Litcius/Paper detail

A Very-Low-Voltage Frequency Divider in Folded MOS Current Mode Logic With Complementary n- and p-type Flip-Flops

Francesco Centurelli, Giuseppe Scotti, G. Palumbo

2021IEEE Transactions on Very Large Scale Integration (VLSI) Systems16 citationsDOIOpen Access PDF

Abstract

In this article, a static frequency divider based on folded MOS current mode logic (FMCML) is presented. The design is based on alternating FMCML flip-flops with complementary pMOS or nMOS input differential pairs since common-mode problems arise by using only one type of FMCML flip-flops. The design is carried out after detailed theoretical modeling and analysis versus the flip-flop bias current, thus allowing defining optimized design strategies for the maximum speed or the minimum power-delay product (PDP). The frequency divider architecture and design strategies are validated considering a commercial 28-nm FDSOI CMOS technology. Post layout simulations of a divider-by-16 show a maximum frequency of about 12 GHz with 74-μW power consumption for the high-speed design and a maximum frequency of 10 GHz with 53-μW power consumption for the minimum PDP design.

Topics & Concepts

NMOS logicFrequency dividerPower–delay productCurrent-mode logicPMOS logicFlip-flopCMOSFLOPSElectronic engineeringEngineeringElectrical engineeringLow-power electronicsIntegrated circuit designVoltagePower (physics)Computer sciencePower consumptionTransistorPhysicsAdderParallel computingQuantum mechanicsRadio Frequency Integrated Circuit DesignLow-power high-performance VLSI designAdvancements in PLL and VCO Technologies
A Very-Low-Voltage Frequency Divider in Folded MOS Current Mode Logic With Complementary n- and p-type Flip-Flops | Litcius