Grupo de Ingeniería Microelectrónica

Grupo de Ingeniería Microelectrónica

Departamento de Tecnología Electrónica, Ingeniería de Sistemas y Automática Universidad de Cantabria
Home   Personas   Investigación   Docencia   Doctorado   Publicaciones   Herramientas   Bolsa de Empleo   english version Sun 22-Dec-24 . 08:09



Mapa Web


Localización

Noticias

Info Santander



Gestión BD

GIM>Investigación>Publicación
   PUBLICACION
 
   Ficha completa
Título:Theoretical fundamentals of functional verification based on random test benches
Tipo:Publicacion en Proceedings o Actas internacionales
Lugar:IEEE European Test Symposium ETS'05 Estonia
Fecha:2005-05
Autores: Iñigo Ugarte
Pablo Pedro Sánchez
Líneas:
Proyectos:
ISBN:
Fichero:ver fichero
Resumen:The latest releases of commercial verification tools often include coverage metrics and constraint-based generation of random test benches. This commercial interest may be provoked by several factors. Firstly, it seems that currently, the best method of functional verification automation is the coverage-driven random-based test bench generation. Secondly, designers show confidence in the results of random-based functional verification and there is even the impression that these test benches work better for verification than for test. This impression is mainly supported by practical experiences because although there is a huge amount of work on the theoretical bases of random testing, as far as we know, there is no similar work on functional verification. II. SYSTEM MODEL In this paper, we assume that the system is described at behavioral level as a set of statements that operate with integer data. Some basic operators are supported (addition, subtraction, multiplication, relational and logic operators) as well as ‘if’ control statements. Every execution path in the behavioral description can be modeled with polynomials (which model the system behavior) and a set of constraints, which model the if-statement conditions. The main goal of this paper is to explore theories that can analyze random-based functional verification methodologies. They are based on polynomial models of the system under verification and they provide fault-model independent coverage.
© Copyright GIM (TEISA-UC)    ¤    Todos los derechos Reservados.    ¤    Términos LegalesE-Mail Webmaster