• Journal of Korea Society of Industrial Information Systems
• /
• v.19 no.6
• /
• pp.33-41
• /
• 2014

In this paper, we propose a D flip-flop based on quantum-dot cellular automata(QCA) clocking and design a programmable quantum-dot cell(QPCA) structure using the proposed D flip-flop. Previous D flip-flops on QCA are that input should be set to an arbitrary value, and wasted output values exist because it was utilized to duplicate by clock pulse and QCA clocking. In order to eliminate these defects, we propose a D flip-flop structure using binary wire and clocking technique on QCA. QPCA structure consists of wire control logic, rule control logic, D flip-flop and XOR logic gate. In experiment, we perform the simulation of QPCA structure using QCADesigner. As the result, we confirm the efficiency of the proposed structure.

• Journal of the Institute of Electronics Engineers of Korea SD
• /
• v.42 no.8 s.338
• /
• pp.35-42
• /
• 2005

This paper describes novel flip-flops with improved robustness and reduced power consumption. Variable sampling window flip-flop (VSWFF) adjusts the width of the sampling window according to input data, providing robust data latching as well as shorter hold time. The flip-flop also reduces power consumption for higher input switching activities as compared to the conventional low-power flip-flop. Clock swing-reduced variable sampling window flip-flop (CSR-VSWFF) reduces clock power consumption by allowing the use of a small swing clock. Unlike conventional reduced clock swing flip-flops, it requires no additional voltage higher than the supply voltage, eliminating design overhead related to the generation and distribution of this voltage. Simulation results indicate that the proposed flip-flops provide uniform latency for narrower sampling window and improved power-delay product as compared to conventional flip-flops. To evaluate the performance of the proposed flip-flops, test structures were designed and implemented in a $0.3\mu m$ CMOS process technology. Experimental result indicates that VSWFF yields power reduction for the maximum input switching activity, and a synchronous counter designed with CSR-VSWFF improves performance in terms of power consumption with no use of extra voltage higher than the supply voltage.

• 전자공학회논문지 IE
• /
• v.44 no.2
• /
• pp.14-20
• /
• 2007

This paper presents quaternary D flip-flop with advanced performance. Quaternary D flip-flop is composed of the components such as thermometer code output circuit, EX-OR gate, bias inverter, transmission gate and binary D flip-flop circuit. The designed circuit is simulated by HSPICE in $0.35{\mu}m$ one-poly six-metal CMOS process parameters with a single +3.3V supply voltage. In the simulations, sampling frequencies is measured around 100MHz. The PDP parameters and FOM we estimated to be 59.3fJ, 33.7 respectively.

• Journal of the Institute of Electronics Engineers of Korea SC
• /
• v.39 no.4
• /
• pp.43-53
• /
• 2002

In this paper, a new dynamic D-flip-flop which does not suffer from charge sharing and glitch problems is proposed. And a dual-modulus divide-by-128/129 prescaler has been designed with the proposed D-flip-flops using a 0.6$0.6{\mu}m$ CMOS technology. Eleven-transistor architecture enables it to operate at the higher frequency range and the transistor merging technique contributes to the reduction of power consumption. At 5V supply voltage, the simulated maximum operating frequency and the current consumption of the divide-by-128/129 prescaler are 1.97GHz and 7.453mA, respectively.

• Journal of the Korea Institute of Information and Communication Engineering
• /
• v.23 no.7
• /
• pp.816-821
• /
• 2019

A counter-type time-to-digital converter was designed using a dual edge T flip-flop. The time-to-digital converter was designed with a $0.18{\mu}m$ CMOS process at a supply voltage of 1.5 volts. In a typical time-to-digital converter, when the period of the clock is T, a conversion error corresponding to the period of the clock occurs due to the asynchronism between the input signal and the clock. However, the clock of the time-to-digital converter proposed in this paper is generated in synchronization with the start signal which is the input signal. As a result, conversion errors that may occur due to asynchronization of the start signal and the clock do not occur. The flip-flops constituting the counters are composed of dual-edge flip-flops operating at the positive and negative edges of the clock to improve the resolution.

• The Journal of the Convergence on Culture Technology
• /
• v.7 no.1
• /
• pp.558-563
• /
• 2021

Quantum-Dot Cellular Automata is a next-generation nanocircular design technology that is drawing attention from many research organizations not only because it is possible to design efficient circuits by overcoming the physical size limitations of existing CMOS circuits, but also because of its energy-efficient features. In this paper, one of the existing digital circuits, T flip-flop circuit, is proposed using QCA. The previously proposed T flip-flops are designed based on the majority gate, so the circuits are complex and have long delays. Therefore, the design of the XOR gate-based T flip-flop using cell interaction reduces circuit complexity and minimizes latency. The proposed circuit is simulated using QCADesigner, and the performance is compared and analyzed with the existing proposed circuits.

• Journal of Software Assessment and Valuation
• /
• v.15 no.1
• /
• pp.103-107
• /
• 2019

Recently, many technologies have been developed to realize low power high speed digital data communication and one of them is related to duty cycle correction. In this paper, a low-area duty cycle correction circuit for a voltage-controlled ring generator is proposed. The duty cycle correction circuit is a circuit that corrects the duty cycle using a 180 degree phase difference of a voltage controlled ring oscillator. The proposed low-area duty cycle circuit changes a conventional flip-flop to a true single phase clocking (TSPC) flip-flop And a low-area high-performance circuit is realized. By using TSPC flip-flop instead of general flip-flop, it is possible to realize low-area circuit compared to existing circuit, and it is expected to be used for high-performance circuit for low-power because it is easy to operate at high speed.

• Journal of the Institute of Electronics Engineers of Korea SD
• /
• v.43 no.9 s.351
• /
• pp.1-9
• /
• 2006

In the System-on-Chip(SoC) design, the global wires are critical parts for the performance. Therefore, the global wires need to be pipelined using flip-flops or latches. Since the timing constraint of the latch is more flexible than it of the flip-flop, the latch-based design can provide a better solution for the clock period. Retiming is an optimizing technique which repositions memory elements in the circuits to reduce the clock period. Traditionally, retiming is used on gate-level netlist, but retiming for SoC is used on macro-level netlist. In this paper, we extend the previous work of retiming for SoC using flip-flops to retiming for SoC using single-phase clocked latches. In this paper we propose a MILP for retiming for SoC using single-phase clocked latches, and apply the fixpoint computation to solve it. Experimental results show that retiming for SoC using latches reduces the clock period of circuits by average 10 percent compared with retiming for SoC using flip-flops.

• Journal of IKEEE
• /
• v.9 no.2 s.17
• /
• pp.152-160
• /
• 2005

A prescaler is an essential building block for PLL-based frequency synthesizers and must satisfy high-speed and low-power characteristics. The design of D-flip flips used in the prescaler implementation is thus critical. Conventional TSPC D-flip flops suffer from glitches, unbalanced propagation delay, and unnecessary charge/discharge at internal nodes in precharge phase, which results in increased power consumption. In this paper a new dynamic D-flip flop is proposed to overcome these problems. Glitches are minimized using discharge suppression scheme, speed is improved by making balanced propagation delay, and low power consumption is achieved by removing unnecessary discharge. The proposed D-flip flop is employed in designing a 128/129 dual-modulus prescaler using $0.18{\mu}m$ CMOS process parameters. The designed prescaler operates up to 5GHz while conventional one can operate up to 4.5GHz under same conditions. It consumes 0.394mW at 4GHz that is a 34% improved result compared with conventional one.

• Journal of the Institute of Electronics Engineers of Korea SD
• /
• v.48 no.8
• /
• pp.10-17
• /
• 2011

As the data path of the processor widens and the depth of the pipeline deepens, the number of required registers increases. Consequently, careful attention must be paid to the design of clocked storage elements like latches and flipflops as they have a significant bearing on the overall performance of a synchronous VLSI circuit. As technology is also scaling down, noise immunity is becoming an important factor. In this paper, we present a new flipflop which has an improved noise immunity when compared to the hybrid latch flipflop and the conditional precharge flipflop. Simulation results in 65nm CMOS technology with 1.2V supply voltage are used to demonstrate the effectiveness of the proposed flipflop structure.