Design and Analysis of Improved Domino Logic with Noise Tolerance and High Performance

The demands of upcoming computing, as well as the challenges of nanometer-era of VLSI design necessitate new digital logic techniques and styles that are at the same time high performance, energy efficient and robust to noise and variation. Dynamic CMOS logic gates are broadly used to design high performance circuits due to their high speed. Conversely, the vital demerit of dynamic logic style is its high noise sensitivity. The main reason for this is the sub-threshold leakage current flowing through the pull down network. With continuous technology scaling, this problem is getting more and more severe. In this thesis, a new noise tolerant dynamic CMOS circuit technique is proposed. In the proposed work, we have enhanced the behavior of the domino CMOS logic. This technique also gets benefit in terms of delay and power. This thesis describes the new low power, noise tolerant and high speed domino logic technique and presents a comparison result of this logic with previously reported schemes. Simulation results prove that, in 180 nm CMOS technology when we used this logic style to realize wide fan-in logic gates, it could achieve maximum level of noise robustness as compared to its basic counterpart. In addition, the logic also works efficiently with sequential circuits. The feasibility of this new technique is demonstrated by means of a real hardware, we have built a custom test-chip in the UMC 180 nm process technology with an ALU core, using the proposed domino logic style for each design block. In this thesis, we have also described the design and implementation of this chip. In addition to this, we have also presented initial power and delay performance comparisons between the circuit level simulated ALU and test-chip implemented in the proposed domino logic style. Finally we conclude that, the thesis contributes a very efficient logic style for wide fan-in gates, which is not only noise robust but also energy efficient and high speed

A 100-MIPS GaAs asynchronous microprocessor

The authors describe how they ported an asynchronous microprocessor previously implemented in CMOS to gallium arsenide, using a technology-independent asynchronous design technique. They introduce new circuits including a sense-amplifier, a completion detection circuit, and a general circuit structure for operators specified by production rules. The authors used and tested these circuits in a variety of designs

NIM and CAMAC module studies

The feasibility of adapting two NIM and two CAMAC modules for space research was studied. Methods are outlined for reducing the power in each module by approximately fifty percent. Components that could not be replaced from the NASA approved component list are identified. Special problems associated with grounding, vacuum operation, temperature variations, vibration and shock are outlined. Suggested solutions for these problems are discussed