1 / 10

Mobile Ad Hoc Networks

Mobile Ad Hoc Networks. Myungchul Kim mckim@icu.ac.kr. From Handbook of Wireless Networks and Mobile Computing, edited by Ivan Stojmenovic. 2002 John Wiley & Sons. Introduction Ad hoc networks : no infrastructure = without any central control Applications:

gisela
Télécharger la présentation

Mobile Ad Hoc Networks

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Mobile Ad Hoc Networks Myungchul Kim mckim@icu.ac.kr

  2. From Handbook of Wireless Networks and Mobile Computing, edited by Ivan Stojmenovic. 2002 John Wiley & Sons. • Introduction • Ad hoc networks : no infrastructure = without any central control • Applications: • The multihop nature and the lack of fixed infrastructure -> new research problems such as configuration advertising, discovery, maintenance, addressing and self-routing. • The characteristics of mobile ad hoc networks • The topology is highly dynamic • Lower capacity due to wireless links • Physical security • Higher loss rate, delay and jitter • Energy saving

  3. Layered architecture of mobile ad hoc networks • Cellular systems: single-hop wireless systems • Radio spectrum • Power consumption: circuit, architecture and software • MAC layer of IEEE 802.11: all the nodes must use the same channel • The existing standard of IEEE 802.11 does not support multihop systems. • MANET in IETF: routing in ad hoc networks scaling up to hundreds of routers • Location management • Zeroconf working group • Security • QoS for multimedia data • Location-area application • Sensor networks

  4. MAC layer • Wireless personal area networks (WPAN): a radius of 10 meters • Multiple access networks • Random access: IEEE 802.11 • Demand assignment: Bluetooth, QoS • IEEE 802.11 • Physical and MAC layer • Physical layers: infrared, frequency hopping and direct sequence spread spectrum • CSMA/CA • Neighboring cells can use different frequencies to avoid interference and increase the cell’s capacity • 802.11 ad hoc link • Power saving policy

  5. Bluetooth • The physical layer utilizes frequency hopping spread spectrum • 1Mb/s • Contention-free, token-based multiple access network • A master and slaves • Synchronous connection-oriented (SCO) link and asynchronous connectionless (ACL) link • Piconet: two or more devices sharing the same frequency • Scatternet: piconets overlap • Can support one asyn. Data link between two devices, up to three simultaneous syn. voice links. • A max asym data rate of 723.2kb/s (and up to 57.6 kb/s in the return direction) or a sym data rate of 433.9 kb/s

  6. Mobile ad hoc networks and the internet • Mobile ad hoc network’s characteristics • Dynamic topologies • Bandwidth-constrained and variable capacity links • Energy-constrained operation • Limited physical security • Desirable qualitative properties of mobile ad hoc network routing protocols • Distributed operation • Loop-freedom • Demand-based operation • Proactive operation • Security • “sleep” period operation • Unidirectional link support

  7. Quantitative metrics • End-to-end data throughput and delay • Route acquisition time • Percentage out-of-order delivery • Efficiency • Proactive protocols ( table-driven protocols) • Control overhead in terms of both traffic and power consumption • Reactive protocols • Latency period due to the route discovery procedure • The on-demand design is based (1) on the observation that in a dynamic topology routes expire frequently and (2) on the assumption that not all the routes are used at the same time. • New addressing approach • The existing location-based routing protocols propose to use location information for reducing the propagation of control messages.

  8. Scalability: clustering with clusterheads and border nodes • Multicast routing: allow optimization of resource usage • Mobile ad hoc networks do not provide QoS by design • QoS provisioning • Routing in self-organized networks • Large mobile ad hoc networks (larger than a thousand nodes and/or constituting a wide or geographical network with limited resources): business model of citizen band, amateur radio and walkie-talkie systems, in which multihop wireless comm allow voice and data messaging among all users. • These networks are likely to be very large and not Internet-based. • Self-organization • Nonauthority-based networks • Very large and not regularly distributed • Highly cooperative

  9. Six degrees of separation: Entire human population has a diameter of six or less edges. • Routing solution design • Scalability • Dynamic changing network connectivity • High collaboration among nodes • For a potentially large network, both traditional proactive and reactive approaches are not feasible. • People-based networks • PDA • Mobile ad hoc network with no central administration • Self-organizing and fairly robust • The users have, simultaneously, their traditional role and “network” role. • User/application-oriented approach

  10. Minimize the inexpert user’s exposure to the administrative infrastructure and make necessary activities as intuitive as possible

More Related