An expandable time-division circuit switching LSI and networkarchitecture for broadband ISDN

A broadband network architecture is proposed that integrates multimedia services, such as data, video, and telephony information, using 52-Mb/s based STM-paths at the user network interface (UNI). The user can access any new service via the STM-based access network via either synchronous transfer mode (STM) switching or asynchronous transfer mode (ATM) switching. STM circuit switching supports long duration, constant bandwidth data transfer services such as video and high-definition television (HDTV) distribution and will also be used for the crossconnect system. Circuit switching can provide transparent transmission during long connection periods. This paper also proposes an expandable time-division switch architecture, an expandable time-division switching LSI, and an expandable switching module for small to large size system applications. The proposed time-division switching LSI, module, and system handle 52-Mb/s bearer signals and have throughputs of 2.4 Gb/s, 10 Gb/s, and 40 Gb/s, respectively. The time-division switch realizes video distribution with 1:n connections. Finally, a local switching node that features an expandable 52-Mb/s time-division circuit switching network is shown for multimedia access networking     

Newly structured expandable 52-Mbit/s, 48-channel time-division switching LSI with 2.4 Gbit/s throughput

An expandable Si bipolar 2.4 Gbit/s throughput, 52 Mbit/s 48-channel time-division switching LSI system is described. A high-throughput of 2.4 Gbit/s and a power-dissipation of 5.3 W are achieved by adopting a low-voltage swing four-serial-gated differential bipolar circuit design and super self-aligned process (SST-1A) logic-in-memory LSI technology. This LSI is applicable to the digital video time-division switching and digital crossconnect systems of future B-ISDN.<>     

20.8 Gb/s GaAs LSI self-routing switch for ATM switching systems

An 8×8 self-routing hardware switch providing 20.8 Gb/s throughput has been developed for asynchronous transfer mode (ATM) switching systems. The basic architecture of this switch is a Batcher-Banyan network. A new mechanism for data processing and distributing high-speed signals is proposed. This switching system consists of three LSIs using a 0.5-μm gate GaAs MESFET technology. These LSIs are a switching network LSI for exchanging packet cells with eight cell channels, a negotiation network for screening of cells destined for the same output port, and a demultiplexer LSI for converting the cell streams from the switching network LSI to the eight streams per channel. These LSIs are mounted in a 520-pin multichip module package. The total number of logic gates is 13.3 k, and the power dissipation is 24 W. The switching system fully operates at a data rate of 2.6 Gb/s, and its throughput is 20.8 Gb/s     

A circuit design for 2-Gbit/s Si bipolar crosspoint switch LSIs

An 8×8 and an expandable 16×16 crosspoint switch LSI utilizing a new circuit design and super self-aligned process technology (SST-1A) are discussed. The LSIs successfully switched with a bit error rate of less than 10^-9 at 2.5 Gb/s using a 2⁹-1 pseudorandom NRZ sequence. Pulse jitter was limited to less than 80 ps at 1.2 Gb/s by utilizing a small internal voltage swing (225 mV) employing a differential CML cell, including a selector. The LSIs have an ECL-compatible interface, -4-V and -2-V power supply voltages, and a power dissipation of less than 0.9 W for the 8×8 LSI and 2.8 W for the expandable 16×16 LSI     

2 Gbit/s, 16*16 expandable high-speed space-division-switch LSI using SST

A Si bipolar 2 Gbit/s 16*16 high-speed space-division-switch LSI is described. High-speed operation of 2 Gbit/s and low-power dissipation of 2.8 W are achieved by adopting a new expandable structure, a very low voltage swing-differential bipolar circuit design and a super self-aligned process technology (SST-1A). This LSI is applicable to future B-ISDN HDTV switching systems.<>     

CMOS gigabit-per-second switching

An analysis and experimental results for a 600-Mb/s 1.2-μm CMOS space switch chip are provided. The high bit rate is achieved with a tree architecture, which is relatively insensitive to on-chip stray capacitance. Computer simulations indicate that bit rates in excess of 1 Gb/s are achievable with 1-μm CMOS and circuit/layout optimization. An obstacle to achieving high bit rate is crosstalk, which is primarily caused by chip packaging and not by the chip itself. Even the best discrete packaging technologies result in excessive crosstalk when 32 outputs switch simultaneously at 600 Mb/s. Tolerable crosstalk was achieved by limiting outputs to two per power supply pin. A major increase in bit rate can be obtained by switching bytes (8 b parallel) of information. This requires on-chip information storage and reclocking to maintain synchronization between the eight parallel bits. Experiments with a second-generation synchronous switch chip have demonstrated switching at 311 MB/s, which corresponds to an STS-48 rate of 2.488 Gb/s     

Scalable 10 Gbit/s 4×20.25 μm CMOS/SIMOX ATM switch LSIcircuit based on distributed contention control

A scalable 10 Gbit/s 4×2 ATM switch LSI circuit has been fabricated. It employs a new distributed contention control technique that makes the LSI circuit expandable. To increase the LSI circuit throughput, 0.2 μm CMOS/SIMOX (separation by implanted oxygen) technology is used. It allows the LSI circuit to offer 221 I/O pins, an operating speed of 1.25 Gbit/s and 7 W power consumption     

Advanced architecture for a one-chip 16×16 digital switch

A one-chip 16×16 digital switch (SWEL) is presented which is designed for use in a wide variety of applications, ranging from digital mobile radio and satellite applications, to PCM switching systems (integrated services digital network). It provides a compact, low-power solution to perform in channel-controlled switching of 64-kb/s or 2-Mb/s channels. Both architecture and design issues are discussed in detail; a 1.2 μm double metal CMOS technology was employed in the design. The multiplexed architecture allows for easy implementation of new application-specific requirements, making this circuit the cornerstone for new telecommunication switching products     

A high-speed CMOS circuit for 1.2-Gb/s 16*16 ATM switching

The authors describe a 0.7- mu m CMOS asynchronous transfer mode (ATM) switch circuit of 350 K transistors, the kernel of a fully autonomous 16*16 ATM switching matrix devoted to telecommunications. This matrix is able to switch ATM multiplexes with a throughput of up to 1.2 Gb/s per access line, and was implemented using 16 receiver/transmitter circuits and a control circuit. The architecture of the ATM switch circuit is based on a large embedded and shared dual-access memory. Each chip processes 4-b slices of each incoming multiplex. Seven such chips working in parallel are enough to achieve standard ATM cell switching. Up-to-date test features, such as boundary scan, built-in self-test, and redundancy were implemented in the circuit.<>     

A 9.6-Gb/s HEMT ATM switch LSI with event-controlled FIFO

An asynchronous-transfer-mode (ATM) switch LSI was designed for the broadband integrated services digital network (B-ISDN) and fabricated using 0.6-μm high-electron-mobility-transistor (HEMT) technology. To enhance the high-speed performance of direct-coupled FET logic (DCFL), event-controlled logic was used instead of conventional static memory for the first-in first-out (FIFO) buffer circuit. The 4.8-mm×4.7-mm chip contains 7100 DCFL gates. The maximum operating frequency was 1.2 GHz at room temperature with a power dissipation of 3.7 W. The single-chip throughput was 9.6 Gb/s. An experimental 4-to-4 ATM switching module using 16 switch LSIs achieved a throughput of 38.4 Gb/s     

Architecture, design, and modeling of the OPSnet asynchronous optical packet switching node

An all-optical packet-switched network supporting multiple services represents a long-term goal for network operators and service providers alike. The EPSRC-funded OPSnet project partnership addresses this issue from device through to network architecture perspectives with the key objective of the design, development, and demonstration of a fully operational asynchronous optical packet switch (OPS) suitable for 100 Gb/s dense-wavelength-division multiplexing (DWDM) operation. The OPS is built around a novel buffer and control architecture that has been shown to be highly flexible and to offer the promise of fair and consistent packet delivery at high load conditions with full support for quality of service (QoS) based on differentiated services over generalized multiprotocol label switching.     

A 1.5 Gb/s 8×8 cross-connect switch using a time reservationalgorithm

An input queuing type switching architecture that uses a high-performance contention resolution algorithm to achieve high-speed and large-capacity cross-connect switching is presented. The algorithm, called the time reservation algorithm, features time scheduling and pipeline processing. The performance of this switch is evaluated by computer simulation. The throughput of this switch is about 90%, without requiring high internal operation speeds. Three LSI designs are developed to verify the feasibility of the high-speed switch. They are the input buffer controller LSI, the contention-resolution module LSI, and the space-division switching LSI. The LSIs were constructed with an advanced Si-bipolar high-speed process. Also, 8×8 cross-connect switching boards are introduced. The measured maximum port speed is 1.55 Gb/s     

A scalable ATM switching system architecture

The architecture of an asynchronous transfer mode (ATM) switching system for prototype applications is presented. The general concept to upgrade the existing ISDN switch with an ATM module is introduced, and the building blocks of this ATM module are described in detail. Switching of ATM cells is performed in a single application-specific integrated circuit (ASIC). ASICs can be cascaded to form large switching modules. Peripheral modules interface the ATM switch to external transmission systems and perform all ATM-related functions, including means for redundancy of the switching network. The redundancy scheme tolerates single failures without affecting the user information. A switching network architecture is shown to be capable of fulfilling varying demands in terms of the number of ports for ATM switches and cross connects, concentrators, and multiplexers     

Multiwavelength networks and new approaches to packet switching

The author shows how the bandwidth available through the use of multiwavelength optical-fiber technology can be used to achieve novel large-capacity switching systems to address anticipated switching bottlenecks. He does so by describing the features and network applications of a specific multiwavelength network, the Bellcore LAMBDANET packet switch. The discussion is then extended to a number of recent proposals for switching fabrics based on this new multiwavelength technology. The particular technologies he discusses are: the photonic knockout switch, a proposal similar to the concept of the LAMBDANET, but not requiring N receivers at each node; the FOX (fast optical cross-connect), an active wavelength routing approach; the ShuffleNet architecture; the HYPASS and BHYPASS switches; the coherent wavelength division λ switch; and the Bellcore Star-Track multicast switch     

A 0.8-μm BiCMOS ATM switch on an 800 Mb/s asynchronous bufferedbanyan network

An experimental element switch LSI for asynchronous transfer mode (ATM) switching systems was realized using 0.8-μm BiCMOS technology. The element switch transfers cells asynchronously when used in a buffered banyan network. Three key features of the element switch architecture are CASO buffers to increase the throughput, a synchronization technique called SCDB (synchronization in a clocked dual port buffer) to make possible asynchronous cell transmission on the element switches with simple hardware, and an implementation technique for virtual cut through, called CELL-BYPASS, which lowers the latency. An implementation of elastic store is proposed to achieve high-speed synchronization with simple hardware. The element switch LSI adopts an emitter-coupled-logic (ECL) interface. The maximum operation frequency of the element switch LSI is 200 MHz (typical)     

Optimum switching architectures using D-fiber opticalspace switches

An optical space switch based on D-fibers has been fabricated and its use in switching networks investigated. The characteristics of a switching network depend not only on the nature of the switches used, but also on the architecture utilized. In general, architectural complexity can be used in a trade with switch specification to achieve a given network behavior. Several architectures are reviewed and their consequences on the switch specification evaluated. The principles of a D-fiber space switch are described, and the switching characteristics predicted and measured. The characteristics of the switch, within its optimum architecture, enable a fully transparent network, i.e. totally nonblocking with minimum restriction on optical bandwidth, to be realized. The limits to the size of such a network are calculated using the measured characteristics of a switch fabricated in the laboratory     

High-Speed Digital Switching Technology Using Space-Division-Switch LSI's

NTT is planning a high-speed broad-band switching network that offers high-speed digital and 4 MHz video services. This paper discusses the hardware design of the high-speed space-division digital switching network and requirements for a switch LSI. In addition, the design and measured performance of a 32 × 32 CMOS space-division-switch LSI are described. In this network, video signals are converted into 32 Mbit/s digital signals by band-compression technology. In order to switch such digital signals, space-division switches are more advantageous than time-division switches. This is because time-division switches cannot multiplex many channels at that bit rate. Furthermore, the use of the space-division-switch LSI is the most effective way to miniaturize the switching system.     

Multi-stage switching system using optical WDM grouped links based on dynamic bandwidth sharing

A three-stage Clos switch architecture is attractive because of its scalability. From an implementation point of view, it allows us to relax the cooling limitation, but there is a problem interconnecting different stages. This article presents a three-stage switching system that uses optical WDM grouped links and dynamic bandwidth sharing. We call it a WDM grouped-link switch. The introduction of WDM makes the number of cables used in the system proportional to the switch size. Dynamic bandwidth sharing among WDM grouped links prevents the statistical multiplexing gain offered by WDM from falling even if the switching system becomes large. The WDM grouped-link switch uses cell-by-cell wavelength routing. A performance evaluation confirms the scalability and cost-effectiveness of this switch. An implementation of the WDM grouped link and a compact planar lightwave circuit platform is described. This architecture allows us to expand the throughput of the switching system up to 5 Tb/s.     

1 Gbit/s, 32*32 high-speed space-division switching module for broadband ISDN using SST LSIs

A high-speed 32*32 space-division switching module for high-definition TV broadcasting and switching systems is described. It employs a newly developed Si-bipolar SST 8*8 switch LSI, high-speed peripheral ICs and a high-speed impedance-controlled board. The module is capable of a 1.0 Gbit/s signal speed using 1:1 and 1:n connections.<>     

基于通用改进型扩展Benes型光开关的智能光交换模块

分析了基于通用改进型扩展Benes型光开关的动态交换特性,阐述了核心光交换控制电路的设计,并组建了实验网络.采用一种巧妙的编程方法,实现了GDMB光开关矩阵的动态光路交换,利于实现高速、可靠的数据交换.