Back to the Future: Current-Mode Processor in the Era of Deeply Scaled CMOS

Bai, Yuxin; Song, Yanwei; Bojnordi, Mahdi Nazm; Shapiro, Alexander E.; Friedman, Eby G.; Ïpek, Engin

doi:10.1109/tvlsi.2015.2455874

Cited by 18 publications

(6 citation statements)

References 70 publications

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“…The registers are synchronous circuits [21,22]. It is extensively used in almost all the applications to store the state information.…”

Section: Based 8-bit Registermentioning

confidence: 99%

Reversible Logic Based MOS Current Mode Logic Implementation in Digital Circuits

Devi¹,

Bhanumathi²

2022

Computers, Materials &Amp; Continua

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Now a days, MOS Current Mode Logic (MCML) has emerged as a better alternative to Complementary Metal Oxide Semiconductor (CMOS) logic in digital circuits. Recent works have only traditional logic gates that have issues with information loss. Reversible logic is incorporated with MOS Current Mode Logic (MCML) in this proposed work to solve this problem, which is used for multiplier design, D Flip-Flop (DFF) and register. The minimization of power and area is the main aim of the work. In reversible logic, the count of outputs and inputs is retained as the same value for creating one-to-one mapping. A unique output vector set can be generated for each input vector set and information loss is also prevented. In reversible MCML based multiplier, reversible logic full adder is utilized to minimize the area and power. D flip-flops based on reversible MCML are often designed to store information that is then combined to form a reversible MCML based register. The proposed reversible MCML multiplier attains average power of 0.683 mW, Reversible MCML based DFF achieves 0.56 µW and Reversible MCML based 8-bit register attains 04.04 µW. The result shows that the proposed Reversible MCML based multiplier, Reversible MCML based D flip-flop and Reversible MCML based register achieves better performance in terms of current, power dissipation, average power and area.

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“…The registers are synchronous circuits [21,22]. It is extensively used in almost all the applications to store the state information.…”

Section: Based 8-bit Registermentioning

confidence: 99%

Reversible Logic Based MOS Current Mode Logic Implementation in Digital Circuits

Devi¹,

Bhanumathi²

2022

Computers, Materials &Amp; Continua

View full text Add to dashboard Cite

show abstract

“…Parasitic effects in CMOS refer to unintended or undesired electrical characteristics that arise due to the inherent nature of the CMOS fabrication process or the layout of the integrated circuit. These effects can impact circuit performance, introduce errors, and degrade overall system functionality [22], [23]. CML topology is frequently used for D-Latch design where high-speed operation is required [24]- [26].…”

Section: Introductionmentioning

confidence: 99%

Design of a high-speed MCML D-Latch at 0.6 V in 45 nm CMOS technology

Madheswaran,

Panneerselvam

2024

IJPEDS

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Metal oxide semiconductor (MOS) current mode logic (MCML) is generally preferred for high-speed circuit design. In this paper, a novel low voltage folded (LVF) MCML D-Latch is designed. The existing topologies of the MCML D-Latch consume more power and operate at 1 V. The proposed D-Latch can operate at 0.6V with better delay and power management. MCML circuits minimize delay and perform fast operations, hence it can be used in high-frequency applications. The proposed LVF MCML D–Latch is analyzed with the parameters such as power, delay, power delay product and output noise using cadence virtuoso in 45 nm complementary metal oxide semiconductor (CMOS) technology at a voltage of 0.6 V and a temperature of 27 °C. The proposed technique achieves 62.11% of power reduction, transient response speed improved by 51.23% and noise cancellation becomes 26.13% improvement over the existing circuit. It also achieves 96% of output swing which is more efficient compared to others. Finally, the parametric analysis is performed with different temperatures to verify the stability of the proposed circuit. From the simulated results, it is clear that the proposed LVF MCML D-Latch provides better performance in high-speed phase locked loop (PLL) applications.

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“…MCML gates have been popular, and due to their very low switching noise, inherent robustness, and speed, they continue to be used in applications ranging from very high-speed embedded systems [25][26][27][28][29] to mixed-signal processing [30][31][32][33][34][35][36][37]. In this scenario, digital gate models with a good trade-off between simplicity and accuracy still remain a fundamental design tool for the designer.…”

Section: Introductionmentioning

confidence: 99%

Simple and Accurate Model for the Propagation Delay in MCML Gates

2023

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In this article, we develop a simple and accurate model for evaluating the propagation delay in MOS Current-Mode Logic (MCML) gates. The model describes the behavior of MCML gates in a linear fashion despite the circuits themselves being non-linear. Indeed, we demonstrate that a linear model can be used, provided that, for each small-signal parameter, its average value calculated between the two different switching logic states is used. The proposed model is validated through simulations of MCML universal gates designed using modern nanometer processes. The model forecasts simulated values with an error lower than 4% and 20% in 65-nm standard CMOS and 28-nm Fully-Depleted Silicon-On-Insulator (FD-SOI), respectively.

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Back to the Future: Current-Mode Processor in the Era of Deeply Scaled CMOS

Cited by 18 publications

References 70 publications

Reversible Logic Based MOS Current Mode Logic Implementation in Digital Circuits

Reversible Logic Based MOS Current Mode Logic Implementation in Digital Circuits

Design of a high-speed MCML D-Latch at 0.6 V in 45 nm CMOS technology

Simple and Accurate Model for the Propagation Delay in MCML Gates

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