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This book provides detailed and accurate information on the
history, structure, operation, benefits and advanced structures of
silicon MESFET, along with modeling and analysis of the device. The
authors explain the detailed physics that are important in modeling
of SOI-MESFETs, and present the derivations of compact model
expressions so that users can recognize the physical meaning of the
model equations and parameters. The discussion also includes
advanced structures for SOI-MESFET for submicron applications.
Nanotechnology has become one of the most important fields in
science. Nanoparticles exhibit unique chemical, physical and
electronic properties that are different from those of bulk
materials, due to their small size and better architecture.
Nanoparticles can be used to construct novel sensing devices; in
particular electrochemical sensors. Electrochemical detection is
highly attractive for the monitoring of glucose, cancer cells,
cholesterol and infectious diseases. Unique nanocomposite-based
films proposed in this book open new doors to the design and
fabrication of high-performance electrochemical sensors.
Micro-ring resonators (MRRs) are employed to generate signals used
for optical communication applications, where they can be
integrated in a single system. These structures are ideal
candidates for very large-scale integrated (VLSI) photonic
circuits, since they provide a wide range of optical signal
processing functions while being ultra-compact. Soliton pulses have
sufficient stability for preservation of their shape and velocity.
Technological progress in fields such as tunable narrow band laser
systems, multiple transmission, and MRR systems constitute a base
for the development of new transmission techniques. Controlling the
speed of a light signal has many potential applications in fiber
optic communication and quantum computing. The slow light effect
has many important applications and is a key technology for all
optical networks such as optical signal processing. Generation of
slow light in MRRs is based on the nonlinear optical fibers. Slow
light can be generated within the micro-ring devices, which will be
able to be used with the mobile telephone. Therefore, the message
can be kept encrypted via quantum cryptography. Thus perfect
security in a mobile telephone network is plausible. This research
study involves both numerical experiments and theoretical work
based on MRRs for secured communication.
This Brief highlights different approaches used to create stable
cellulase and its use in different fields. Cellulase is an
industrial enzyme with a broad range of significant applications in
biofuel production and cellulosic waste management. Cellulase 7a
from Trichoderma reesei is the most efficient enzyme in the bio
hydrolysis of cellulose. In order to improve its thermal stability,
it can be engineered using a variety of approaches, such as
hydrophobic interactions, aromatic interactions, hydrogen bonds,
ion pairs and disulfide bridge creation.
The title explain new technique of secured and high capacity
optical communication signals generation by using the micro and
nano ring resonators. The pulses are known as soliton pulses which
are more secured due to having the properties of chaotic and dark
soliton signals with ultra short bandwidth. They have high capacity
due to the fact that ring resonators are able to generate pulses in
the form of solitons in multiples and train form. These pulses
generated by ring resonators are suitable in optical communication
due to use the compact and integrated rings system, easy to
control, flexibility, less loss, application in long distance
communication and many other advantages. Using these pulses
overcome the problems such as losses during the propagation, long
distances, error detection, using many repeaters or amplifiers,
undetectable received signals, pulse broadening, overlapping and so
on. This book show how to generate soliton pulses using ring
resonators in the micro and nano range which can be used in optical
communication to improve the transmission technique and quality of
received signals in networks such as WiFi and wireless
communication.
Micro-ring resonators (MRRs) are employed to generate signals used
for optical communication applications, where they can be
integrated in a single system. These structures are ideal
candidates for very large-scale integrated (VLSI) photonic
circuits, since they provide a wide range of optical signal
processing functions while being ultra-compact. Soliton pulses have
sufficient stability for preservation of their shape and velocity.
Technological progress in fields such as tunable narrow band laser
systems, multiple transmission, and MRR systems constitute a base
for the development of new transmission techniques. Controlling the
speed of a light signal has many potential applications in fiber
optic communication and quantum computing. The slow light effect
has many important applications and is a key technology for all
optical networks such as optical signal processing. Generation of
slow light in MRRs is based on the nonlinear optical fibers. Slow
light can be generated within the micro-ring devices, which will be
able to be used with the mobile telephone. Therefore, the message
can be kept encrypted via quantum cryptography. Thus perfect
security in a mobile telephone network is plausible. This research
study involves both numerical experiments and theoretical work
based on MRRs for secured communication.
This book investigates the effect of sintering temperature on
willemite based glass-ceramic doped with different content of
Er2O3. It is the first to report research on producing willemite by
using waste materials and using trivalent erbium (Er3+) as a
dopant. This book provides a survey of the literature on glass and
glass-ceramic, while comprehensive experiments and analysis have
been performed on the material used.
This book describes Service-Oriented Architecture (SOA) and the
significant factors which affect its adoption, such as governance,
strategy, complexity, Return on Investment (ROI), business and IT
alignment, culture and communication, costs, and security. The
study on which this book is based, involved a quantitative analysis
to investigate the influential factors for adopting SOA, paving the
way to further research in the field.
This book demonstrates the implementation of an automated measuring
system for very efficient measurement of chromatic dispersion,
which uses a modulation phase shift method over long haul of
optical single mode fiber. The authors show how a new scheme for
measuring chromatic dispersion is adopted in conjunction with a
tunable laser (TLS), providing the optical power at required
wavelength and digital oscilloscope (DOSC) for measuring the phase
difference between microwave signals from transmitter and microwave
signals at the receiver. This is a novel approach for real-time
chromatic dispersion in optical systems such as optical fibers. The
setup used is very simple, accurate and cost effective, compared to
other methods such as direct measurement, differential mode delay,
polarization mode dispersion measurement and phase delay method.
This book focuses on the analysis and treatment of osteoporotic
bone based on drug administration, tracking fatigue behavior and
taking into consideration the mechanical interaction of implants
with trabecular bone. Weak trabeculae are one of the most important
clinical features that need to be addressed in order to prevent hip
joint fractures.
This brief analyzes the characteristics of a microring resonator
(MRR) to perform communication using ultra-short soliton pulses.
The raising of nonlinear refractive indices, coupling coefficients
and radius of the single microring resonator leads to decrease in
input power and round trips wherein the bifurcation occurs. As a
result, bifurcation or chaos behaviors are seen at lower input
power of 44 W, where the nonlinear refractive index is n2=3.2x10 20
m2/W. Using a decimal convertor system, these ultra-short signals
can be converted into quantum information. Results show that multi
solitons with FWHM and FSR of 10 pm and 600 pm can be generated
respectively. The multi optical soliton with FWHM and FSR of 325 pm
and 880 nm can be incorporated with a time division multiple access
(TDMA) system wherein the transportation of quantum information is
performed.
Nonlinear behavior of light such as chaos can be observed during
propagation of a laser beam inside the microring resonator (MRR)
systems. This Brief highlights the design of a system of MRRs to
generate a series of logic codes. An optical soliton is used to
generate an entangled photon. The ultra-short soliton pulses
provide the required communication signals to generate a pair of
polarization entangled photons required for quantum keys. In the
frequency domain, MRRs can be used to generate optical
millimetre-wave solitons with a broadband frequency of 0-100 GHz.
The soliton signals are multiplexed and modulated with the logic
codes to transmit the data via a network system. The soliton
carriers play critical roles to transmit the data via an optical
communication link and provide many applications in secured optical
communications. Therefore, transmission of data information can be
performed via a communication network using soliton pulse carriers.
A system known as optical multiplexer can be used to increase the
channel capacity and security of the signals.
This book discusses the enhancement of efficiency in currently used
solar cells. The authors have characterized different structures of
the solar cell system to optimize system parameters, particularly
the performance of the Copper-Tin-Sulphide solar cell using Solar
Cell Capacitance Simulator (SCAPS). This research can help
scientist to overcome the current limitations and build up new
designs of the system with higher efficiency and greater
functionality. The authors have investigated the corresponding
samples from various viewpoints, including structural
(crystallinity, composition and surface morphology), optical
(UV-vis-near-IR transmittance/reflectance spectra) and electrical
resistivity properties. Describes investigations on Cu2SnS3 solar
cells and prospective low cost absorber layer of thin film solar
cells; Discusses the potential device structure of
Copper-Tin-Sulphide based on thin film technologies; Explains solar
cell structure optimization to perform a higher conversion
efficiency of Copper-Tin-Sulphide.
Due to the limitation of the electrical OFDM signal and electrical
Fast Fourier Transform (FFT), all-optical OFDMs have recently
received much attention. Accordingly, this research study was
conducted to investigate the effect of phase noise in the
performance of an all-optical OFDM transmission system with 4-point
FFT single mode fiber (SMF) links by considering the effects of
fiber length, input laser power and a number of channels. In all
optical systems, the transmitter side consists of a comb power
generator, wavelength selected switch and an optical QAM generator.
A comb power generator generates channels with a frequency
separation of f=25 GHz. Subsequently, a Wavelength Selected Switch
(WSS) was used to split subcarriers and then the subcarriers were
modulated individually with Optical QAM modulators. As the results
show, a higher number of channels led more phase noise in terms of
XPM and FWM nonlinearities, and signal power was the main factor in
nonlinear fiber optics. As a consequence, there is more phase noise
distortion at a higher signal power for a higher number of channels
rather than the lower number of channels.
This book consists of two parts. The first part is on the
development of the proposition that if there exists a type of
function, then there exists a functional with the same type based
on the proposition of the inheritance and generalizability
properties of a function in a functional. This study presents the
abstract convex, increasing positively homogeneous and
convex-along-rays functionals via this proposition. The second part
concerns the investigation of the use of a global search
optimization algorithm called the Cutting Angle Method (CAM) on
Optimal Control Problems (OCP). Many algorithms are available for
solving OCP, but they are basically local search algorithms. To
overcome the problem associated with local searches, most OCP are
modeled as Linear Quadratic Regulator (LQR) problems in the hope
that the solution found estimates of the true global solution to
the original problem. However, in doing so, a lot of information
carried by the original problem might be lost in its translation
into LQR models. CAM being a global search algorithm is expected to
overcome this problem. It can be used alone or in combination with
a local search to find the global solution. CAM has been
successfully used on functions, however, OCP are functionals. To do
this, a model has been introduced based on inheritance and
generalizability properties to demonstrate that the optimization
algorithms that are used for functions can also be extended for use
in functionals. Based on these properties, the study discovered
that with the Unit Vectors Combinations Technique (UVCT) proposed
in this research, CAM could successfully work on functionals in
general and OCP particularly. To help speed up the convergence of
CAM, the literature proposed the use of local searches for the
determination of the initial solution. In a case study done in the
research, CAM was successfully combined with a local search known
as the Dynamic Integrated System Optimization and Parameter
Estimation (DISOPE) algorithm. Moreover, the initial solution given
by the DISOPE algorithm has been verified as a global influence by
CAM.
This research consists of two parts. The first part focuses on the
development of the proposition that if there exists a type of
function, then there exists a functional with the same type based
on the proposition of the Inheritance and Generalizability
properties of the function in a functional. This study presents the
abstract convex, increasing positively homogeneous and
convex-along-rays functionals via this proposition. The second part
is on the investigation of the global search optimization algorithm
use called the Cutting Angle Method (CAM) on Optimal Control
Problems (OCP). Many algorithms are available for solving OCP, but
they are basically local search algorithms. To overcome the problem
associated with local searches, most OCP are modelled as Linear
Quadratic Regulator (LQR) problems in the hope that the solution
found estimates the true global solution of the original problem.
However, in doing so, a lot of information carried by the original
problem might be lost in its translation into LQR models. CAM being
a global search algorithm is expected to overcome this problem. It
can be used alone or in combination with a local search to find the
global solution. CAM has been successfully used on functions;
however, OCPs are functionals. To do this, a model has been
introduced based on Inheritance and Generalizability properties to
demonstrate that the optimization algorithms which are used for
functions can also be extended for use in functionals. Based on
these properties, the study discovered that with the Unit Vectors
Combinations Technique (UVCT) proposed in this research, and CAM
could successfully work on functionals in general and with OCP
particularly. To help speed up the convergence of CAM, the
literature proposed the use of local searches for the determination
of the initial solution. In a case study done in the research, CAM
was successfully combined with a local search named the Dynamic
Integrated System Optimization and Parameter Estimation (DISOPE)
algorithm. Moreover, the initial solution given by DISOPE algorithm
has been verified as global by CAM.
Nanotechnology has become one of the most important fields in
science. Nanoparticles exhibit unique chemical, physical and
electronic properties that are different from those of bulk
materials, due to their small size and better architecture.
Nanoparticles can be used to construct novel sensing devices; in
particular electrochemical sensors. Electrochemical detection is
highly attractive for the monitoring of glucose, cancer cells,
cholesterol and infectious diseases. Unique nanocomposite-based
films proposed in this book open new doors to the design and
fabrication of high-performance electrochemical sensors.
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