On the limits of electronic ATM switching

This article discusses the principal advantages and limitations of electronic switching in asynchronous transfer mode (ATM) networks. Key design parameters of ATM switch implementations are defined, and their relationships with respect to performance, complexity, and cost are modeled and discussed. Design and implementation experience is reported on a very high-performance four-input, four-output ATM switch that has been designed as part of the DARPA-sponsored “Thunder and Lightning” project at the University of California, Santa Barbara. This research project is focused on the design and prototype demonstration of ATM links and electronic switches operating at 40 Gb/s per link (TDM), with potential scalability to 100 Gb/s. Such aggressive link rates are near the implementation limits for electronic ATM switches; they place severe requirements on switch architecture, particularly the buffering scheme     

Scalable optoelectronic ATM networks: the iPOINT fully functionaltestbed

Our prototype of a fully-functional asynchronous transfer mode (ATM) switch validates the design of a 128 Gb/s optoelectronic ATM switch. Optoelectronics, rather than all optical components, are used to simultaneously address all of the specific requirements mandated by the ATM protocol. In this paper, we present the Illinois pulsar-based optical interconnect (iPOINT) testbed, and present our results obtained for the prototype switch in a working environment consisting of an optical network of Sun SPARC Stations and other local and wide-area ATM switches     

A 2.5 Gb/s ATM switch chip set

The design and implementation of two application specific integrated circuits used to build an ATM switch are described. The chip set is composed of the CMC which is an input/output processor of ATM cells implemented on a BICMOS 0.7 μm technology and the ICM, a 0.7 μm CMOS IC, that performs cell switching at 68 MHz. The ATM switch exploits parallelism and segmentation to perform 2.5 Gb/s switching per input/output. The main advantage of the high-speed link rates in the range of Gb/s, is the exploitation of statistical gain with bursty high peak rate sources. Another feature of the high speed ATM switches is that the number of interface devices and stages is reduced on an ATM network. To demonstrate the usefulness of the switch, an evaluation of the network efficiency improvement by using statistical gain is presented in the paper     

A 622-Mb/s 8×8 ATM switch chip set with shared multibufferarchitecture

An asynchronous transfer mode (ATM) switch chip set, which employs a shared multibuffer architecture, and its control method are described. This switch architecture features multiple-buffer memories located between two crosspoint switches. By controlling the input-side crosspoint switch so as to equalize the number of stored ATM cells in each buffer memory, these buffer memories can be treated as a single large shared buffer memory. Thus, buffers are used efficiently and the cell loss ratio is reduced to a minimum. Furthermore, no multiplexing or demultiplexing is required to store and restore the ATM cells by virtue of parallel access to the buffer memories via the crosspoint switches. Access time for the buffer memory is thus greatly reduced. This feature enables high-speed switch operation. A three-VLSI chip set using 0.8-μm BiCMOS process technology has been developed. Four aligner LSIs, nine bit-sliced buffer-switch LSIs, and one control LSI are combined to create a 622-Mb/s 8×8 ATM switching system that operates at 78 MHz. In the switch fabric, 155-Mb/s ATM cells can also be switched on the 622-Mb/s port using time-division multiplexing     

A Shared Buffer Memory ATM Access Switch

１ＩｎｔｒｏｄｕｃｔｉｏｎＴｈｅＡｓｙｎｃｈｒｏｎｏｕｓＴｒａｎｓｆｅｒＭｏｄｅ（ＡＴＭ）ｉｓｃｏｎｓｉｄｅｒｅｄａｐｒｏｍｉｓｉｎｇｔｅｃｈｎｉｑｕｅｔｏｔｒａｎｓｆｅｒａｎｄｓｗｉｔｃｈｖａｒｉｏｕｓｋｉｎｄｓｏｆｍｅｄｉａ，ｓｕｃｈａｓｔｅｌｅ...     

Large-scale WDM star-based photonic ATM switches

This paper describes the large-scale photonic asynchronous transfer mode (ATM) switching systems being developed in NTT Laboratories. It uses wavelength division multiplexing (WDM) techniques to attack 1 TB/s throughput. The architecture is a simple star with modular structure and effectively combines optical WDM techniques and electrical control circuits. Recent achievements in important key technologies leading to the realization of large-scale photonic ATM switches based on the architecture are described. We show that we can obtain a 320 Gb/s system that can tolerate the polarization and wavelength dependencies of optical devices. Our experiments using rack-mounted prototypes demonstrate the feasibility of our architecture. The experiments showed stable system operation and high-speed WDM switching capability up to the total optical bandwidth of 12.8 nm, as well as successful 10 Gb/s 4×4 broadcast-and-select and 2.5 Gb/s 16×16 wavelength-routing switch operations     

A new architecture of photonic ATM switches

A photonic asynchronous transfer mode (ATM) switch architecture for ATM operation at throughputs greater than 1 Tbit/s is proposed. The switch uses vertical-to-surface transmission electrophotonic devices (VSTEPs) for the optical buffer memory, and an optical-header-driven self-routing circuit in contrast with conventional photonic ATM switches using electrically controlled optical matrix switches. The optical buffer memory using massively parallel optical interconnections is an effective solution to achieve ultra-high throughput in the buffer. In the optical-header-driven self-routing circuit, a time difference method for a priority control is proposed. For the optical buffer memory, the write and read operations to and from the VSTEP memory for 1.6 Gbit/s, 8-bit optical signal are confirmed. The optical self-routing operation and priority control operation by the time difference method in the 4×4 self-routing circuit were performed by 1.6-Gbit/s 256-bit data with a 10-ns optical header pulse     

A photonic front-end processor in a WDM ATM multicast switch

Dense wavelength-division multiplexing (DWDM) technology has provided tremendous transmission capacity in optical fiber communications. However, switching and routing capacity is still far behind transmission capacity. This is because most of today's packet switches and routers are implemented using electronic technologies. Optical packet switches are the potential candidate to boost switching capacity to be comparable with transmission capacity. In this paper, we present a photonic asynchronous transfer mode (ATM) front-end processor that has been implemented and is to be used in an optically transparent WDM ATM multicast (3M) switch. We have successfully demonstrate the front-end processor in two different experiments. One performs cell delineation based on ITU standards and overwrites VCI/VPI optically at 2.5 Gb/s. The other performs cell synchronization, where cells from different input ports running at 2.5 Gb/s are phase-aligned in the optical domain before they are routed in the switch fabric. The resolution of alignment is achieved to the extent of 100 ps (or 1/4 bit). An integrated 1×2 Y-junction semiconductor optical amplifier (SOA) switch has been developed to facilitate the cell synchronizer     

Physical performance limits for shared buffer ATM switches

Performance studies, linking ATM switch capabilities to physical limitations imposed by integrated circuit technology, have been scarce. This paper explores trends in circuit capabilities, and makes projections toward the 0.25-μm technologies that will be available to all switch designers in the year 2000. The limits imposed by circuit technology are applied to shared buffer ATM switches. We determine requirements and physical limits for buffer capacity, buffer throughput, chip I/O throughput, and power dissipation. As a result, we are able to project chip counts, aggregate switch throughputs, and switch dimensions. As well, performance capabilities of single-chip shared buffer switches are estimated. A single-chip shared buffer switch implemented in 0.25-μm technology will be capable of an aggregate throughput of 1.3 Tb/s, will accomplish almost arbitrarily low cell loss rates for bursty traffic, and may be integrated together with translation tables supporting hundreds of connections per port     

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     

Performance and buffering requirements of Internet protocols overATM ABR and UBR services

ATM networks are quickly being adopted as backbones over various parts of the Internet. This article studies the dynamics and performance of the TCP/IP protocol over the ABR and UBR services of ATM networks. Specifically the buffering requirements in the ATM switches as well as the ATM edge devices. It is shown that with a good switch algorithm, ABR pushes congestion to the edges of the ATM network while UBR leaves it inside the ATM portion. As a result, the switch ABR buffer requirement for zero-packet-loss high-throughput TCP transmission is a sublinear function of the number of TCP connections     

新型光缓存器和2×622Mb／s ATM光交换系统

本文给出一种新型的光缓存器的结构，以解决在ＡＴＭ光交换中的信元碰撞问题。这种缓存器由光纤延迟线、光波导开关阵及非线性半导体光放大器构成。文中还报告了一种用于交换各用户不同速率的信元（可达６２２Ｍｂ／ｓ）的ＡＴＭ光交换实验系统，系统的总容量为１．２Ｇｂ／ｓ。     

The single-queue switch: a building block for switches withprogrammable scheduling

We introduce a new approach to ATM switching. We propose an ATM switch architecture which uses only a single shift-register-type buffering element to store and queue cells, and within the same (physical) queue, switches the cells by organizing them in logical queues destined for different output lines. The buffer is also a sequencer which allows flexible ordering of the cells in each logical queue to achieve any appropriate scheduling algorithm. This switch is proposed for use as the building block of large-stale multistage ATM switches because of low hardware complexity and flexibility in providing (per-VC) scheduling among the cells. The switch can also be used as scheduler/controller for RAM-based switches. The single-queue switch implements output queueing and performs full buffer sharing. The hardware complexity is low. The number of input and output lines can vary independently without affecting the switch core. The size of the buffering space can be increased simply by cascading the buffering elements     

A high-speed-retry banyan switch architecture for giga-bit-rate BISDN networks

This paper proposes a high-speed ATM switch architecture for handling cell rates of several Gb/s in a broadband communication switching system or cross-connect system. The proposed switch architecture, named the high-speed-retry banyan switch, employs a bufferless banyan network between input and output buffers; a cell is repeatedly transmitted from an input buffer until it can be successfully transmitted to the desired output buffer. A simple cell-retransmission algorithm, is employed as is a ring-arbitration algorithm for cell conflict. They are suitable for FIFO type buffers and bufferless highspeed devices. Good traffic characteristics which are independent of switch size are achieved for an internal speed ratio of only four times the input line speed. A prototype system with the internal speed of 1·2 Gb/s is constructed in order to confirm the basic operation of the high-speed-retry banyan switch. The prototype system, even in its present state, could be used to realize a giga-bit-rate BISDN switching system.     

An approximate analysis of shared‐buffer channel‐grouped ATM switches under imbalanced traffic

Grouping output channels in a shared‐buffer ATM switch has shown to provide great saving in buffer space and better throughput under uniform traffic. However, uniform traffic does not represent a realistic view of traffic patterns in real systems. In this paper, we extend the queuing analysis of shared‐buffer channel‐grouped (SBCG) ATM switches under imbalanced traffic, as it better represent real‐life situations. The study focuses on the impact of the grouping factor and other key switch design parameters on the performance of such switches as compared to the unichannel allocation scheme in terms of cell loss probability, throughput, mean cell delay and buffer occupancy. Numerical results from both the analytical model and simulation are presented, and the accuracy of the analysis is presented. Copyright © 2005 John Wiley & Sons, Ltd.     

32×32 shared buffer type ATM switch VLSIs for B-ISDNs

A set of 0.8 μm CMOS VLSIs developed for shared buffer switches in asynchronous transfer mode (ATM) switching systems is described. A 32×32 unit switch consists of eight buffer memory VLSIs, two memory control VLSIs, and two commercially available first in first out (FIFO) memory LSIs. Using the VLSIs, the switch can be mounted on a printed board. To provide excellent traffic characteristics not only under random traffic conditions but also under burst traffic conditions, this switch has a 2-Mb shared buffer memory, the largest reported to date. which can save 4096 cells among 32 output ports. This switch has a priority control function to meet the different cell loss rate requirements and switching delay requirements of different service classes. A multicast function and a 600 Mb/s link switch architecture, which are suitable for ATM network systems connecting various media, and an expansion method using the 32×32 switching board to achieve large-scale switching systems such as 256×256 or 1024×1024 switches are discussed     

Cell loss analysis and design trade-offs of nonblocking ATMswitches with nonuniform traffic

In practical ATM switch design, a proper dimensioning of buffer sizes and a cost effective selection of speed-up factor should be considered to guarantee a specified cell loss requirement for a given traffic. Although a larger speed-up factor provides better throughput for the switch, increasing the speed-up factor involves greater complexity and cost. Hence, it may not be cost effective to increase the speed-up factor for 100% throughput. Moreover, with a given buffer budget, an increase in the speed-up factor beyond a certain value only adds to the cell loss. The paper addresses design trade-offs existing between finite input/output buffer sizes and speed-up factor in a nonblocking ATM switch. Another important issue is the adverse effect on cell loss performance caused by nonuniform traffic (different traffic intensity and unevenly distributed routing). The paper analyzes cell loss performance of ATM switches with nonuniform traffic, and examines the effect of each nonuniform traffic parameter. The authors also provide an algorithm for effective buffer sharing that alleviates the performance degradation caused by traffic nonuniformity     

Optical input buffers for the HiPower photonic ATM switch-analysisand experiments

We describe an optical input buffer for the HiPower photonic ATM switch. This buffer can control the cell throughput in accordance with back pressure signals and incoming optical cells. We analyze the cell loss probability of the optical input buffer. Only a small buffer size of five is needed to obtain a cell loss probability of less than 10^-15 with 1024 ports. Experimental 10 Gb/s operation using optical fiber delay lines with gate control circuits shows that the bit error rate of the buffer is less than 10^-12     

Large-scale ATM multistage switching network with shared buffermemory switches

The configuration of an asynchronous transfer mode (ATM) switch architecture using a shared buffer memory switch (SBMS) is discussed. The scaling factors of the ATM switching network under a condition of mixed applications, including a conventional mix and telecommunication with video, are analyzed. The use of the SBMS as the unit switch for a multistage switching network is examined. A prototype system and its performance evaluation and experimental data are presented. The data indicate excellent performance under a burst cell arrival condition. The buffer size of the SBMS can be reduced in comparison with that of an individual (nonshared) buffer memory switch. A configuration for a large-scale ATM switching network with multistage switches is proposed