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This book set introduces "multiple-valued quantum-DNA computing"
and "multiple-valued DNA-quantum computing", a noble combination of
quantum physics and molecular biology. Multiple-Valued Computing in
Quantum Molecular Biology, Two Volume Set, is a blend of quantum
physics and theoretical computer science that allows it to be more
unique and faster than current silicon-based multiple-valued
computing systems. Multiple-valued Quantum computing is an exciting
topic for multiple-valued computing systems since it addresses many
problematic multiple-valued traditional computer concerns. Volume
one, Multiple-Valued Computing in Quantum Molecular Biology:
Arithmetic and Combinational Circuits, introduces Multiple-Valued
Quantum Computing and DNA Computing. It contains the basic
understandings of Multiple-Valued Quantum Computing,
Multiple-Valued DNA Computing. Part two reviews heat calculation,
speed calculation, heat transfer, data conversion and data
management in multivalued quantum, DNA, quantum-DNA and DNA-quantum
computing. Part three discusses multiple-valued logic operations in
quantum and DNA computing such as ternary AND, NAND, OR, NOR, XOR,
XNOR, multiple-valued arithmetic operations such as adder,
multiplier, and divider. Part four explains multiple-valued quantum
and DNA combinational circuits such as multiple-valued DNA-quantum
and quantum-DNA multiplexer, demultiplexer, encoder, and decoder.
Volume two, Multiple-Valued Computing in Quantum Molecular Biology:
Sequential Circuits, Memory Devices, Programmable Logic Devices,
and Nano Processors, discusses multiple-valued quantum and DNA
sequential circuits such as D flip-flop, SR latch, SR flip-flop, JK
flip-flop, T flip-flop, shift register, ripple counter, synchronous
counter are described with the applications and working procedures.
Part two discusses the architecture and design procedure of memory
devices such as Random Access Memory (RAM), Read Only Memory (ROM),
Programmable Read Only memory (PROM) in multiple-valued quantum,
DNA, quantum-DNA, and DNA-quantum computing. Part three examines
programmable logic devices such as Programmable Logic Array (PLA),
Programmable Array Logic (PAL), Field Programmable Gate Array
(FPGA), and Complex Programmable Logic Device (CPLD) in
multiple-valued quantum, DNA, quantum-DNA and DNA-quantum computing
are described with their architectures and working principles. Part
four explores the designs and algorithms of Multiple-valued
quantum, DNA, quantum-DNA and DNA-quantum nano processors. This
book set will be of interest to those working in Quantum Computing,
DNA Computing, Quantum-DNA Computing and DNA-Quantum Computing
researchers, as well as graduate level students.
Discusses various design aspects of multiple-valued logic
DNA-quantum and quantum-DNA sequential circuits, memory devices,
programmable logic devices and nano-processors Presents how
multiple-valued quantum, DNA, quantum-DNA and DNA-quantum nano
processors are designed with algorithms Examines the architecture
and design procedure of memory devices such as Random Access Memory
(RAM), Read Only Memory (ROM) Reviews the designs and algorithms of
Multiple-valued quantum, DNA, quantum-DNA and DNA-quantum nano
processors.
This book focuses on the design methodologies of various quantum
circuits, DNA circuits, DNA-quantum circuits and quantum-DNA
circuits. It considers the merits and challenges of multivalued
logic circuits in quantum, DNA, quantum-DNA and DNA-quantum
computing. Multiple-Valued Computing in Quantum Molecular Biology:
Arithmetic and Combinational Circuits is Volume 1 of a two-volume
set. From fundamentals to advanced levels, this book discusses
different multiple-valued logic DNA-quantum and quantum-DNA
circuits. The text consists of four parts. Part I introduces
multiple-valued quantum computing and DNA computing. It contains
the basic understanding of multiple-valued quantum computing,
multiple-valued DNA computing, multiple-valued quantum-DNA
computing and multiple-valued DNA-quantum computing. Part II
examines heat calculation, speed calculation, heat transfer, data
conversion and data management in multi-valued quantum, DNA,
quantum-DNA and DNA-quantum computing. Part III discusses
multiple-valued logic operations in quantum and DNA computing such
as ternary AND, NAND, OR, NOR, XOR, XNOR and multiple-valued
arithmetic operations such as adder, multiplier, divider and more.
Quantum-DNA and DNA-quantum multiple-valued arithmetic operations
are also explained in this section. Part IV explains
multiple-valued quantum and DNA combinational circuits such as
multiple-valued DNA-quantum and quantum-DNA multiplexer,
demultiplexer, encoder and decoder. This book will be of great help
to researchers and students in quantum computing, DNA computing,
quantum-DNA computing and DNA-quantum computing researchers.
The book provides general knowledge of automatic control
engineering and its applications. Providing an overview of control
theory and systems, the chapters introduce transfer functions,
modeling of control systems, automatic control systems, block
diagrams, and signal flow graphs. While control system analysis and
design are accompanied by root-locus methods and frequency response
analyses, distributed control systems, nonlinarity in control
systems including Z-transformation are also presented. With
straightforward demonstrations, examples, and multiple-choice
questions, this book can be used as a reference textbook for
electrical and electronics engineering, computer control
engineering, automation engineering, mechatronics engineering,
mechanics, robotics, AI control systems, hydraulics, process
engineering, safety control engineering, aeronautical and aerospace
engineering, auto-pilot system, decision-making system, and stock
exchange, and will be suitable for majors, non-majors, and experts
in the field of science and technology.
Very Large-Scale Integration (VLSI) creates an integrated circuit
(IC) by combining thousands of transistors into a single chip.
While designing a circuit, reduction of power consumption is a
great challenge. VLSI designs reduce the size of circuits which
eventually reduces the power consumption of the devices. However,
it increases the complexity of the digital system. Therefore,
computer-aided design tools are introduced into hardware design
processes. Unlike the general-purpose computer, an embedded system
is engineered to manage a wide range of processing tasks. Single or
multiple processing cores manage embedded systems in the form of
microcontrollers, digital signal processors, field-programmable
gate arrays, and application-specific integrated circuits. Security
threats have become a significant issue since most embedded systems
lack security even more than personal computers. Many embedded
systems hacking tools are readily available on the internet.
Hacking in the PDAs and modems is a pervasive example of embedded
systems hacking. This book explores the designs of VLSI circuits
and embedded systems. These two vast topics are divided into four
parts. In the book's first part, the Decision Diagrams (DD) have
been covered. DDs have extensively used Computer-Aided Design (CAD)
software to synthesize circuits and formal verification. The book's
second part mainly covers the design architectures of
Multiple-Valued Logic (MVL) Circuits. MVL circuits offer several
potential opportunities to improve present VLSI circuit designs.
The book's third part deals with Programmable Logic Devices (PLD).
PLDs can be programmed to incorporate a complex logic function
within a single IC for VLSI circuits and Embedded Systems. The
fourth part of the book concentrates on the design architectures of
Complex Digital Circuits of Embedded Systems. As a whole, from this
book, core researchers, academicians, and students will get the
complete picture of VLSI Circuits and Embedded Systems and their
applications.
The book provides general knowledge of automatic control
engineering and its applications. Providing an overview of control
theory and systems, the chapters introduce transfer functions,
modeling of control systems, automatic control systems, block
diagrams, and signal flow graphs. While control system analysis and
design are accompanied by root-locus methods and frequency response
analyses, distributed control systems, nonlinarity in control
systems including Z-transformation are also presented. With
straightforward demonstrations, examples, and multiple-choice
questions, this book can be used as a reference textbook for
electrical and electronics engineering, computer control
engineering, automation engineering, mechatronics engineering,
mechanics, robotics, AI control systems, hydraulics, process
engineering, safety control engineering, aeronautical and aerospace
engineering, auto-pilot system, decision-making system, and stock
exchange, and will be suitable for majors, non-majors, and experts
in the field of science and technology.
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