Automatic layout generation of static CMOS circuits targeting delay and power

The evolution of integrated circuits technologies demands the development of new CAD tools. The traditional development of digital circuits at physical level is based in library of cells. These libraries of cells offer certain predictability of the electrical behavior of the design due to the previous characterization of the cells. Besides, different versions of each cell are required in such a way that delay and power consumption characteristics are taken into account, increasing the number of cells in a library. The automatic full custom layout generation is an alternative each time more important to cell based generation approaches. This strategy implements transistors and connections according patterns defined by algorithms. So, it is possible to implement any logic function avoiding the limitations of the library of cells. Tools of analysis and estimate must offer the predictability in automatic full custom layouts. These tools must be able to work with layout estimates and to generate information related to delay, power consumption and area occupation. This work includes the research of new methods of physical synthesis and the implementation of an automatic layout generation in which the cells are generated at the moment of the layout synthesis. The research investigates different strategies of elements disposition (transistors, contacts and connections) in a layout and their effects in the area occupation and circuit delay. The presented layout strategy applies delay optimization by the integration with a gate sizing technique. This is performed in such a way the folding method allows individual discrete sizing to transistors. The main characteristics of the proposed strategy are: power supply lines between rows, over the layout routing (channel routing is not used), circuit routing performed before layout generation and layout generation targeting delay reduction by the application of the sizing technique. The possibility to implement any logic function, without restrictions imposed by a library of cells, allows the circuit synthesis with optimization in the number of the transistors. This reduction in the number of transistors decreases the delay and power consumption, mainly the static power consumption in submicrometer circuits. Comparisons between the proposed strategy and other well-known methods are presented in such a way the proposed method is validated.

Um Estudo de técnicas de aceleração para algoritmos de análise de timing funcional baseados em geração automática de teste

Este trabalho tem como objetivo estudar e avaliar técnicas para a aceleração de algoritmos de análise de timing funcional (FTA - Functional Timing Analysis) baseados em geração automática de testes (ATPG – Automatic Test Generation). Para tanto, são abordados três algoritmos conhecidos : algoritmo-D, o PODEM e o FAN. Após a análise dos algoritmos e o estudo de algumas técnicas de aceleração, é proposto o algoritmo DETA (Delay Enumeration-Based Timing Analysis) que determina o atraso crítico de circuitos que contêm portas complexas. O DETA está definido como um algoritmo baseado em ATPG com sensibilização concorrente de caminhos. Na implementação do algoritmo, foi possível validar o modelo de computação de atrasos para circuitos que contêm portas complexas utilizando a abordagem de macro-expansão implícita. Além disso, alguns resultados parciais demonstram que, para alguns circuitos, o DETA apresenta uma pequena dependência do número de entradas quando comparado com a dependência no procedimento de simulação. Desta forma, é possível evitar uma pesquisa extensa antes de se encontrar o teste e assim, obter sucesso na aplicação de métodos para aceleração do algoritmo.