NORA: a racefree dynamic CMOS technique for pipelined logic structures
N.F. Goncalves,H. De Man +1 more
TLDR
A new dynamic CMOS technique which is fully racefree, yet has high logic flexibility, and logic inversion is provided, which means higher logic flexibility and less transistors for the same function.Abstract:
Describes a new dynamic CMOS technique which is fully racefree, yet has high logic flexibility. The circuits operate racefree from two clocks /spl phi/ and /spl phi/~ regardless of their overlap time. In contrast to the critical clock skew specification in the conventional CMOS pipelined circuits, the proposed technique imposes no restriction to the amount of clock skew. The main building blocks of the NORA technique are dynamic CMOS and C/SUP 2/MOS logic functions. Static CMOS functions can also be employed. Logic composition rules to mix dynamic CMOS, C/SUP 2/MOS, and conventional CMOS will be presented. Different from Domino technique, logic inversion is also provided. This means higher logic flexibility and less transistors for the same function. The effects of charge redistribution, noise margin, and leakage in the dynamic CMOS blocks are also analyzed. Experimental results show the feasibility of the principles discussed.read more
Citations
More filters
Bit-level pipelined multiplier- accumulator new dynamic full-adder cell design
Fang Lu,Henry Samueli +1 more
Proceedings Article
High Speed Programmable Logic Arrays in ESFI MOS Technology
TL;DR: Exploratory MOS programmable logic arrays (PLA's) operating up to a clock frequency of 22 MHz have been realized and successfully operated as mentioned in this paper, and the problems arising with the use of these dynamic logic gates are discussed and different circuits are presented.
Book ChapterDOI
Introduction to Dual Mode Logic (DML)
Itamar Levi,Alexander Fish +1 more
TL;DR: In this article, the authors present DML basic architectures at the circuit level and describe the two modes of DML operation in detail, and compare DML designs to standard CMOS designs.
Journal Article
Power efficient frequency divider circuit based on adaptive voltage level technique
TL;DR: A frequency divider circuit has been proposed which consumes less power based on adaptive voltage level at supply (AVLS) technique, in which the supply voltage potential is reduced so as to reduce the power consumption of certain transistors.
Book ChapterDOI
Clocked Logic Styles
Kerry Bernstein,Keith M. Carrig,Christopher M. Durham,Patrick R. Hansen,David Hogenmiller,Edward J. Nowak,Norman J. Rohrer +6 more
TL;DR: In the preceeding chapter, nonclocked circuit topologies were shown generally to be versatile, reliable, and relatively low in power consumption.
References
More filters
Journal ArticleDOI
High-speed compact circuits with CMOS
TL;DR: A new circuit type, the CMOS domino circuit, is described, which involves the connection of dynamic CMOS gates in such a way that a single clock edge can be used to turn on all gates in the circuit at once.
Journal ArticleDOI
Clocked CMOS calculator circuitry
Y. Suzuki,M. Hirasawa,K. Odagawa +2 more
TL;DR: A novel circuit technique that has been applied to the world's first CMOS-LSI for a desktop calculator is described in detail.
Journal ArticleDOI
High-density CMOS ROM arrays
TL;DR: The CMOSROMs produced are competitive with NMOS ROMs in both density and speed, yet retain all of the advantages of static CMOS circuits such as 1-/spl mu/W power dissipation, full 2.8-15 V voltage operating range, and full -55/spl deg/C-125/spl Deg/C temperature range.
Proceedings Article
NP-CMOS: A Racefree - Dynamic CMOS Technique for Pipelined Logic Structures
N.F. Gqncalves,H. De Man +1 more
TL;DR: In this paper, a new dynamic CMOS circuit technique using n and p logic trees is presented, which operates race-free from two clocks O and O regardless of their overlap time.
Journal ArticleDOI
High-speed programmable logic arrays in ESFI SOS technology
E. Hebenstreit,K. Horninger +1 more
TL;DR: Exploratory MOS programmable logic arrays (PLA's) operating up to a clock frequency of 22 MHz have been realized and successfully operated as discussed by the authors, and the problems arising with the use of these dynamic logic gates are discussed and different circuits are presented.