TY - BOOK ID - 37041898 TI - Equivalence checking of digital circuits : fundamentals, principles, methods AU - Molitor, Paul AU - Mohnke, Janett PY - 2004 SN - 140202603X 1402077254 PB - New York : Kluwer Academic Publishers, DB - UniCat KW - Digital electronics KW - Electronic circuits KW - Testing. KW - Electronics. KW - Systems engineering. KW - Computer engineering. KW - Artificial intelligence. KW - Computer aided design. KW - Electronics and Microelectronics, Instrumentation. KW - Circuits and Systems. KW - Electrical Engineering. KW - Artificial Intelligence. KW - Computer-Aided Engineering (CAD, CAE) and Design. KW - Microelectronics. KW - Electronic circuits. KW - Electrical engineering. KW - Computer-aided engineering. KW - CAE KW - Engineering KW - AI (Artificial intelligence) KW - Artificial thinking KW - Electronic brains KW - Intellectronics KW - Intelligence, Artificial KW - Intelligent machines KW - Machine intelligence KW - Thinking, Artificial KW - Bionics KW - Cognitive science KW - Digital computer simulation KW - Electronic data processing KW - Logic machines KW - Machine theory KW - Self-organizing systems KW - Simulation methods KW - Fifth generation computers KW - Neural computers KW - Electric engineering KW - Electron-tube circuits KW - Electric circuits KW - Electron tubes KW - Electronics KW - Microminiature electronic equipment KW - Microminiaturization (Electronics) KW - Microtechnology KW - Semiconductors KW - Miniature electronic equipment KW - Electrical engineering KW - Physical sciences KW - Data processing UR - https://www.unicat.be/uniCat?func=search&query=sysid:37041898 AB - Hardware veri?cation is the process of checking whether a design conforms to its speci?cations of functionality and timing. In today’s design processes it becomes more and more important. Very large scale integrated (VLSI) circuits and the resulting digital systems have conquered a place in almost all areas of our life, even in security sensitive applications. Complex digital systems control airplanes, have been used in banks and on intensive-care units. Hence, the demand for error-free designs is more important than ever. In addition, economic reasons underline this demand as well. The design and production process of present day VLSI-circuits is highly time- and cost-intensive. Mo- over, it is nearly impossible to repair integrated circuits. Thus, it is desirable to detect design errors early in the design process and not just after producing the prototype chip. All these facts are re?ected by developing and prod- tion statistics of present day companies. For example, In?neon Technologies [118] assumed that about 60% to 80% of the overall design time was spent for veri?cation in 2000. Other sources cite the 3-to-1 head count ratio between veri?cation engineers and logic designers. This shows that verifying logical correctness of the design of hardware systems is a major gate to the problem of time-to-market (cf. [113]). With the chip complexity constantly increasing, the dif?culty as well as the - portance of functional veri?cation of new product designs has been increased. It is not only more important to get error-free designs. ER -