We describe the design of ECL write circuits and a CMOS memory cell in an ECL-CMOS SRAM to achieve ultra-fast cycle time. Factors determining the write cycle are reduced by several novel circuit techniques and by optimizing the design of the write circuits and CMOS memory cell, thereby, enabling ultra-fast cycle time. Key techniques are a bit line overdriving, the use of an overshoot suppressing emitter follower and a WPG with a replica memory cell delayer. The 72-kb ECL-CMOS SRAM macro through which these techniques were implemented was fabricated using 0. 3-µm BiCMOS technology. The RAM macro achieves a short cycle time of 2 ns without sacrificing stable memory cell operation. These techniques thus provide SRAMs with a shorter cycle time in the cache memories of high performance computer systems.

This paper proposes a high-speed input and output buffering ATM switch, named Tandem-Crosspoint (TDXP) switch. The TDXP switch consists of multiple crossbar switch planes. These switch planes are connected in tandem at every crosspoint. Even if a cell can not be transmitted to an output port on the first plane, it has a chance to be transmitted on the next plane. Cell transmission is executed on each switch plane in a pipeline manner. Therefore, more than one cell can be transmitted to the same output port within one cell time slot, although the internal line speed of each switch is equal to the input /output line speed. The TDXP switch architecture has several advantages in implementation. First, the TDXP switch does not increase the internal line speed in eliminating Head-Of-Line (HOL) blocking. Second, since the TDXP switch employs a simple cell reading algorithm at the input buffer in order to retain the cell sequence, the TDXP switch does not require to rebuild the cell sequences at output buffers using time stamps, as is required by a parallel switch. These merits make implementing the high-speed ATM switch easy. Numerical results show that the TDXP switch can eliminate the HOL blocking effectively and achieve high throughput both for unicasting and multicasting traffic. This switch architecture is expected to enable the development of high-speed ATM switching systems that can realize over 1 Tb/s throughput in a cost-effective way.

This paper describes an MOS current-mode sample-and-hold (S/H) circuit that potentially operates with a sub-1. 5 V supply voltage, 20 MHz clock frequency, and less than 0. 1% linearity. A newly developed voltage-to-current converter suppresses the voltage change at an input terminal and achieves low-voltage operation with superior linearity. Sample switches are differentially placed at the inputs of a differential amplifier so that the feedthrough errors from switches cancel out. The MOS current-mode S/H circuit is designed and simulated using CMOS 0. 6 µm device parameters. Simulation results indicate that an operation with 20 MHz clock frequency, linearity error of less than 0. 1%, and 1 MHz input from a 1. 5 V power supply is achievable.

We present a collection of new network control protocols for high-speed networks that are geared to overcome some of the important drawbacks of existing protocols, namely (a) the inefficiencies of existing wait-for-reservation type of protocols for multigigabit wide area networks, (b) the implementation difficulties of credit-based flow control schemes, and (c) the packet resequencing problem of deflection-based schemes. Two of the protocols that will be outlined here were designed in the context of the DARPA sponsored Thunder and Lightning project, at the University of California, Santa Barbara, which is a continuing research effort to design and build a virtual-circuit switched, ATM-based, fiber optic network operating at link speeds of up to 40 Gb/s (see, for instance). The third protocol was designed in the context of MOST project, which is a project on (almost) all-optical switching supported by DARPA. All protocols achieve lossless transmission, efficient utilization of the capacity, and minimum pre-transmission delay for delay-sensitive traffic.

Optimization of InGaAs/InAlAs multiple quantum well structures for high-speed and low-driving modulation, as well as polarization insensitivity and low chirp, was investigated as a function of well thickness and strain magnitude. As a result, very short optical pulses with 4-6 ps was obtained using a low driving-voltage (<2. 0 Vpp) electroabsorption modulator module operating at a 40-GHz large signal modulation. Small chirp operation for low insertion loss (<8 dB from fiber-to-fiber) with prebias was also demonstrated and the product of the pulse width and the spectral width was estimated to be 0. 39 for a 5 ps pulse width that is nearly transform-limited.

This paper surveys low-power design techniques for Si bipolar Gbit/s LSIs. First, a total strategy for power reduction in bipolar LSIs is described. The power dissipation of Si bipolar LSIs can be minimized by reducing the supply voltage, switching and driving currents, the power of input and output circuits, and the equivalent "on" ratio. Widely spread activities from device to architecture levels are indispensable and each of the low-power techniques reduces power by a factor of about 0.5 to 0.7. The integration of these techniques is very important, and as a certain example of their effectiveness, an SOH signal processing LSI is demonstrated with a reduction factor of 1/10. Comparisons with other device technologies for low power characteristics reveal the low-power potential of bipolar LSIs in the Gbit/s region.

A 100MIPS high speed and low power fixed point Digital Signal Processor (DSP) has been developed applying 0.45µm CMOS TLM technology. The DSP contains a 16-bit32K full CMOS static RAM with a hierarchical low power architecture. The device is a RAM based DSP with a total of 4.2 million transistors and a new low power design and process which enabled an approximate 50% reduction in power as compared to conventional DSPs at 40 MHz. In order to cover very wide application requirements, this DSP is capable of operating at 1.0 V for DSP core and 3.3 V for I/O. This was achieved by new level shifter circuitry to interface with cost effective 3 V external commodity products and confirmed 80% of power reduction at Core VDD=2.0 V, I/O VDD=3.3 V at 40MHz. This paper describes the new features of the high speed and low power DSP.

This paper describes the design and architecture for a newly developed microprocessor suitable for consumer applications, which we call SuperH. To achieve both low-power and high-speed, the SuperH architecture includes 16-bit fixed length instruction code and several power saving features. The 16-bit fixed length instruction code makes the SuperH possible to achieve excellent code efficiency for the SPECint benchmarks when compared with conventional microcontrollers and RISC's for workstations and PC's. As a result, the SuperH provides almost the same code efficiency as that of 8-bit microcontrollers, and also achieves similar performance as that of RISC's with 32-bit fixed length instruction code. The SuperH also incorporates several power reduction techniques through the control of clock frequency and clock distribution. Thus, the 16-bit code format, power saving features, and other architectural innovations make the SuperH particularly proficient for portable multi-media applications.

Distributed multimedia applications are often sensitive to the Quality of Service (QoS) provided by the communication network. They usually require guaranteed QoS service, so that real-time communication is possible. However, searching a route with multiple QoS constraints is known to be a NP-complete problem. In this paper, we propose a new simple and efficient distributed QoS routing algorithm, called "DQoSR," for supporting real-time communication in high-speed networks. It searches a route that could guarantee bandwidth, delay, and delay jitter requirements. Routing decision is based only on the modified cost, hop and delay vectors stored in the routing table at each node and its directly connected neighbors. Moreover, DQoSR is proved to construct loop-free routes. Its worst case message complexity is O(|V|2), where |V| is the number of nodes in the network. Thus DQoSR is fast and scales well to large networks. Finally, extensive simulations show that average rate of establishing successful connection of DQoSR is very near to optimum (the difference is less than 0.4%).

In this paper, we consider conventional signaling link fault tolerance and error correction mechanisms to provide reliable services of mobile multimedia telecommunication network based on ATM (Asynchronous Transfer Mode) technology. Also, we propose an efficient signaling protocol interworking architecture and a reliable distributed interworking network architecture between SS7 based FPLMTS and ATM networks. Besides, we evaluate the performance of proposed method through computer simulation. According to the results, proposed signaling architecture shows efficient and fast fault restoration characteristics than conventional MTP-3/3b based network. Functional signaling protocol stack and network architecture of proposed fast rerouting mechanism provide reliable and efficient restoration performance in view of interworking between SS7 based FPLMTS and ATM networks.

This paper proposes a novel FEC (forward error correction) scheme for high-speed wireless systems aiming at mobile computing applications. The proposed scheme combines inner nonredundant error correction with outer parallel encoding random FEC for differentially detected QPSK (quadrature phase shift keying) signals. This paper, first, examines error patterns after the differential detection with nonredundant error correction and reveals that particular double symbol errors occur with relatively high probability. To improve the outer FEC performance degradation due to the double symbol errors, the proposed scheme uses I and Q channel serial to parallel conversion in the transmission side and parallel to serial conversion in the receiving side. As a result, it enables to use simple FEC for the outer parallel encoding random FEC without interleaving. Computer simulation results show the proposed scheme employing one bit correction BCH coding obtains a required Eb/No improvement of 1.2 dB at a Pe of 10-5 compared to that with the same memory size interleaving in an AWGN environment. Moreover, in a Rician fading environment where directional beam antennas are assumed to be used to improve the degradation due to severe multipath signals, an overall Eb/No improvement at Pe of 10-5 of 3.0 dB is achieved compared to simple differential detection when the condition of delay spread of 5 nsec, carrier to multipath signal power ratio of 20 dB and Doppler frequency at 20 GHz band of 150 Hz.

High-speed display of 3-D objects in virtual reality environments is one of the currently important subjects. Shape simplification is considered an efficient method. This paper presents a method of hierarchical cube-based segmentation for shape simplification and multiresolution model construction. The relations among shape simplification, resolution and visual distance are derived firstly. The first level model is generated from scattered range data by cube-base segmentation with the first level cube size. Multiresolution models are then generated by re-sampling polygonal patch vertices of each former level model with hierarchical cube-based segmentation structure. The results show that the algorithm is efficient for constructing multiresolution models of free-form shape 3-D objects from scattered range data and high compression ratio can be obtained with little noticeable difference during the visualization.

This paper discusses the features of SOI/CMOS circuits in comparison with bulk/CMOS circuits. We have to design circuits with small fan outs and short wires to take advantage of high-speed and low-power SOI/CMOS devices to their fullest. We can take advantage of the SOI/CMOS structure if the ratio of the source/drain capacitances to the gate capacitances is much greater in the load capacitance. Thus, we propose a new flip-flop circuit with a smaller gate capacitance. The flip-flop circuit operates 30% faster than the previous circuit at 2.0 V. We also propose a buffer circuit having less delay disparity between the complementary output signals. The buffer circuit has the delay disparity of 18 ps at 0.2 pF and 2.0 V. We fabricated an 8-bit frequency divider and a 4-bit demultiplexer using the proposed circuits and 0.35 µm SOI/CMOS process. The 8-bit frequency divider and the 4-bit demultiplexer operate at 2.8 GHz and 1.6 GHz, respectively, at 2.0 V.

A 167-MHz 1-Mbit CMOS synchronous cache SRAM was developed using 0.40-µm process technology. The floor plan was designed so that the address registers are located in the center of the chip, and high-speed circuits were developed such as the quasi latch (QL) sense amplifier and the one-shot control (OSC) output register. To maintain suitable setup and hold time margins, an equivalent margin (EM) design method was developed. 167-MHz operation was measured at a supply voltage of 2.5 V and an ambient temperature of 75. The same margins 1.1 ns of the setup time and hold time were measured for the specifications of a setup time of 2.0 ns and a hold time of 0.5 ns.

This paper presents Super-CMOS SRAM process technology that integrates bipolar and CMOS transistors in a chip while adding only one ion implantation step and no lithography mask steps to the conventional CMOS SRAM process. The Super-CMOS SRAM process therefore has the same process cost as the CMOS SRAMs, while it achieves higher access speeds. In order to demonstrate the Super-CMOS SRAM, we have developed a 3.3 V/5 V 256 kb SRAM using 0.4 µm Super-CMOS process technology. By applying bipolar transistors to the sense amplifier circuits, a high-speed access time of 5.8 ns with a 3.0 V power supply is successfully achieved.

In this paper, we give a concrete example of a 10-bit video rate ADC and introduce the effect of top-down design methodology with analog-HDL from the viewpoint of utilization techniques. First, we explain that analog top-down design methodology can improve chip performance by optimizing the architecture. Next, we concretely discuss the importance of modeling and verification. Verification of the full system does not require extracting all the information for each block at the transistor level in detail. The flexible verification method that we propose can provide good and fast full chip verification. We think analog top-down disign methodology will become increasingly more important from now on because "system-on-chip" requires one chip mixed-signal system LSIs.

Petrify is a tool for (1) manipulating concurrent specifications and (2) synthesis and optimization of asynchronous control circuits. Given a Petri Net (PN), a Signal Transition Graph (STG), or a Transition System (TS) it (1) generates another PN or STG which is simpler than the original description and (2) produces an optimized net-list of an asynchronous controller in the target gate library while preserving the specified input-output behavior. An ability of back-annotating to the specification level helps the designer to control the design process. For transforming a specification petrify performs a token flow analysis of the initial PN and produces a transition system (TS). In the initial TS, all transitions with the same label are considered as one event. The TS is then transformed and transitions relabeled to fulfill the conditions required to obtain a safe irredundant PN. For synthesis of an asynchronous circuit petrify performs state assignment by solving the Complete State Coding problem. State assignment is coupled with logic minimization and speed-independent technology mapping to a target library. The final net-list is guaranteed to be speed-independent, i.e., hazard-free under any distribution of gate delays and multiple input changes satisfying the initial specification. The tool has been used for synthesis of PNs and PNs composition, synthesis and re-synthesis of asynchronous controllers and can be also applied in areas related with the analysis of concurrent programs. This paper provides an overview of petrify and the theory behind its main functions.

Signal Transition Graphs (STG's) are Petri nets, which were introduced to represent a behavior of asynchronous circuits. To derive logic functions from an STG, the reachability graph should be constructed. In the verification of STG's some method based on an Occurrence net (OCN) and its prefix, called an unfolding, has been proposed. OCN's can represent both causality and concurrency between two nodes by net structure. In this paper, we propose a method to derive a logic function by generating sub state space of a given STG using the structural properties of OCN.

This paper proposes a synthesis method to obtain speed-independent asynchronous circuits directly from signal transition graph (STG) specifications with single cycle signals which can be non-persistent and have free-choice operations. The resulting circuits are implemented with basic gates and asynchronous latches, and operate correctly under finite but unbounded gate delays and the zero wire delay assumptions. The proposed method introduces 5 types of lock relations to implement a non-persistent STG. A non-persistent STG can be implemented if every non-persistent signal to a signal t is super-locked with t. The resulting circuits are optimized by extracting of literals, mapping onto asymmetric C-elements, etc. Experimental results show that the proposed synthesis method outperforms the existing synthesis systems such as SYN and SIS.

A high-speed silicon-on-insulator (SOI) of a 1/8 frequency divider and a 64-bit adder were realized using an optimized gate-overlapped LDD and a self-aligned titanium silicide (TiSi2) source-drain structure. The advantages of the delay time and power consumption were analyzed by circuit simulation. The maximum operation frequency of the SOI divider is 2.9 GHz at 3.3 V. The SOI divider operates about 1.6 times faster than the bulk-Si divider. The power consumption of the SOI divider at the maximum operating frequency is about 60% of that of the bulk divider. On the other hand, the speed of the SOI adder is 1.9 nsec at 3.3 V. The SOI adder speed is about 1.3 times faster than the bulk adder. The power consumption of the SOI adder is about 80% of that of the bulk divider. It was found that the high speed, low power features of the SOI divider were due to the pass transistor which had low junction capacitance and little substrate bias effects, in addition to the low wiring capacitance and low fanout capacitance compared to the bulk adder. As a result, it is suggested that SOI circuits using pass transistor have a potential for GHz level systems and it is expected they will be applied to handy communication systems and portable computers used in the multimedia era.