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.     

Low-voltage, high-speed CMOS analog latched voltage comparator using the “flipped voltage follower” as input stage

The design and characterization of a low-voltage, high-speed CMOS analog latched voltage comparator based on the flipped voltage follower (FVF) cell and input signal regeneration is presented. The proposed circuit consists of a differential input stage with a common-mode signal detector, followed by a regenerative latch and a Set-Reset (S-R) latch. It is suitable for successive-approximation type’s analog-to-digital converters (ADC), but can also be adapted for use in flash-type ADCs. The circuit was fabricated using 0.18 μm CMOS technology, and its measured performance shows 12-bit resolution at 20 MHz comparison rate and 1 V single supply voltage, with a total power consumption of 63.5 μW.     

An improved low offset latch comparator for high-speed ADCs

This paper presents a new high-speed and low offset latch comparator. The proposed offset compensation technique for latch comparator enables the preamplifier design relaxation for high-speed and high-resolution analog-to-digital converters. Employing the negative resistance of regeneration latch to enhance the comparator gain in input tracking phase is the key idea to reduce the latch input referred offset voltage. The Monte-Carlo simulation results for the designed comparator in 0.18 μm CMOS process show that equivalent input referred offset voltage is 200 μV at 1 sigma while it was 26 mV at 1 sigma before offset cancellation. The comparator dissipates 600 μW from a 1.8 V supply while operating in 500 MHz clock frequency.     

A novel high-speed sense-amplifier-based flip-flop

A new sense-amplifier-based flip-flop is presented. The output latch of the proposed circuit can be considered as an hybrid solution between the standard NAND-based set/reset latch and the NC-/sup 2/MOS approach. The proposed flip-flop provides ratioless design, reduced short-circuit power dissipation, and glitch-free operation. The simulation results, obtained for a 0.25-/spl mu/m technology, show improvements in the clock-to-output delay and the power dissipation with respect to the recently proposed high-speed flip-flops. The new circuit has been successfully employed in a high-speed direct digital frequency synthesizer chip, highlighting the effectiveness of the proposed flip-flop in high-speed standard cell-based applications.     

长波长高速雪崩光电二极管的理论研究

本文以现有的理论研究和实验研究的结果为依据,提出了长波长高速及超高速雪崩光电二极管(APD)的两设计原则:一是在雪崩管内建立合理的电场强度分布;二是尽可能减少电寄生。这是得到高速或超高速响应、高量子效率以及低噪声性能的根本途径。     

Analysis and design of low-voltage low-power high-speed double tail current dynamic latch comparator

The demanding need of ultra-high speed, area efficient and power optimized analog-to-digital converter is forcing towards the exploration and usage of the dynamic regenerative comparator to minimize the power, area and maximize the speed. In this paper, detailed analysis of the delay for the various dynamic latch based comparators is presented and analytical expressions are derived. With the help of analytical expressions, the designer can obtain insight view of the different parameters, which are the contributors of the delay in the dynamic comparator. Based on the findings, various tradeoffs can be explored. Based on the literature and presented analysis, a new dynamic latch based comparator is proposed. The basic double tail dynamic latch based comparator and shared charge logic are modified for low-power and high-speed with the reduced power supply in the proposed comparator. With the modified structure of double tail latch comparator and adding the shared charge logic, the regeneration delay is reduced, at the same time, power consumption is also reduced. Simulation results in 90 nm CMOS technology confirm the claimed reductions. The simulation is carried out using 90 nm technology with a supply voltage of 1 V, at 1 GHz of frequency resulting into the delay of 50.9 ps while consuming 31.80 μW of power.     

A 3$,times,$5-Gb/s Multilane Low-Power 0.18-$mu{hbox {m}}$ CMOS Pseudorandom Bit Sequence Generator

A low-power, three-lane, pseudorandom bit sequence (PRBS) generator has been fabricated in a 0.18-mum CMOS process to test a multilane multi-Gb/s transmitter that cancels far-end crosstalk. Although the proposed PRBS generator was designed to produce three uncorrelated 12-Gb/s PRBS sequences, measurement results included in this paper have been obtained at only 5 Gb/s due to test setup limitations. The prototype employs a CMOS latch optimized to operate at frequencies close to the of the process and a current-mode logic (CML) MUX with modified active inductor loads for better high-speed large-signal behavior. In order to reduce the power consumption, a quarter-clock rate linear feedback shift register (LFSR) core in a power-efficient parallel architecture has been implemented to minimize the use of power-hungry, high-speed circuitry. Further power reduction has been achieved through the clever partitioning of the system into static logic and CML. In addition, the prototype design produces three uncorrelated 12-Gb/s data streams from a single quarter-rate LFSR core, thereby amortizing the power across multiple channels which lowers the power per channel by 3 times. The total measured power consumption at 5 Gb/s is 131 mW per lane and the calculated figure of merit per lane is 0.84 pJ/bit, which is significantly better than previously published designs.     

Architectures and technologies for high-speed optical data networks

Current optical networks are migrating to wavelength division multiplexing (WDM)-based fiber transport between traditional electronic multiplexers/demultiplexers, routers, and switches. Passive optical add-drop WDM networks have emerged but an optical data network that makes full use of the technologies of dynamic optical routing and switching exists only in experimental test-beds. This paper discusses architecture and technology issues for the design of high performance optical data networks with two classes of technologies, WDM and time division multiplexing (TDM). The WDM network architecture presented stresses WDM aware Internet protocol (IP), taking full advantage of optical reconfiguration, optical protection and restoration, traffic grooming to minimize electronics costs, and optical flow-switching for large transactions. Special attention is paid to the access network where innovative approaches to architecture may have a significant cost benefit. In the more distant future, ultrahigh-speed optical TDM networks, operating at single stream data rates of 100 Gb/s, may offer unique advantages over WDM networks. These advantages may include the ability to provide integrated services to high-end users, multiple quality-of-service (QoS) levels, and truly flexible bandwidth-on-demand. The paper gives an overview of an ultrahigh-speed TDM network architecture and describes recent key technology developments such as high-speed sources, switches, buffers, and rate converters     

A Josephson latch

A latch has been developed which is suitable for use in a high-speed Josephson latching-logic computer. Measurements on a test chip incorporating latch circuits have shown that the flip-flop is capable of changing states in ~120 ps and that races can be prevented by deriving timing information from the AC power waveform. Details of the design and experimental results are given.     

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     

A 20-Gb/s 1:2 demultiplexer in 0.18-μm CMOS

A 1:2 demultiplexer (DEMUX) has been designed and fabricated in SMIC's standard 0.18-μm CMOS technology, based on standard CML logic and current-density-centric design philosophy. For the integrity of the DEMUX and the reliability of the internal operations, a data input buffer and a static latch were adopted. At the same time, the static latch enables the IC to work in a broader data rate range than the dynamic latch. Measurement results show that under a 1.8-V supply voltage, the DEMUX can operate reliably at any data rate in the range of 5-20 Gb/s. The chip size is 875 × 640 μm2 and the power consumption is 144 mW, in which the core circuit has a share of less than 28%.     

A dual-page programming scheme for high-speed multigigabit-scaleNAND flash memories

To realize a low-cost and high-speed programming NAND flash memory, a new programming scheme, a “dual-page programming scheme,” has been proposed. This architecture drastically increases the program throughput without circuit area overhead. In the proposed scheme, two memory cells are programmed at the same time using only one page buffer. Therefore, the page size, i.e., the number of memory cells programmed simultaneously, is doubled and the program speed is improved. As the number of page buffers required in the proposed scheme is the same as that in the conventional one, there is no circuit area increase. This novel operation is made possible by using a bitline as a dynamic latch to temporarily store the program data. As a result, the programming is accelerated by 73% in a 1-Gb generation and 62% in a 4-Gb generation, 18.2-MB/s 1-Gb or 30.7-MB/s 4-Gb NAND flash memory can be realized with this new architecture     

CMOS Latch Using Quad for High-Speed Comparators

The well-known CMOS quad consisting of two asymmetric differential pairs is a transconductance element. It provides an additional output current proportional to the square of its differential input voltage. Here, we use both the linear and square-law outputs of a quad to build a high-speed latch that has differential low-voltage output swing. This latch retains the useful property of constant power-supply current like all current-biased differential current-mode logic circuits. Simulation results for 0.18-mum CMOS process are presented. The design is application specific and is intended for use in high-speed comparators needed for analog-to-digital converters     

基于0.13 μm CMOS工艺的低电压高速1:2分频器设计

在光纤传输系统中,分频器是工作在最高频率的电路之一,起着至关重要的作用,本文就采用了由锁存器构成的数字1:2分频器.采用UMC 0.13μm CMOS工艺,设计了电源电压为1V,工作频率范围为5～20GHz的1:2分频器电路.该电路由基本分频器单元以及输入输出缓冲组成.基本分频器单元采用单端动态负载锁存器.整体电路功耗...     

A 60 mW per Lane, 4$,times,$23-Gb/s 2$ ^7 -$1 PRBS Generator

An ultra-low-power, 2$ ^7-$1 PRBS generator with four, appropriately delayed, parallel output streams was designed. It was fabricated in a 150-GHz$f_T$SiGe BiCMOS technology and measured to work up to 23 Gb/s. The four-channel PRBS generator consumes 235 mW from 2.5 V, which results in only 60 mW per output lane. The circuit is based on a 2.5-mW BiCMOS CML latch topology, which, to the best of our knowledge, represents the lowest power for a latch operating above 10 Gb/s. A power consumption and speed comparison of series and parallel PRBS generation techniques is presented. Low-power BiCMOS CML latch topologies are analyzed using the OCTC method.     

A 1?mW power-efficient high frequency CML 2:1 divider

In this study, a low power high operating frequency current mode logic (CML) 2:1 divider is presented. Because the latching transistor pair is biased in low current mode, the proposed divider is power-saving. In this divider, each latch has only one clock transistor, which means that the capacitive load to the former stages is reduced. This makes the buffer of the voltage controlled oscillator (VCO) or VCO be easily designed in phase locked loops. Besides, an active inductor is used in this circuit to resonate with parasitic capacitances and thus endows this topology a high-speed capability. The measurement results indicate that the proposed divider achieves an operation band from 10 to 15?GHz with only 1mW power dissipation.     

Low-Voltage Topologies for 40-Gb/s Circuits in Nanoscale CMOS

This paper presents low-voltage circuit topologies for 40-Gb/s communications in 90-nm and 65-nm CMOS. A retiming flip-flop implemented in two different 90-nm CMOS technologies employs a MOS-CML Master-Slave latch topology with only two vertically stacked transistors. Operation at 40 Gb/s is achieved by a combination of low and high-V_T MOSFETs in the latch. Full-rate retiming with jitter reduction is demonstrated up to 40 Gb/s. Low-power broadband amplifiers based on resistor-inductor transimpedance feedback are realized in 90-nm and 65-nm CMOS to investigate the portability of high-speed building blocks between technology nodes. Experiments show that the transimpedance amplifier based on the CMOS inverter can reach 40-Gb/s operation with a record power consumption of 0.15 mW/Gb/s. A comparison between CMOS technologies underlines the importance of General Purpose rather than Low Power processes for high-speed digital design.     

Radiation Hardened by Design Latches — A Review and SEU Fault Simulations

There are many Radiation Hardened by Design (RHBD) architectures presented in the literature to mitigate Single Event Upset (SEU) in a storage element, a latch. Nevertheless, the design of a SEU hardened latch is being continuously improved with respect to reliability, performance, power consumption and area overhead. SEU mitigating techniques by design focus on reducing criticality of sensitive nodes in a latch. Sensitive node(s) in a latch could be an active and/or a high impedance node(s). In this paper, we have classified previously presented SEU hardened by design latch architectures and reviewed SEU mechanisms in selected RHBD latch architectures on Complementary Metal Oxide Semiconductor (CMOS) technology models. Simulation studies using latest fault simulation model have been carried out. Simulation results have revealed some interesting observations described in this paper. Our findings, based on analyses, will provide valuable design inputs for futuristic RHBD latches with advanced technology nodes.     

Selectively doped heterostructure frequency dividers

The operation of high-speed divide-by-two circuit (binary counter) composed of selectively doped heterostructure logic gates is reported for the first time. These field-effect transistor circuits utilize the enhanced transport properties of high-mobility electrons confined near a heterojunction interface in a selectively doped AlGaAs/GaAs structure. The dividers are based on a Type-D flip-flop composed of six direct-coupled NOR-gates having 1-µm gate lengths and 4-µm source-drain spacings. They are fabricated by conventional optical contact lithography on a four-layer Al.3Ga.7As/GaAs structure grown by molecular-beam epitaxy. Successful operation is demonstrated at 5.9 GHz at 77 K for 1.3-V bias and 30-mW total power dissipation (including output buffers) and 3.7 GHz at 300 K for 1.4-V bias and 19-mW total power dissipation. Total power dissipation values as low as 3.9 mW at 0.65-V bias were also obtained for 2.85-GHz operation at 300 K. These preliminary results illustrate the promise of SDHT logic for ultrahigh-speed low-power applications.     

A 2.5 Gb/s ATM add-drop unit for B-ISDN based on a GaAs LSI

This paper describes the design and implementation of a high-speed GaAs asynchronous transfer mode (ATM) mux-demux ASIC (AMDA) which is the core LSI circuit in a high-speed ATM add-drop unit (ADU). This unit is used in a new distributed ATM multiplexing-demultiplexing architecture for broadband switching systems. The ADU provides a cell-based interface between systems operating at different data rates (the high-speed interface being 2.5 Gb/s and the low-speed interface being 155/622 Mb/s), or can be used for building local high-speed switches and LANs. Self-timed first-in-first-out (FIFO) buffers are used for handling the speed gaps between domains operating at different clock rates, and a self-timed at receiver's input (STARI) interface is used at all high-speed chip-to-chip links to eliminate timing skews. A printed circuit board (PCB) with two ADUs in a distributed multiplexing-demultiplexing architecture has been developed, and the AMDA demonstrated operation above 4 Gb/s (500 MHz clock frequency) with an associated power dissipation of 5 W in a standard 0.8 μm E/D MESFET process