A new true-single-phase-clocking BiCMOS dynamic pipelined logicfamily for high-speed, low-voltage pipelined system applications

New true-single-phase-clocking (TSPC) BiCMOS/BiNMOS/BiPMOS dynamic logic circuits and BiCMOS/BiNMOS dynamic latch logic circuits for high-speed dynamic pipelined system applications are proposed and analyzed. In the proposed circuits, the bootstrapping technique is utilized to achieve fast near-full-swing operation. The circuit performance of the proposed new dynamic logic circuits and dynamic latch logic circuits in both domino and pipelined applications are simulated by using HSPICE with 1 μm BiCMOS technology. Simulation results have shown that the new dynamic logic circuits and dynamic latch logic circuits in both domino and pipelined applications have better speed performance than that of CMOS and other BiCMOS dynamic logic circuits as the supply voltage is scaled down to 2 V. The operating frequency and power dissipation/MHz of the pipelined system, which is constructed by the new clock-high-evaluate-BiCMOS dynamic latch logic circuit and clock-low-evaluate-BiCMOS (BiNMOS) dynamic latch logic circuit, and the logic units with two stacked MOS transistors, are about 2.36 (2.2) times and 1.15 (1.1) times those of the CMOS TSPC dynamic logic under 1.5-pF output loading at 2 V, respectively. Moreover, the chip area of these two BiCMOS pipelined systems is about 1.9 times and 1.7 times as compared with that of the CMOS TSPC pipelined system. A two-input dynamic AND gate fabricated with 1 μm BiCMOS technology verifies the speed advantage of the new BiNMOS dynamic logic circuit. Due to the excellent circuit performance in high-speed, low-voltage operation, the proposed new dynamic logic circuits and dynamic latch logic circuits are feasible for high-speed, low-voltage dynamic pipelined system applications     

Dynamic latch for high speed GaAs domino circuits

A latch for use with GaAs domino logic gates is presented. A hybrid of a GaAs domino logic gate and a two-phase dynamic FET logic gate, the latch stores data during the precharge phase of domino logic operation. It enables the use of domino logic in large scale systems without the need for interfacing with power consumptive static latches. It is implemented with depletion mode MESFETs and dissipates 0.8 mW.<>     

An efficient triple-tail cell based PFSCL D latch

In this paper, an efficient positive feedback source-coupled logic (PFSCL) D latch topology is proposed. It uses triple-tail cell concept which results in lesser number of stages as well as gate count in comparison to the traditional PFSCL D latch. The operation of the proposed D latch is described and is supported with mathematical formulations. The functionality is verified through SPICE simulations using TSMC 0.18 µm CMOS technology parameters. It is found that the proposed D latch topology significantly reduces the power consumption and delay in comparison to the traditional PFSCL D latch. The impact of process variation on the proposed and traditional PFSCL D latch at different design corners shows similar variations.     

Charge recycling differential logic (CRDL) for low powerapplication

A novel logic family, called charge recycling differential logic (CRDL), has been proposed and analyzed. CRDL reduces power consumption by utilizing a charge recycling technique with the speed comparable to those of conventional dynamic logic circuits. It has an additional benefit of improved noise margin due to inherently static operation. The noise margin problem of true single-phase-clock latch (TSPC) is also eliminated when a CRDL logic circuit is connected to it. Two swing-suppressed-input latches (SSILs), which are introduced for use with CRDL, have better performance than the conventional transmission gate latch. Moreover, a pipeline configuration with CRDL in a true two-phase clocking scheme shows completely race-free operation with no constraints on logic composition. Eight-bit Manchester carry chains and full adders were fabricated using a 0.8 μm single-poly double-metal n-well CMOS technology to verify the relative performance of the proposed logic family. The measurement results indicate that about 16-48% improvements in power-delay product are obtained compared with differential cascode voltage switch (DCVS) logic     

Efficient design of parity preserving logic in quantum-dot cellular automata targeting enhanced scalability in testing

Design of parity preserving logic based on emerging nanotechnology is very limited due to present technological limitation in tackling its high error rate. In this work, Quantum-dot cellular automata (QCA), a potential alternative to CMOS, is investigated for designing easily testable logic circuit. A novel self-testable logic structure referred to as the testable-QCA (t-QCA), using parity preserving logic, is proposed. Design flexibility of t-QCA then evaluated through synthesis of standard functions. The programmability feature of t-QCA is utilized to implement an ALU, realizing six important functions. Although the parity preservation property of t-QCA enables concurrent detection of permanent as well as the transient faults, an augmented test logic circuit (TC) using QCA primitives has been introduced to cover the cell defects in nanotechnology. Experimental results establish the efficiency of the proposed design that outperforms the existing technologies in terms of design cost and test overhead. The achievement of 100% stuck-at fault coverage and the 100% fault coverage for single missing/additional cell defects in QCA layout of the t-QCA gate, address the reliability issues of QCA nano-circuit design.     

Reversible Gates and Testability of One Dimensional Arrays of Molecular QCA

An extensive literature exists on the mathematical characterization of reversible logic. However, the possible technological basis of this computing paradigm still remains unsolved. In this paper, quantum-dot cellular automata (QCA) is investigated for testable implementations of reversible logic. Two new reversible gates (referred to as QCA1 and QCA2) are proposed. These gates are compared (in terms of delay, area and logic synthesis) with other reversible gates (such as Toffoli and Fredkin) for QCA implementation. Due to the expected high error rates in nano-scale manufacturing, testing of nano devices, including QCA, has received considerable attention. The focus of this paper is on the testability of a one-dimensional array made of QCA reversible gates, because the bijective nature of reversible gates significantly facilitates testing of arrays. The investigation of testability relies on a fault model for molecular QCA that is based on a single missing/additional cell assumption. It is shown that C-testability of a 1D reversible QCA gate array can be guaranteed for single fault. Theory and circuit examples show that error masking can occur when multiple faults are considered.     

Reliability and Defect Tolerance in Metallic Quantum-dot Cellular Automata

The computational paradigm known as quantum-dot cellular automata (QCA) encodes binary information in the charge configuration of Coulomb-coupled quantum-dot cells. Functioning QCA devices made of metal-dot cells have been fabricated and measured. We focus here on the issue of robustness in the presence of disorder and thermal fluctuations. We examine the performance of a semi-infinite QCA shift register as a function of both clock period and temperature. The existence of power gain in QCA cells acts to restore signal levels even in situations where high speed operation and high temperature operation threaten signal stability. Random variations in capacitance values can also be tolerated.     

Investigation on low-voltage low-power silicon bipolar designtopology for high-speed digital circuits

This paper investigates a bipolar design topology which is suitable to operate from a voltage supply well below 1.5 V, while maintaining the ability of high frequency operation. The topology has been applied in the design of different divide-by-4 circuits, utilizing a 20-GHz 0.6-μm Si bipolar technology. The different versions featured slight modifications in the architecture of the logic cells and the influence on the frequency and supply voltage range of operation has been investigated. Measurements have shown operation from 1.0-V supply voltage and up to 4.2-GHz input frequency to 1.5 V and up to 6 GHz. The power consumption is approximately 0.3 mW/latch and 1.2 mW/latch, respectively     

Experimental demonstration of single flux quantum logic withresettable latch

We report experimental demonstrations of logic functions based on single flux quantum logic with resettable latch (SFQ-RL) logic. SFQ-RL has been proposed as new SFQ logic, which enables us to initialize the whole circuit. This initialization function is essential for the state machine into which conventional SFQ logic is classified, and makes SFQ logic more applicable to a large-scale logic system, such as a processor. In addition, the function can prevent circuits from performing the failed operation caused by a trapped flux in storage loops. The logic consists of three primitives, which can compose any logic function. We have experimentally demonstrated the operation of “half adder” based on SFQ-RL with the bias margin of ±16%. In order to examine the function of initialization, we designed and evaluated a pseudo random sequence generator by numerical simulation. In addition, we experimentally confirmed the initialization of the generator and “circular buffer” with the bias margin of ±20%     

Quaternary static latch circuit

A new voltage-mode quaternary CMOS static latch circuit is presented. Only devices available in a standard digital CMOS fabrication technology—enhancement-mode NMOS and PMOS transistors with single threshold voltage values—are used. No depletion-mode devices or special transistor threshold voltages are required. Three reference voltages and ground are used to define the logic levels. The operation of the quaternary latch is experimentally verified. Using data for a standard 2-micron digital CMOS fabrication technology, best- and worst-case on-chip setup and hold times are estimated, using simulation, to be approximately 2.8 ns and 6.8 ns, respectively.     

Design of sequential circuits by quantum-dot cellular automata

This paper proposes a detailed design analysis of sequential circuits for quantum-dot cellular automata (QCA). This analysis encompasses flip-flop (FF) devices as well as circuits. Initially, a novel RS-type FF amenable to a QCA implementation is proposed. This FF extends a previous threshold-based configuration to QCA by taking into account the timing issues associated with the adiabatic switching of this technology. The characterization of a D-type FF as a device consisting of an embedded wire is also presented. Unique timing constraints in QCA sequential logic design are identified and investigated. An algorithm for assigning appropriate clocking zones to a QCA sequential circuit is proposed. A technique referred to as stretching is used in the algorithm to ensure timing and delay matching. This algorithm relies on a topological sorting and enumeration step to consistently traversing only once the edges of the graph representation of the QCA sequential circuit. Examples of QCA sequential circuits are provided.     

An improved current mode logic latch for high‐speed applications

In this paper, an improved current mode logic (CML) latch design is proposed for high‐speed on‐chip applications. Transceivers use various methods in fast data transmission in wireless/wire‐line application. For an asynchronous transceiver, the improved CML latch is designed using additional NMOS transistors in conventional CML latch which helps to boost the output voltage swing. The proposed low‐power CML latch‐based frequency divider is compatible for higher operating frequency (16 GHz). Next, the delay model is also developed based on small signal equivalent circuit for the analysis of the proposed latch. The output voltage behavior of the proposed latch is analyzed using 180‐nm standard CMOS technology.     

Design of reliable universal QCA logic in the presence of cell deposition defect

The emergence of Quantum-dot Cellular Automata (QCA) has resulted in being identified as a promising alternative to the currently prevailing techniques of very large scale integration. QCA can provide low-power nanocircuit with high device density. Keeping aside the profound acceptance of QCA, the challenge that it is facing can be quoted as susceptibility to high error rate. The work produced in this article aims towards the design of a reliable universal logic gate (r-ULG) in QCA (r-ULG along with the single clock zone and r-ULG-II along with multiple clock zones). The design would include hybrid orientation of cells that would realise majority and minority, functions and high fault tolerance simultaneously. The characterisation of the defective behaviour of r-ULGs under different kinds of cell deposition defects is investigated. The outcomes of the investigation provide an indication that the proposed r-ULG provides a fault tolerance of 75% under single clock zone and a fault tolerance of 100% under dual clock zones. The high functional aspects of r-ULGs in the implementation of different logic functions successfully under cell deposition defects are affirmed by the experimental results. The high-level logic around the multiplexer is synthesised, which helps to extend the design capability to the higher-level circuit synthesis.     

An advanced SEU tolerant latch based on error detection

This paper proposes a latch that can mitigate SEUs via an error detection circuit.The error detection circuit is hardened by a C-element and a stacked PMOS.In the hold state,a particle strikes the latch or the error detection circuit may cause a fault logic state of the circuit.The error detection circuit can detect the upset node in the latch and the fault output will be corrected.The upset node in the error detection circuit can be corrected by the Celement.The power dissipation and propagation delay of the proposed latch are analyzed by HSPICE simulations.The proposed latch consumes about 77.5％ less energy and 33.1％ less propagation delay than the triple modular redundancy (TMR) latch.Simulation results demonstrate that the proposed latch can mitigate SEU effectively.     

Design metal-dot based QCA circuits using SPICE model

This paper proposes a SPICE model development methodology for quantum-dot cellular automata (QCA) cells and presents a SPICE model for QCA cells. The model is validated by simulating the basic logic gates such as inverter and majority voter. The proposed model makes it possible to design and simulate QCA combinational circuits and hybrid circuits of QCA and other NANO devices using SPICE. In the second half part of the paper, SET and QCA co-design methodology is proposed and SET is used as a readout interface of the QCA cell array. The SET and QCA hybrid circuit is a promising nano-scale solution.     

Fault Tolerant Reversible T Latch with Enhanced Testability at Nano-Scale for Application of Ripple Counters

Russian Microelectronics - Reversible logic is an attracting approach to design the circuits with low power consumption. The cusp of reversible logic and Quantum dot cellular automata (QCA) ease...     

量子元胞自动机器件和电路的研究进展

量子元胞自动机(QCA)是一种新颖的纳米技术,该技术不再通过电流或电压而是基于场相互作用进行信息的计算和传递。首先,综述了两种量子元胞自动机(EQCA和MQCA)器件的计算原理、基本逻辑门和时钟。指出了QCA元胞构成的不同线结构可在相同层交叉传递信号而不受影响。然后,进一步总结了制备QCA器件和功能阵列或电路的实验方法和材料,得出MQCA器件和分子EQCA器件的发展将使该器件逐步达到实际应用水平的结论。详细讨论了目前QCA器件和电路(尤其是存储单元结构)研究取得的重要进展以及面临的问题。提出了QCA器件未来理论和应用研究中的开放课题和方向。     

量子触发器的设计与优化

量子触发器是量子逻辑电路中一个很重要的量子器件,在量子计算领域有着重要的意义。根据量子触发器的逻辑功能,利用量子触发器输入和输出之间的关系,研究了一种通过引入辅助比特来解决数字电路反馈问题以及实现数据保持状态锁存功能的方法。设计构造了五种不同的量子触发器并对量子线路进行了优化。这些量子锁存器在建造量子计算机中可以作为可扩展的基本锁存功能单元使用。     

Reliable ultra-low-voltage low-power probabilistic-based noise-tolerant latch design

In this paper, we proposed a reliable ultra-low-voltage low-power latch design based on the probabilistic-based Markov random field (MRF) theory ,  and  to greatly improve the ability of noise-tolerance. Through MRF mapping decomposition, we map the previous state and the current state compatible logic function of the latch into the MRF network separately. In this way, we can overcome the challenge of applying Markov random field theory to sequential noise-tolerant circuits. In order to further lower the hardware cost and circuit complexity of the chip, we apply the absorption law and H-tree logic combination techniques [4] to simplify the circuit complexity of the MRF noise-tolerant latch circuit. To preserve the noise tolerant capability of MRF latch, we utilize the cross-coupled latching mechanism in the output of MRF latch. Finally, we apply the proposed MRF latch design in a 16-bit carry-lookahead adder circuit. In TSMC 90 nm CMOS process, our proposed circuit can operate reliably under a lower supply voltage of 0.55 V with superior noise tolerance and consumes only 31 μW power, which is 59.2% lower as compared with the conventional CMOS latch design.     

简易逻辑分析仪设计

本系统是以STC89C52单片机和复杂可编程逻辑器件CPLD的组合电路为核心,利用锁存器在时钟上升沿将输入端的数据锁存的原理,构建了一个基于实时采样和直接数据存储器存储（DMA）的简易逻辑分析仪。系统由五部分组成：按键模块、CPLD模块、DDS采样时钟发生模块、LCD显示模块、DMA数据采集模块。相比于市场上的逻辑分析仪,本系统结构简单,易制作,成本低,可同时测量8路TTL信号。本系统可以用来分析数字逻辑电路中的时序逻辑关系,本文还用该逻辑分析仪研究了51单片机对外部地址读写操作的时序,得到与单片机数据手册一致的波形时序图。