Evolutionary algorithms are general-purpose search procedures based on the mechanisms of natural selection and population genetics. They are appealing because they are simple, easy to interface, and easy to extend. This volume is concerned with applications of evolutionary algorithms and associated strategies in engineering. It will be useful for engineers, designers, developers, and researchers in any scientific discipline interested in the applications of evolutionary algorithms. The volume consists of five parts, each with four or five chapters. The topics are chosen to emphasize application areas in different fields of engineering. Each chapter can be used for self-study or as a reference by practitioners to help them apply evolutionary algorithms to problems in their engineering domains.

Evolutionary Algorithms in Engineering Applications

The IEEE T RANSACTIONS ON C OMPUTER -A IDED D ESIGN OF I NTEGRATED C IRCUITS AND S YSTEMS publishes manuscripts focusing on methods, algorithms, and human-machine interfaces for physical and logical design, including: planning, synthesis, partitioning, modeling, simulation, layout, veriﬁcation, testing, and documentation of integrated-circuit and systems designs of all complexities. Practical applications of aids resulting in producible analog, digital, optical, or microwave integrated circuits are emphasized.TheIEEE T RANSACTIONS ON C OMPUTER -A IDED D ESIGN OF I NTEGRATED C IRCUITS AND S YSTEMS is published by the IEEE Council on Electronic Design Au- tomation. The IEEE Council on Electronic Design Automation (CEDA) is an organizational unit of the IEEE that has six IEEE member societies, namely, Antennas and Propagation, Circuits and Systems, Computer, Electron Devices, Microwave Theory and Techniques, and the Solid-State Circuits Societies. The objectives of CEDA include fostering design automation of electronic circuits and systems at all levels, by means of publications, conferences/workshops and volunteer activities. For membership and subscription information and pricing, please visit www.ieee.org/membership-catalog. Member copies of Transactions/Journals are for personal use only.

IEEE transactions on computer-aided design of integrated circuits and systems : a publication of the IEEE Circuits and Systems Society

Vertical integration of two-dimensional van der Waals materials is predicted to lead to novel electronic and optical properties not found in the constituent layers. Here, we present the direct synthesis of two unique, atomically thin, multi-junction heterostructures by combining graphene with the monolayer transition-metal dichalcogenides: molybdenum disulfide (MoS2), molybdenum diselenide (MoSe2) and tungsten diselenide (WSe2). The realization of MoS2-WSe2-graphene and WSe2-MoS2-graphene heterostructures leads to resonant tunnelling in an atomically thin stack with spectrally narrow, room temperature negative differential resistance characteristics.

/pdf/atomically-thin-resonant-tunnel-diodes-built-from-synthetic-17ky9g2yre.pdf

Atomically thin resonant tunnel diodes built from synthetic van der Waals heterostructures

The resonant tunneling diode (RTD) has been widely studied because of its importance in the field of nanoelectronic science and technology and its potential applications in very high speed/functionality devices and circuits. Even though much progress has been made in this regard, additional work is needed to realize the full potential of RTD's. As research on RTD's continues, we will try in this tutorial review to provide the reader with an overall and succinct picture of where we stand in this exciting field or research and to address the following questions: What makes RTD's so attractive? To what extent can RTD's be modeled for design purposes? What are the required and achievable device properties in terms of digital logic applications? To address these issues, we review the device operational principles, various modeling approaches, and major device properties. Comparisons among the various RTD physical models and major features of RTD's, resonant interband tunneling diodes, and Esaki tunnel diodes are presented. The tutorial and analysis provided in this paper may help the reader in becoming familiar with current research efforts, as well as to examine the important aspects in further RTD developments and their circuit applications.

/pdf/resonant-tunneling-diodes-models-and-properties-16lzfs8v3d.pdf

Resonant tunneling diodes: models and properties

An analytic expression for the current-voltage characteristics of resonant tunneling diodes is derived from basic principles. The form is ideal for insertion into circuit simulation models. It is demonstrated for a conventional InGaAs-AlAs RTD and for an InAs-AlSb-GaSb RIT diode. The expression is based on the quantum tunneling formalism and contains parameters that originate from physical quantities, but which can also be treated as empirical. Empirical fitting is straightforward and results in an excellent match to the data. Additional levels of physical realism can be incorporated in a natural way.

Physics-based RTD current-voltage equation

Quantum electronic devices with negative differential resistance (NDR) characteristics have been used to design compact multiplexers. These multiplexers may be used either as analog multiplexers where the signal on a single select line selects one out of four analog inputs, or as four-valued logic multiplexers where the select line and the input lines represent one of four quantized signal values and the output line corresponds to the selected input. Any four-valued logic function can be implemented using only four-valued multiplexers (also known as T-gates), and this T-gate uses just 13 devices (transistors) as compared to 44 devices in CMOS. The design of the T-gate was done using a combination of resonant tunneling diodes (RTD's) and heterojunction bipolar transistors (HBT's) with the folded I-V characteristic (NDR characteristic) of the RTD's providing the compact logic implementation and the HBT's providing the gain and isolation. The application of the same design principles to the design of T-gates using other NDR devices such as resonant tunneling hot electron transistors (RHET's) and resonant tunneling bipolar transistors (RTBT's) is also demonstrated.

/pdf/compact-multiple-valued-multiplexers-using-negative-4l0csmdio4.pdf

Compact multiple-valued multiplexers using negative differential resistance devices

New quantum electronic devices such as resonant tunnelling diodes and transistors have negative differential resistance characteristics that can be exploited to design novel high-speed circuits. The high intrinsic switching speed of these devices, combined with the novel circuit structures used to implement standard logic functions, leads to ultrafast computing circuits. The new circuit structures presented here provide extremely compact implementations of functions such as carry generation and addition. The most significant impact of these circuits on the field of logic design is the introduction of a totally new set of relative costs of various basic gates; reevaluation of the logic in the light of these new cost functions leads to ultrafast and compact designs.

Logic design based on negative differential resistance characteristics of quantum electronic devices

Negative differential resistance characteristics of several new quantum electronic devices have been used to design high-speed logic gates with the latching property. These latching gates form the basis of the ultrafast pipelined adder circuit described in this paper. The latching or memory feature of these circuits, which was previously considered to be a nuisance in the design of combinational circuits, is exploited to overcome the pipeline overheads of area and time. Simulation studies show that application of pipelining techniques can provide an effective throughput of one 32-bit addition every 1.6 ns using minimal hardware.

Ultrafast pipelined arithmetic using quantum electronic devices

Ultrafast adders that perform 32 bit additions in less than 1 ns using resonant tunnelling transistors (RTTs) are proposed. Simulation results showing their subnanosecond performance are presented. The adders are shown to be better than others in terms of both area and speed. These results are obtained using true bistable logic which makes use of the bistability of circuits using the negative differential resistance (NDR) characteristic of the RTTs.

Ultrafast pipelined adders using RTTs

Quantum electronic devices such as resonant tunneling diodes and transistors are now beginning to be used in ultrafast and compact circuit designs. These devices exhibit negative differential resistance (NDR) and/or negative transconductance in their I-V characteristics and have active dimensions of a few nanometers. Since the conventional drift-diffusion approximation is not valid for simulation of device behavior at this microscopic scale, quantum simulation models based on the Schrodinger equation are required to accurately predict the behavior of the device. However, these models are too slow for circuit simulation. This paper describes a modeling scheme that maintains the accuracy of the quantum simulation while achieving satisfactory speed for circuit simulation, and is applicable to a wide range of two and three terminal resonant tunneling devices and may also be extended to future scaled-down MOS and bipolar devices. A self-consistent solution of the Poisson and the Schrodinger equations for various bias points is used to build up tables of conductances, capacitances and other parameters. Table-lookup methods are then used during circuit simulation. Convergence techniques have been developed to overcome the problems caused by the NDR characteristics and the lookup-table model in simulation. While implementation details are presented for a resonant tunneling transistor (RTT), models for several other quantum electronic devices have also been implemented in NDR-SPICE. >

/pdf/device-and-circuit-simulation-of-quantum-electronic-devices-5dce90om2f.pdf

Device and circuit simulation of quantum electronic devices

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