In this paper, a flip-flop (FF) that minimizes the transition of internal nodes by using a dual change-sensing scheme is discussed. Further, in order to reduce power consumption, a new technique to eliminate short-circuit currents is described. The proposed dual change-sensing FF (DCSFF) composed of 24T (T: number of transistors) has the lowest dynamic power consumption among conventional FFs, independent of the data activity ratio. According to the measured results with a 65 nm CMOS process, the power consumption of DCSFF is reduced by 98% and 32%, when the data activity is close to 0% and 100%, respectively, compared to that of conventional transmission gate FF. Further, compared to that of change-sensing FF, the power consumption of DCSF...
A new dual edge-triggered flip-flop that saves power by inhibiting transitions of the nodes that are...
The very low power and high speed dual VDD Flip Flop (FF) is proposed in this paper. The power reduc...
This dissertation presents a new systematic approach to flip-flop design using Internal Clock Gating...
This paper presents an extremely low-voltage and low-power single-phase-clocking redundant-transitio...
The main purpose of this project was to design low power and high performance flip-flop. This was be...
The increasing demand of portable applications motivates the research on low power and high speed ci...
This paper introduces a Low Power Dual DynamicNode FlipFlop(DDFF) using Sleep Transistor with NMOS. ...
Abstract: In this paper, implementations of the flip-flops are presented which are level triggered a...
The design of low-power devices is currently an important area of research due to an increase in dem...
A new technique is based on the design and comparison between Conventional Transistorized flip flop ...
[[abstract]]In this paper, a new low power and high speed CMOS double-edge triggered flip-flop (DETF...
A low-voltage and low-power true single-phase flip-flop that minimum the total transistor count by u...
To date, most studies focus on complex designs to realize offset cancelation characteristics in nonv...
In this work, a new area and power efficient single edge triggered flip-flop has been proposed. The ...
Fulfillment of dual edge flip-flops gets freshly develops into the goal of countless exploration to ...
A new dual edge-triggered flip-flop that saves power by inhibiting transitions of the nodes that are...
The very low power and high speed dual VDD Flip Flop (FF) is proposed in this paper. The power reduc...
This dissertation presents a new systematic approach to flip-flop design using Internal Clock Gating...
This paper presents an extremely low-voltage and low-power single-phase-clocking redundant-transitio...
The main purpose of this project was to design low power and high performance flip-flop. This was be...
The increasing demand of portable applications motivates the research on low power and high speed ci...
This paper introduces a Low Power Dual DynamicNode FlipFlop(DDFF) using Sleep Transistor with NMOS. ...
Abstract: In this paper, implementations of the flip-flops are presented which are level triggered a...
The design of low-power devices is currently an important area of research due to an increase in dem...
A new technique is based on the design and comparison between Conventional Transistorized flip flop ...
[[abstract]]In this paper, a new low power and high speed CMOS double-edge triggered flip-flop (DETF...
A low-voltage and low-power true single-phase flip-flop that minimum the total transistor count by u...
To date, most studies focus on complex designs to realize offset cancelation characteristics in nonv...
In this work, a new area and power efficient single edge triggered flip-flop has been proposed. The ...
Fulfillment of dual edge flip-flops gets freshly develops into the goal of countless exploration to ...
A new dual edge-triggered flip-flop that saves power by inhibiting transitions of the nodes that are...
The very low power and high speed dual VDD Flip Flop (FF) is proposed in this paper. The power reduc...
This dissertation presents a new systematic approach to flip-flop design using Internal Clock Gating...