batteries
made with wax and soap
Nowadays, lithium - ion batteries
are so popular in everything from cellular
phones to automobiles is their
relatively quick charge times, reasonable,
capacity, and resistance to fatigue.
Unfortunately, Li-ion
batteries are still somewhat expansive
as their manufacturing
process reduces a good
amount of energy and some
of their usual metal companies
such as cobalt and nickel, are
not entirely inexpensive.
Researches at the Pacific
Northwest National Laboratory
(PNNL) with the help from the
U.S. Department of Energy are
working on developing Li-ion
batteries which can perform at
similar levels but cost much less
to produces the cost reduction
will come from a change
in both production methods and materials
used. Rather than the typical
lithium metal oxide construction, the
PNNL team looked to replace the oxide
and expensive cobalt and n ickel
with a phosphate and maganese or
iron.
The simpler process involves nothing
much more than parafin wax, soap
and heat. They began by mixing the
lithium, phosphate and maganes e
together with melted wax and soap.
Parafin wax is made of long an d
mostly inert molecule chains w hich
Faraj Ahmad
EC - II year
helped direct the crystal growth, while
the soap, as a surfactant, hel ped
spread the important constitue nts
evenly. Next, raised the temperature
of the mixture 400 degree celsius, the
wax and shop evaporated away from
the mixture, living tiny lithi um
maganese phosphate (LMP) crystals
of approximately 50 by 2000 nanometers.
For comparision, a human hair is
about 50,000 to 60,000 nanomet ers
in diameter. They further rais ed the
temperature to bond the crysta l together
and form a plate of cat hode
material.
improves the throughput drasti cally.
CAMs can help in such a cause by
maintaining a signature data base and
an associate processor can scan the
packets for such signatures and drop
packets if necessary; such a functionality
would add immense value to the
content moved across the Inter net
WAY FORWARD
CAMs, as seen above, are becoming
an important tool in the communications
arena and any research towards
further improving their value by
enhancing their throughput or reducing
the cost would add to the advantage.
Lasers keep mini
Helicopter hovering
for hours
Abhishek Kr. Sharma
EC - II year
INTRODUCTION
Seattle research and development
company Laser Motive have succeeded
in keeping a model helicopter
hovering for six hours, powered only
by the energy of a laser.
Laser Measuring Instruments-
METTLER TOLEDO measurement sensors
to calculate length, widt h &
height .
In this type of Aeroplane there is
no pilot because there is limited flying
time. The operation time can b e increased
if it is provided with fuel or
batteries. Unmanned vehicles used by
the military are strong and he avier
than ultralights.
The laser power model
helicopter's weight is only 22grams.
HOW IT WORKS
The beam which will not damage
eye track of the helicopter is illuminated
by the photovoltaic cell s that
generate electricity visible. The photo
voltaic cells convert 50% of the laser
power to electricity which provide few
watts around the helicopter which is
enough to keep the helicopter rotors
spinning.
APPLICATIONS
Its application include delive ring
emergency power in disaster situation
and military use in remote rural communities.
19 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Indian Engineering Services (IES)
Department of Electronics & Co mmunication
Saurabh Sharma
EC - III year
Indian Engineering Services (IES)
constitutes of engineers that work
under the government of India to
manage a large segment of publ ic
sector economy which constitutes of
Railroads, Public works, Power ,
Telecommunications,etc.
A combined competitive examination
is conducted by the Union Public
Services Commission (UPSC) for recruitment
to the Indian Engine ering
Services. The examination constitutes
of a written examination followed by
an interview for personality test.
The recruitment of qualified candidates
are made under the following
categories:
ELECTRONICS AND
COMMUNICATION
ENGINEERING
The service offers to electron ics
and communication engineeriner-
(i) Indian Railway Service of Signal
Engineers.
(ii) Indian Railway Stores Service.
(iii) Indian Ordinance Factories Service.
(iv) Indian Naval Armament Service.
(v) Assistant Executive Engine er (in
Ministry of Defence).
(vi) Engineer in Wireless Planning and
Coordination Wing/Monitoring
Organisation.
(vii) Assistant Naval Stores officer (in
Indian Navy).
(viii) Survey of India Service.
(I) ELIGIBILITY
CONDITIONS
(i) Age limits:
21-30 years as on 1.8.2011(FOR
2011 EXAM). (Upper age limit relaxable
for SCs/Sts, OBCs and certain other
categories as specified in the Notice).
(II) EDUCATIONAL
QUALIFICATIONS:
Degree in Engineering or equivalent
in any discipline, M.Sc Degree or
its equivalent with Wireless Communication,
Electronics, Radio Physics or
Radio Engineering as a special subject
also acceptable for certain posts. (See
Notice in the Employment News).
HOW TO APPLY
Application form:
• The application form is common
for all their examinations which will
be processed on computerized
machines.
• The application packet contains,
the Application form, information
brochure, an acknowledgment
card, and an envelope for sending
the Application.
• The Application is available at designated
Head Post Offices/Post
Offices throughout the country.
The form should be purchased
from the designated Post Offices
only.
• This form can be used only once
and for only one examination.
• A photocopy/reproduction/unauthorized
printed copy of the form
is not allowed.
• Acknowledgment cards with a
postage stamp of Rs. 6/- should
accompany the application form.
• The name of examination, should
be written on the envelope.
Written Examination
• The application packet will co n-
tain the detailed instruction for filling
the application form.
EXAMINATION PATTERN
The entrance for Indian Engineering
Service comprises of a Written
Exam (Section I and II) and an
Interview. The details follow:
• One Engineering Discipline should
be chosen from the following categories:
o Civil Engineering
o Mechanical Engineering
o Electrical Engineering
o Electronics and communication
Engineering
• The written examination will comprise
two sections:
o Section I - objective types
o
questions
Section II – conventional
(essay) type question papers.
• Both Sections will cover the entire
syllabus of the relevant engineering
subject.
INTERVIEW
Interview for Personality test of
selected candidates: 200 mark.
GENERAL (BUT
IMPORTANT)
INSTRUCTIONS
• All Question Papers must be Answered
in English. Question Pa -
pers will be set in English only.
• Candidates must write the papers
themselves. ·They will not be allowed
a scribe to write the an -
Category Section Subject Duration Max Marks
Civil / Mechanical / Section I – Objective Paper General Ability Test: 2 hours 200
Electrical / Electronic and
Telecommunication
Engineering
Part A – General English
Part B – General Studies
Paper I 2 hours 200
Paper II 2 hours 200
Section II – Conventional Pape r Paper I 3 hours 200
Paper II 3 hours 200
Total 1000
20 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
swer for them under “any circumstances”.
• Points (upto 5%) may be deducted
from the total points of a
candidate if his/her handwriting is
not easily legible.
• Put in a serious and sincere e f-
fort.
o
Marks are not allotted for
mere superficial knowledge.
Orderly, effective and exact
expression combined with
due economy of words will be
rewarded.
• SI units will be used in the papers
and Candidates should use only
International form of Indian n u-
merals (i.e. 1,2,3,4,5,6 etc.) while
answering question papers.
• The Commission have discretion
to fix qualifying marks in any or all
the subjects of the examination.
o
Quantum mirage
The Objective Type papers will
be evaluated first and evaluation
of the Conventional
type papers is done only for
those candidates who obtain
the minimum qualifying marks
in Objective types papers, as
fixed by the Commission.
• Strongly Prepare general abili ty
Question Paper.
• Solve the previous years Question
Paper.
• Set the timing for every section-
’time is a big key’.
• Solve confidentally.
• Prefer best books.
• Prefer short, confident techniques
for saving time.
• Prepare for interview.
SUGGESTED BOOKS
1. Electronics Devices and Circuit &
Analog Electronics
o Microelectronic circuit –
SEDRA & SMITH.
o Solid State Electronic Devices
– STREETMAN & BANERJEE.
2. Communication System
o Mordern Digital & Analog
Communication – B.P.LATHI.
o Electronic Communication
System – KANNEDYAND
DEVIS.
3. Signal & System – OPPENHEIN &
WILLSKY.
4. Control System – B.S.MANKKE.
5. Electromagnetic Theory
o Elements of Electromagnetic
– SADIKU.
o Antenna & Wave Propagation
– K.D.PRASAD.
6. Digital Electronics
o
Digital Design – M.MORRIS
MANO.
o Mordern Digital Electronic –
R.P.JAIN.
SUGGESTED WEBSITES
www.upsc .com
www.onestopgate.com
Priya Srivastava
EC - III year
Since it first appeared on the cover
of Nature in February 2000, th e
“quantum mirage" has featured on
posters, calendars, websites and the
covers of various books and ma gazines.
The image - which was obtained
using a scanning tunnelling microscope
- shows the electronic wave functions
inside an elliptical "quantum corral"
made of cobalt atoms on a copp er
surface. It was created by Har i
Manoharan, Christopher Lutz and Don
Eigler of the IBM Almaden Rese arch
Center in California. In 1990, working
with Erhard Schweizer, Eiger spelt out
the letters "IBM" using 35 xenon atoms.
And three years later, wo rking
with Lutz and Michael Crommie, he
released the first images of the "quantum
corral", which have also been reproduced
in numerous places.
All moving particles have a wavelike
nature. This is rarely significant on
an everyday scale. But in atom ic dimensions,
where distances are measured
in nanometers, moving particles
behave like waves. This phenomenon
is what makes the electron mic roscope
workable. It is of inter est to
researchers in nanotechnology, who
are looking for ways to deliver electric
currents through circuits too small for
conventional wiring. The term quantum
mirage refers to a phenomenon
that may make it possible to transfer
data without conventional elec trical
wiring. Instead of forcing charge carriers
through solid conductors, a process
impractical on a microscopic scale,
electron wave phenomena are made
to produce effective currents.
A quantum mirage is a peculiar result
in quantum chaos. Every system
of quantum dynamical billiards will exhibit
an effect called scarring, where
the quantum probability density shows
traces of the paths a classical billiard
ball would take. For an elliptical arena,
the scarring is particularly pronounced
at the foci, as this is the region where
many classical trajectories converge.
The scars at the foci are coll oquially
referred to as the "quantum mirage".
They are two dimensional struc -
tures built atom by atom (usin g approximately
30-80 atoms) on at omically
smooth metallic surfaces using a
scanning tunneling microscope (STM).
Once the corrals are built, th e STM
can be used to study these nan ometer
scale structures with atomic resolution
in space and better tha n meV
(micro electron Volt) resolution in energy.
The data of the STM can be
rendered in false color to pro duce
breathtaking images that reveal standing
wave patterns of coherent electrons
inside the corrals.
The presence or absence of a
quantum mirage might be used t o
represent one bit of data in a region
far smaller than any current electronic
device can manage. It has the potential
to enable data transfer within future
nano-scale electronic circuits so
small that conventional wires do not
work.
IBM scientists are hoping to use
quantum mirages to construct atomic
scale processors in the future.
21 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Application specific integrated circuit (ASIC)
An Integrated Circuit (IC) designed
for a particular use and not f or
general use is called an Appli cation-
Specific Integrated Circuit (ASIC).It is
basically an integrated circuit designed
specifically for a special pur pose or
application.Application specif ic integrated
circuits provide their users the
ability to manufacture products having
a proper design.Many diffe rent
ASIC technologies are available, including
gate array, standard cell, full custom
design, and programmable logic
devices. The ASIC forms, in a single,
semi-conductor substrate, the equivalent
of several different integrated circuits
each designed to perform one
or more desired operations, such as a
microprocessor operation, a memory
operation, various interface operations
(e.g., memory interface, proce ssor
interface), etc.
ASIC operational blocks are ty pically
designed to include thousands of
individual logic gates necessary for performing
the desired operation( s) An
example of this is a chip which is designed
only to run a cell phon e.
Whereas there are 7400 series and
4000 series integrated circuits as logic
building blocks which can be w ired
together and used in various applications.
Application specific in tegrated
circuits (ASICs) can consolida te the
work of many chips into a sing le,
smaller, faster package, reducing manufacturing
and support costs wh ile
boosting the speed of the device built
with them. Designers prefer us ing
application specific integrated circuits
as it lets them use the power of constantly
improving silicon technology to
build devices targeted at specific functions,
such as routing. Modern application
specific integrated circuit chips
often include entire 32-bit processors
and other large building-blocks. This
type of ASIC chip is often referred to
as a system-on-a-chip (SoC). Design
flow of ASIC chips is highly automated.
EXAMPLES OF ASIC
Examples of ASIC’s include:
‣ An IC that encodes and decodes
digital data using a proper encoding/decoding
algorithm.
‣ A medical IC designed to monitor
a specific human biometric parameter.
‣ An IC designed to serve a special
function within a factory automation
system.
‣ An amplifier IC designed to meet
certain specifications not available
in standard amplifier products.
‣ A proprietary system-on-a-chip
(SOC).
‣ An IC that’s custom-made for a
particular automated test equipment.
DESIGNING OF ASIC
ASIC design can be divided int o
following sections: register-t ransfer
level (RTL) description, simul ation,
syntheses, extraction, and phy sical
verification. A hierarchy of p rogrammable
interconnects allows the logic
blocks of an FPGA ASIC chip to be
interconnected, similar to a one-chip
programmable breadboard. The logic
blocks interconnected then can be
programmed so that the FPGA ASIC
chip can perform whatever logical function
is needed. A structured ASIC provides
reduced entry cost and f aster
time by using a predefined arr angement
of late-stage, mask-customizable
logic and prediffused macros and IP.
With the integration of increasing system
components on single ASIC chips,
Alok Kumar Pandey
EC - III year
the complexity of ASIC prototyping is
increased. System design invol ves
complex layout issues. Specifications
of cells are provided by the vendors
in form of a technology library which
contains information about geometry,
delay, and power characteristi cs of
cells. ASIC chips are designed and
manufactured to meet most industry
specifications.
TYPES OF ASIC
1. Cell Based Application Specific
Integrated Circuits (ASICS)
Benefits
‣ Highest performance, power and
integration.
‣ Cell-based ASICs are offered with
a selection of IP cores.
‣ Perfect for high-volume design s
that require the highest densi ty
and performance.
‣ available in a range of proces s
technologies
‣ Max. clock speed: Up to 1 GHz
‣ Memory: High-density SRAM and
embedded DRAM
‣ Signal I/Os: Up to 1400
‣ Usable ASIC gates: Up to 100M
‣ Featured IP: ARM CPUs, Tensilica
CPUs and DSPs, USB 2.0, eDRAM,
SerDes, PCI Express, SATA/SAS,
SPI4.2.
IPCORE
There are a large number of IP
22 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
cores in cell-based ICs, including CPU
cores and analog logic cores. Customers
are supported in their own system
chip design development by
these options.
Core List
• Digital Core
• Analog Core
• SRAM
• eDRAM
• I/O
Services Provided During Cell-Based
IC Development Linked processe s
from logic design to manufactu ring
features in production of cell-based ICs
helps in providing an environment for
short turnaround time in mass-producing
large-scale integration, advanced
performance, and low power con -
sumption.
Benefits
‣ Logic design taking layout design
into account at an early stage.
‣ Layout design taking manufacturing
(DFY or DFM) into account.
‣ Test design improving manufacturing
quality.
‣ Feedback from manufacturing to
logic design and test design.
2. Gate Array & Embedded Array
ASICs
Gate arrays help reduce the cost,
turnaround time and risk while improving
power consumption, EMI and performance.
These arrays, based on a
sea-of-gates architecture, whi ch is
customized using only the metallization
layers for interconnect. Low NRE
costs and fast turnaround time are its
results.
HIGHLIGHTS
‣ From the #1 supplier worldwide,
with over 750 tape-outs over the
past 3 years
‣ Low price, low NRE cost (as low
as $10,000), easy-to-design op -
tion, easy Logic consolidation due
to small gate counts and small
package design.
‣ FPGA-compatible packages also
available. In just nine short days
from tape out, we can have engineering
samples ready to go.
‣ Max. clock speed: 133 MHz
‣ Memory: Diffused and metallized
SRAM
‣ Signal I/Os: From 20 to 876
‣ Usable ASIC Gates: From 1.5K to
1.6M
‣ Featured IP: DMA controller, i n-
terrupt controller, PCI controller,
DPLL, UART, timer, parallel interface
unit, UART + FIFO, Tensilica
CPUs and DSPs
‣ Master slices: 158
3. EDRAM Application Specific
Integrated Circuits (ASICS)
Following are some of the features
that make eDRAM, the ideal solution
for a wide variety of applications-
‣ Random access time an order of
magnitude shorter than competitor
offerings
‣ Fully CMOS-compatible process
using a single fab and few extra
masks to minimize cost
‣ SRAM-like access for easy integration
with existing intellectual property
(IP)
‣ SoC-friendly macros that simplify
integration, with orientation in
any direction and over-the-top
routing
The latest 55 nm family, which
adds significant process enh ancements
to the improved mater ials
that have proven so successful in
our previous 90 nm family.
APPLICATIONS
These characteristics have helped
fuel the growing popularity of eDRAM
for a variety of applications – from
communications systems to home
electronics, from enterprise servers to
entertainment systems. The success
complex system LSI chip for th e
Nintendo Wii and Microsoft® XBox
360 has propelled fabrication volume
to many millions of devices.
FUTURE ASPECTS
If it is used in proper way or manner
then it can proved as a bo on to
the whole world as it is already proving
its importance in the field of satellite
and radar systems.
Minox digital spy cam DSC silver: The camera of tomorrow
Spy cameras are not just for d e-
tectives anymore. They are als o for
people who have a weird taste in
snapping photos of other discreetly (or
for a more apt term, those they call
stolen shots). The Minox Digit al Spy
Cam DSC Silver is a next gener ation
digital camera that surprisingly turned
into a digital device.
This camera has a silver metal finish,
1.5-inch display screen to preview
shots and 16GB worth of memory
card. It is capable of shooting with its
5.1MP sensor, as well as this will also
come with external flash module when
the need arises for it. This s py camera
allows you also to take photos with
intricate.
23 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Smart dust
INTRODUCTION
WHAT IS SMART DUST? Smart
dust is a tiny dust size device
with extra-ordinary capabilities. Smart
dust is a hypothetical wireless ne t-
work of tiny microelectromechanical
sensors (MEMS), robots, or dev ices,
that can detect (for example) light,
temperature, or vibration which was
introduced by Kristopher S.J. Pister.
Smart dust combines sensing, c omputing,
wireless communication capabilities
and autonomous power supply
within volume of only few millimeters
and that too at a very low cost. These
devices are proposed to be so small
and light in weight that they can remain
suspended in the environm ent
like an ordinary dust particle . These
properties of Smart Dust will render it
useful in monitoring real world phenomenon
without disturbing the original
process to an observable extends.
Presently the achievable size of Smart
Dust is about 5mm cube, but we hope
that it will eventually be as small as a
speck of dust. Individual sens ors of
smart dust are often referred to as
motes because of their small size.
BACKGROUND
The Defense Advanced Research
Projects Agency (DARPA)
has been funding Smart Dust research
heavily since the late 1990s, seeing
virtually limitless applicatio ns in the
sphere of modern warfare. So far the
research has been promising, w ith
prototype smart dust sensors as small
as 5mm.But further scaling dow n
needs advance technological changes.
We are well aware that costs h ave
been dropping rapidly with technological
innovations, bringing indi vidual
motes down to as little as $50 each,
with hopes of dropping below $1 per
mote in the near future.
STRUCTURE
A smart dust particle is often called
motes. Now one single mote has a
Micro Electro Mechanical System
(MEMS), a semiconductor laser diode,
MEMS beam steering mirror for
active optical transmission, a MEMS
corner cube retro-reflector for passive
optical transmission, an optic al receiver,
a signal processing and control
circuitry, and a power source based
on thick-film batteries and solar cells.
The major challenge is to be faced
when all the functions are to be incorporated
maintaining very lo w
power consumption and optimizi ng
the operating life of the mote. Smart
dust motes consist of a passive optical
transmitter with a micro fabricated
Corner- Cube Retro-Reflector
(CCR). Now this CCR contains three
mutually perpendicular mirror fabricated
of gold- coated poly-silicon. The
CCR reflects any ray of light within a
certain range of angles center ed
about the cube diagonally back to the
source. The power system consists of
a thick-film battery or a solar cell, or
both with a charge-integrating capacitor
(power capacitor). The thick film
battery of sol. or gel V2O3 provides a
backup in darkness, while solar cells
generate energy from sunlight. Depending
on its objective, the design
integrates various sensors, including
light, temperature, vibration, magnetic
field, wind shear, on to the m ote.
Active transmitters make possi ble
peer-to-peer communication between
dust motes, provided the re
exists a line-of-sight path be tween
them.
CORNER CUBE RETRO-
REFLECTOR (CCR)
Department of Electronics & Co mmunication
CCR comprises of three mutually
perpendicular mirrors of gold-coated
polysilicon. It has the proper ty that
any incident ray of light is r eflected
back to the source (provided t hat it
is incident within a certain r ange of
angles centered about the cube ’s
body diagonal). If any one of the mirrors
is misaligned, this retro-reflection
property is spoiled. So the micro-fabricated
CCR includes an electr ostatic
actuator that can deflect one of the
mirrors at kilohertz rates. Si nce the
dust mote itself cannot emit light, the
passive transmitter consumes l ittle
power. Using a micro-fabricated CCR,
we can achieve data transmission at a
bit rate up to 1 kilobit per s econd,
and over a range of up to 150 meters,
using a 5 milliwatt illuminating laser.
It should note that CCR-based pas-
Kislaya Srivastava
EC - III year
sive optical links require an uninterrupted
line-of-sight path. Moreover, a
CCR-based passive transmitter is inherently
directional; a CCR can transmit
to the BTS only when the CCR b ody
diagonal happens to point directly toward
the BTS, within a few ten s of
degrees. A passive transmitter can be
made more Omni-directional by employing
several CCRs oriented in different
directions, at the expe nse of
increased dust mote size. If a dust
mote employs only one or a few CCRs,
the lack of Omni-directional transmission
has important consequence on
feasible network routing strategies.
COMMUNICATION
TECHNOLOGIES:
I. Radio Frequency Transmission
II. Optical transmission technique
a) Active Laser based Communication
b) Fiber Optic Communication
I. RADIO FREQUENCY
TRANSMISSION
It is based on the generation,
propagation and detection of electromagnetic
waves with a frequenc y
range from tens of kHz to hund reds
of GHz. It could be used to fu nction
as both the uplink and the downlink.
Since RF transceiver typically consists
of relatively complex circuitry, it is impossible
to achieve the required low
power operation using such an approach
in a smart dust system. When
large numbers of motes are involved
in smart dust, RF links may employ alternative
multiplexing techniq ues:
time, frequency or code-division multiplexing.
Their use leads to modulation,
band pass filtering, demodulation
circuitry, and additional circuitry, all of
which needs to be considered based
on power consumption,etc.
II. Optical Transmission
Technique
The Smart Dust can employ a passive
laser based communication
scheme to establish a bi-direc tional
communication link between dus t
nodes and a base station transceiver
(BST). For downlink communicat ion
(BST to dust), the base station points
a modulated laser beam at a no de.
24 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
The latter uses a simple optic al receiver
to decode the incoming message.
For uplink communication (dust
to BST), the base station poin ts an
un-modulated laser beam at a node,
which in turn modulates and reflects
back the beam to the BST. For this,
the dust nodes are equipped wi th a
Corner Cube Retro Reflector (C CR).
The CCR has the property that any
incident ray of light is reflected back
to the source under certain co nditions.
If one of the mirrors i s misaligned,
this retro reflection property
is spoiled. The Smart Dust CCR has an
electrostatic actuator that can deflect
one of the mirrors at kilohertz rates.
Using this actuator, the incident laser
beam is “on-off” modulated and reflected
back to the BST.
A) Active Laser based
Communication
Active optical communication typically
uses an active-steered laser-diode
based transmitter to send a collimated
laser beam to a base station.
This system contains a semicon ductor
laser, a collimating lens and a beamsteering
micro-mirror as shown in Figure
2. Active optical communic ation
is suitable for peer-to-peer communication,
provided there exist a line of
sight path between them. Using
MEMS technology, the components of
the active communication netwo rk
can be made to be small enough to
fit into the smart dust motes.
GPS maptor
Maptor, the navigational gadge t
is the combination of Map and Projector.
It is used to project map on
any desired surface. Its really portable
due to its small size. The mos t discussed
advantage of Maptor is that,
we don't need any one's help on the
way, even if we are lost.
GPS Maptor is GPS included with
Maptor. We know that GPS is Global
Positioning System; it is a US space
based Global Navigation Satellite System.
It provides reliable positioning,
navigation and timing services to
worldwide users. Maptor gives the
combined effect of two technologies.
As a result of the above said combination
we can locate our cur rent
position on the map with the help of
a red arrow that points the location.
Another advantage is the map pro-
One of the disadvantages of th e
active transmitter is its relatively high
power consumption. This leads to the
use of active optical communic ation
for short duration burst-mode communication
only. In order to minimize
the power consumption, the act ive
transmitter should have some protocol
to aim the beams toward the receiver,
for example, using directional
beam and an active beam-steeri ng
mechanism. These components
would make the design of the d ust
mote more complicated.
B) Fiber-optic communication
Fiber-optical communication em -
ploys semiconductor laser, fiber cable
and a diode receiver to gener ate,
transfer and detect the optical signal.
Its most of the characteristics matches
with that of passive optical communication.
The relatively small size of the
optical transceiver is employe d with
low-power operation. Each dust mote
does not need to have an on bo ard
light source to transmit the data. By
the using MEMS technology, Cor ner
cube retro-reflector is employ ed on
each dust mote to modulate upl ink
data to base station.
APPLICATION OF
SMART DUST
It is very hard to detect the presence
of the Smart Dust and it is even
harder to get rid of them once deployed.
Moreover it does not c ost
jection is easily viewable even in day
light. This concept is designed by Jin-
much so can be densely deploye d.
Due to the above-mentioned fea -
tures, Smart Dust can be used in varied
application fields. These are as follows:
1) Environmental protection (identification
and monitoring of pollution).
2) Habitat monitoring (observing the
behavior of the animals in the re
natural habitat).
3) Military application (monitoring activities
in inaccessible areas , accompany
soldiers and alert them
to any poisons or dangerous biological
substances in the air).
4) Indoor/Outdoor Environmental
Monitoring
5) Security and Tracking
6) Health and Wellness Monitoring
(enter human bodies and check
for physiological problems)
7) Power Monitoring
8) Inventory Location Awareness
9) Factory and Process Automation
10) Seismic and Structural Monitoring
11) Monitor traffic and redirecting it.
There are many ongoing researches
on Smart Dust, the ma in
purpose of these researches is to
make Smart Dust mote as small as
possible and to make it available at as
low price as possible. Soon we will see
Smart Dust being used in varied application
from all spans of life.
Priyanka Shukla
EC - III year
Sun Park and Seon-Keun Park
to make a new wave in the
gadget industry.
The GPS Maptor combines
GPS facility for maps, locations
and directions capsulated
in a mini projector. This
gadget is really a handy one
with its awesome shape.
Moreover different projectors
are available like Nokia
Cellphone projector and
Explay Handheld Projector,
but still this new design may
seem to be good for those
who don't require the combination
of cellphone and GPS
navigation. Actually this device
is really a boon to the
tourists and for those who love travelling.
25 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Genetic algorithms
INTRODUCTION
GENETIC algorithms are one of the
best ways to solve a problem for
which little is known. They are a very
general algorithm and so will work well
in any search space. All you need to
know is the solution to be able to do
well, and a genetic algorithm will be
able to create a high quality solution.
Genetic algorithms use the principles
of selection and evolution to produce
several solutions to a given problem.
Genetic Algorithms are a way of
solving problems by mimicking
the same processes which
Mother Nature uses. They use
the same combination of selection,
recombination and mutation
to evolve a solution to a prob -
lem.
Genetic algorithms tend to
thrive in an environment in which
there is a very large set of candidates
solutions and in which the
search space is uneven and has
many hills and valleys. Geneti c
algorithms will do well in any environment,
but they will be
greatly outclassed by more situation
specific algorithms in the
simpler search spaces.
Therefore, you must keep in
mind that genetic algorithms are
not always the best choice.
Sometimes they can take quite
a while to run and are therefore
not always feasible for real time
use. They are, however, one of
the most powerful methods
which quickly create high quality
solutions to a problem. Now,
before we start, I’m going to
provide you with some key terms
so that this article makes a sense.
‣ Individual - Any possible solution
‣ Population - Group of all individuals
‣ Search Space - All possible solutions
to the problem
‣ Chromosome - Blueprint for an
individual
‣ Trait - Possible aspect of an individual
‣ Allele - Possible settings for a trait
‣ Locus - The position of a gene
on the chromosome
‣ Genome - Collection of all chr o-
mosomes for an individual
FOUNDATIONS IN
SCIENCE
In the mid 1800s, 1859 to be exact,
a British naturalist named Charles
Darwin published a book that changed
the humans view to the world. In this
book, The Origin of Species, D arwin
proposed that humans, and in fact all
creatures, were not put on this planet
Sudhanshu Singh
EC - III year
by God and made unchanging, bu t
rather that they evolved from other
creatures. At the time, the id ea
sounded preposterous, but later we
have discovered that he may be correct.
Advancement in technolog y
have made it possible for us t o read
our DNA and that of other creatures,
and what it has shown us is that we
aren’t as different from other creatures
as we think. Over time, creatures
change to adapt to their environment
to survive and thrive.
One of the most striking examples
of this is the Galapagos Islands, located
in the Pacific Ocean, off the coast of
Ecuador, this series of islands is one of
the most prominent examples of evolution
and adaptation. The island contains
many species which are n ot
found anywhere else on the pla net,
including several species of birds that
share many characteristics; too many
for it to be a coincidence. It is believed
that many birds were
blown to the islands by winds
and were unable to get back.
Over time, the birds spread
throughout the island and began
survive in the differing environments
of the islands. Some
birds developed large, strong
beaks suited to crack nuts, others
long, narrow beaks more
suitable for digging bugs out of
wood. The birds that had these
characteristics when blown to
the island survived longer than
other birds. This allowed them
to reproduce more and therefore
have more offspring that
also had this unique characteristic.
Those without the characteristic
gradually died out
from starvation. Eventually all of
the birds had a type of beak
that helped it survive on its island.
This is the process of natural
selection and evolution. The
individuals themselves do not
change, but those that survive
better, or have a higher fitness,
will survive longer and produce
more offspring. This continues
to happen, with the individuals
becoming more suited to their environment
every generation. It was this
continuous improvement that inspired
computer scientists, one of the most
prominent being John Holland, to create
genetic algorithms.
WHY A GENETIC
ALGORITHM?
Advances in computer technology
have made molecular dynamics simulations
more and more popular in
26 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
studying the behavior of complex systems.
Even with modern-day computers,
however, there are still two main
limitations facing atomistic simulations:
system size and simulation time. While
recent developments in parallel computer
design and algorithms ha ve
made considerable progress in enlarging
the system size that can b e accessed
using atomistic simulat ions,
methods for shortening the simulation
time still remain relatively unexplored.
One example where such methods
will be useful is in the determination
of the lowest energy conf igurations
of a collection of atoms. Because
the number of candidate local energy
minima grows exponentially with the
number of atoms, the computational
effort scales exponentially with problem
size, making it a member of the
NP-hard problem class.
For a few atoms, the ground state
can sometimes be found by a br ute
force search of configuration space.
For up to ten or twenty atoms, depending
upon the potential, simulated
annealing may be employed to g enerate
some candidate ground st ate
configurations. For more atoms than
this, attempts to use simulate d annealing
to find the global energy minimum
are frustrated by high ene rgy
barriers which trap the simulation in
one of the numerous metastable configurations.
An algorithm is needed which can
‘hop’ from one minimum to anot her
and permit an efficient sampli ng of
phase space. Our approach is based
on the genetic algorithm (GA), an
optimization strategy inspired by the
Darwinian evolution process. Starting
with a population of candidate structures,
we relax these candidat es to
the nearest local minimum. Using the
relaxed energies as the criteria of fitness,
a fraction of the popula tion is
selected as “parents.” The next generation
of candidate structures is produced
by “mating” these parents. The
process is repeated until the ground
state structure is located.
APPLICATIONS OF
GENERIC ALGORITHM
Genetic algorithms are a very effective
way of quickly finding a reasonable
solution to a complex problem.
Granted they aren’t insta ntaneous,
or even close, but they do an
excellent job of searching through a
large and complex search space. Genetic
algorithms are most effective in
a search space for which little is known.
You may know exactly what you want
a solution to do but have no idea how
you want it to go about doing it. This
is where genetic algorithms th rive.
They produce solutions that solve the
problem in ways you may never have
even considered. Then again, they can
also produce solutions that only work
within the test environment an d
flounder once you try to use them in
the real world. Put simply: use genetic
algorithms for everything you cannot
easily do with another algorithm.
Originally defined by the crea tor
John Holland, the goal of genetic algorithm
was to abstract and rigorously
explain the adaptive processes of
natural systems and to develop ways
in which natural adaptation might aid
computer systems and software. This
lead to important discoveries in both
the natural and artificial realms.
Smart card is just one aspect of a whole smart ID
A smart card is essentially a card
or token comprising a secure m icro
processor core and non volatil e
memory. It is like a visiting card, with
a tiny computer chip inside it.
It can store information and communicate
with smart card termi nals
that can read and write that information
to the card, as well as act as interface
between smart card and larger
network.
It is highly secured. At a bas ic
level, smart card can perform four
functions like data storage, identification,
authentication and appli cation
processing.
In an ideal situation, a person can
carry just a single smart card that acts
as a credit card, cash card, ration card,
PAN card, voter's card and eve n a
passport.
In this, security is in the form of
PIN number, passwords etc... w ith
sophisticated hacking equipmen t,
smart card data can be interce pted.
A secure processor core, on the other
hand, would be tamper-resistant and
prevent retrieval or modification of onchip
physical attacks.
The functioning of the smart card,
especially the communication task requires
power. The mode of performing
the power giving process depends
largely on the functions perfo rmed
and the power required for these.
Smart ID's are promising to he lp
Shashank Shekhar Singh
EC - II year
government agencies tackle the se
upcoming challenges better. As the
technology reasonably matures, this
is indeed the right time to in troduce
smart ID's.
27 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Junctionless transistor
Revolutionize chip industry
Transistor junction, what’s your function now..??
THE first transistors built in 19 47
were over 1 centimeter in size .
The smallest transistors today are less
than 30 nanometers long–over three
hundred thousand times smaller. The
result of these efforts is bil lion-transistor
processors where a bill ion or
more transistor-based circuits are integrated
into a single chip. B ut this
development cannot continue fo r
much longer. One of the increasingly
difficult problems that chip designers
are facing is that the high density of
components packed on a chip makes
inter-connections increasingly difficult;
and as conventional chip struc tures
continue to shrink.
The challenge over past decades
has been to keep up with Moore ’s
Law by cramming more and more transistors
into the limited real estate provided
by silicon chip fabrication methods.
But as future tech leans more
heavily on smaller, lighter, more mobile
devices with increased co mputing
power, the imperative to slim down
chip design while increasing efficiency
has grown increasingly greater.
Unfortunately, existing transistor
junctions - two pieces of silicon with
opposite polarities that allow the current
to be switched on and off within
the transistor are not all that efficient.
Current can leak from junction s,
upcoming power consumption and
causing overall inefficiency in devices
that increases with the number of
transistors. Junctions are also a major
factor in driving up costs in the chip
manufacturing process; as gateways
for current, they are the key mechanisms
in transistors, and manufacturing
high quality junctions can quickly
become very expensive.
In modern transistors, a negativepositive-negative
(black-white-black)
structure needs to be created, where
the width of the positive (white) region
is only a few dozens of a toms
wide, and the coloring has to be done
with a paint brush. It is very difficult
to avoid the black paint from smudging
into the white region. By contrast,
a junctionless transistor is e ntirely
painted white or black. This is much
easier to fabricate, especially at very
small dimensions.
The junctionless transistor circumvents
the need for junctions by pumping
current through a thin silicon wire
just a few atoms in diameter. A component
nicknamed the “wedding ring”
regulates the flow of current by electrically
“squeezing” the wire to stop
the electron flow, much in the way
you might crimp a drinking straw to
stop liquid from moving through it. The
architecture of the junctionless transistor
is simple enough that it can be
Schematic of a junctionless
nanowire transistor (top) an d
transmission electron microgra ph
of a single nano- ribbon devic e
(bottom). Individual atomic ro ws
cheaply produced even at very small
sizes, means, that the tech could contribute
to significantly cheaper transistors
in future. And because the
current is moving straight through a
silicon wire, it leaks very little current,
making these new structures a good
deal more efficient.
The key to fabricating a
junctionless gated transistor is the
formation of a semiconductor l ayer
that is thin and narrow enough to allow
for full depletion of carriers when
the device is turned off. The semiconductor
also needs to be hea vily
Department of Electronics & Co mmunication
Ashutosh Vikram Singh
EC - III year
doped to allow for a reasonabl e
amount of current flow when th e
device is turned on. Putting these two
constraints together imposes the use
of nano-scale dimensions and high doping
concentrations.
The electric field perpendicular to
the current flow is found to be significantly
lower in junctionless transistors
than in regular inversion-mode or accumulation-mode
field-effect transistors.
Since inversion channel mobility
in metal-oxide-semionductor transistors
is reduced by this electr ic field,
the low field in junctionless transistor
may give them an advantage in terms
of current drive for nanometer-scale
complementary metal-oxide semiconductor
applications. This observation
still applies when quantum con finement
is present.
Semiconductor companies are not
only looking at improving the performance
of their products, but also at
cutting down fabrication cost. The
fabrication of sharp junctions for the
22nm node and below require ex -
tremely fast, sophisticated and costly
annealing techniques. These ar e no
longer necessary in transistor s that
have no junctions.
Another key challenge for the
semiconductor industry is reducing the
power consumption of microchip s.
Minimizing current leakage is one of
the main challenge in today’s complex
transistors. Our junctionless devices
have near ideal electrical pro perties
and behave like the most perfect transistors.
They have the potenti al of
operating faster and using less energy
than the conventional transistors used
in today’s microprocessors.
Nevertheless, fabricating thes e
junctionless transistors is not without
challenges. The main task is to obtain
ultra pure, defect-free silicon crystals
with a thickness and a width of a few
atoms. This requires the use and control
of high-precision instruments like
electron-beam lithography equipment
and highly skilled operators.
28 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Green laser
A
laser works on the principle of
Light Amplification by Stimulated
Emission of Radiations. Traditional lasers
were of red color which offered
less strength, versatility and brightness
as compared to the advanced gr een
color lasers. A green color laser can
be generated within the small body
of a miniature flashlight. The green
color lies in the visible range and moreover,
can easily travel long distances.
Therefore, amateur astronomers often
use this laser to point at stars and
galaxies which are far away in space.
In green laser the devices create
coherent green light in a three step
process. A standard laser diod e first
generates near infrared light with a
wavelength of 808nm. This is focused
on a neodymium crystal that converts
the light into infrared with a wav e-
length of 1064nm. In the final step,
the light passes into a frequency doubling
crystal that emits green light at
a wavelength of 532 nm. All th ese
are easily be assembled into a cigarsized
packet and powered by a couple
of AAA batteries. And power ou tput
is 10 mW.
Green laser pointers are signi ficantly
brighter (about 60 times) than
a red laser pointer and because of its
unusual color it is much more noticeable.
FEATURES OF GREEN
LASER
• Extremely bright green laser a t
532 nm wavelength.
• Output power

SMS Institute of Technology, L ucknow
Campus interview
To access the personality trade of
any candidate, the interview i s
taken by the HR manager. In today's
cut-throat competition an empl oyer
is not supposed to having only technical
knowledge, but should be
equipped with some personality trades
such as a team player, leadership ability,
adaptability, grasping ability and
high tolerance of stress. In o rder to
check these qualities in a can didate
interviews are conducted by HR manager.
For a fresher level entry like engineering
graduates there are two
types of interviews has been c onducted.
‣ Technical interview
‣ HR interview
TECHNICAL INTERVIEW
A technical interview for a jo b
such as engineering, not only requires
more preparation more in depth of
knowledge the interviewee must
demonstrate his ability to solve problems.
While it may be easy to feel
overwhelmed about what technic al
question will be asked during the interview,
the key to doing well in a
technical interview is being a ble to
confidently demonstrate your knowledge.
HOW TO PREPARE FOR
A TECHNICAL
INTERVIEW
Make a list of the technical s kills
that you will need to review and study.
Read the job description and learn as
much as you can about the company
with which you are interviewing. Determine
what qualification tha t the
company is looking for and what skills
you need to have to do the job successfully.
Your research will give you
an idea of what questions migh t be
asked during the interview and what
you need to study.
SAMPLE QUESTIONS
Difference between big endian
and little endian?
What is race around condition?
WAP to display fibonacci series.
They will check some basic knowledge
in our core subjects and some
programming languages. They wi ll
also check your confidence level. So
be cool there.
HR INTERVIEW
When it comes to Human Resources
Management, the person ality
of the candidate is gauged at the
HR interview with a rather simple, logical
set of questions. And the key to
success is mainly your honesty in answering
the question from your own
experience and knowledge. You don't
have to cover a big syllabus or master
text books to prepare for the interview.
Let us divide the questions into
sets-
PERSONAL
INFORMATION
"Tell us about yourself"
This probably the first question at
an HR interview where they wou ld
judge the following:
‣ Your language fluency and presentation
style.
‣ Your family background and attitude
towards family, etc.
‣ Your priorities, values and beliefs.
It is a good practice to make yourself
clear about your personal life before
you start to think about who are
sitting in front of the panel. Details
like your family, your parent's where
abouts, your brother and siste r, etc.
and a little information about your
schooling, college with dates, values
of faith of religion, etc. could be organized
in a step by step manner, to
summarize in about two minutes , it
would be enough.
CARRIER OBJECTIVE
Department of Electronics & Co mmunication
Ashutosh Vikram Singh &
Prashant Mathur
EC - III year
Be specific about your carrier objective
and the objective of t he interview.
"In what way is this job going
to help you in your carrier objective?"
could be the most likely question.
If you are not convinced about
the positive impact of the job , you
are sure to lose the job too.
However, a little extra information
like the profile of the compan y general
knowledge and current aff air in
politics, sports, etc. might also come
up during the discussion. You might
as well know that most of the HR
manager are tired of interviewing candidates,
and if you can really keep
engaged with your answers not leaving
much of silence waiting for them
to dig out information from you, you
have better chances to getting the
job. If the interview lasts for longer,
the chances of you getting appointed
are higher.
Why should I hire
you?
Believe it or not, this is a killer question
because so many candidates are
unprepared for it. By now you can see
how critical it is to apply th e overall
strategy of uncovering the employer's
need before you answer the que s-
tion. If you know the employe r's
greatest needs and desire, this question
will give you a big leg u p over
other candidates because you will give
him better reasons for hiring you than
anyone else is likely to…reasons tied
directly to his needs.
Whether your interviewer asks
you this question explicitly or not, this
is the most important question of your
interview because he must answ er
this question favorably in is own mind
before you will be hired.Walk through
each of the position's require ments
as you understand them, and fo llow
each with a reason why you meet that
requirement so well.
SOME IMPORTANT TIPS
FOR INTERVIEW
‣ Do not smoke, chew gum, or eat
garlic beforehand.
‣ Wear suitable interview clothes.
‣ Take copies of your CV with you.
‣ Arrive on time for your job interview.
‣ Any applications handed before
the interview begins, are to b e
filled in as accurately as possible,
make sure they match the information
in your CV and Cover Letter.
‣ Always greet the interviewer b y
his/her last name and try to pronounce
it correctly.
‣ Have a good firm handshake.
‣ Look alert and interested. Sca n
the room once and then keep
your eyes on the interviewer.
‣ Wait until you are offered a chair
(Continued on Page 32)
30 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
IPTV: The future TV
I
PTV (Internet protocol Television)
is a new technology based on
internet protocol, offering en d-users
total control and high entertainment
value, is the need of the chan ging
technological scenario. IPTV to a large
extent, fits the bill, as it comprises a
host of application centred on IP, user
choice and rich content. IPTV services
may be classified into three m ain
groups: live television, time- shifted
programming, and video on demand
(VOD). It is distinguished fro m general
Internet-based or webbased
multimedia services by
its on-going standardization
process (e.g., European Telecommunications
Standards
Institute) and preferential
deployment scenarios in subscriber-based
telecommunications
networks with highspeed
access channels into
end-user premises via set-top
boxes or other customer premises
equipment. Over the
last decades, the HDTV have
all left their marks on TV scenario,
but none were considered
adequate enough to fit
the bill of the usage. IPTV
delivers programming to
households via a broadband
connection, using Internet
protocols. IPTV is clubbed
with other services like video -on-demand
(VOD), voice-over IP (VOIP) or
digital phone and Web access, collectively
referred to as triple play. Triple
play implies high-speed internet and
television/telephone service o ver a
single broad band connection. With
wireless, it is called quadruple play and
grouped services are called multi-play.
A value added application with high
average revenue per user seemed to
be the necessity of the hour, and it
was essential for this new application
to be based on internet protocol (IP)
to give the end-user full control and
high entertainment value. IP Television,
to a large extent fits the bill for
this kind of application as it represents
a host of applications centred on IP,
user choice and rich content.
DIFFERENCE BETWEEN
IPTV AND INTERNET TV
There is a very small differen ce
between IPTV and Internet TV. IPTV
refers to a closed and proprietary TV
system. The content of IPTV is sent
over secure IP channels, which can
be controlled.
Whereas Internet TV is an open
and evolving framework, to whi ch
small and medium-sized video producers
contribute. It is an open setup and
anyone having an internet connection
can access the data.
IPTV COMPONENTS
Video encoders: Video encoders
transform an input stream that can
be of various formats into a d igital
compressed stream.
Video server: Video servers are
computer-based devices linked to
large storage systems. Video content,
previously encoded, is stored either
on disk or in large banks of RAM Video
servers stream video and content.
Middleware: Middleware is the
software and hardware infrastructure
that conjoins the components o f an
IPTV solution. It is distribut ed operating
system that runs both on servers
at the telco's location and STBs.
STB/terminal: The STB is a CPE
that facilitates interface with the user,
Gaurav Mishra
EC - III year
the television and the network . For
live TV and VOD, the STB suppo rts
an EPG that allows customers to navigate
through the programming. The
STB transforms a jumbled digital compressed
signal into one that c an be
sent to the TV. The STB hosts the
middleware and is the centre of the
communications infrastructure within
a home.
HOW DOES IT
FUNCTIONS
It is different from conventi onal
analogue TV, IPTV runs through a
telephone line and a STB. It is a real
time-interactive medium by which a
user request can be processed in
real time. This feature allows
users to watch different
programmes depending on
their choice and time availability.
IPTV is also a multicast
and unicast platform, through
which viewers can choose
from hundreds of channels.
They can also demand for
channels of their choice in
IPTV, whereas cable TV and
satellite TV are only broadcast
modes, wherein viewers can
see only what is being broadcast.
This distinct differention
makes IPTV unique and desirable.
However, with IPTV, one
question comes up frequently: Where
does the STB receive its picture from?
"Most video content enters the system
at the telco's national head-end,
where network feeds are pulled from
satellites and encoded if nece ssary.
The video stream is broken up into IP
packets and put into the telco's core
network, which is a massive IP network,
that handles all sorts of traffic
(data, voice, etc), in addition to the
video". The video streams are received
by local office, where local content
(such as TV stations, advertising
and VOD) is appended to the mix. It
is also the spot where the IPT V
middleware is housed. This software
stack handles user authenticat ion,
channel change request, billin g and
VOD request. How does an IPTV sub-
31 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
scriber get hundreds of channels with
a digital subscriber line (DSL)? When
a user changes the channel on his STB,
the box does not tune a channel like
a cable system. It switches channels
by using the IP group membersh ip
protocol v2 to join a new mult icast
group. When the local office receives
this request, it checks to make sure
that the user is authorised to view
the new channel, directs the routers
in the local office to add the particular
user to the channel's distribution
index. In this way, only signa ls that
are currently being watched ar e actually
being sent from the loc al office
to the digital subscriber line access
multiplexer (DSLAM) and finally,
to the user".
Zigbee
A Zigbee standard has evolved
standardized sets of solution called layers.
These layers facilitate the features
that make Zigbee very attractive, low
cost easy implementation, reliable data
transfer, short range operation, very
low power consumption and adequate
security features.
Zigbee is one of the newest technologies
enabling wireless per sonal
area network (WPAN). It is a wireless
technology developed as an open global
standard to address the un ique
needs of low cost, low power w ireless
M2M network. The Zigbee p rotocol
has been ratified by mem ber
companies of the Zigbee alliance. It is
designed to provide an easy to use
wireless data solution characterized by
secured, reliable wireless network architecture.
The name of the brand was originated
with reference to the behaviour
of honey bees after their retu rn to
the beehive. Specified maximum
range of operation for zigbee devices
is 76 meters substantially further than
that by used Bluetooth capable devices.
A Zigbee protocol is de signed
to communicate through hostile RF
environments that are common i n
commercial and industrial applications.
Zigbee protocols features include;
‣ Support for multiple network topologies
such as point to poin t,
point to multipoint and mesh network.
IPTV VS DTH, CABLE TV
Although it is not appropriate to
compare IPTV with other modes of
broadcast, but there lies a difference
that is " The entry cost of IPTV service
is at par with cable TV but DTH
and other cable TV require m uch
more bandwidth (8 Mbps per hom e,
per connection), whereas IPTV can
be viewed at 2-3 Mbps."
ADVANTAGES OF IPTV
IPTV is a truly interactive service
and can provide numerous services like
e-commerce, e-governance, e-education,
e-medicine, weather and entertainment.
However, its penetration is
heavily dependent on good qual ity,
‣ Low latency.
‣ Low duty cycle-provide long battery
life.
‣ Direct spread spectrum.
‣ Collision avoidance.
In Industry, Zigbee is being used
for next generation automated manufacturing
with small transmitt ers in
every device on the floor, allowing for
communication between devices to
a central computer.
high bandwidth and broadband c onnectivity.
IPTV is still in it s nascent
phase in India. Considering th e current
scenario, IPTV can be said to have
both pros and cons. One of the best
advantages of IPTV is that it uses
Internet protocol to provide two-way
communication, making the television
viewing experience truly interactive.
Through this technology viewers not
only receive data but can also send
data back like e-mailing, instant messaging,
ticket booking, etc. With the
help of IPTV orders for buying different
products can be placed. The number
of application that can be put on
IPTV are virtually infinite.
Pooja Sharma
EC - III year
It provides the ability to run for
years on inexpensive batteries for a
host of monitoring and control applications.
Automatic meter readi ng,
lighting control, medical devices, fleet
applications are just some of the many
spaces where Zigbee technology is
making significant advancements.
32 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
MEMS
INTRODUCTION
A
Micro-Electro-Mechanical System
(MEMS) that contains both electrical
and mechanical componen ts
with its ranging size from nanometers
to millimeters. MEMS is a device which
is able to replace bulky networks, sensors,
actuators on a common silicon
substrate. These all are fabri cated
using IC process sequences (e. g.
CMOS, BICMOS process). This re -
duces bulk, cost, weight and p ower
consumption with increase in its performance,
production volume.
Furthermore, there are many applications
to come including g enetic
and disease testing, power dev ices,
RF devices, weapon system and data
storage. Micromirror- based switches
have already proven their importance.
MEMS promises to revolutionize almost
all product category by fabricating together
silicon-based microelectronics
with micromachining technology, making
possible the realization of complete
system-on-chip.
FABRICATION
The fabrication technique used in
MEMS consists of the conventio nal
techniques developed for integrated
circuit processing. The essential elements
in conventional silicon processing
are deposition, lithograph y, and
etching.
DEPOSITION
The essential element in MEMS
processing is the ability to deposit thin
films of material. In this process, we
assume that a thin layer to ha ve a
thickness anywhere between a f ew
nanometers to 100 micrometer. The
thin film then can be etched with the
help of developer. There may be various
types of deposition used for this
process which are as under:
‣ Chemical vapour deposition
‣ Epitaxy
‣ Oxidation
‣ Physical deposition:
Sputtering
Evaporation
Spin-on method
LITHOGRAPHY
Lithography includes three
sequential steps:
‣ Application of photoresist, which
is a photosensitive emulsion layer;
‣ Optical exposure to print an i m-
age of the mask onto the resist;
‣ Immersion in an aqueous developer
solution to dissolve the exposed
resist and render visible the
latent image.
The pattern layout is generate d
using a computer aided design and
transferred into a layer a specialized
mask-making facility, often by electron
beam or laser beam. A complete
microfabrication involves several lithographic
operations with differ ent
masks.
ETCHING
‣ Etch rate- The speed of the etching
should be fast enough to be
good for production but is als o
controllable.
‣ Uniformity- The etching is not location
dependent.
‣ Selectivity- Selection of developer
through which etching is done is
important.
‣ Directionality- They can be isotropic
, or anisotropic.
Isotropic etchants etch unifor mly
in all direction, resulting in rounded
cross sectional.
CATEGORIES OF MEMS
There are several different c ategories
of MEMS which are as under:
Department of Electronics & Co mmunication
Bulk micromachining
Tejashwani Dubey
EC - II year
Bulk micromachining is a technique
which builds mechanical elements by
starting with a silicon wafer, and then
etching away the unwanted parts and
left with useful mechanical devices.
Today almost all pressure sensors
are built with bulk micromachining. Bulk
micromachined pressure sensors offer
several advantages over tradit ional
pressure sensors. They cost less, are
highly reliable, manufacturable, and
there is very good repeatabili ty between
devices. The small size and high
reliability of micromachined pressure
sensors make them ideal for a various
of medical fields.
Surface Micromachining
In bulk micromachining, the de -
vices are build by etching into a warfer,
Surface micromachining builds devices
from the wafer layer by layer. A Surface
Micromachining is a repet itive
33 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Campus Interview
(Continued on Page 28)
before you sit down.
‣ Stress your achievements.
‣ Always conduct yourself profes -
sionally and if something beyond
your control occurs, show a sense
of humor.
‣ Be enthusiastic and show it in
your replies and body language.
‣ Answer the interview question by
more than a simple yes or no but
try not to go over the 60 second
limit.
‣ Avoid at all cost complaining about
your current or former employer
in your job interview.
sequence of depositing thin films on
a wafer, photo patterning the films,
and then etching of the films. In order
to create moving functioning machines,
these layers are alter nating
thin films of a structural material (typically
silicon) and a sacrificial material
(typically silicon dioxide).
Surface Micromachining require s
more fabrication steps than Bu lk
Micromachining, and therefore it is
more expensive. It is able to create
much more complicated devices, capable
of sophisticated functio nality.
Surface Micromachining is suitable for
applications requiring more so phisticated
mechanical elements.
APPLICATIONS
There are various possible applications
for MEMS. Here are a few applications
of current interest:
Biotechnology
MEMS is enabling new discoveries
in engineering such as polymer ase
Chain reaction (PCR) Microsystems for
DNA amplification and identification,
micromachined
scanning tunneling microscopes
(STMs), biochips
etc.
Communications
High frequency circuits
will benefit considerably
from the advent of the RF-
MEMS technology. Electrical
components such as inductors
& capacitors can be improved
if they are made
using MEMS.
Accelerometers
MEMS accelerometers
are rapidly replacing conventional
accelerometers
for crash air-bag deployment
systems in automobiles.
These MEMS accelerometers
are much smaller,
more functional in working,
lighter in weight, more reliable,
and are produced for
a fraction of the cost of the
conventional macroscale accelerometer
elements.
ADVANTAGES
First extremely diverse technology
that could significantly affec t every
category of commercial and mil itary
product. It is used for tasks ranging
from in-dwelling blood pressure monitoring
to active suspension sy stems
for automobiles. The nature of MEMS
and its diversity of useful applications
make it potentially a far more pervasive
technology than even integrated
circuit microchips.
‣ Do not answer questions about
politics or religion if the job is completely
unrelated.
‣ Do not raise salary discussions on
your first interview - this is usually
done on the second interview.
Make sure you do your wage research
before hand.
Your answer to the initial opening
statements in the job intervie w are
important, these are called "ice breakers".
Sometimes the interviewer will
ask whether you had difficulty finding
the company premises. Your ans wer
should be brief and polite. The interviewer
is merely being polite - if you
had problems in finding the premises
he/she doesn't need to know th at.
Use replies such as-
‣ I'm fine thank you, and you?
‣ I'm very well, thank you.
Avoid these because these replies
express a careless attitude-
‣ So, so
‣ OK
‣ Not so well
While you are interviewing jus t
keep these things in your mind and
rest will be good. Don't bother about
result. Just give your 100%.
34 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Electronics unborn
Department of Electronics & Co mmunication
Future of electronic product and services seems to be bright as advancement
in technology affects us in every context of life. Electronics now becomes
a part of our life style. It's harder to imagine a life without electronic
gadgets for e.g. Cell phones, computers and Calculators etc. Development
of the electronic technology in a short span has given us lot of comfort.
Through this article, we will try to summarize various developments taking
place in electronic field and its future aspects.
PLASTIC ELECTRONICS
Polymers that conduct electrici ty
without the assistance of fillers are
quickly emerging as the basis for
future devices, such as electr onic
paper, light weight solar cells and inexpensive.
Compounded conducti ve
polymers will play a critical role in the
successful proliferation and miniaturization
of electronic devices, as they
provide inexpensive protection against
electrostatic discharge and el ectromagnetic
or radio frequency interference.
Conducting polymers also have the
potential to become alternative to silicon-based
electronics. It is b elieved
that plastic electronics, based on thin
film transistors fabricated by organic
films, will create a new range of products
that could not be manufactured
using conventional CMOS approaches.
Flexibility of thin films also suggests
a new product line, including rollup
display, low cost RFID tags, flexible
sensors and photovoltaic arrays. Plastic
electronics also generates less heat
and use less power, thus allev iating
two major problems bothering c onventional
electronics.
GRAPHINE
TECHNOLOGY
New research findings suggest
that use of graphine in microchip could
make them faster in comparison to the
standard silicon microchips. Thus, use
of this technology in future cell phones
and other communication systems will
mean much faster transmission of
data.
With conventional silicon-base d
electronics, frequency cannot be increased,
but graphine technolo gy
could help in developing syste ms in
the 500 to 1000 gigahertz rang e.
Graphine, a pure form of carbon is
the strongest material ever di scovered.
It also has a number of unique
electrical properties, such as mobilitythe
ease with which electron can start
moving in the materials- which is 100
times more than that of silicon.
Researcher have already used the
one-atom-thick layer of carbon atoms
to make prototype transistors and
other simple devices. Frequency multipliers
are being widely used in radio
communications and other appli cations.
But existing system req uires
multiple componenets, signal filtering,
and they consume more power.
Whereas the graphene system ha s
just a single transistor and produces a
clean output efficiency.
MAJOR CHALLENGES
In spite of all the advantage electronics
there are some challen ges
which electronics have to face in future.
Some of these are:
ELECTRONIC WASTE: Electronics
should not have any advers e effect
on the environment. Through responsible
use, reuse and recycling Of
electronic products, the electronic industry
and consumers can protect and
preserve our environment. The rapid
pace of technological advancement in
the field of electronics has made electronics
gadgets both affordabl e and
widely used. This result in large quantities
of electrical and electronic equipments
being added to the waste
stream called electronic waste , also
known as 'E- waste.' These equ ipments
are made up of a multitude of
components, some containing to xic
substances which can have adve rse
effect on human health and environment.
Often, these hazards arise due
to the improper recycling and disposal
processes used.
GREEN TECHNOLOGY: Green
technology emphasis on using e lectronic
products in a manner such that
it has minimum adverse effect. Best
practices like how to stop wastage of
energy, which zioms are greener than
others, and e-waste management are
the prerequisites for moving towards
green technology solution.
QUALITY AND QUANTITY
CONCERN: To cope up with market
and fulfill customer requirement in a
limited budget, electronic manufacturers
compromises with quality of product.
Increasing number of elec tronic
product either discarded or being repaired
indicates their poor quality.
There are billions of circuit board
enter the global market every year,
and there are evidences to ind icate
that there are only 5-10% are as per
current IPC standards. Thus, quality
and reliable products will play important
role in shaping future of electronics.
We must have to learn to produce
them in quantity with rea sonable
market price without compromising
quality. There should be appropriate
relation between production and
application.
35 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
NN Power Planner
Thyristor based intelligent mo tor
controller
Jaikar Sahai
EC - III year
INTRODUCTION
NN Power Planner is a
microcontroller controlled thy ristor
based intelligent Motor Contro ller
which provides a simple, effec tive,
reliable & economical solution to the
problems of an ac Induction Motor by
constantly monitoring the effi ciency
of the motor by utilizing powerful microcomputer
& ensuring that the input
power to the motor is matc hed
exactly to the load as it changes.
Even the slightest variation in the
demand is sensed & NN Power Planner
will respond by supplying full power
to the motor if required in 100th of a
second. This controlled releas e of
power to the motor provides smooth
& step less acceleration & dec eleration,
also enabling more frequent starting
& stopping.
A soft start & soft stop facility incorporated
in all NN Power Planner. 3
phase units ensure about 300 s tarts
per day. Further, by eliminating high
inrush current on start up, maximum
demand is also considerably reduced.
NN Power Planner has unrivalled ability
to change the shape of the applied
voltage waveform thus re duc-
ing the impact of standing losses existing
in all AC induction Motors. Once
the motor has reached its full speed,
the NN Power Planner optimizin g
mode will search for the minim um
power required ensuring the maximum
continuous rating of the motor is
matched exactly to the load it varies.
Thus improving power factor & ensuring
minimum running cost. In short
NN Power Planner gives the motor an
exact amount of power it needs to
do the required job of work at any
instant, no more no less.
HOW NN POWER
PLANNER WORKS
In common with all soft start devices
NN POWER PLANNER uses Thyristors
to accurately control the voltage
applied at the motor terminals.
A characteristic of the Thyristor to
switch rapidly from "OFF" to " ON"
when pulsed, and to remain "ON" until
the current through the device falls
to zero at the end of each half cycle
in the AC supply, is called self communication.
By controlling the switch-on point
relative to the voltage zero c rossing
in each half cycle of the supply, it is
possible to regulate the current flowing
through the thyristor. The closer
the turn on point is to the end of the
cycle the smaller the value of current
that will be allowed to flow. Conversely,
the closer the turn-o n point
is to the beginning of the cyc le the
higher the value of current wi ll be.
Using this principle and by connecting
two Thyristor in anti-parallel to each
of the phase connections to a motor
NN Power Planner continuously adjusts
the voltage to the motor terminals
by precisely controlling the Thyristor
turn-on points. This provides just
sufficient voltage for the mot or to
accelerate the load. So, for instance,
by starting with a large delay to the
turn on point in each half cycle, and
progressively reducing it over a selected
time period, the voltag e applied
to the motor starts from a relatively
low value and increases to full
voltage. Due to the motor torq ue
being proportional to the squa re of
the applied voltage, the start ing
torque increases in a step less manner
ensuring a soft start for both the
motor and the driven load.
ENERGY SAVINGS
When working at or near full load,
the typical 3-phase induction motor is
relatively efficient, achieving efficiencies
of between 80% to 92%.
Motor speeds cannot be varied,
the optimization software in the NN
Power Planner will produce ene rgy
savings in lightly loaded motors.
By detecting the load at any i n-
stant, and adjusting the motor terminal
voltage accordingly, it is possible
to save some of the excitation energy
and load loss, and improve motor
Power Factor when the moto r is
running Inefficiently at light loads.
ENERGY OPTIMIZATION
NN Power Planner has better and
36 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
advanced programmed Microcontroller
which always tries to deliver exact,
matching amount of power to motor
in 1/100th second, so that Mot or
uninterruptly drives the given load with
less POWER. NN Power Planner Guarantees
ENERGY SAVING up to 9-10%
on MOTORS running partly or on
VARIABLE LOAD. It has also got the
feature of dynamic backstop vo ltage
control, which can be fine tuned from
67% LV to 100% LV for better EN-
ERGY savings.
APPLICATIONS
NN Power Planner can be used on
any application where motor's speed
is constant and motor is runni ng on
variable load or part load for most of
its duty cycle. The best appli cations
where NN Power Planner can be used
are:
1- Injection Moulding Machines
2- Hydraulic Press
3- Suction Rod Pump
Quantum computing
Imagine a computer that calculates
the data 10 times faster than the
computer's processor, like Pentium-4
& core 2 duos, use now-a-days!!
Scientists & researchers are trying
for the development of such hi gh
speed processors that work on the
principle -:
"Atoms are natural calculators”. On
this basis, Quantum computers are developing
in present date.Recen tly,a
great physicist ,Prof Michael De Lyukin
leading a team has got the success of
first entanglement of quantum science
between a solid state material and
photon!!Prof.at Harvard university said
that this achievement is the first step
towards development of practic al
quantum computers.
Via the entanglement of photon
& solid state material only th e solid
state bits or qubits are able to communicate
through a longer dist ance
at a very fast pace.Digital computers
use qubits for all specific operations.
Scientists consider photons as the
fastest medium for transmissio n of
quantum information without an y
loss. Seemingly with these technologies,
our future would be embedded
with turbo boost technology!!A t the
Argonne National Laboratory, P aul
Benioff is credited with first applying
4- Machine Tools
5- Grinders
6- Conveyors
7- Metal Cutters
8- Escalators
9- Crusher
IN SUMMARY IT MEANS
THAT NN POWER
PLANNER WILL
1. Reduces the amount of Current
quantum turning machine.
This superposition of qubits gives
to quantum computers their inherent
parallelism. According to phys icist
David Deutsch, this parallelism allows
a quantum computer to work on a
million computations at once. While
our desktop pc works on one. A 30-
Qubit quantum computer would b e
equal the processing power of a conventional
computer that could run at
10 teraflops(trillions of floating-point
operations per second).Today's typical
desktop computers run at s peed
in gigaflops (billions of floating points
operations per second).
Problems and practicality issues (To
get to quantum computers):-
There are a number of practica l
difficulties in building a quantum computer.
David Di Vincenzo, of IBM, listed
the following requirements for a practical
quantum computer:
‣ Scalable physically to inverse the
number of qubits.
‣ Qubits can be initiated to arbitrary
values.
‣ Quantum gates faster than coherence
time.
‣ Turing-complete gate set.
‣ Qubits can be read easily.
To summarise the problem from
the perspective of an engineer, one
consumed by the motor to do its
job of work.
2. Reduces the high starting and inrush
current while starting.
3. Increases motor life by 50% to
70%.
4. By reducing maintenance costs
and equipment down time improves
motor and plant reliability.
5. It is suitable for a very wide range
of applications.
6. Even to high efficiency motor, it
not only provide superb contro l
over the starting and stopping of
the motor, furthermore it gives an
additional saving in overall energy
consumption by its dynamic control.
7. Its prices are extremely attractive
and competitive.
This device is currently in use and
marketed by NN PROJECT LIMITED ,
a firm based in Gurgaon, Haryana.
Siddhant Tripathi
EC - II year
needs to solve the challenge of building
a system which is isolated from
everything except the measurem ent
and manipulation mechanism. Further
more, one needs to be able to turn
off the coupling of the qunits to the
measurement so as to not DECO here
the qubits while performing operations
on them.
QUBIT CONTROL
Computer scientists control th e
microscopic particles that act as qubits
in quantum computers by using control
devices.
‣ Ion traps use optical or magnetic
fields (or Opt magnetic field) to
trap ions.
‣ Optical traps use light waves to
trap and control particles.
‣ Quantum dots are made of semiconductor
material and are used
to contain and manipulate elec -
trons.
‣ Semiconductor impurities contain
electrons by using unwanted atoms
found in semiconductor material.
‣ Superconducting circuits allow
electrons to flow with almost no
resistance at low temperatures.
37 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Plasmonics
PLASMONICS is thought to repre
sent the strongest points of both
optical and electronic data tr ansfer.
Optical data transfer, as in f iber optics,
allows high bandwidth, b ut requires
bulky "wires," or tubes with
reflective interiors. Electron ic data
transfer operates at frequencies inferior
to fiber optics, but only requires
tiny wires. Plasmonics, someti mes
called "light on a wire," would allow
the transmission of data at optical frequencies
along the surface of a tiny
metal wire, despite the fact that the
data travels in the form of el ectron
density distributions rather than photons.
It is the fact that plasmonics have
a great role in the green energy market
economy by integrating with the
existing PN junction solar cell by making
it more absorbent of heat in all
range of the frequency that co mes
from the sunlight.
Plasmonic, Nano particles of gold
or silver.
The main limitation to plasmonics
today is that plasmon tends to dissipate
after only a few millimeters, making
them too short-lived to serve as a
basis for computer chips, which are a
few centimeters across. For se nding
data even longer distances, th e key
is using a material with a low refractive
index, ideally negative, such that
the incoming electromagnetic energy
is reflected parallel to the surface of
the material and transmitted along its
length as far as possible. There exists
no natural material with a neg ative
refractive index, so nano stru ctured
materials must be used to fabr icate
effective plasmonic devices. For this
reason, plasmonics is frequently associated
with nanotechnology.
ABOUT "PLASMON"
The name plasmon derived
from the physical plasma as a
state of matter in which the a t-
oms are ionized. At the lowest
densities this means an ionize d
gas, or classical plasma; but densities
are much higher in a metal,
or quantum plasma.
Plasmon consists of discrete
units known as plasmagenes. The
extrachromosomal gene in plants
was first described in 1908 by the
German botanist.
The plasmon energy for most
metals corresponds
to that of an ultraviolet
photon. However,
for silver, gold, the
alkali metals, and a few
other materials, the plasmon
energy is sufficiently
low to correspond to that
of a visible or near-ultraviolet
photon. This means
there is a possibility of
exciting plasmons by light.
If plasmons are confined
upon a surface, optical
effects can be easily
observed. In this case,
the quanta are called surface
plasmons, and they have the bulk plasmon
energy as an upper energy
limit.Surface plasmons were first proposed
to explain energy losses by electrons
reflected from metal surfaces.
The plasmon is a quasiparticle. Its
energy is approximately equal to L
,
where
Saurabh
EC - II year
is the angular plasma (Langmuir) frequency,
e and m are the charge and
mass of the particles. The energy of
a plasmon is determined from the characteristic
energy losses sustained by
electrons in metals: electrons passing
through the plate expend energy on
the excitation of plasma oscillations,
that is, on the "creation" of plasmons.
Another method of determining the
38 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
energy of a plasmon is analysis of the
light spectrum emitted by plasmons.
APPLICATIONS
Plasmon waveguides, extraordinary
transmission through aper ture
arrays, sensing and surface enhanced
Raman scattering, spectroscopy as
well as meta-materials.
Position and intensity of plasmon
absorption and emission peaks are affected
by molecular adsorption, which
can be used in molecular sensors
Potential applications extend to
new light sources, solar cells, holography,
raman spectroscopy, and microscopy
applications of surface plasmon
resonance spectroscopy was the measurement
of the thickness of adsorbed
self-assembled nanofilms on gold substrates.
Most practical applications is SPR
emission When the surface plas mon
wave hits a local particle or irregularity-like
on a rough surface
GENERATION OF
PLASMON
Plasmons are generated when,
under the right conditions, light strikes
a metal. The electric field of the light
jiggles the electrons in the m etal to
the light's frequency, setting off density
waves of electrons. The process
is analogous to how the vibrations of
the larynx jiggle molecules in the air
into density waves experienced as
sound.
Metals provide the best evidence
of plasmons, because they have a
high density of electrons free to move.
Plasmons are density waves of
electrons, which are created w hen
light hits the surface of a metal under
precise circumstances. Because these
density waves are generated at optical
frequencies, very small and rapid
waves.
Hybrid computer
Computers are devices that exhibit
features of analog computers and digital
computers. The digital component
normally serves as the controller and
provides logical operations, while the
analog component
normally
serves as a
solver of differential
equations.
In hybrid
computer Signals
pass across
the synapses
from one nerve
cell to the next
as discrete
(digital) packets
of chemicals,
which are then
summed within
the nerve cell in
an analog fashion
by building
an electrochemical
potential
until its threshold is re ached,
whereupon it discharges and se nds
out a series of digital packets to the
next nerve cell. The advantage s are
at least threefold: noise within the system
is minimized (and tends no t to
be additive), no common ground ing
system is required, and there is minimal
degradation of the signal even if
there are substantial differen ces in
activity of the cells along a path (only
the signal delays tend to vary ). The
individual nerve cells are analogous to
analog computers; the synapses are
analogous to digital computers.
Note that hybrid computers should
be distinguished from hybrid systems.
The latter may be no more than a
digital computer equipped with an
analog-to-digital converter at the input
and/or a digital-to-analog converter
at the output, to convert analog
signals for ordinary digital signal
processing, and conversely, e.g., for
driving physical control systems, such
as servomechanisms.
Gaurav Mishra
EC - III year
39 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Common Admission Test (CAT)
WHAT IS COMMON
ADMISSION TEST?
The common admission test (CAT)
is an All India test conducted by the
Indian Institutes of managemen t
(IIMs) as an entrance exam for the
management programmes of its 14 B
(Business) schools.
About 250,000 students took
CAT 2008 for about 1500 seats in the
IIMs more selective than the universities.
The CAT is the first step for admission
to the IIMs. After the test,
by the second week of January next
year, the IIMs declare exam sc ores
and put up a list of candidates who
are eligible for the next stag e of a
group discussion for some IIMs & an
individual interview.
CAT 2009: The first ever computer
based CAT conducted by
prometric during 28th nov - 7th dec.
Many other business Schools in
India, other than IIMs, also accept the
CAT scores for admission. This has
contributed to the CAT gaining an
extremely high popularity. As of 2008,
CAT scores are accepted by approximately
120 MBA institutes in India.
WHY CAT ?
CAT is the only exam which provides
entrance in the top B-sc hools
of India inspite of IIMs.
CAT also does not require any
technical background like othe r exams
required. It requires only 8th to
10tn class maths for its quantitative
section. So, some of the points why
we select CAT are :
‣ CAT is not about following rules,
it is all about breaking the rules.
‣ CAT is not about rocket science,
it is about the basics of life.
‣ CAT is not about taken tracks, it
is about defining a new track.
‣ CAT is not about selecting answers,
it is about eliminating the
answer.
HOW TO PREPARE FOR
CAT?
This is a very complex questio n
that how we prepare for CAT. So, the
answer is here.
Many of us thought that CAT is a
test of your managerial aptitu de &
managerial skills like:
‣ Time management
‣ How would handle pressure &
uncertainty.
‣ Decision making.
Remember, CAT is not solving 150
questions in 120 minutes. It is about
solving 90 to 95 questions with 85 to
90 % accuracy. Here are a few tips
that would help to fetch you a call
from the best B-schools in the country.
TIP 1: HANDLE PRESSURE
AND UNCERTAINTY WELL
Handling pressure and uncertainty
is a crucial element of CAT. This is a
essential skill that a manager requires
in his/her daily decision making process.
The CAT examination spans 120
minutes, but if you are able to handle
pressure in the first 15 and l ast 10
minutes, your chances to excel increase.
Some points to help yo u at
this stage are:
1. Have a flexible strategy.
2. Scan your question paper for the
initial three to four minutes to locate
easy questions.
3. Attempt your favourite section
first.
4. Remember CAT is another name
of uncertainty.
TIP 2: SEQUENCE AND
PRIORTISE YOUR MANTRAS
FOR SUCCESS
‣ Deciding on the sequence in
which you will attempt the various
sections.
‣ Allocating an appropriate time for
each section.
‣ Prioritizing questions within sections.
For E.g.- your strategy before entering
the examination hall should be-
1. Scanning : 3-4 minutes
2. Data Interpretation : 40 minutes
3. Verbal Ability : 40 minutes
The section may interchange ac -
cording to your favourite section.
TIP 3: SOME SPECIFIC
SECTION STRATEGIES-
1. Quantitative ability :- Attempt
question in three rounds-
Round 1:
‣ Attempt all one liners
‣ Attempt all two liners
‣ Attempt all four liners
‣ Attempt those questions in which
data are given.
Round 2:
Come back to the left question s
of Round 1. Under pressure, yo u
might left some easy questions . Attempt
them again.
Round 3:
Aman Kumar
EC - III Year
If time permits, attempt the
lengthier questions of your favourite
topics. But remember, it takes just 5
to 10 seconds to decide whether you
should attempt or leave the question.
2. Verbal ability:- Most students
attempt English usage or Reading
and Comprehension part first.
‣ In Para jumbles, look out for
structural & logical connectors.
‣ Before attempting Reading &
Comprehension, scan the
question once.
‣ Be careful in grammatical portion.
3. Data Interpretation / Data
approximation:-
‣ Revise your percentages &
approximation.
‣ Data sufficiency questions are
independent of each other &
should be attempted first.
‣ After data sufficiency questions,
attempt single graph
questions followed by the
double graph questions.
‣ Questions based on logical
games & logical tables should
be attempt at last.
COURCES OFFERED BY
SOME TOP INDIAN B-
SCHOOLS
Courses offered @ IIM Bangalore;
(Continued on Page 42)
40 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Ground Penetrating Radar (GPR)
INTRODUCTION
AS we know landmines are very
harmful for us. Landmines and
unexploded ordnance (UXO) are a
legacy of war, civil disobedience and
guerilla activity. If all mines were cased
or had substantial metallic content, all
that would be required for det ection
are metal detectors. The widespread
use of plastic landmines necessitates
development and deployment of additional
detection technologie s. Because
there is no such thing as a plastic
detector, other sensors at tempt
to exploit ancillary disturbances in the
background, such as thermal, chemical,
or dielectric.
OVERVIEW OF THE
SYSTEM
Because of the difficulty dete cting
the tiny amounts of metal in a plastic
landmine with a metal dete ctor,
technology development has bee n
funded in other areas. Ground penetrating
radar (GPR) has been used
for nearly 70 years for a variety of geophysical
subsurface imaging applications
including utility mapping and hazardous
waste container location and
has been actively applied to the problem
of landmine detection for nearly
20 years. When parameters such as
frequency range, antenna size, antenna
separation and system ti ming
are optimized for detection of minesized
objects in the near subsurface,
GPR is quite effective in dete cting
both metal and plastic landmines in a
variety of soils. The depth of penetration
is a function of both the frequency
range produced and the soil
attenuation.
Lower frequency components
penetrate further but it is a higherfrequency
component that is ne cessary
to image and resolve smaller targets.
Both impulse- based and swept
frequency GPR systems have bee n
employed in Army-sponsored research
programs. Generally a system with a
bandwidth of roughly 1 to 4GHz is
effective for detection of landmines.
Ultimately GPR images the dielectric
properties of the soils a nd any
discontinuities appear as a signal. If soil
were perfectly homogeneous, a discontinuity
caused by a land mi ne
Screen shot of host software f rom GEO-CENTERS
would stand out as an anomaly against
the background. Unfortunately, even
under near-ideal test track conditions,
soil itself is a remarkably in homogeneous
medium and false alarms are
easily generated from the background
itself. Because of this, automatic target
recognition (ATR) algorithms employed
by impulse-based GPR systems
typically calculate and remove background
and try to detect the h yperbolic
signatures that are characteristic
in size and shape of landmine targets
in GEO-CENTERS 400 Series energy
in focusing ground penetr ating
radar (EFGPR), we employ a fuz zy
logic-based algorithm that use prototypes,
or feature sets, for landmines
and prototypes than to clutter.
HOW IT WORKS?
An FR-127-MSCB impulse ground
penetrating radar (ImGPR) syst em
developed by the Commonwealth
Scientific and Industrial Research Organization
(CSIRO), Australia, has been
used for these measurements. T he
system collects 127 returns or surroundings,
per second each composed
of 512 samples with 12 bit acc uracy.
The sounding range may vary from 4
ns to 32ns. The GPR system uses
bistatic bow-tie antennas which transmit
wideband ultrashort durati on
pulses.
The measurements form a two
dimensional matrix referred to as a
radargram or B scan and A scan are
used for visual inspection of data on
Department of Electronics & Co mmunication
B SCAN
Priyanka Shukla
EC - III year
the acquisition computer
and in laboratory
analysis.
A SCAN
A scan is a method
for detecting the presence
and absence of
surrogate mine in clay
soil. The electromagnetic
field is scattered
by the GPR. Scattering
pulses are detecting by
the graph. This graph
is Amplitude Vs Time.
This graph is helpful to
find the landmine and
is used for visual inspection.
B scan is a graph which is Tim e
delay Vs Distance. So B scan helps to
calculate the penetration length. This
graph helps to calculate the distance
from ground to the mine.
ADVANTAGES
‣ GPR locates even small targets.
‣ GPR operates by detecting the
dielectric soils which allows it to
locate even no metallic mines.
‣ Biological sensors can only operate
for limited periods but in GPR
has no such limits.
‣ GPR has been tested in different
environmental conditions.
DISADVANTAGES
‣ The sensor such as GPR is larger
and heavier.
‣ GPR is more power hungry.
‣ GPR can suffer falls alarm rates as
high as metal detectors.
41 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Surface-conduction electron-emitter display
(SED)
Priyanka Gupta
EC - III year
less power than an LCD
television of the same
size.
After considerable
time and effort in the
early and mid-2000s,
SED efforts started
winding down in 2009
as LCD became the
dominant technology.
SED are closely related
to another developing
display technology, the
field emission display, or
FED, differing primarily in
the details of the electron
emitters. Sony, the
main backer of FED, has
similarly backed off from
their development efforts.
Canon's 36" prototype SED, sho wn at the 2006 CES
WORKING
A
surface-conduction electronemitter
display (SED) is a fla t
panel color television technology currently
being developed by a number
of companies. SED use nanoscop icscale
electron emitters to energize colored
phosphors and produce an image.
In a general sense, a SED consists
of a matrix of tiny cath ode ray
tubes, each "tube" forming a s ingle
sub-pixel on the screen, group ed in
threes to form red-green-blue (RGB)
pixels. SED combine the advantages
of CRTs, namely their high con trast
ratios, wide viewing angles and very
fast response times, with the packaging
advantages of LCD and ot her
flat panel displays. They also use much
A conventional cathode ray tub e
(CRT) is powered by an electron gun,
essentially an open-ended vacu um
tube. At one end of the gun el ectrons
are produced by "boiling" them
off a metal filament, which re quires
relatively high current. The electrons
are then accelerated and focused into
a fast-moving beam, flowing forward
towards the screen. Electromag nets
surrounding the gun end of the tube
are used to steer the beam as it travels
forward, allowing the beam to be
scanned across the screen to produce
a 2D display. When the fast-mo ving
electrons strike phosphor on the back
of the screen, light is produced. Color
images are produced by painting the
screen with spots or stripes of three
colored phosphors, one each for red,
green and blue (RGB). When viewed
from a distance, the spots, known as
"sub-pixels", blend together in the eye
to produce a single colored sp ot
known as a pixel.
COMPARISON
Liquid crystal display television
The primary large-screen television
technology being deployed in t he
2000's is the liquid crystal display televisions.
SED aimed at the same market
segment. LCD does not dire ctly
produce light, and have to be back-lit
using cold cathode fluorescent lamps
(CCFL) or high-power LED. The SED
produces light directly on its front surface.
Scenes are lit only on those pixels
that require it, and only to the
amount of brightness they requ ired.
Canon's 55" prototype SED offe red
bright images of 450 cd/m2, 50,000:1
contrast ratios, and a response time
of less than 1 ms. Canon has s tated
that production versions would improve
the response time to 0.2 ms
and 100,000:1 contrast ratios
Current generation
Next generation
Electroluminescent display (EL D),Vacuum fluorescent display (VFD), Light emitting
diode display, Cathode ray tube (CRT),Liquid crystal display (LCD),Plasma display panel
(PDP),Digital light processing (DLP),Liquid crystal on silicon (LCoS).
Organic light-emitting diode (OLED),Surface-conduction electron-emitter display
(SED),Field emission display (FED),Laser TV (Quantum dot laser, Liquid crystal laser),
Ferro liquid display (FLD),Interferometric modulator display (iMoD), Thick-film dielectric
electroluminescent (TDEL),Quantum dot display (QD-LED),Time-multiplexed optical
shutter (TMOS),Telescopic pixel display (TPD),Organic light-emitting transistor
(OLET),Laser phosphor display (LPD).
42 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
E -Waste
Electronic waste, E- scrap or waste Electrical and
electronic equipment (WEEE)
DEFINITION "Electronic waste"
may be defined as all secondary
computers, entertainment devic e
electronics, mobile phones, and other
items such as television sets and refrigerators,
whether sold, donated, or
discarded by their original ow ners.
This definition includes used electronics
which are destined for reuse, resale,
salvage, recycling, or d isposal.
Others define the re-usables ( working
and repairable electronics ) and
secondary scrap (copper, steel, etc.)
to be "commodities", and reserve the
term "waste" for residue or material
which was represented as working or
repairable but which is dumped or disposed
or discarded by the buye r
rather than recycled, includin g residue
from reuse and recycling operations.
"Electronics Waste is a waste
consisting of any broken or unwanted
electrical or electrical appliance."
GLOBEL TRADE IS-
SUES FOR E-WASTE
Increased regulation of electronic
waste and concern over the environmental
harm which can result f rom
toxic electronic waste has raised disposal
costs. The regulation creates an
economic disincentive to remove residues
prior to export. Critics of trade
in used electronics maintain that it is
too easy for brokers calling themselves
recyclers to export unscreened electronic
waste to developing countries,
such as China, India and parts of Africa,
thus avoiding the expens e of
removing items like bad cathode ray
tubes (the processing of which is expensive
and difficult). The de veloping
countries are becoming big dump
yards of e-waste due to their weak
laws. Proponents of internatio nal
trade point to the success of fair trade
programs in other industries, where
cooperation has led creation of sustainable
jobs and can bring affordable
technology in countries where repair
and reuse rates are higher. In highly
polluting, primitive Guiya in the
Shantou region of China, Delhi and
Bangalore in India as well as the
Agbogbloshie site near Accra, Ghana
have electronic waste processing areas.
Uncontrolled burning, disassembly,
and disposal can cause a variety
of environmental problems such as
groundwater contamination, atm o-
spheric pollution, or even water pollution
either by immediate dis charge
or due to surface runoff (espe cially
near coastal areas), as well as health
problems including occupational safety
and health effects among those directly
involved, due to the me thods
of processing the waste. Thous ands
of men, women, and children are employed
recycling technologies, extracting
the metals, toners, and pl astics
from computers and other electronic
Aditya Bhardwaj
EC - III year
waste. Recent studies show tha t 7
out of 10 children in this region have
too much lead in their blood.
SOURCES OF E-WASTE
‣ IT &TELECOM Equipments
‣ Large household Appliances &
Small household Appliances
‣ Consumer & Lighting Equipments
‣ Electrical & Electronics Tools
‣ Toys, Leisure & Sports Equipment
‣ Medical Devices
‣ Monitoring & Control Instruments
E- WASTE
MANAGEMENT
Recycling:
Today the electronic waste rec y-
cling business is in all areas of the developed
world a large and rapidly consolidating
business. Electronic waste
processing systems have matured in
43 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
recent years, following increased regulatory,
public and commercial scrutiny,
and a commensurate increase in entrepreneurial
interest. Part of this evolution
has involved greater di version
of electronic waste from energy-intensive
downcycling processes (e.g., conventional
recycling), where equipment
is reverted to a raw material form. This
diversion is achieved through reuse
and refurbishing. The environm ental
and social benefits of reuse i nclude
diminished demand for new products
and virgin raw materials (with their
own environmental issues); lar ger
quantities of pure water and electricity
for associated manufacturing; less
packaging per unit; availability of technology
to wider swaths of society due
to greater affordability of pr oducts;
and diminished use of landfills.
Audiovisual components, televi -
sions, VCRs, mobile phones, o ther
handheld devices, and computer components
contain valuable eleme nts
and substances suitable for reclamation,
including lead, copper, and gold.
CONSUMER
AWARENESS EFFORTS
Common Admission Test
(Continued on Page 42)
‣ PGP
‣ PGPPM [ PGP IN PUBLICY MAK-
ING ]
‣ PGSEM [PG in software enterprise
management,2.5 yeas part tie
course for working]
‣ EPGP
‣ FPM [fellow programme in management]
‣ MDP [Management Development
programme]
Courses offered @ Indian School
The Electronics TakeBack Coalition
is a campaign aimed at protect ing
human health and limiting envi ronmental
effects where electronics are
being produced, used, and discarded.
The ETBC aims to place responsibility
for disposal of technology products on
electronic manufacturers and b rand
owners, primarily through community
promotions and legal enforcement initiatives.
It provides recommendations
for consumer recycling and a l ist of
recyclers judged environmentally responsible.
Basel Action Network is uniquely
focused on addressing global environmental
injustices and economic inefficiency
of global "toxic trade". It works
for human rights and the environment
by preventing disproportionate dumping
on a large scale. It promotes sustainable
solutions and attempts to ban
waste trade.
PROCESSING
TECHNIQUE
In an alternative bulk system, a
hopper conveys material for shredding
into a sophisticated mechanical separator,
with screening and granulating
machines to separate constitue nt
metal and plastic fractions, which are
sold to smelters or plastics recyclers.
Such recycling machinery is enclosed
and employs a dust collection system.
Most of the emissions are caught by
scrubbers and screens. Magnets, eddy
currents, and trommel screens are
employed to separate glass, pl astic,
and ferrous and nonferrous met als,
which can then be further separated
at a smelter. Leaded glass from CRTs
is reused in car batteries, ammunition,
and lead wheel weights, or sol d to
foundries as a fluxing agent in processing
raw lead ore. Copper, gold, palladium,
silver, and tin are valuable metals
sold to smelters for recycling. Hazardous
smoke and gases are captured,
contained, and treated to miti gate
environmental threat. These methods
allow for safe reclamation of all valuable
computer construction materials.
Hewlett-Packard product recycl ing
solutions manager Renee St. De nis
describes its process as: "We move
them through giant shredders a bout
30 feet tall and it shreds eve rything
into pieces about the size of a quarter.
Once your disk drive is shredded
into pieces about this big, it's hard to
get the data off."
of Business (ISB) Hyderabad
‣ 1 year PGP
‣ Business Research Fellowship
Programme (BRFP)
Courses offered @ Management
Development Institute (MDI) Gurgaon
‣ PGP
‣ National Management
Programme, NMP
‣ PGPPM
‣ PGP in Human Resource Management
ELECTRONIC WASTE
SUBSTANCES
Some computer components can
be reused in assembling new co m-
puter products, while others a re reduced
to metals that can be re used
in applications as varied as construction,
flatware, and jewelry.
Substances found in large quantities
include epoxy resins, fiberglass,
PCBs, PVC (polyvinyl chlorides), thermosetting
plastics, lead, tin, copper,
silicon, beryllium, carbon, iron and aluminium.
Elements found in trace amounts
include americium, antimony, arsenic,
barium, bismuth, boron, cobalt , europium,
gallium, germanium, gold, indium,
lithium, manganese, nickel, niobium,
palladium, platinum, rho dium,
ruthenium, selenium, silver, tantalum,
terbium, thorium, titanium, vanadium,
and yttrium.
ADVANTAGES OF E-
WASTE MANAGEMENT
‣ Create jobs,e-cycling create jobs
for professional recyclers.
‣ Conserve natural resources, recycling
covers valuable material s
from old electronics that can be
used to make new products.
‣ Saves landfill space,e-waste i s
growing waste stream by recycling
these items.
DISADVANTAGES OF E-
WASTE MANAGEMENT:
‣ Non-biodegradable wastes take a
long time or never to decompose.
‣ The leading disadvantage of this
process is it's effective cost is very
high.
‣ PGP in International Management
‣ School of Energy Management
Courses offered @ Xavier Labour
Research Institute (XLRI)
Jamshedpur
‣ PGP in Business Administration
‣ PGP in Personnel Management &
Industrial Relations (PMIR)
Courses offered @ Faculty of Management
Sciences (FMS) University Of
Delhi
44 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
Tech-Buzz-Arena
To inculcate technical knowledge among budding engineers,
scientists and technocrats by providing a platform
to interact and exchange their idea with each other and
rest of the nation, Tech events are best way to incorporate
all these stuff. Apart from Book knowledge, an engineer
should have proficient knowledge of cutting
edge technology .Seminars, workshop and technical fests
are best ways to get exposure of latest technologies and
to develop competitive approach. It also helps in personality
development (Team player, time dedication, tolerance
of stress etc.) of us and provides chance to realize
our potential. In this section, we will try to cover all the
tech events and happening in various colleges across country
so that no one missed out
Event name: HacXplore 2010
Event type: Workshop
Venue: Tezpur University
Date: 22-23th October, 2010
Organized by: Sunny Vaghela, Director and
CEO of TechDefence Pvt. Ltd
o
o
o
Workshop Highlights:
Live Demonstration of Latest Hacking Techniques
& tools.
Live investigation Demonstration of various cases
solved by Sunny Vaghela.
Personal Interaction with Sunny Vaghela
Fest: Engineer'10
Fest Type: Technical fest
Organized By : NITK Surathkal, Karnataka
Fest Dates: October 22-25 2010
Eligibility: No restriction
Entry Fee: Depends on event
Description: Engineer'10 techn ical fest conducted every
year by NIT surathkal to bring out the talent in students
belonging to different branches in technical field.
Events: Events are conducted in the following categories
Mechatronix
Online
Hands-On
Geek Quotient
Design
Biz
SCE
TechSpeak
Workshops
Freefall
Technites
For registration and more details : www.engineer.org.in
Event name : Ethical hacking and Information Security
Event type : Workshop
Event Venue : NIT Jalandhar
Organised by Kyrion Digital Securities
Key Dates : 23rd & 24th October, 2010
Workshop Details : Course Duration - 16 Hours (Will be
covered in two days)
Charges - Rs. 1100/- per student.
Benefits - Free Ethical Hacking and Information Security
Software Tool Kit, Training Ma terial, Authorized Certificate
Event Name : Neuron 2010
Event type : Tech Fest
Event Venue : MNIT, Jaipur
Key Dates : 22 - 24 October, 2010
Details : 3 full days of events and recreation including interactive
lectures by influential personalities.
45 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Project : Mobile phone operated robot
Department of Electronics & Co mmunication
OVERVIEW
TODAY as the mobile phones are
very essential for everyone an d
has a vital use so to think ab out a
mobile phone operated robot is an
innovative idea. We can operate our
robot from any distant or remote area.
It is a wireless robot but ins tead of
using a separate wireless modu le
(transmitter and receiver) we are using
the cell phones for this purpose.
This robot has advantages over simple
wireless robot as it overcomes the limitations
of wireless like limited range,
frequency interference etc. Mo bile
operated robot is having a wide range
(service provider range), less fear of
interference as every call is having a
unique frequency and moreover it has
more control keys (12 keys).The principle
used for mobile controlled robot
is the decoding of the DTMF to ne.
DTMF tone stands for dual-tone multifrequency
tone. During any cal l if a
button is pressed, a tone corresponding
to that button is generate d and
heard at the other end of the call.
This tone is basically known as DTMF
tone and these tones are stand ard
one, fixed by IEEE, ISO, EIA, ITU etc.
CIRCUIT DESCRIPTION:
WORKING:
The mobile operated robot is having
basically five main phases:
1. Make a call to mobile on robot.
2. Sending the signal generated by
DTMF encoder in transmitter.
3. Receiving the signal by receiver.
4. Decode the signal with HT9170
DTMF decoder IC.
5. Process the decoded signal wit h
on board processor ATmega16.
Firstly make a call from the remote
phone to the phone attached to the
robot and connect the receiving mobile
phone with headset in aut o answer
mode. As the call is rece ived,
the connection is established between
two. Now if you press a button
then the DTMF tone generates a
signal by adding the frequency corre-
Saurabh Gupta
EC - III year
sponding to that button and se nds
to the receiver. Receiver dete cts it
and sends it to HT9170 decoder IC
which decodes the DTMF tone an d
fed the decoded signal to the
microcontroller ATmega16 i.e. on
board processor. According to the
program in the microcontroller the
robot starts moving.
All type of HT9170 series use
digital counting techniques to detect
and decode all the 16 DTMF ton e
pair into 4-bit code output.
The decoded digital data is then
negated using 4 NOR gates of 7404
HEX INVERTER. This inverted input
will be given to Port A of
microcontroller. The microcontroller is
46 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
programmed to give output at P ort
D,to control the motor driver. As the
microcontroller is not able to drive the
motor so a motor driver IC L293D is
used for this purpose.
47 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Campus interview paper
SELECTION PROCEDURE:
1ST ROUND:- WRITTEN TEST
3 SECTIONS:
English:
Fill in the blanks type questions for
prepositions and articles only.
2 Reading comprehensions not much
difficult and related to some technical
topic like RAID, Inter protocol communication
etc.
Reasoning:
Questions like replacing 1 with $ and 0
with * in binary code.
Changing the places of alphabets in a
word.
Concentration questions
Some other reasoning type questions
Quantitative:
Questions which requires knowledge
of union and intersection formulas like
A/\B A\/B ..
Similar figure type questions
Some other simple quant questions
2ND ROUND:- GD
Wipro just want to see 2 qualities of yours
in GD.
1st- Communication skills.
2nd- Group dynamics
3RD ROUND:- TECHNICAL
INTERVIEW
Go through your current project and
subjects of interest. Microprocessor & Digital
Electronics are very important.simple C
program like prime number..
4TH ROUND:- HR INTERVIEW
If you have cleared the above 3 rounds
than you are 80% selected. In HR they ask
you just basic qsns like your introduction,
role model, why Wipro... whether you r
relocatable or not.. . just give the interview
very casually with good attitude...
very less rejections in this round.
Given below is the collection of frequently
asked questions by IT companies
for ECE students(while other section remain
same, Technical changes)
1. An electron moving in an electromagnetic
field moves in a
(a) In a straight path
(b) Along the same plane in the direction
of its propagation
(c) Opposite to the original direction of
propagation
(d) In a sine wave
2. The total work done on the particle is
equal to the change in its kinetic energy
(a) Always
(b) Only if the forces acting on the
body are conservative.
(c) Only if the forces acting on the
body are gravitational.
(d) Only if the forces acting on the
body are elastic.
3. The following unit measure energy:
(a) Kilo-watt hour.
(b) Volt*volt/sec*ohm.
(c) Pascal*foot*foot
(d) (Coulomb*coulomb)*farad
4. Astronauts in stable orbits around the
earth are in a state of weightlessness
because
(a) There is no gravitational force acting
on them.
(b) The satellite and the air inside it
have an acceleration equal to that
of gravitational acceleration
there.
(c) The gravitational force of the earth
and the sun balance giving null
resultant.
(d) There is no atmosphere at the
height at which the satellites
move.
5. An organ pipe, open at both ends and
another organ pipe closed at one end,
will resonate with each other, if their
lengths are in the ratio of
(a) 1:1
(b) 1:4
(c) 2:1
(d) 1:2
6. During an isothermal expansion of an
ideal gas
(a) Its internal energy increases.
(b) Its internal energy decreases.
(c) Its internal energy does n ot
change.
(d) The work done by the gas is not
equal to the quantity of heat absorbed
by it.
7. A parallel plate capacitor is charged
and the charging battery is then disconnected.
If the plates of the capacitor
are moved further apart by
means of insulating handles
(a) The charge on the capacitor increases.
(b) The voltage across the plates increases.
(c) The capacitance increases.
(d) The electrostatic energy stored in
the capacitor decreases.
8. Two equal negative charges q a re
fixed at point (0,a) and (0,-a) on the
y-axis. A positive charge Q is released
from rest at the point (2a,0) on the x-
axis. The charge Q will
(a) Execute simple harmonic motion
about the origin
(b) Move to the origin and remain at
rest
Department of Electronics & Co mmunication
(c) Move to infinity
(d) Execute oscillatory but not simple
harmonic motion
9. A square conducting loop of length Lon
a side carries a current I. The magnetic
field at the center of the loop is
(a) Independant of L
(b) Proportional to L*L
(c) Inversely proportoinal to L
(d) Directly proportional to L
10. The focal length of a convex lens when
placed in air and then in water will
(a) Increase in water with respect to
air
(b) Increase in air with respect to water
(c) Decrease in water with respect to.
air
(d) Remain the same
11. The maximum kinetic energy of the photoelectron
emitted from the surface is
dependant on
(a) The intensity of incident radiation
(b) The potential of the collector electrode
(c) The frequency of incident radiation
(d) The angle of incidence of radiation
of the surface
12. An electron orbiting in a circular orbit
around the nucleus of the atom
(a) Has a magnetic dipole moment
(b) Exerts an electric force o n the
nucleus equal to that on it by the
nucleus
(c) Does not produce a magnetic induction
at the nucleus
(d) All of the above
13. The X-rays beam coming from an X-ray
tube will be:
(a) Monochromatic
(b) Having all wavelengths smaller than
a certain minimum wavelength
(c) Having all wavelengths larger than
a certain minimum wavelength
(d) Having all wavelengths lying between
a minimum and a maximum
wavelength
14. The mass number of a nucleus is
(a) Always less than its atomic number
(b) Always more than its atomic number
(c) Always equal to its atomic number
(d) Sometimes more and sometimes
equal to its atomic number
15. Two successive elements belonging to
the first transition series ha ve the
same number of electrons partially filling
orbital. They are
(a) V and Cr
(b) Ti and V
(c) Mn and Cr
(d) Fe and Co
48 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
16. When n+l has the same value for two
or more orbitals, the new electron enters
the orbital where
(a) n is maximum
(b) n is minimum
(c) l is maximum
(d) l is minimum
17. A balloon filled with ethylene is pricked
with a sharp pointed needle and quickly
placed in a tank full of hydrogen at the
same pressure. After a while the balloon
would have
(a) Shrunk
(b) Enlarged
(c) Completely collapsed
(d) Remain unchanged in size
18. Which of the following statements is
not true?
(a) The ratio of the mean speed to the
rms speed is independent of temperature
(b) Tthe square of the mean speed of
the molecules is equal to the
mean squared speed at a certain
temperature
(c) Mean kinetic energy of the gas
molecules at any given temperature
is independent of the mean
speed
(d) None
19. Which of the following statements represent
Raoult's Law
(a) Mole fraction of solvent = ratio of
vapour pressure of the solution
to vapour pressure of the solvent
(b) Mole fraction of solute = ratio of
vapour pressure of the solution
to vapour pressure of the solvent
(c) Mole fraction of solute = lowering
of vapour pressure of the solution
(d) Mole fraction of solvent = lowering
of vapour pressure of the solution
20. Pure water does not conduct electricity
because it is
(a) Almost not ionised
(b) Low boiling
(c) Neutral
(d) Readily decomposed
21. In a salt bridge, KCl is used because
(a) It is an electrolyte
(b) The transference number of K+
and Cl¯ is nearly the same
(c) It is a good conductor of electricity
(d) All of the above
22. A depolarizer used in the dry cell batteries
is
(a) KCl (b) MnO2
(c) KOH (d) None of the above
23. The hydrolysis of alkyl halides by aqueous
NaOH is best termed as
(a) Electrophylic substitution reaction
(b) Electrophylic addition reaction
(c) Nnucleophylic addition reaction
(d) Nucleophylic substitution reaction
24. The hydrocarbon that gives a red precipitate
with ammoniacal cuprous chloride
is (where 'º' means a triple bond)
(a) CH3-CH2-CH2-CH3
(b) CH3-CºC-CH3
(c) CH2=CH-CH=CH2
(d) CH3-CH2-CºCH
25. Which of the following reagents is neither
neutral nor basic
(a) Lucas' reagent
(b) Tollen's reagent
(c) Bayer's reagent
(d) Fehling's solution
26. The substance which is most easily nitrated
(a) Toluene
(b) Bbenzene
(c) Nitrobenzene
(d) Chlorobenzene
27. Carbylamine reaction is a test for
(a) Primary amine
(b) Secondary amine
(c) Tertiary amine
(d) Quarternary ammonium salt
28. Which of the following oxides cannot
be reduced by carbon to obtain metal
(a) ZnO (b) Al2O3
(c) Fe2O3 (d) PbO
29. Which of the following is not an oxide
ore?
(a) Cassiterite (b) Siderite
(c) Pyrolusite (d) Bauxite
30. Which among the following is called
philosopher's wool
(a) Cellulose (b) Calamine
(c) Stellite (d) Cerussite
31. Out of 10 white, 9 black and 7 red
balls, in how many ways can we select
one or more balls
(a) 234 (b) 52
(c) 630 (d) 879
32. A and B throw a dice. The probability
that A's throw is not greater than B's
is
(a) 5/12 (b) 7/12
(c) 11/12 (d) 5/36
33. Given two numbers a and b. Let A denote
the single AM between these and
S denote the sum of n AMs between
them. Then S/A depends upon
(a) n (b) n,a
(c) n,b (d) n,a,b
34. If the sum of the roots of the equation
ax²+bx+c=0 is equal to the sum of
the squares of their reciprocals, then,
a/c, b/a, c/b are in
(a) AP (b) GP
(c) HP (d) None of the these
In the following questions ~ represents
the integral sign-for eg .
1~2[f(x)] means integration of the
function f(x) over the interval 1 to2.
35. Value of -1~2[|2-x²|]dx, ie integration
of the function |2-x²| over the interval
-1 to 2.
(a) 0 (b) 1
(c) 2 (d) None of the above
36. If 0~P[log sinx]dx=k,then the value of
0~P/4[log(1 + tan x)]dx ,where P
stands for pi,is
(a) -k/4 (b) k/4
(c) -k/8 (d) k/8
37. If a,b,c be in GP and p,q be respectively
AM between a, b and b, c then
(a) 2/b=1/p+1/q
(b) 2/b=1/p-1/q
(c) 2=a/p-c/q
(d) None of the above
38. A solution of KMnO4 is reduced to MnO2
.The normality of solution is 0.6.The
molarity is
(a) 1.8M (b) 0.6M
(c) 0.1M (d) 0.2M
The questions 41-46 are based on the
following pattern. The problems below
contain a question and two statements
giving certain data. You have
to decide whether the data given in
the statements are sufficient for answering
the questions. The correct
answer is
(A) If statement (I) alone is sufficient
but statement (II) alone is not
sufficient.
(B) If statement (II) alone is sufficient
but statement (I) alone is not sufficient.
(C) If both statements together are
sufficient but neither of stat e-
ments alone is sufficient.
(D) If both together are not sufficient.
39. What is John's age?
(I) In 15 years John will be twice as old
as Dias would be
(II) Dias was born 5 years ago
40. What is the distance from city A to city
C in kms?
(I) City A is 90 kms from City B
(II) City B is 30 kms from City C
41. Is A=C ? A,B,C are real numbers
(I) A-B=B-C
(II) A-2C = C-2B
42. What is the 30th term of a given sequence
?
(I) The first two terms of the sequence
are 1,1/2
(II) The common difference is -1/2
43. Was Avinash early, on time or late for
work?
(I) He thought his watch was 10 minutes
fast
(II) Actually his watch was 5 minutes
slow
44. What is the value of A if A is an integer?
(I) A4 = 1
(II) A3 + 1 = 0
45. A person travels 12 km in the southward
direction and then travels 5km
to the right and then travels 15km toward
the right and finally travels 5km
towards the east, how far is he from
his starting place?
(a) 5.5 kms (b) 3 km
(c) 13 km (d) 6.4 km
49 Electronics Spectra, 2010

SMS Institute of Technology, L ucknow
Department of Electronics & Co mmunication
46. X's father's wife's father's granddaughter
uncle will be related to X as
(a) Son (b) Nephew
(c) Uncle (d) Grandfather
47. Find the next number in the series 1, 3
,7 ,13 ,21 ,31
(a) 43 (b) 33
(c) 41 (d) 45
48. If in a certain code "RANGE" is coded
as 12345 and "RANDOM" is coded as
123678. Then the code for the word
"MANGO" would be
(a) 82357 (b) 89343
(c) 84629 (d) 82347
49. If "PROMPT" is coded as QSPLOS ,then
"PLAYER" should be
(a) QMBZFS (b) QWMFDW
(c) QUREXM (d) URESTI
The questions 52-53 are based on the
following data 6 people A, B, C, D, E
and F sit around a table for dinner.
Since A does not like C, he doesn't sit
either opposite or beside C.B and F
always like to sit opposite each other.
50. If A is beside F then who is are the two
neighbors of B?
(a) D and C (b) E and C
(c) D and E (d) Either (a) or (b)
51. If D is adjacent to F then who is adjacent
to C?
(a) E and B (b) D and A
(c) D and B (d) either (a) or (c)
52. Complete the sequence A, E ,I ,M ,Q ,U
, _ , _
(a) B, F (b) Y, C
(c) G, I (d) K, O
53. A person travels 6km towards west,
then travels 5km towards north ,then
finally travels 6km towards we st.
Where is he with respect to his starting
position?
(a) 13km east
(b) 13km northeast
(c) 13km northwest
(d) 13km west
54. If A speaks the truth 80% of the times,
B speaks the truth 60% of the times.
What is the probability that they tell
the truth at the same time
(a) 0.8 (b) 0.48
(c) 0.6 (d) 0.14
55. If the time quantum is too large, Round
Robin scheduling degenerates to
(a) Shortest Job First Scheduling
(b) Multilevel Queue Scheduling
(c) FCFS
(d) None of the above
56. Transponders are used for which of the
following purposes
(a) Uplinking
(b) Downlinking
(c) Both (a) and (b)
(d) None of the above
57. Virtual functions allow you to
(a) Create an array of type pointerto-base-class
that can hold pointers
to derived classes
(b) Create functions that have no body
(c) Group objects of different classes
so they can all be accessed by
the same function code
(d) Use the same function call to execute
member functions to objects
from different classes
58. A sorting algorithm which can prove to
be a best time algorithm in one case
and a worst time algorithm in worst
case is
(a) Quick Sort (b) Heap Sort
(c) Merge Sort (d) Insert Sort
59. What details should never be found in
the top level of a top-down design?
(a) Details
(b) Coding
(c) Decisions
(d) None of the above
60. In an absolute loading scheme, which
loader function is accomplished by assembler
(a) Reallocation
(b) Allocation
(c) Linking
(d) Both (a) and (b)
61. Banker's algorithm for resource allocation
deals with
(a) Deadlock prevention
(b) Deadlock avoidance
(c) Deadlock recovery
(d) None of these
62. Thrashing can be avoided if
(a) The pages, belonging to the working
set of the programs, are in
main memory
(b) The speed of CPU is increased
(c) The speed of I/O processor are
increased
(d) All of the above
63. Which of the following communications
lines is best suited to interactive processing
applications?
(a) Narrowband channels
(b) Simplex channels
(c) Full-duplex channels
(d) Mixedband channels
64. A feasibility document should contain
all of the following except
(a) Project name
(b) Problem descriptions
(c) Feasible alternative
(d) Data flow diagrams
65. What is the main function of a data link
content monitor?
(a) To detect problems in protocols
(b) To determine the type of transmission
used in a data link
(c) To determine the type of switching
used in a data link
(d) To determine the flow of data
66. Which of the following is a broadband
communications channel?
(a) Coaxial cable
(b) Fiber optic cable
(c) Microwave circuits
(d) All of the above
67. Which of the following memories has
the shortest access time?
(a) Cache memory
(b) Magnetic bubble memory
(c) Magnetic core memory
(d) RAM
68. A shift register can be used for
(a) Parallel to serial conversion
(b) Serial to parallel conversion
(c) Digital delay line
(d) All the above
69. In which of the following page replacement
policies, Balady's anomaly occurs?
(a) FIFO (b) LRU
(c) LFU (d) NRU
70. Subschema can be used to
(a) Create very different, personalized
views of the same data
(b) Present information in different
formats
(c) Hide sensitive information by omitting
fields from the sub-schema's
description
(d) All of the above
Answer of Campus Interview Pap er
1.(b) 2. (a) 3. (a) 4. (b) 5. (c) 6. (c) 7. (b) 8. (d) 9. (c) 10. (a) 11. (c) 12. (d) 13. (c) 14. (d) 15. (c) 16. (b)
17. (b) 18. (b) 19. (a) 21. (a ) 22. (d) 23. (b) 24. (d) 25. (d) 26. (a) 27. (a) 28. (a) 29. (b) 30. (c) 31. (c)
32. (d) 33. (b) 34. (a) 35. (c ) 36. (d) 37. (c) 38. (a) 39. (d) 40. (c) 41. (d) 42. (c) 43 . (a) 44. (d) 45. (b)
46. (b) 47. (c) 48. (a) 49. (d ) 50. (a) 51. (c) 52. (d) 53. (b) 54. (c) 55. (b) 56. (c) 57 . (c) 58. (a)
59. (a) 60. (c) 61. (d) 62. (b) 63. (a) 64. (b) 65. (d) 66. (a) 67. (d) 68. (a) 69. (d) 70. (a)
50 Electronics Spectra, 2010

OUR DEPARTMENTAL ACTIVITIES
TECHCOM - 1
(Technical Paper Presentation)
MAJOR TOPICS COVERED :
RSA Algorithm
Railway Signaling
4G (Mobile Comm.)
Heterojunction Lasers
Neural Network (AI)
SIGNIT (EW)
INDUSTRIAL TOUR
at
Non-Conventional Energy Development Agency
(NEDA)
Lucknow
PARTICIPATED IN TECH FEST
at
ISM University, Dhanbad
Mechathlon 2009 (Robotics)
PARTICIPATED IN CULTURAL ACTIVITIES
at
BBD NITM, Lucknow
(Utkarsh 2009)