This paper describes the architecture and the performances of a GaAs 88 self-routing switch LSI for ATM switching system. The communication system such as broadband integrated sevices digital network (B-ISDN) requires the hardware switch LSI which exchanges packet cells at a date rate up to several Gb/s. GaAs LSIs are suitable for such application because of its high speed operation and low power dissipation. To clarify the feasibility of GaAs LSI, an 88 self-routing switch LSI is fabricated using 0.5 µm gate GaAs MESFETs and its oerformances are examined. This LSI consists of a switching network for exchanging the packet cells and the "NEMAWASHI" network which detects the cell destined to the same output port. The basic network architecture is a self-routing switch using Batcher-Banyan network. This network consists of basic 22 switch element. Since each element switches the route accorging to the destination of the input cells, self-routing operation is performed without the external circuit for routing control. The LSI is fabricated using 0.5 µm gate GaAs MESFETs. 7003 logic gate are integrated on the chip of 8.2 mm7.4 mm. To reduce the impedance of ground line on the chip and to obtain the enough noise margin, the third level interconnection with low sheet resistance is implemented. As the results of functional evalution, the full function of switching network and "NEMAWASHI" network are verified. Maximum operation speed of 1 GHz is obtained.

The effectiveness of traffic shaping for VBR traffic is analyzed. Evaluation results prove that traffic shaping can improve link efficiency for most forms of bursty VBR traffic and that link efficiency gains of more than 250% can be expected without the shaping delay imposing any significant QOS deterioration. Traffic shaping increases the link efficiency to about 80% for traffic with short burst repetition periods. The traffic shaping techniques and analytical results described herein can be employed in the traffic management of future B-ISDN/ATM networks.

Fiber-optic subscriber loops are beginning to be constructed worldwide as an infrastructure for the 21st century. Making the most of the superior transmission capabilities of optical fiber cable, high-speed and broadband services such as so-called Broadband-ISDN (B-ISDN) services are expected to be achieved. We review current trends in fiber-optic systems and discuss how fiber-optic subscriber loops should be implemented from the points of view of services and technology. First, prospective services offered over fiber-optic subscriber loops and resulting requirements for such loops are presented. Various kinds of services produced through fiber-optic subscriber loops will further develop the information-oriented society and have a major influence not only on the industrial world but on family life as well. Next, basic concepts of totally fiber-optic subscriber loops and proposals for shifting from the existing metallic cable network to totally fiber-optic subscriber loops are discussed. In this regard, we must consider the advantages of optical fiber cables and improve upon the disadvantages of the existing metallic cable network. In particular, a Digital Loop Carrier (DLC) system or a Passive Double Star (PDS) have been proposed to shift from the existing metallic cable network to totally fiber-optic subscriber loops effectively and economically. Finally, line configuration topology and latest fiber-optic technologies such as high-count cable, construction techniques and operation systems for use in achieving totally fiber optic subscriber loops are shown. We believe a single star configuration is the most appropriate for totally fiber-optic subscriber loops.

This paper proposes a next-generation narrow-band ISDN (N-ISDN), including a suitable network and network node architecture. The proposed N-ISDN allows every subscriber to use H0/HI-class calls as easily as present telephone calls, and could rapidly expand ISDN services to all the subscribers of a public network. The present status of ISDN is first analyzed then the need for popularization of H0/HI-call services is discussed. The proposed key technologies to popularize HO/HI services are (1) on-chip integration of ISDN switching systems, (2) distribution of small on-chip switching systems over the subscriber switching area, (3) H0-based trunk circuit networks using H0 on-chip switching systems and (4) efficient and flexible call management for 64-kb/s basic-class calls. An estimation of hardware volume of switching nodes is used to show that the proposed architecture is more economical than other possible alternatives, i.e. conventional ISDN and B-ISDN.

Network planning for a public switched telephone network is essentially the same as the company's business strategy. The social environment providing the market for communications services is undergoing rapid change in Japan as it evolves from an era of one basic mainstay service-namely, plain-old telephone service-to one in which a wide range of advanced new services are, or soon will be, available and there is fierce competition to provide those services. This paper covers some of the thinking behind NTT's strategy to put in place a flexible and effectual network that fully reflects the needs and desires of customers in this fast-changing environment.

In this paper, restricted overflow strategy is proposed as a novel channel access strategy for the queueable hierarchical channel structure, which has been proposed as one of "Wideband-ISDN" channel structures. In this policy, overflow from higher bit rate channels to lower bit rate channels is partly restricted by the number of waiting customers in the higher channel's buffer. Therefore, thresholds, which restrict overflow, are considered on the buffer. First, we present the system model with two types of services and restricted overflow strategy. Next, we provide a queueing analysis of this strategy. After that, some numerical results of both conventional overflow strategy and restricted overflow strategy are presented, and we compare the average holding times under these strategies. Finally, we show that, if we choose appropriate thresholds, the average holding time of higher level traffic is improved.

This paper describes the application of a neural network to the optimal routing problem in broadband multimedia networks, where the objective is to maximize network utilization while considering the performance required for each call. In a multimedia environment, the performance required for each call is different, and an optimal path must be found whenever a call arrives. A neural network is appropriate for the computation of an optimal path, as it provides real-time solutions to difficult optimization problems. We formulated optimal routing based on the Hop field neural network model, and evaluated the basic behavior of neural networks. This evaluation confirmed the validity of the neural network formulation, which has a small computation time even if there are many nodes. This characteristic is especially suitable for a large-scale system. In addition, we performed a computer simulation of the proposed routing scheme and compared it with conventional alternate routing schemes. The results show the benefit of neural networks for the routing problem, as our scheme always balances the network load and attains high network utilization.

This paper provides an analytical method to evaluate the cell loss probability in ATM (Asyncronous Transfer Mode) networks employing statistical cell multiplexing. A fairly simple design procedure for path/link capacity is also developed. It is demonstrated that the proposed method yields a conservative capacity value over the entire range examined. This was confirmed by comparing the results obtained through the proposed method with computer simulation results. The method yields a link capacity design approach that can effectively handle different bandwidth and types of VPs within the same link. Evaluations show that the method allows 10% to 1400% more traffic than possible with the peak bandwidth allocation scheme in the parameter range we examined; the specified cell loss probability is set at 10-9. As a result, it is shown that the proposed analytical procedure to evaluate the cell loss probability in statistical cell multiplexing, and the path/link capacity design method are effective and practical even though they use fairly simple procedures.

In an ATM network, there are quality impairments particular to the ATM network such as cell loss and delay variation. During ATM network planning, therefore, various causes of quality impairments should be clarified. This paper overviews ATM network performance issues, and discusses performance requirements for the SDH network which will be applied as a physical layer of the ATM network. It also presents ATM network performance planning methods on cell loss and cell delay.

This paper describes the configuration and performance of a stable, high compression video coding scheme suitable for broadcast quality. This scheme was developed for application to high quality image packet transmission in Asynchronous Transfer Mode (ATM) networks. There are two problems in implementing image packet transmission in ATM networks, namely the achievement of a compression scheme with high coding efficiency, and the achievement of an effective compensation method for cell loss. We describe a scheme which resolves both these problems. It comprises the division of a two-dimensional spectral image signal into several sub-bands. In the case of the high frequency band, block-matching interframe prediction and Discrete Cosine Transform (DCT) are applied to achieve high compression ratio, while intraframe DCT coding is applied to the baseband. This scheme, moreover, provides a stable compensation for cell loss. It is shown that, based on this system, an original image signal of 216Mbit/s is compressed to about 1/10, and a high quality reconstructed image stable to cell loss is obtained.

A fully integrated digital PLL (Phase Locked Loop) with on-chip CMOS oscillator is described. Nominal division number of the variable divider is automatically tuned in this digital PLL and this feature makes it possible to widen the pull-in range. In general, output jitter may increase if the pull-in range is widened. To overcome this problem, output jitter is reduced by utilizing the dual loop architecture. Wide pull-in range enables us on-chip oscillator, which is not so precise as the expensive crystal oscillator. This CMOS oscillator must be carefully designed to be stable against the temperature and the supply voltage variations. Using these digital PLL techniques, together with the on-chip CMOS oscillator, a fully integrated PLL can be achieved. Circuits are designed for 1.544 Mbit/s ISDN primary rate interface, and 6.25% pull-in range is obtained.

One performance limitation of the "Leaky Bucket algorithm" for usage parameter control and traffic management in Asynchronous Transfer Mode (ATM) networks is analyzed. Simulation results show that the conventional statistical bandwidth allocation method, which uses the most bursty pattern permitted by the Leaky Bucket algorithm, can not guarantee the QOS of established Virtual Channels/Paths (VC/VP). As a result, the VC/VP bandwidth allocation method based on the Leaky Bucket algorithm is proven to be unsatisfactory.

Electromagnetic interference on a bus wiring configuration of the ISDN basic interface using metallic telecommunication lines is studied. A simple circuit to simulate terminal equipment unbalance about earth is developed for measurement purposes, based on the fact that the unbalance weakens the withstanding capability against interference. The electromagnetic interferences from low-voltage supply lines, analog telephone lines and broadcasting waves are evaluated by experiments using the circuit. The interference is measured by both induced voltage on the interface line and the error rate of the transmission signal line. Consequently, it is clarified that the basic interface is disturbed by the induced voltage, because the terminal equipment in the CCITT Recommendation I.430 has too large an unbalance about earth to maintain transmission quality. Adding to this, countermeasures to reduce interference are proposed.