• Title/Summary/Keyword: D-flip flop

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Design of Synchronous Quaternary Counter using Quaternary Logic Gate Based on Neuron-MOS (뉴런 모스 기반의 4치 논리게이트를 이용한 동기식 4치 카운터 설계)

  • Choi Young-Hee;Yoon Byoung-Hee;Kim Heung-Soo
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.42 no.3 s.333
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    • pp.43-50
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    • 2005
  • In this paper, quaternary logic gates using Down literal circuit(DLC) has been designed, and then synchronous Quaternary un/down counter using those gates has been proposed The proposed counter consists of T-type quaternary flip flop and 1-of-2 threshold-t MUX, and T-type quaternary flip flop consists of D-type quaternary flip flop and quaternary logic gates(modulo-4 addition gates, Quaternary inverter, identity cell, 1-of-4 MUX). The simulation result of this counter show delay time of 10[ns] and power consumption of 8.48[mW]. Also, assigning the designed counter to MVL(Multiple-valued Logic) circuit, it has advantages of the reduced interconnection and chip area as well as easy expansion of digit.

The Design of the Ternary Sequential Logic Circuit Using Ternary Logic Gates (3치 논리 게이트를 이용한 3치 순차 논리 회로 설계)

  • 윤병희;최영희;이철우;김흥수
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.40 no.10
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    • pp.52-62
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    • 2003
  • This paper discusses ternary logic gate, ternary D flip-flop, and ternary four-digit parallel input/output register. The ternary logic gates consist of n-channel pass transistors and neuron MOS(νMOS) threshold inverters on voltage mode. They are designed with a transmission function using threshold inverter that are in turn, designed using Down Literal Circuit(DLC) that has various threshold voltages. The νMOS pass transistor is very suitable gate to the multiple-valued logic(MVL) and has the input signal of the multi-level νMOS threshold inverter. The ternary D flip-flop uses the storage element of the ternary data. The ternary four-digit parallel input/output register consists of four ternary D flip-flops which can temporarily store four-digit ternary data. In this paper, these circuits use 3.3V low power supply voltage and 0.35m process parameter, and also represent HSPICE simulation result.

A 23.52µW / 0.7V Multi-stage Flip-flop Architecture Steered by a LECTOR-based Gated Clock

  • Bhattacharjee, Pritam;Majumder, Alak;Nath, Bipasha
    • IEIE Transactions on Smart Processing and Computing
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    • v.6 no.3
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    • pp.220-227
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    • 2017
  • Technology development is leading to the invention of more sophisticated electronics appliances that require long battery life. Therefore, saving power is a major concern in current-day scenarios. A notable source of power dissipation in sequential structures of integrated circuits is due to the continuous switching of high-frequency clock signals, which do not carry any information, and hence, their switching is eliminated by a method called clock gating. In this paper, we have incorporated a recent clock-gating style named Leakage Control Transistor (LECTOR)-based clock gating to drive a multi-stage sequential architectures, and we focus on its performance under three different process corners (fast-fast, slow-slow, typical-typical) through Monte Carlo simulation at 18 GHz clock with 90 nm technology. This gating is found to be one of the best gated approaches for multi-stage architectures in terms of total power consumption.

Design and Measurement of SFQ DFFC and Inverter (단자속 양자 DFFC와 Inverter의 설계와 측정)

  • 정구락;홍희송;박종혁;임해용;강준희;한택상
    • Progress in Superconductivity
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    • v.5 no.1
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    • pp.17-20
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    • 2003
  • We have designed and measured a SFQ(Single Flux Quantum) DFFC and an Inverter(NOT) for superconducting ALU(Arithmetic Logic Unit) development. To optimize the circuit, we used Julia, XIC, and L meter for circuit simulations and circuit layouts. The Inverter was consisted of a D Flip-Flop, a data input, a clock input and a data output. If a data pulse arrives at the inverter, then the output reads ‘0’ (no output pulse is produced) at the next clock period. If there is no input data pulse, it reads out ‘1’(output pulse is produced). The DFFC was consisted of a D flip-Flop, an Inverter, a Data in, a Clock in and two outputs. If a data pulse arrives at the DFFC circuit, then the output2 reads ‘1’ at the next clock period, otherwise it reads out ‘1’ to output1. Operation of the fabricated chip was performed at the liquid helium temperature and at the frequencies of 1KHz.

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Design of Single Flux Quantum D2 Cell and Inverter for ALU (ALU를 위한 단자속 양자 D2 Cell과 Inverter의 설계)

  • 정구락;박종혁;임해용;강준희;한택상
    • Proceedings of the Korea Institute of Applied Superconductivity and Cryogenics Conference
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    • 2003.02a
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    • pp.140-142
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    • 2003
  • We have designed a SFQ (Single Flux Quantum) D2 Cell and Inverter(NOT) for a superconducting ALU (Arithmetic Logic Unit). To optimize the circuit, we have used Julia, XIC and Lmeter for simulations and layouts. We obtained the circuit margin of larger than $\pm$25%. After layout, we drew chip for fabrication of SFQ D2 Cell and Inverter. We connected D2 Cell and Inverter to jtl, DC/SFQ, SFQ/DC and RS flip-flop for measurement.

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High-speed CMOS Frequency Divider with Inductive Peaking Technique

  • Park, Jung-Woong;Ahn, Se-Hyuk;Jeong, Hye-Im;Kim, Nam-Soo
    • Transactions on Electrical and Electronic Materials
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    • v.15 no.6
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    • pp.309-314
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    • 2014
  • This work proposes an integrated high frequency divider with an inductive peaking technique implemented in a current mode logic (CML) frequency divider. The proposed divider is composed with a master-slave flip-flop, and the master-slave flip-flop acts as a latch and read circuits which have the differential pair and cross-coupled n-MOSFETs. The cascode bias is applied in an inductive peaking circuit as a current source and the cascode bias is used for its high current driving capability and stable frequency response. The proposed divider is designed with $0.18-{\mu}m$ CMOS process, and the simulation used to evaluate the divider is performed with phase-locked loop (PLL) circuit as a feedback circuit. A divide-by-two operation is properly performed at a high frequency of 20 GHz. In the output frequency spectrum of the PLL, a peak frequency of 2 GHz is obtained witha divide-by-eight circuit at an input frequency of 250 MHz. The reference spur is obtained at -64 dBc and the power consumption is 13 mW.

A PFD (Phase Frequency Detector) with Shortened Reset time scheme (Reset time을 줄인 Phase Frequency Detector)

  • 윤상화;최영식;최혁환;권태하
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • 2003.10a
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    • pp.385-388
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    • 2003
  • In this paper, a D-Latch is replaced by a memory cell on the proposed PFD to improve response tine by reducing reset me. The PFD has been simulated using HSPICE with a Hynix 0.35um CMOS process to prove the performance improvement.

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