Novel broad-band bit-synchronization circuit module for optical interconnections

A novel broad-band and ultrafast bit-synchronization circuit module is proposed and fabricated for optical interconnections. In optical packet switch fabric or optical interconnection between electric circuit boards, instantaneous bit synchronization is crucial to properly retime incoming packets with a random phase and reduce the number of preamble overhead bits. The developed bit-synchronization circuit module has a new clock selection circuit, which is configured with a phase comparator and an amplitude comparator. Since device-dependent delay circuits, such as buffer amplifiers or RC phasors, are not adopted, the newly developed clock selection circuit can operate under broad-band frequencies. The bit-synchronization circuit module was fabricated with a Si-bipolar gate array and it can operate at broad-band bit rates of up to 10.5 Gb/s. It also exhibits a power sensitivity penalty as low as 3 dB for 10-Gb/s input signals. The synchronization acquisition time of less than 9 b over the entire 360/spl deg/ phase range was confirmed by experiment.     

Low jitter and multirate clock and data recovery circuit using a MSADLL for chip-to-chip interconnection

A fully integrated clock and data recovery circuit (CDR) using a multiplying shifted-averaging delay locked loop and a rate-detection circuit is presented. It can achieve wide range and low jitter operation. A duty-cycle-insensitive phase detector is also proposed to mitigate the dependency on clock duty cycle variations. The experimental prototype has been fabricated in a 0.25-/spl mu/m 1P5M CMOS technology and occupies an active area of 2.89 mm/sup 2/. The measured CDR could operate from 125 Mb/s to 2.0 Gb/s with a bit error rate better than 10/sup -12/ from a 2.5-V supply. Over the entire operating frequency range, the maximum rms jitter of the recovered clock is less than 4 ps.     

All-Optical 3R Burst-Mode Reception at 40 Gb/s Using Four Integrated MZI Switches

We demonstrate an all-optical retime, reshape, reamplify (3R) burst-mode receiver (BMR) operating error-free with a 40-Gb/s variable-length asynchronous optical data packets that exhibit up to 9-dB packet-to-packet power variation. The circuit is completely based upon hybrid integrated Mach-Zehnder interferometric (MZI) switches as it employs four cascaded MZIs, each one performing a different functionality. The 3R burst-mode reception is achieved with the combination of two discrete all-optical subsystems. A reshape, reamplify BMR employing a single MZI is used first to perform power equalization of the incoming bursts and provide error-free data reception. This novel approach is experimentally demonstrated to operate error-free, even for a 9-dB dynamic range of power variation between bursty data packets and for a wide range of average input power. The obtained power-equalized data packets are then fed into a 3R regenerator to improve the signal quality by reducing the phase and amplitude jitter of the incoming data. This packet-mode 3R regenerator employs three MZIs that perform wavelength conversion, clock extraction, and data regeneration for every packet separately and operates at 40 Gb/s, exhibiting rms timing jitter reduction from 4 ps at the input to 1 ps at the output and a power penalty improvement of 2.5 dB     

A 2.5-10-GHz clock multiplier unit with 0.22-ps RMS jitter in standard 0.18-/spl mu/m CMOS

This paper demonstrates a low-jitter clock multiplier unit that generates a 10-GHz output clock from a 2.5-GHz reference clock. An integrated 10-GHz LC oscillator is locked to the input clock, using a simple and fast phase detector circuit that overcomes the speed limitation of a conventional tri-state phase frequency detector due to the lack of an internal feedback loop. A frequency detector guarantees PLL locking without degenerating jitter performance. The clock multiplier is implemented in a standard 0.18-/spl mu/m CMOS process and achieves a jitter generation of 0.22 ps while consuming 100 mW power from a 1.8-V supply.     

A direct-skew-detect synchronous mirror delay forapplication-specific integrated circuits

A nonfeedback CMOS digital-clock-generator, direct-skew-detect synchronous-mirror-delay (direct SMD) circuit has been developed that achieves clock-skew suppression in only two clock cycles for application-specific integrated circuits having unfixed and various clock paths. The direct SMD circuit detects both clock skew and clock cycle by using a direct-skew detector and clock-suspension circuitry. The skew-detection scheme removes the phase errors caused by delay in the clock-driver circuit. Measurements demonstrated that the direct SMD circuit eliminates various amounts of clock skew (2.0-3.0 ns) at 200 MHz in two clock cycles     

ATM-PON系统的突发同步技术

在采用ＴＤＭＡ协议的无源光网络中,突发同步是一项关键技术,一般采用基于多相对钏的关键字检测法。本文提出了一种新颖的基于数据地的突发同步技术,采用了高速ＦＰ－ＧＡ和ＥＣＬ有源延时器的方式实现１５５Ｍｂｉｔ／ｓ突发同步器。由于膝用同一主时钏对数据抽样,不需要进行相位校准,简化了电路的设计;相对于传统的ＡＳＩＣ设计方案,该 开发成本低、开发周期短的优点。     

单光子探测盖革雪崩焦平面用低抖动多相位时钟电路设计

针对单光子探测盖革雪崩焦平面读出电路应用,基于全局共享延迟锁相环和2维H型时钟树网络,该文设计一款低抖动多相位时钟电路.延迟锁相环采用8相位压控延迟链、双边沿触发型鉴相器和启动-复位模块,引入差分电荷泵结构,减小充放电流失配,降低时钟抖动.采用H时钟树结构,减小大规模电路芯片传输路径不对称引起的相位差异,确保多路分相时...     

40 Gb/s Transimpedance-AGC Amplifier and CDR Circuit for Broadband Data Receivers in 90 nm CMOS

High-speed front-end amplifiers and CDR circuits play critical roles in broadband data receivers as the former needs to perform amplification at high data rate and the latter has to retime the data with the extracted low-jitter clock. In this paper, the design and experimental results of 40 Gb/s transimpedance-AGC amplifier and CDR circuit are described. The transimpedance amplifier incorporates reversed triple-resonance networks (RTRNs) and negative feedback in a common-gate configuration. A mathematical model is derived to facilitate the design and analysis of the RTRN, showing that the bandwidth is extended by a larger factor compared to using the shunt-series peaking technique, especially in cases when the parasitic capacitance is dominated by the next stage. Operating at 40 Gb/s, the amplifier provides an overall gain of 2 kOmega and a differential output swing of 520 mV_pp with for input spanning from to . The measured integrated input-referred noise is 3.3muA_rms. The half-rate CDR circuit employs a direction-determined rotary-wave quadrature VCO to solve the bidirectional-rotation problem in conventional rotary-wave oscillators. This guarantees the phase sequence while negligibly affecting the phase noise. With 40 Gb/s 2³¹ - 1 PRBS input, the recovered clock jitter is and 0.7ps_rms. The retimed data exhibits 13.3 ps_pp jitter with BER . Fabricated in 90 nm digital CMOS technology, the overall amplifier consumes 75 mW and the CDR circuit consumes 48 mW excluding the output buffers, all from a 1.2 V supply.     

A 10-Gb/s CMOS clock and data recovery circuit with a half-ratelinear phase detector

A 10-Gb/s phase-locked clock and data recovery circuit incorporates an interpolating voltage-controlled oscillator and a half-rate phase detector. The phase detector provides a linear characteristic while retiming and demultiplexing the data with no systematic phase offset. Fabricated in a 0.18-μm CMOS technology in an area of 1.1×0.9 mm², the circuit exhibits an RMS jitter of 1 ps, a peak-to-peak jitter of 14.5 ps in the recovered clock, and a bit-error rate of 1.28×10^-6, with random data input of length 2²³-1. The power dissipation is 72 mW from a 2.5-V supply     

Traffic management for ATM local area networks

Asynchronous transfer mode (ATM) is the first switching technology to be capable of supporting circuit switching and packet switching within a single integrated switching mechanism. This was one of the research goals that led to the development of ATM. Considerable progress has already been made in implementing constant bit-rate services, similar to conventional circuit switching, over ATM. The authors briefly consider how to support LAN emulation over an ATM network and then explore how to offer the dynamic bandwidth sharing in the local area. Considerable progress has already been made in implementing constant bit-rate services, similar to conventional circuit switching, over ATM. However, the bursty nature of data traffic requires dynamic bandwidth sharing similar to packet switching, and this is still under investigation     

10Gb/s CMOS时钟和数据恢复电路的设计

介绍了利用0.18μmCMOS工艺实现了应用于光纤传输系统SDHSTM-64级别的时钟和数据恢复电路。采用了电荷泵锁相环(CPPLL)结构,CPPLL中的鉴相器能够鉴测相位产生超前滞后逻辑,采样数据具有1∶2分接的功能。振荡器采用全集成LC压控振荡器,鉴相器采用半速率的结构。对应于10Gb/s的PRBS数据(231-1),恢复出的5GHz时钟的相位噪声为-112dBc/Hz@1MHz,同时10Gb/s的PRBS数据分接出两路5Gb/s数据。芯片面积仅为1.00mm×0.8mm,电源电压1.8V时功耗为158mW。     

2.5Gb/s Ga As MESFET定时判决电路

设计了 2 .5 Gb/ s光纤通信用耗尽型 Ga As MESFET定时判决电路 .通过 SPICE模拟表明恢复的时钟频率达2 .5 GHz,判决电路传输速率达 2 .5 Gb/ s.实验证明经时钟信号抽样后判决电路可产生正确的数字信号 ,传输速率达 2 .5 Gb/ s     

Clock and data recovery IC for 40-Gb/s fiber-optic receiver

The integrated clock and data recovery (CDR) circuit is a key element for broad-band optical communication systems at 40 Gb/s. We report a 40-Gb/s CDR fabricated in indium-phosphide heterojunction bipolar transistor (InP HBT) technology using a robust architecture of a phase-locked loop (PLL) with a digital early-late phase detector. The faster InP HBT technology allows the digital phase detector to operate at the full data rate of 40 Gb/s. This, in turn, reduces the circuit complexity (transistor count) and the voltage-controlled oscillator (VCO) requirements. The IC includes an on-chip LC VCO, on-chip clock dividers to drive an external demultiplexer, and low-frequency PLL control loop and on-chip limiting amplifier buffers for the data and clock I/O. To our knowledge, this is the first demonstration of a mixed-signal IC operating at the clock rate of 40 GHz. We also describe the chip architecture and measurement results.     

Burst switching-an update

Burst switching research in dispersed control and integrated switching is described. Burst transport is integrated in that voice and data are switched through the same switching fabric and transmission media. Burst switching is compared to and distinguished from fast packet, fast circuit, and ATM (asynchronous transfer mode) switching. Misunderstandings about burst transport that have appeared in the literature are corrected, to wit: burst does not immediately clip in case of channel contention; burst switches voice and data in the same way; and a burst switch interfaces naturally to other types of switches. Round-trip delay performance is calculated to be less than 5 ms. The current status of the burst project is described     

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     

An all-digital PLL for frequency multiplication by 4 to 1022 with seven-cycle lock time

An all-digital phase-locked loop (PLL) circuit in which resolution in the phase detector and digitally controlled oscillator (DCO) exactly matches the gate-delay time is presented. The pulse delay circuit is connected in a ring shape with 32 inverters (2/sup 5/ inverters). With the inverter gate-delay time as the time base, the pulse phase difference is detected simultaneously with the generation of the output clock. In this system, the phase detector and oscillator share a single ring-delay-line (RDL). This means the resolution is the same at all times, making a high-speed response possible. In a prototype integrated circuit (IC) using 0.65-/spl mu/m CMOS, the generation of a frequency multiplication clock was achieved with four reference clocks, and that of a phase-locked clock with seven reference clocks, for a high-speed response. The cell size was 1.08 /spl times/ 1.08 mm/sup 2/, and the output clock frequency had a wide range of 50 kHz/spl sim/60 MHz. The multiplication range of the clock frequency was also a very wide 4/spl sim/1022, and a high level of precision was achieved with a clock jitter standard deviation of 234 ps. This digital PLL can withstand a broad range of operating environments, from -30/spl deg/C/spl sim/140/spl deg/C, and is suitable for making a programmable clock generator on a chip.     

High speed GaAs digital integrated circuit with clock frequency of 4.1 GHz

A maximum clock frequency of 4.1 GHz was obtained for a GaAs digital integrated circuit using deep recess normally-on GaAs MESFETs with 1.2 ?m long gate and interdigitated Schottky diodes. The Ti/Pt/Au gate electrode was made by a lift-off technique with conventional photolithography. The minimum propagation delay of a NAND/AND gate was estimated to be 100 ps/gate for a fan-out of 2 from the self-oscillation frequency of the master-slave flip-flops.     

Highly integrated InP HBT optical receivers

This paper presents two highly integrated receiver circuits fabricated in InP heterojunction bipolar transistor (HBT) technology operating at up to 2.5 and 7.5 Gb/s, respectively. The first IC is a generic digital receiver circuit with CMOS-compatible outputs. It integrates monolithically an automatic-gain-control amplifier, a digital clock and data recovery circuit, and a 1:8 demultiplexer, and consumes an extremely low 340 mW of power at 3.3 V, including output buffers. It can realize a full optical receiver when connected to a photo detector/preamplifier front end. The second circuit is a complete multirate optical receiver application-specific integrated circuit (ASIC) that integrates a photodiode, a transimpedance amplifier, a limiting amplifier, a digital clock and data recovery circuit, a 1:10 demultiplexer, and the asynchronous-transfer-mode-compatible word synchronization logic. It is the most functionally complex InP HBT optoelectronic integrated circuit reported to date. A custom package has also been developed for this ASIC     

High-speed GaAs SCFL monolithic integrated decision circuit for Gbit/s optical repeaters

A high-speed GaAs monolithic integrated decision circuit for Gbit/s optical repeaters, based on source coupled FET logic (SCFL) and designed to be completely ECL-compatible, has been developed. A clock phase margin of 150 degrees at 2 Gbit/s and IC yields of about 60% are achieved by using SCFL configuration. The developed IC operates stably from 10 to 60°C ambient temperature over a supply voltage fluctuation of more than 2 V.     

A 20-Gb/s 0.13-/spl mu/m CMOS serial link transmitter using an LC-PLL to directly drive the output multiplexer

A 20-Gb/s transmitter is implemented in 0.13-/spl mu/m CMOS technology. An on-die 10-GHz LC oscillator phase-locked loop (PLL) creates two sinusoidal 10-GHz complementary clock phases as well as eight 2.5-GHz interleaved feedback divider clock phases. After a 2/sup 20/-1 pseudorandom bit sequence generator (PRBS) creates eight 2.5-Gb/s data streams, the eight 2.5-GHz interleaved clocks 4:1 multiplex the eight 2.5-Gb/s data streams to two 10-Gb/s data streams. 10-GHz analog sample-and-hold circuits retime the two 10-Gb/s data streams to be in phase with the 10-GHz complementary clocks. Two-tap equalization of the 10-Gb/s data streams compensate for bandwidth rolloff of the 10-Gb/s data outputs at the 10-GHz analog latches. A final 20-Gb/s 2:1 output multiplexer, clocked by the complementary 10-GHz clock phases, creates 20-Gb/s data from the two retimed 10-Gb/s data streams. The LC-VCO is integrated with the output multiplexer and analog latches, resonating the load and eliminating the need for clock buffers, reducing power supply induced jitter and static phase mismatch. Power, active die area, and jitter (rms/pk-pk) are 165 mW, 650 /spl mu/m/spl times/350 /spl mu/m, and 2.37 ps/15 ps, respectively.