Dielectric breakdown and its application in high density, electrically programmable memories

Billingham, Phillip

January 1992

No description available.

530.41

VLSI circuits

Studies of propagation delay for high-speed bipolar logic circuits

Fang, Wen

January 1990

No description available.

621.3192

Bipolar VLSI circuits

An efficient channel routing algorithm and its application to sparse matrix superchips

Chukwudebe, Gloria Azogini

January 1992

No description available.

621.3192

VLSI circuits

Physical phenomena in Silicon-On-Insulator devices

Bunyan, Robert John Tremayne

January 1993

No description available.

621.3192

VLSI circuits; MOSFETs

A Performance Driven Placement System Using an Integrated Timing Analysis Engine

Peter, Shaun K.

13 October 2014

No description available.

Computer Engineering

VLSI circuits

Intermediate frequency CMOS analogue cells for wireless communications

Manetakis, Konstantinos

January 1999

No description available.

621.3192

Wireless transceivers; VLSI circuits

Functional Abstraction From Structure in VLSI Simulation Models

Lathrop, Richard H., Robert J. Hall,, Kirk, Robert S.

01 May 1987

High-level functional (or behavioral) simulation models are difficult, time-consuming, and expensive to develop. We report on a method for automatically generating the program code for a high-level functional simulation model. The high-level model is produced directly from the program code for the circuit components' functional models and a netlist description of their connectivity. A prototype has been implemented in LISP for the SIMMER functional simulator.

VLSI circuits

simulation

functional models

temporal reasoning

STRICT : a language and tool set for the design of very large scale integrated circuits

Koelmans, Albertus Maria

January 1996

An essential requirement for the design of large VLSI circuits is a design methodology which would allow the designer to overcome the complexity and correctness issues associated with the building of such circuits. We propose that many of the problems of the design of large circuits can be solved by using a formal design notation based upon the functional programming paradigm, that embodies design concepts that have been used extensively as the framework for software construction. The design notation should permit parallel, sequential, and recursive decompositions of a design into smaller components, and it should allow large circuits to be constructed from simpler circuits that can be embedded in a design in a modular fashion. Consistency checking should be provided as early as possible in a design. Such a methodology would structure the design of a circuit in much the same way that procedures, classes, and control structures may be used to structure large software systems. However, such a design notation must be supported by tools which automatically check the consistency of the design, if the methodology is to be practical. In principle, the methodology should impose constraints upon circuit design to reduce errors and provide' correctness by construction' . It should be possible to generate efficient and correct circuits, by providing a route to a large variety of design tools commonly found in design systems: simulators, automatic placement and routing tools, module generators, schematic capture tools, and formal verification and synthesis tools.

621.3192

A formal, hierarchical design and validation methodology for VLSI

Davie, Bruce S.

January 1988

The high cost of fabricating VLSI circuits requires that they be validated, that is, shown to function correctly, before manufacture. The cost of design errors can be kept to a minimum if such validation occurs as early as possible; this is achieved by integrating validation into a hierarchical design procedure. In this thesis, a hierarchical approach to design, in which validation is performed between each pair of adjacent levels in the hierarchy, is developed. In order to adopt such an approach, a language is required for the formal description of hardware behaviour and structure. Therefore an important aspect of the development of the methodology, and a major theme of the thesis, is the development of languages to support the methodology. An enhanced version of CIRCAL, which enables large and abstract devices to be described concisely and supports formal reasoning about the behaviour of constructed systems, is presented. Specifications should accurately model the behaviour of real hardware and should be useful for design and validation; they should also be easy to write. In order to realise these goals, a number of specification techniques have been developed and a new language which enforces some of these techniques, thereby easing the specification task, is proposed. Ways in which a language may assist design have been investigated. Language constructs which restrict a designer, thereby removing some design decisions, have been developed. A simple correctness-preserving transformation is presented, illustrating another way in which a designer may be assisted by a formal language. Specification techniques play an important part in the validation task, as accurate and consistent modelling is vital in establishing the correctness of implementations. Techniques have also been developed which enable detailed implementations to be usefully compared with more abstract specifications. This is demonstrated in a large example, the specification, design and formal verification of a simple microprocessor. Finally, the concept of contextual constraints, restrictions on the environment in which a device may be placed, is introduced. A method of specifying such constraints has been developed, and it is shown that their formal treatment can provide assistance in specification, design and verification.

621.3192

Trace theory and VLSI design

Van de Snepscheut, Jan L. A.,

January 1900

Thesis (Ph. D.)--Eindhoven University of Technology. / Includes bibliographical references (p. 134-137) and index.