12Gb/s 0.25μm CMOS低功耗1:4分接器

实现了一种能运用于光传输系统SONET OC-192的低功耗单级分接器,其工作速率高达12Gb/s.该电路采用了特征栅长为0.25μm的TSMC混和信号CMOS工艺.所有的电路都采用了源极耦合逻辑,在抑制共模噪声的同时达到尽可能高的工作速率.该分接器具有利用四分之一速率的正交时钟来实现单级分接的特征,减少了分接器器件,降低了功耗.通过在晶圆测试,该芯片在输入12Gb/s长度为231-1伪随机码流时,分接功能正确.芯片面积为0.9mm×0.9mm,在2.5V单电源供电的情况下的典型功耗是210mW.     

A 20-Gb/s 1 : 2 Demultiplexer With Capacitive-Splitting Current-Mode-Logic Latches

This paper presents a high-speed 1:2 demultiplexer (DEMUX) implemented in a 0.18-mum CMOS process. By employing a capacitive-splitting architecture for the current-mode-logic latches, a significant speed improvement is achieved in the proposed DEMUX. Provided a 2²³ - 1 pseudorandom bit sequence from the pattern generator, the fabricated circuit operates at an input data rate up to 20 Gb/s. The fully integrated DEMUX consumes a dc power of 150 mW from a 2-V supply voltage.     

0.18-μm CMOS 10-Gb/s multiplexer/demultiplexer ICs using currentmode logic with tolerance to threshold voltage fluctuation

A feedback MOS current mode logic (MCML) is proposed for the high-speed operation of CMOS transistors. This logic is more tolerant to the threshold voltage fluctuation than the conventional MCML and is suitable for gigahertz operation of deep-submicron CMOS transistors. Using this logic, 8:1 multiplexer (MUX) and 1:8 demultiplexer (DEMUX) ICs for optical-fiber-link systems have been fabricated with 0.18-μm CMOS transistors. The ICs are faster than conventional CMOS MUX and DEMUX ICs and their power consumption is less than 1/4 of that of the conventional 10-Gb/s MUX and DEMUX ICs made using Si bipolar or GaAs transistors     

A 40–44 Gb/s 3× Oversampling CMOS CDR/1:16 DEMUX

A CMOS CDR and 1:16 DEMUX fabricated in a low-cost 90 nm bulk CMOS process operates at 40-44 Gb/s and dissipates 910 mW. A quarter-rate hybrid phase-tracking/3times blind-oversampling architecture is used to improve jitter tolerance, reduce the need for high-power CML circuits, and enable frequency acquisition without a reference clock. Input data are sampled using a 24-phase distributed VCO, and a digital CDR recovers 16 bits and a 2.5 GHz clock from 48 demultiplexed samples spanning 16 UI. Conformance to the ITU-T G.8251 jitter tolerance mask (BER <10^-12 with a 2³¹-1 PRBS source) is demonstrated using both an on-chip and an external BERT.     

用于光纤传输系统的10Gbit/s CMOS 1:8分接器

采用TSMC 0.25μm RF CMOS工艺设计了一个应用于光纤传输系统的10Gbit/s CMOS 1:8分接器.整个系统采用树型结构,由3级1:2分接器、2级1:2分频器、级间缓冲器和输入、输出接口电路构成.为了适应高速度的要求,所有电路全都采用源极耦合场效应管逻辑来实现.使用SmartSpice进行了仿真,结果表明:在电源电压为3.3V时,电路的最高工作速率可以达到10Gbit/s,电路功耗约为800mW.     

A redundant multivalued logic for a 10-Gb/s CMOS demultiplexer IC

A redundant multivalued logic is proposed for high-speed communication ICs. In this logic, serial binary data are received and converted into parallel redundant multivalued data. Then they are restored into parallel binary data. Because of the multivalued data conversion, this logic makes it possible to achieve higher operating speeds than that of a conventional binary logic. Using this logic, a 1:4 demultiplexer (DEMUX, serial-parallel converter) IC was fabricated using a 0.18-/spl mu/m CMOS process. The IC achieved an operating speed of 10 Gb/s with a supply voltage of only 1.3 V and with power consumption of 38 mW. This logic may achieve CMOS communication ICs with an operating speed several times greater than 10 Gb/s.     

BiCMOS circuit technology for a 704 MHz ATM switch LSI

This paper describes BiCMOS level-converter circuits and clock circuits that increase VLSI interface speed to 1 GHz, and their application to a 704 MHz ATM switch LSI. An LSI with a high speed interface requires a BiCMOS multiplexer/demultiplexer (MUX/DEMUX) on the chip to reduce internal operation speed. A MUX/DEMUX with minimum power dissipation and a minimum pattern area can be designed using the proposed converter circuits. The converter circuits, using weakly cross-coupled CMOS inverters and a voltage regulator circuit, can convert signal levels between LCML and positive CMOS at a speed of 500 MHz. Data synchronization in the high speed region is ensured by a new BiCMOS clock circuit consisting of a pure ECL path and retiming circuits. The clock circuit reduces the chip latency fluctuation of the clock signal and absorbs the delay difference between the ECL clock and data through the CMOS circuits. A rerouting-Banyan (RRB) ATM switch, employing both the proposed converter circuits and the clock circuits, has been fabricated with 0.5 μm BiCMOS technology. The LSI, composed of CMOS 15 K gate logic, 8 Kb RAM, I Kb FIFO and ECL 1.6 K gate logic, achieved an operation speed of 704-MHz with power dissipation of 7.2 W     

Low-Power Circuits for a 2.5-V, 10.7-to-86-Gb/s Serial Transmitter in 130-nm SiGe BiCMOS

Low-power building blocks for a serial transmitter operating up to 86 Gb/s are designed and implemented in a 130-nm SiGe BiCMOS technology with 150-GHz SiGe f_T HBT. Design techniques are presented which aim to minimize high-speed building block power consumption. They include lowering the supply voltage by employing a true BiCMOS high-speed logic family, as well as reducing current consumption by trading off tail currents for inductive peaking. A serial transmitter testchip consuming under 1 W is fabricated and operation is verified up to 86 Gb/s at room temperature (92 Gb/s and 71 Gb/s at 0degC and 100degC, respectively). The circuit operates from a 2.5-V supply voltage, which is the lowest supply voltage for circuits at this data rate in silicon technologies reported to date.     

基于FPGA的千兆以太网设计

千兆以太网拥有传输速度快、传输距离远、稳定可靠等优点,是当前嵌入式系统的应用热点。FPGA拥有丰富的逻辑和管脚资源,常用于高速数据处理和通信的嵌入式系统。本文描述一个基于FPGA的千兆以太网系统的设计,本设计在硬件上主要使用千兆以太网PHY芯片88E1111和Altera公司的StratixⅢ系列的FPGA,在FPGA的逻辑上实现NiosⅡ嵌入式系统和以太网的MAC控制器,在NiosⅡ系统的软件上移植入MicroC／OS-Ⅱ实时多任务操作系统和NicheStackTCP／IP协议堆栈。在FPGA上实现千兆以太网设计,有效提高了系统的可靠性和集成性,充分扩展FPGA的功能。     

A 1.5-V full-swing BiCMOS logic circuit

A BiCMOS logic circuit applicable to sub-2-V digital circuits has been developed. A transiently saturated full-swing BiCMOS (TS-FS-BiCMOS) logic circuit operates twice as fast as CMOS at 1.5-V supply. A newly developed transient-saturation technique, with which bipolar transistors saturate only during switching periods, is the key to sub-2-V operation because a high-speed full-swing operation is achieved to remove the voltage loss due to the base-emitter turn-on voltage. Both small load dependence and small fan-in dependence of gate delay time are attained with this technique. A two-input gate fabricated with 0.3-μm BiCMOS technology verifies the performance advantage of TS-FS-BiCMOS over other BiCMOS circuits and CMOS at sub 2-V supply     

Ultrafast nonlinear interferometer (UNI)-based digital optical circuits and their use in packet switching

Digital optical logic circuits capable of performing bit-wise signal processing are critical building blocks for the realization of future high-speed packet-switched networks. In this paper, we present recent advances in all-optical processing circuits and examine the potential of their integration into a system environment. On this concept, we demonstrate serial all-optical Boolean AND/XOR logic at 20 Gb/s and a novel all-optical packet clock recovery circuit, with low capturing time, suitable for burst-mode traffic. The circuits use the semiconductor-based ultrafast nonlinear interferometer (UNI) as the nonlinear switching element. We also present the integration of these circuits in a more complex unit that performs header and payload separation from short synchronous data packets at 10 Gb/s. Finally, we discuss a method to realize a novel packet scheduling switch architecture, which guarantees lossless communication for specific traffic burstiness constraints, using these logic units.     

Gigabit-per-second, ECL-compatible I/O interface in 0.35-μm CMOS

This paper presents high-speed differential input and output (I/O) interface circuits for gigabit-per-second serial data communication. The circuits are implemented in a 3.3-V/0.35-μm CMOS process. Signal levels are compatible with industry standards for low-voltage positive emitter-coupled logic (ECL), with the possibility of ac-coupling to standard ECL systems. A differential open-drain circuit with pulsed bias and active pullups offers significantly improved speed performance for a transmitter and creates wide open eye patterns. Combining circuit techniques with the features of a submicrometer technology, the presented I/O blocks enable a full-CMOS chip to communicate with high-speed ECL-compatible systems and ease up a common I/O-related speed bottleneck. The circuits operate at 622 Mb/s (OC-12) and 1.24 Gb/s (OC-24) in a repeater and a retimer configuration. The asynchronous performance of the receiver and the transmitter was tested at rates up to 2.5 Gb/s     

A novel FPGA-programmable switch matrix interconnection element in quantum-dot cellular automata

The Quantum-dot cellular automata (QCA) is a novel nanotechnology, promising extra low-power, extremely dense and very high-speed structure for the construction of logical circuits at a nanoscale. In this paper, initially previous works on QCA-based FPGA’s routing elements are investigated, and then an efficient, symmetric and reliable QCA programmable switch matrix (PSM) interconnection element is introduced. This element has a simple structure and offers a complete routing capability. It is implemented using a bottom-up design approach that starts from a dense and high-speed 2:1 multiplexer and utilise it to build the target PSM interconnection element. In this study, simulations of the proposed circuits are carried out using QCAdesigner, a layout and simulation tool for QCA circuits. The results demonstrate high efficiency of the proposed designs in QCA-based FPGA routing.     

The Triptych FPGA architecture

Field-programmable gate arrays (FPGAs) are an important implementation medium for digital logic. Unfortunately, they currently suffer from poor silicon area utilization due to routing constraints. In this paper we present Triptych, an FPGA architecture designed to achieve improved logic density with competitive performance. This is done by allowing a per-mapping tradeoff between logic and routing resources, and with a routing scheme designed to match the structure of typical circuits. We show that, using manual placement, this architecture yields a logic density improvement of up to a factor of 3.5 over commercial FPGAs, with comparable performance. We also describe Montage, the first FPGA architecture to fully support asynchronous and synchronous interface circuits     

一种基于AND-LUT的混合FPGA结构

提出了一种混合FPGA新结构--新颖的AND-LUT阵列结构.其创新之处在于由可编程逻辑簇(Cluster)和相关的连接盒(CB)组成的可编程逻辑单元片(Tile)可以根据应用需要灵活地配置成PLA或LUT,前者较适合于高扇入逻辑,后者较适合于低扇入逻辑.因此,结合两者优点的新颖AND-LUT阵列结构在实现各种输入的用户逻辑时都能保持很好的逻辑利用率.MCNC电路测试结果进一步表明,同一逻辑电路在文中提出的混合FPGA新结构中实现与在基于LUT的对称FPGA结构中实现相比,面积平均可节省46%,因而大大提高了FPGA器件的逻辑利用率.     

一种基于AND-LUT的混合FPGA结构

提出了一种混合FPGA新结构--新颖的AND-LUT阵列结构.其创新之处在于由可编程逻辑簇(Cluster)和相关的连接盒(CB)组成的可编程逻辑单元片(Tile)可以根据应用需要灵活地配置成PLA或LUT,前者较适合于高扇入逻辑,后者较适合于低扇入逻辑.因此,结合两者优点的新颖AND-LUT阵列结构在实现各种输入的用户逻辑时都能保持很好的逻辑利用率.MCNC电路测试结果进一步表明,同一逻辑电路在文中提出的混合FPGA新结构中实现与在基于LUT的对称FPGA结构中实现相比,面积平均可节省46%,因而大大提高了FPGA器件的逻辑利用率.     

GaAs HBT's for high-speed digital integrated circuit applications

GaAs HBT technology has emerged as one of the most important developments for digital circuits operating at clock frequencies of 100 MHz and higher. High-speed frequency dividers operating as high as 34.8 GHz and VLSI circuits as complex as 32-b CPU's operating at 200-MHz clock rate have been demonstrated. This paper reviews the role of GaAs HBT technologies for high-speed digital IC applications. The requirements for high-speed IC's and the characteristics of various HBT device structures and logic families are discussed. A summary of published results of the ultrahigh-speed circuits and the status of several high-speed VLSI circuits are presented to provide a guide for future developments     

4-bit multiplexer/demultiplexer chip set for 40-Gbit/s optical communication systems

We have designed and fabricated a low-power 4:1 multiplexer (MUX), 1:4 demultiplexer (DEMUX) and full-clock-rate 1:4 DEMUX with a clock and data recovery (CDR) circuit using undoped-emitter InP-InGaAs HBTs. Our HBTs exhibit an f/sub T/ of approximately 150 GHz and an f/sub max/ of approximately 200 GHz at a collector current density of 50 kA/spl mu/m/sup 2/. In the circuit design, we utilize emitter-coupled logic and current-mode logic series gate flip-flops and optimized the collector current density of each transistor to achieve low-power operation at required high bit rates. Error-free operation at bit rates of up to 50 Gbit/s were confirmed for the 4:1 MUX and 1:4 DEMUX, which dissipates 2.3 and 2.5 W, respectively. In addition, the full-clock-rate 1:4 DEMUX with the CDR achieved 40-Gbit/s error-free operation.     

High-performance implanted base silicon bipolar technology for RFapplications

A 0.4 μm silicon bipolar technology for mixed digital/analog RF-applications is described. Without increasing the process complexity in comparison to current production technologies transit frequencies of 52 GHz, maximum oscillation frequencies of 65 GHz and minimum noise figures of 0.7 and 1.3 dB at 3 and 6 GHz are achieved. Emitter-coupled logic (ECL) ring oscillators have a minimum gate delay of 12 ps, the low power capability of the technology is proven by a current-mode logic (CML) power delay product of 5.2 fJ and a dynamic frequency divider operates up to 52 GHz. These results demonstrate the suitability of this technology for mobile communications up to at least 6 GHz and for high-speed optical data links at 10 Gbit/s and above     

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