Power and Delay Analysis of Flip Flop Using Pulse Control Method

The past few years, increasing difficulty in integration can be solved by low power, which is very important and also choosing flip-flop solves the challenges like low power. In this paper, we design and compare the power problem of various indirect pulse triggered flip flop are examined. It can be attained by reconstructing the lower part of Single-ended Conditional Capture Energy Recovery (SCCER) design and by employing the control pulse scheme. The results after the simulation derives transistor count and power required are significantly reduced in the proposed design over existing design

Design and analysis of Low Power High Speed Pulse Triggered Flip Flop

The main important aspect is to outline a high speed and utilization of low power pulse triggered flip-flop and simulate the same. Also, we have to minimize leakage in the consumption of power in a flip-flop by employing pulse triggering technique that is adopted for clocks. Here, to solve the problem in the discharging path of the similar flip flop implementations, we employ signal feed through technique. The discharge time is reduced by the proposed method. This design out performs all the other similar pulse triggered flip flop implementation both in speed and power consumption. Now, it is implemented by employing Cadence Virtuoso Schematic Composer in 90nm GPDK. Simulation is done by a simulator known as Spectre

A Novel Approach For Design Of Pulse Triggered Flip-Flop To Enhance Speed And Power

In VLSI Technology, flip-flops contribute a significant portion of chip area and power consumption to overall system design. Pulse triggered flip-flops (P-FF) have single latch and hence simpler in circuit complexity. Use of Explicit type design for P-FF gives the speed advantage. This paper presents various Pulse triggered Flip-flop (P-FF) designs and various techniques to achieve a better design in terms of power consumption and speed. Introduction of simple pass transistor in latch design can be used to speed up data transition. Dual edge triggering can be adopted as it consumes less power as compared to single edge triggering. Also conditional discharge technique can be used to reduce switching activity. The work is done in tanner tool software. DOI: 10.17762/ijritcc2321-8169.15025

High Performance Low Power Dual Edge Triggered Static D Flip-Flop

In this paper a low-power double-edge triggered static flip-flop (DETSFF) suitable for low-power and high performance applications is presented. The designed DETFF is verified at gpdk 180nm-1.8V CMOS technology. Comparison with some of the latest DETFFs shows that the proposed DETSFF can achieve the lowest power consumption, lowest clock to Q delay and thus Power-delay-product (PDP). Moreover, the proposed DETSFF comprises of only 15 transistors hence require lesser number of transistors and thus requires lesser overall silicon area.DOI:http://dx.doi.org/10.11591/ijece.v3i5.316

A Modified Signal Feed-Through Pulsed Flip-Flop for Low Power Applications

In this paper a modified signal feed-through pulsed flip-flop has been presented for low power applications. Signal feed-through flip-flop uses a pass transistor to feed input data directly to the output. Feed through transistor and feedback signals have been modified for delay, static and dynamic power reduction. HSPICE simulation shows 22% reduction in leakage power and 8% of dynamic power. Delay has been reduced by 14% using TSMC 90nm technology parameters. The proposed pulsed flip-flop has the lowest PDP (Power Delay Product) among other pulsed flip-flops discussed

Low-Power Redundant-Transition-Free TSPC Dual-Edge-Triggering Flip-Flop Using Single-Transistor-Clocked Buffer

In the modern graphics processing unit (GPU)/artificial intelligence (AI) era, flip-flop (FF) has become one of the most power-hungry blocks in processors. To address this issue, a novel single-phase-clock dual-edge-triggering (DET) FF using a single-transistor-clocked (STC) buffer (STCB) is proposed. The STCB uses a single-clocked transistor in the data sampling path, which completely removes clock redundant transitions (RTs) and internal RTs that exist in other DET designs. Verified by post-layout simulations in 22 nm fully depleted silicon on insulator (FD-SOI) CMOS, when operating at 10% switching activity, the proposed STC-DET outperforms prior state-of-the-art low-power DET in power consumption by 14% and 9.5%, at 0.4 and 0.8 V, respectively. It also achieves the lowest power-delay-product (PDP) among the DETs

High Performance and Low Power VLSI Synchronous Systems Using an Explicit Pulsed Dual Edge Triggered Flip Flops

ABSTRACT: An explicit pulsed dual edge triggered sense amplifier flip flops (DET-FF).In this dual edge triggered sense amplifier flip flop is used for low-power consumption and high performance application. By incorporating the dual edge triggering mechanism, the dual edge triggered flip flop is able to achieve low power consumption that has minimum delay. Clock gating is a popular technique used in many synchronous circuits; hence, the power dissipation is very much reduced. Reducing dynamic power reduction. Clock gating saves power by adding more logic gates in the circuit. It can be used in various applications like digital VLSI clocking system, buffers, registers, microprocessors etc. KEYWORDS: Clock pulse gating,high performance,low power,delay,pulse dual edge triggered, sense amplifier flip flop. I. INTRODUCTION In many digital very large scale integration (VLSI) design, which consists of the clock distribution network and timing elements, is one of the most power consumption. Flip-flops are critical timing elements in digital circuits which have a large impact on circuit speed and power consumption. The performance of the Flip-Flop is an important element to determine the performance of the whole synchronous circuit. In this dual edge triggered sense amplifier as developed from single edge triggered sense amplifier flip flops. At each rising or falling edge of a clock signal, the data stored in a set of flip-flops is readily available so that it can be applied as inputs to other combinational or sequential circuitry. Such flip-flops that store data on both the leading edge and the trailing edge of a clock pulse are referred to as double-edge triggered flip-flops otherwise it is called as single edge triggered flip-flops. The dual edge triggering is a very important technique is to reduce the power consumption in the clock distribution network. In this dual edge triggering is to introduce the clock gating. In this clock gating with clock storage element is to reduce the dynamic power. Two types of clock gating are used in the dual edge triggering mechanism. These are latch free clock gating and latch based clock gating. When technology scales down, total power dissipation will decrease and at the same time delay varies depends upon supply voltage, threshold voltage, oxide thickness. II.DUAL EDGE TRIGGERED FLIP FLOP The dual edge triggered flip flops have two stages. These are pulse generator stage and latching stage. If the clock pulse as the input of the pulse generator. It produces the triggering pulse signal. Latching stage as generate the output pulse signal. In this dual edge triggering flip flop used two types of clock gating. These are latch based clock gating and latch free clock gating. The general block is shown i

An Overlap-Contention Free True-Single-Phase Clock Dual-Edge-Triggered Flip-Flop

Dual-edge-triggered (DET) synchronous operation is a very attractive option for low-power, high-performance designs. Compared to conventional single-edge synchronous systems, DET operation is capable of providing the same throughput at half the clock frequency. This can lead to significant power savings on the clock network that is often one of the major contributors to total system power. However, in order to implement DET operation, special registers need to be introduced that sample data on both clock-edges. These registers are more complex than their single-edge counterparts, and often suffer from a certain amount of clock-overlap between the main clock and the internally generated inverted clock. This overlap can cause contention inside the cell and lead to logic failures, especially when operating at scaled power supplies and under process variations that characterize nanometer technologies. This paper presents a novel, static DET flip-flop (DET-FF) with a true-single-phase clock that completely avoids clock overlap hazards by eliminating the need for an inverted clock edge for functionality. The proposed DET FF was implemented in a standard 40nm CMOS technology, showing full functionality at low-voltage operating points, where conventional DET-FFs fail. Under a near-threshold, 500mV supply voltage, the proposed cell also provides a 35% lower CK-to-Q delay and the lowest power-delay-product compared to all considered DET-FF implementations. © 2015 IEEE

Power Efficient Enhancement Technique for Flip- Flop Design

Abstract-Low power pulse triggered flip-flop is designed in this paper. In the pulse generation control logic, AND function is removed and a simple twotransistor AND gate design is used to reduce complexity and to facilitate a faster discharge operation. A pulse enhancement technique is applied to speed up the discharge along the critical path when needed. In resultant circuit, transistor size in the delay inverter and pulse generator circuit is reduced for power saving. Various post layout simulation results based on UMC CMOS 90-nm technology reveal that the proposed design features the best power-delay-product performance in seven FF designs under comparison. Its maximum power saving against existing design is up to 38.4%. Compared with the conventional transmission gatebased FF design, the average leakage power consumption is also reduced by a factor of 3.52