Global ETD Search

51	Estudo e implementação de somador com detecção de fim de cálculo para circuitos assíncronos / Study and implementation of adders with completion detection targeted to asynchronous circuits design Sartori, Giovani Heriberto January 2005 (has links) É contínua a procura por técnicas de construção de circuitos que ajudem a minimizar os problemas existentes no mercado de microeletrônica atual. Uma alternativa para a resolução destes problemas consiste na utilização de circuitos assíncronos. Circuitos aritméticos são alvo de um contínuo esforço na busca de melhores resultados de desempenho e área. Em especial o somador é uma das partes constituintes desta classe de circuitos que apresenta interessante campo para pesquisas. Este trabalho apresenta um método de avaliação de somadores implementados através do uso de famílias lógicas CMOS dual-rail. Esta tarefa é realizada através do uso de um circuito assíncrono que serve como base de avaliação. Este circuito obedece ao protocolo de comunicação utilizado pelos somadores e nele são desenvolvidas diversas aplicações para que seja possível avaliar o comportamento dos somadores quando expostos a diferentes padrões de vetores. Os parâmetros avaliados nas estruturas dos somadores são número de transistores, atraso e consumo de potência para topologias carry look-ahead e ripple carry adders. Na avaliação dos somadores através de simulação elétrica são utilizadas as ferramentas Pspice e Spectre da Cadence. As tecnologias utilizadas nesta caracterização são AMI 0.5 da MOSIS e AMS 0.35. Como resultados são apresentados dados que demonstram a economia no número de transistores obtida através do uso da técnica de múltiplas saídas para o CLA, que a família DCVS geralmente apresenta os menores atrasos médios quando comparada a outras estruturas e a potencialidade de famílias NCL. / The search for construction techniques of circuits that helps to minimize the challenges that occurs in nowadays microelectronic market is continuous. An alternative to solve great part of these problems is the use of asynchronous circuits. Arithmetic circuits are the target of a continuous effort in the pursuit of better results in terms of performance and area. Adder circuits in special compose a subset of this class of circuits that presents an interesting research field. This work presents an evaluation method for adders that where implemented through different dual-rail logic families. This task is accomplished through the use of asynchronous circuits used as an evaluation base. The asynchronous circuits implemented obey the communication protocol adopted by the adders and implement different applications. These applications are constructed with the finality of study the adder’s behavior when they are exposed to different vector patterns. The adder’s evaluated parameters are the number of transistors, delay and power consumption of topologies like Carry Look-ahead and Ripple Carry Adders. The electrical simulations were accomplished trough the use of Pspice and Cadence’s Spectre cad tools. MOSIS AMI 0.5 and AMS 0.35 transistor technologies were utilized in the electrical characterization of the adders. Some of the results obtained trough this work that could be cited are: the low transistor count presented for the Multiple Outputs CLA structures, the performance advantage of the DCVS family in relation to the other families and the evaluation of NCL logic family potentiality. Microeletrônica Circuitos assincronos Arithmetic circuits Self-timed architectures Asynchronous circuits Project and simulation of adders
52	Elastic circuits in FPGA Silva, Thiago de Oliveira January 2017 (has links) O avanço da microeletrônica nas últimas décadas trouxe maior densidade aos circuitos integrados, possibilitando a implementação de funções de alta complexidade em uma menor área de silício. Como efeito desta integração em larga escala, as latências dos fios passaram a representar uma maior fração do atraso de propagação de dados em um design, tornando a tarefa de “timing closure” mais desafiadora e demandando mais iterações entre etapas do design. Por meio de uma revisão na teoria dos circuitos insensíveis a latência (Latency-Insensitive theory), este trabalho explora a metodologia de designs elásticos (Elastic Design methodology) em circuitos síncronos, com o objetivo de solucionar o impacto que a latência adicional dos fios insere no fluxo de design de circuitos integrados, sem demandar uma grande mudança de paradigma por parte dos designers. A fim de exemplificar o processo de “elasticização”, foi implementada uma versão síncrona da arquitetura do microprocessador Neander que posteriormente foi convertida a um Circuito Elástico utilizando um protocolo insensível a latência nas transferências de dados entre os processos computacionais do design. Ambas as versões do Neander foram validadas em uma plataforma FPGA utilizando ferramentas e fluxo de design síncrono bem estabelecidos. A comparação das características de timing e área entre os designs demonstra que a versão Elástica pode apresentar ganhos de performance para sistemas complexos ao custo de um aumento da área necessária. Estes resultados mostram que a metodologia de designs elásticos é uma boa candidata para projetar circuitos integrados complexos sem demandar custosas iterações entre fases de design e reutilizando as já estabelecidas ferramentas de design síncrono, resultando em uma alternativa economicamente vantajosa para os designers. / The advance of microelectronics brought increased density to integrated circuits, allowing high complexity functions to be implemented in smaller silicon areas. As a side effect of this large-scale integration, the wire latencies became a higher fraction of a design’s data propagation latency, turning timing closure into a challenging task that often demand several iterations among design phases. By reviewing the Latency-Insensitive theory, this work presents the exploration of the Elastic Design methodology in synchronous circuits, with the objective of solving the increased wire latency impact on integrated circuits design flow without requiring a big paradigm change for designers. To exemplify the elasticization process, the educational Neander microprocessor architecture is synchronously implemented and turned into an Elastic Circuit by using a latency-insensitive protocol in the design’s computational processes data transfers. Both designs are validated in an FPGA platform, using well known synchronous design tools and flow. The timing and area comparison between the designs demonstrates that the Elastic version can present performance advantages for more complex systems at the price of increased area. These results show that the Elastic Design methodology is a good candidate for designing complex integrated circuits without costly iterations between design phases. This methodology also leverages the reuse of the mostly adopted synchronous design tools, resulting in a cost-effective alternative for designers. Microeletrônica Circuitos digitais Elastic Circuits Asynchronous Circuits Synchronous Circuits ASIC FPGA IC Design Methodology Digital IC
53	Estudo e implementação de somador com detecção de fim de cálculo para circuitos assíncronos / Study and implementation of adders with completion detection targeted to asynchronous circuits design Sartori, Giovani Heriberto January 2005 (has links) É contínua a procura por técnicas de construção de circuitos que ajudem a minimizar os problemas existentes no mercado de microeletrônica atual. Uma alternativa para a resolução destes problemas consiste na utilização de circuitos assíncronos. Circuitos aritméticos são alvo de um contínuo esforço na busca de melhores resultados de desempenho e área. Em especial o somador é uma das partes constituintes desta classe de circuitos que apresenta interessante campo para pesquisas. Este trabalho apresenta um método de avaliação de somadores implementados através do uso de famílias lógicas CMOS dual-rail. Esta tarefa é realizada através do uso de um circuito assíncrono que serve como base de avaliação. Este circuito obedece ao protocolo de comunicação utilizado pelos somadores e nele são desenvolvidas diversas aplicações para que seja possível avaliar o comportamento dos somadores quando expostos a diferentes padrões de vetores. Os parâmetros avaliados nas estruturas dos somadores são número de transistores, atraso e consumo de potência para topologias carry look-ahead e ripple carry adders. Na avaliação dos somadores através de simulação elétrica são utilizadas as ferramentas Pspice e Spectre da Cadence. As tecnologias utilizadas nesta caracterização são AMI 0.5 da MOSIS e AMS 0.35. Como resultados são apresentados dados que demonstram a economia no número de transistores obtida através do uso da técnica de múltiplas saídas para o CLA, que a família DCVS geralmente apresenta os menores atrasos médios quando comparada a outras estruturas e a potencialidade de famílias NCL. / The search for construction techniques of circuits that helps to minimize the challenges that occurs in nowadays microelectronic market is continuous. An alternative to solve great part of these problems is the use of asynchronous circuits. Arithmetic circuits are the target of a continuous effort in the pursuit of better results in terms of performance and area. Adder circuits in special compose a subset of this class of circuits that presents an interesting research field. This work presents an evaluation method for adders that where implemented through different dual-rail logic families. This task is accomplished through the use of asynchronous circuits used as an evaluation base. The asynchronous circuits implemented obey the communication protocol adopted by the adders and implement different applications. These applications are constructed with the finality of study the adder’s behavior when they are exposed to different vector patterns. The adder’s evaluated parameters are the number of transistors, delay and power consumption of topologies like Carry Look-ahead and Ripple Carry Adders. The electrical simulations were accomplished trough the use of Pspice and Cadence’s Spectre cad tools. MOSIS AMI 0.5 and AMS 0.35 transistor technologies were utilized in the electrical characterization of the adders. Some of the results obtained trough this work that could be cited are: the low transistor count presented for the Multiple Outputs CLA structures, the performance advantage of the DCVS family in relation to the other families and the evaluation of NCL logic family potentiality. Microeletrônica Circuitos assincronos Arithmetic circuits Self-timed architectures Asynchronous circuits Project and simulation of adders
54	An SRAM system based on a reduced-area four-transistor CMOS SRAM cell De Beer, Stephan Joseph 27 October 2005 (has links) The traditional method of implementing SRAM in CMOS is via a six-transistor cell and five routing lines. If the number of transistors and the number of wires could be reduced, the packing density of the memory cells could be increased, and the area reduced. This document describes the design of an SRAM system based on a new four¬transistor SRAM cell. The primary design goal was to create a functional system, so that the relationship between reduced cell area and a potentially reduced system area could be investigated. A new write method and associated array structure has been used, and the design of the system parameters was accomplished using static noise margin theory. The power dissipation and percentage reduction in cell area have been improved over previous designs. The circuits to achieve the access to the cell have been designed and simulated. These include low-impedance driver circuits, that allow the power supply of the cell's devices to be individually modified to read and write the cell, and a current sense amplifier system to convert the output current to a digital voltage. These circuits allow complete and accurate control to be achieved, but a price is paid for the complexity in terms of layout area. The SRAM system emulates a standard SRAM, and could therefore be used to replace current SRAM implementations. The design was simulated on a system level, and found to operate correctly. Although it is outperformed by its six-transistor cell counterpart in terms of power dissipation, speed and layout area, the groundwork for defining further research and improving the characteristics of further designs has been laid. / Dissertation (MEng (Electronic Engineering))--University of Pretoria, 2002. / Electrical, Electronic and Computer Engineering / unrestricted Electric circuits Electric engineering Transistor circuits Asynchronous circuits Digital data processing systems UCTD
55	Design of a Reconfigurable Pulsed Quad-Cell for Cellular-Automata-Based Conformal Computing Tan, Zhou January 2011 (has links) This paper presents the design of a reconfigurable asynchronous unit, called the pulsed quad-cell (PQ-cell), for conformal computing. The conformal computing vision is to create computational materials that can conform to the physical and computational needs of an application. PQ-cells, like cellular automata, are assembled into arrays with nearest neighbor communication and are capable of general computation. They operate asynchronously to minimize power consumption and to allow sealing without the limitations imposed by a global clock. Cell operations are stimulated by pulses which use two wires to encode a data bit. Cells are individually reconfirgurable to perform logic, move and store information, and coordinate parallel activity. The PQ-cell design targets a 0.25 μm CMOS technology. Simulation results show that a PQ-cell, when pulsed at 1.3 GHz, consumes 16.9 pJ per operation. Examples of self-timed multi-cell structures include a 98 MHz ring oscillator and a 385 MHz pipeline. Cellular automata. Asynchronous circuits. Pulse circuits. Field programmable gate arrays. Gate array circuits.
56	Self-Timed DRAM Data Interface Nerkar, Rajesh 24 September 2013 (has links) A DRAM communicates with a processing unit via two interfaces: a data interface and a command interface. In today's DRAMs, also known as synchronous DRAMs (SDRAMs), both interfaces use a clock to communicate with the processing unit. The clock times the communication between the processing unit and the SDRAM on both the data interface and the command interface. We propose a self-timed DRAM. The self-timed DRAM introduces more flexibility into the DRAM interface by eliminating the clock. The command interface and the data interface each communicate with the processing unit using a handshake protocol rather than a clock. This thesis presents the data interface between the self-timed DRAM and the processing unit. The proposed data interface is self-timed. The self-timed data interface allows the DRAM to deliver data to or accept data from the processing unit as the processing unit demands rather than on a schedule set from the command interface. The self-timed data interface is designed using GasP circuits and micropipeline circuits. The design is simulated in 180nm CMOs process technology using hspice. This thesis presents the effects of width mismatch on the self-timed data interface. The micropipeline is slightly faster than the GasP. Also, the thesis compares the self-timed DRAM data interface with synchronous DRAM for the data burst rate. Dynamic random access memory Digital Circuits Electrical and Computer Engineering
57	Library Characterization and Static Timing Analysis of Single-Track Circuits in GasP Mettala Gilla, Swetha 01 January 2010 (has links) Library characterization and 'Static Timing Analysis' (STA) are widely used in the design of modern CMOS integrated circuits to confirm that critical timing constraints are met. While many commercial tools are available to do timing validation using library characterization and static timing analysis, their operation depends on calculations relative to a global synchronous clock. This thesis applies timing validation to circuits from which the global synchronous clock is absent, making application of commercial tools difficult. Previous work at the University of Southern California (USC) showed how to overcome the incompatibility of commercial STA tools for asynchronous circuits. This thesis shows how to overcome the incompatibility of library characterization with respect to asynchronous circuits, and ties the results into the STA solution of USC. The particular family of circuits considered in this thesis is called GasP. GasP circuits are light in area and light in power. They have demonstrated operation at about twice the throughput one would expect from conventional clocked circuits. This makes GasP circuits excellent candidates for modern many-core, concurrent network-on-chip and system-on-chip architectures. In part, GasP circuits achieve their performance advantages by using a `single-track' signaling protocol. Two GasP modules communicate with each other over a single wire. One module drives the wire up and a second module at the other end of the wire drives the wire down. This conflicts with the common assumption that wires are driven only from one end. As a result, special circuitry is needed to characterize a GasP library module. This thesis shows how to break a GasP module and its timing constraints into manageable pieces and how to simulate and collect the data relevant for characterization and static timing analysis. When combined with software tools for identifying the critical timing constraints, the results of this work will provide confidence in the correct operation of GasP circuits. Electronic digital computers -- Circuits Asynchronous circuits Systems on a chip
58	On testing concurrent systems through contexts of queues Huo, Jiale. January 2006 (has links) No description available. Asynchronous circuits -- Testing. Queuing networks (Data transmission)
59	Investigation of a Control-Driven Design Style for a 16-Bit Microprocessor Implementation Taylor, Ryan 04 May 2018 (has links) Asynchronous design is a possible alternative design methodology that has the ability to alleviate issues associated with clock skew, power dissipation, and process and environmental variability among transistors, issues encountered in typical synchronous design methodologies. This investigation studies the implementation of two asynchronous models of the Texas Instruments MSP430 processor family using a logic system known as Null Convention Logic (NCL). The study also investigates two design styles of NCL: the data-driven and control-driven design styles. This example and others show that although there are tradeoffs in chip area and performance, the control-driven design style is a viable methodology that can lead to designs that are low in energy usage. The openMSP430 processor project is the baseline for the investigation as it is a mature open-source project. Silicon-proven multiple times and fully synthesizable, it parallels the original Texas Instruments family nearly cycle for cycle. UNCLE (Unified NCL Environment) is a toolset used to create comparable implementations of the openMSP430 architecture that are data-driven and control-driven in nature. This investigation shows that the control-driven implementation has a slightly larger chip area due to the complexity of the control path and its effects on the data path. While the control path has a lower area than the data-driven model due to area optimization, the data path of the control-driven version is larger than that of the data-driven model. Because of these issues of complexity in both the control and data paths, the performance of the model suffers as well, degrading from the already poor performance of the traditional data-driven NCL model. Along with the increase in chip area and the decrease in performance, the control-driven model sees a 50.2% average decrease in energy usage as compared to the data-driven model. As with most design choices in engineering, there are tradeoffs when using either design style of NCL. This investigation serves to allow designers to make a well-informed decision when deciding between the two. microprocessor msp430 data-driven control-driven asynchronous circuits null convention logic
60	Testing of the delay-insensitive asynchronous circuits Hadzibabic, Aleksandar 01 July 2000 (has links) No description available. Asynchronous circuits Electrical and Computer Engineering Engineering Systems and Communications

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