Energy-efficient wireless communication

In this chapter we present an energy-efficient highly adaptive network interface architecture and a novel data link layer protocol for wireless networks that provides Quality of Service (QoS) support for diverse traffic types. Due to the dynamic nature of wireless networks, adaptations in bandwidth scheduling and error control are necessary to achieve energy efficiency and an acceptable quality of service. In our approach we apply adaptability through all layers of the protocol stack, and provide feedback to the applications. In this way the applications can adapt the data streams, and the network protocols can adapt the communication parameters

Comparison of multi-layer bus interconnection and a network on chip solution

Abstract. This thesis explains the basic subjects that are required to take in consideration when designing a network on chip solutions in the semiconductor world. For example, general topologies such as mesh, torus, octagon and fat tree are explained. In addition, discussion related to network interfaces, switches, arbitration, flow control, routing, error avoidance and error handling are provided. Furthermore, there is discussion related to design flow, a computer aided designing tools and a few comprehensive researches. However, several networks are designed for the minimum latency, although there are also versions which trade performance for decreased bus widths. These designed networks are compared with a corresponding multi-layer bus interconnection and both synthesis and register transfer level simulations are run. For example, results from throughput, latency, logic area and power consumptions are gathered and compared. It was discovered that overall throughput was well balanced with the network on chip solutions, although its maximum throughput was limited by protocol conversions. For example, the multi-layer bus interconnection was capable of providing a few times smaller latencies and higher throughputs when only a single interface was injected at the time. However, with parallel traffic and high-performance requirements a network on chip solution provided better results, even though the difference decreased when performance requirements were lower. Furthermore, it was discovered that the network on chip solutions required approximately 3–4 times higher total cell area than the multi-layer bus interconnection and that resources were mainly located at network interfaces and switches. In addition, power consumption was approximately 2–3 times higher and was mostly caused by dynamic consumption.Monitasoisen väyläarkkitehtuurin ja tietokoneverkkomaisen ratkaisun vertailua. Tiivistelmä. Tutkielmassa käsitellään tärkeimpiä aihealueita, jotka tulee huomioida suunniteltaessa tietokoneverkkomaisia väyläratkaisuja puolijohdemaailmassa. Esimerkiksi yleiset rakenteet, kuten verkko-, torus-, kahdeksankulmio- ja puutopologiat käsitellään lyhyesti. Lisäksi alustetaan verkon liitäntäkohdat, kytkimet, vuorottelu, vuon hallinta, reititys, virheiden välttely ja -käsittely. Lopuksi kerrotaan suunnitteluvuon oleellisimmat välivaiheet ja niihin soveltuvia kaupallisia työkaluja, sekä käsitellään lyhyesti muutaman aiemman julkaisun tuloksia. Tutkielmassa käytetään suunnittelutyökalua muutaman tietokoneverkkomaisen ratkaisun toteutukseen ja tavoitteena on saavuttaa pienin mahdollinen latenssi. Toisaalta myös hieman suuremman latenssin versioita suunnitellaan, mutta pienemmillä väylänleveyksillä. Lisäksi suunniteltuja tietokoneverkkomaisia ratkaisuja vertaillaan perinteisempään monitasoiseen väyläarkkitehtuuriin. Esimerkiksi synteesi- ja simulaatiotuloksia, kuten logiikan vaatimaa pinta-alaa, tehonkulutusta, latenssia ja suorituskykyä, vertaillaan keskenään. Tutkielmassa selvisi, että suunnittelutyökalulla toteutetut tietokoneverkkomaiset ratkaisut mahdollistivat tasaisemman suorituskyvyn, joskin niiden suurin saavutettu suorituskyky ja pienin latenssi määräytyivät protokollan käännöksen aiheuttamasta viiveestä. Tutkielmassa havaittiin, että perinteisemmillä menetelmillä saavutettiin noin kaksi kertaa suurempi suorituskyky ja pienempi latenssi, kun verkossa ei ollut muuta liikennettä. Rinnakkaisen liikenteen lisääntyessä tietokoneverkkomainen ratkaisu tarjosi keskimäärin paremman suorituskyvyn, kun sille asetetut tehokkuusvaateet olivat suuret, mutta suorituskykyvaatimuksien laskiessa erot kapenivat. Lisäksi huomattiin, että tietokoneverkkomaisten ratkaisujen käyttämä pinta-ala oli noin 3–4 kertaa suurempi kuin monitasoisella väyläarkkitehtuurilla ja että resurssit sijaitsivat enimmäkseen verkon liittymäkohdissa ja kytkimissä. Lisäksi tehonkulutuksen huomattiin olevan noin 2–3 kertaa suurempi, joskin sen havaittiin koostuvan pääosin dynaamisesta kulutuksesta

Future of asynchronous transfer mode networking

The growth of Asynchronous Transfer Mode (ATM) was considered to be the ideal carrier of the high bandwidth applications like video on demand and multimedia e-learning. ATM emerged commercially in the beginning of the 1990\u27s. It was designed to provide a different quality of service at a speed up 100 Gbps for both real time and non real time application. The turn of the 90\u27s saw a variety of technologies being developed. This project analyzes these technologies, compares them to the Asynchronous Transfer Mode and assesses the future of ATM

The application of forward error correction techniques in wireless ATM

Bibliography: pages 116-121.The possibility of providing wireless access to an ATM network promises nomadic users a communication tool of unparalleled power and flexibility. Unfortunately, the physical realization of a wireless A TM system is fraught with technical difficulties, not the least of which is the problem of supporting a traditional ATM protocol over a non-benign wireless link. The objective of this thesis, titled "The Application of Forward Error Correction Techniques in Wireless ATM' is to examine the feasibility of using forward error correction techniques to improve the perceived channel characteristics to the extent that the channel becomes transparent to the higher layers and allows the use of an unmodified A TM protocol over the channel. In the course of the investigation that this dissertation describes, three possible error control strategies were suggested for implementation in a generic wireless channel. These schemes used a combination of forward error correction coding schemes, automatic repeat request schemes and interleavers to combat the impact of bit errors on the performance of the link. The following error control strategies were considered : 1. A stand alone fixed rate Reed-Solomon encoder/decoder with automatic repeat request. 2. A concatenated Reed-Solomon, convolution encoder/decoder with automatic request and convolution interleaving for the convolution codec. 3. A dynamic rate encoder/decoder using either a concatenated Reed-Solomon, convolution scheme or a Reed-Solomon only scheme with variable length Reed-Solomon words

A Performance evaluation of several ATM switching architectures

The goal of this thesis is to evaluate the performance of three Asynchronous Transfer Mode switching architectures. After examining many different ATM switching architectures in literature, the three architectures chosen for study were the Knockout switch, the Sunshine switch, and the Helical switch. A discrete-time, event driven system simulator, named ProModel, was used to model the switching behavior of these architectures. Each switching architecture was modeled and studied under at least two design configurations. The performance of the three architectures was then investigated under three different traffic types representative of traffic found in B-ISDN: random, constant bit rate, and bursty. Several key performance parameters were measured and compared between the architectures. This thesis also explored the implementation complexities and fault tolerance of the three selected architectures

Design of traffic shaper / scheduler for packet switches and DiffServ networks : algorithms and architectures

The convergence of communications, information, commerce and computing are creating a significant demand and opportunity for multimedia and multi-class communication services. In such environments, controlling the network behavior and guaranteeing the user\u27s quality of service is required. A flexible hierarchical sorting architecture which can function either as a traffic shaper or a scheduler according to the requirement of the traffic load is presented to meet the requirement. The core structure can be implemented as a hierarchical traffic shaper which can support a large number of connections with a wide variety of rates and burstiness without the loss of the granularity in cells\u27 conforming departure time. The hierarchical traffic shaper can implement the exact sorting scheme with a substantial reduced memory size by using two stages of timing queues, and with substantial reduction in complexity, without introducing any sorting inaccuracy. By setting a suitable threshold to the length of the departure queue and using a lookahead algorithm, the core structure can be converted to a hierarchical rateadaptive scheduler. Based on the traffic load, it can work as an exact sorting traffic shaper or a Generic Cell Rate Algorithm (GCRA) scheduler. Such a rate-adaptive scheduler can reduce the Cell Transfer Delay and the Maximum Memory Occupancy greatly while keeping the fairness in the bandwidth assignment which is the inherent characteristic of GCRA. By introducing a best-effort queue to accommodate besteffort traffic, the hierarchical sorting architecture can be changed to a near workconserving scheduler. It assigns remaining bandwidth to the best-effort traffic so that it improves the utilization, of the outlink while it guarantees the quality of service requirements of those services which require quality of service guarantees. The inherent flexibility of the hierarchical sorting architecture combined with intelligent algorithms determines its multiple functions. Its implementation not only can manage buffer and bandwidth resources effectively, but also does not require no more than off-the-shelf hardware technology. The correlation of the extra shaping delay and the rate of the connections is revealed, and an improved fair traffic shaping algorithm, Departure Event Driven plus Completing Service Time Resorting algorithm, is presented. The proposed algorithm introduces a resorting process into Departure Event Driven Traffic Shaping Algorithm to resolve the contention of multiple cells which are all eligible for transmission in the traffic shaper. By using the resorting process based on each connection\u27s rate, better fairness and flexibility in the bandwidth assignment for connections with wide range of rates can be given. A Dual Level Leaky Bucket Traffic Shaper(DLLBTS) architecture is proposed to be implemented at the edge nodes of Differentiated Services Networks in order to facilitate the quality of service management process. The proposed architecture can guarantee not only the class-based Service Level Agreement, but also the fair resource sharing among flows belonging to the same class. A simplified DLLBTS architecture is also given, which can achieve the goals of DLLBTS while maintain a very low implementation complexity so that it can be implemented with the current VLSI technology. In summary, the shaping and scheduling algorithms in the high speed packet switches and DiffServ networks are studied, and the intelligent implementation schemes are proposed for them

Simulation and analytical performance studies of generic atm switch fabrics.

As technology improves exciting new services such as video phone become possible and economically viable but their deployment is hampered by the inability of the present networks to carry them. The long term vision is to have a single network able to carry all present and future services. Asynchronous Transfer Mode, ATM, is the versatile new packet -based switching and multiplexing technique proposed for the single network. Interest in ATM is currently high as both industrial and academic institutions strive to understand more about the technique. Using both simulation and analysis, this research has investigated how the performance of ATM switches is affected by architectural variations in the switch fabric design and how the stochastic nature of ATM affects the timing of constant bit rate services. As a result the research has contributed new ATM switch performance data, a general purpose ATM switch simulator and analytic models that further research may utilise and has uncovered a significant timing problem of the ATM technique. The thesis will also be of interest and assistance to anyone planning on using simulation as a research tool to model an ATM switch

Journal of Telecommunications and Information Technology, 2002, nr 2

kwartalni

Simulation of LAN Interconnection via ATM

http://www.worldcat.org/oclc/3088061