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Wi-Fi and Cellular Handoff

Wi-Fi and Cellular Handoff. Sowjanya Talasila Shilpa Pamidimukkala Sravanthi Yalamanchili. Agenda. Cellular Networks WLAN Vertical Handoff Fixed Mobile Convergence Introduction to HTN HTN working Performance Introduction to UMA UMA specifications UMA technology. Cellular Networks.

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Wi-Fi and Cellular Handoff

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  1. Wi-Fi and Cellular Handoff Sowjanya Talasila Shilpa Pamidimukkala Sravanthi Yalamanchili

  2. Agenda • Cellular Networks • WLAN • Vertical Handoff • Fixed Mobile Convergence • Introduction to HTN • HTN working • Performance • Introduction to UMA • UMA specifications • UMA technology

  3. Cellular Networks • Wide coverage (km range) • Large number of users • Low speeds (in Kbps) • High deployment costs

  4. Wireless LANs • High Inexpensive to set up • Speeds up to 108 Mbps • Low coverage • Small number of users

  5. Vertical Handoff Vertical handoff is a technique that allows a mobile user to roam between different networks and access technologies ,in a manner that is transparent to the applications and users , without disrupting connectivity.

  6. Benefits of Vertical Handoff • Simultaneous use of different access networks and technologies. • Seamless transfer of connection between different networks and access technologies.

  7. Motivations Mobility Vehicle 3G 2G Complementary performance Vertical handover Walk WLAN Fix LAN Data rate Mbit/s 2 50 1000 0.1 Mobility vs. Throughput for communication systems

  8. Combining both WLAN and Cellular • Combine advantages of cellular networks and Wi-Fi hotspots • Higher bandwidth • Extended coverage • Inexpensive • Large number of users

  9. Goals of Vertical Handoff • Low handoff latency • Power saving • Low bandwidth overhead

  10. Vertical Handoff Procedure - Mobile Downward CDMA cellular card activate

  11. Vertical Handoff Procedure- Mobile Upward check beacon and activate WLAN card

  12. Handoff Decision • Radio link characteristic • Application traffic classes

  13. Fixed Mobile Convergence • Fixed mobile convergence (FMC) solutions enable seamless handoff of calls and call features across wireline (Wi-Fi or 802.11) and wireless (cellular) networks . • FMC solutions available today enable wireline carriers to recapture lost revenue and subscribers by extending mobility into the enterprise while keeping wireless minutes on the wireline network.

  14. Contd.. • These solutions use dual-mode handsets to seamlessly roam between Wi-Fi and cellular networks and provide users with one set of business telephony features, one phone number, and one user interface.

  15. FMC

  16. FMC Approaches Two approaches to Fixed Mobile Convergence • Handoff Trigger Node(HTN) • Unlicensed Multiple Access(UMA)

  17. Handoff Trigger Node

  18. Handoff Trigger Node (HTN) A simple WiFi handoff trigger node can be installed in the WLAN/cellular transition region and generates link layer triggers which cause the initiation of the vertical handoff process.

  19. HTN Two solutions for inter-working of WLAN/ Cellular • Tight-coupling Integrates WLAN hotspot into cellular infrastructure. WiFi operate as a slave to cellular coverage cell. • Loosely-coupling No such close relation between the networks and allows many network operators and service providers to operate in the same market.

  20. HTN (contd..) • When roaming inside a WiFi hotspot, a dual mode MS uses IEEE 802.11 layer 2 roaming procedures. • When the receive signal strength indication (RSSI) drops consistently below a certain threshold, MS scans for the new access point (AP) using standard IEEE 802.11 procedures.

  21. Without HTN

  22. HTN (contd..) • The latency associated with the above can be significant and includes components such as BS searching and higher layer signaling functions. • Existing WiFi/cellular transition coverage areas are highly site specific.

  23. Using HTN • HTN can be installed in the WLAN/cellular transition region, generate link layer triggers which cause the initiation of the vertical handoff process. • HTN does not function as an access point but as a regular data station with enhanced capabilities.

  24. HTN (contd..) • During a successful vertical handoff, the MS is assigned capacity in the cellular system. • In a tightly-coupled WIFI/cellular design it is possible to reserve capacity for WiFi-cellular handoffs, so that call dropping probability is acceptably low. • In loosely- coupled BS may not be able to distinguish WiFi-cellular handoff from new call request.

  25. Handoff Trigger Node (HTN)

  26. How HTN works • HTN acts as a simple WiFi end station and associates with the closest AP i.e. AP3 in fig just as normal IEEE 802.11 station. • HTN then continuously scans IEEE 802.11channel corresponding to the coverage area of AP3. • The scanning that is performed is done in “promiscuous mode”, i.e. normal HTN MAC filtering is disabled and it intercepts and listens to all the station transmissions.

  27. How HTN works (contd..) • The packets that are received are then filtered at higher protocol layers for active voice connections. • The objective of this is to identify, if possible , all active voice connections that are with in the range of the HTN. • When the HTN is installed, it is configured with a site-specific receive signal strength indication (RSSI) threshold, denoted by yhot.

  28. How HTN works (contd..) • When an end station is detected HTN station scanning, whose RSSI exceeds yHOT, a HO_TRIGGER_CMD is sent to the MS in question. • HTN must extract the MS MAC address from the scanned packets and use this information to send a trigger command to the station in question. • Once the mobile station receives the HO_TRIGGER_CMD, it initiates the vertical handoff procedure.

  29. How HTN works (contd..) • This includes having the MS turn on its cellular radio prior to setting up the vertical handoff. • A handoff Trigger Node can easily perform handoff trigger in mulitichannel/multi-AP coverage situations simply by serially scanning on the various channels of interest.

  30. HTN Performance Here are some of the results obtained from a stimulation of HTN design using the below table.

  31. Performance (contd..) • In the result there is a comparison between LHO- legacy handoff case. HOT-Handoff triggering case.

  32. Handoff Dropping Probability • This is the probability that a call with at least one handoff attempt from the WLAN to the cellular system is dropped. • This is computed by the total number of stations that have at least one handoff request.

  33. Handoff Dropping Probability

  34. Cellular Time Fraction • This is the average fraction of time that a call which has stared inside the WiFi hotspot, spends being served by the cellular system.

  35. Cellular Time Fraction

  36. Mean Vertical Handoff Deadline • This is the average time the MS has to complete a vertical handoff after its first handoff attempt.

  37. Mean Vertical Handoff Deadline

  38. False vertical Handoff Rate • This is the false alarm rate ,i.e. the rate at which unnecessary vertical handoffs are triggered. • This is obtained by computing the fraction of vertical handoffs that occur which are unnecessary because the MS completes its call before leaving the WiFi coverage area.

  39. False vertical Handoff Rate

  40. Result: • An important function provided by the HTN is to significantly reduce the call dropping rate even when there is very little collaboration between the cellular and WLAN hotspot providers.

  41. UMA

  42. Unlicensed Mobile Access UMA establishes a standard for seamless hand-off and roaming between a cellular network and fixed IP-based wireless networks UMA is an extension of GSM/GPRS mobile services. What is UMA?

  43. UMA (Unlicensed Mobile Access) • UMA lets mobile operators deliver voice, data and IMS/SIP(IP Multi media Subsystem /Session Initiated Protocol) applications to mobile phones on Wi-Fi access network.

  44. UMA is on top of it at the transport layer (Layer 4) and has its own set of control protocols . Limits IP packet Delivery?? UMA Protocols

  45. UNC • The UMA specification is based around UNC. What is UNC??? A UMA Network Controller (UNC) acts as a virtual base station, providing handoff between cellular and Wi-Fi networks.

  46. How UMA Technology Works • A mobile subscriber with a UMA-enabled, dual-mode handset moves within range of an unlicensed wireless network to which the handset is allowed to connect. • Upon connecting, the handset contacts the UMA Network Controller (UNC) over the broadband IP access network to be authenticated and authorized to access GSM voice and GPRS data services via the unlicensed wireless network.

  47. If approved, the subscriber’s current location information stored in the core network is updated, and from that point on all mobile voice and data traffic is routed to the handset via the Unlicensed Mobile Access Network (UMAN) rather than the cellular radio access network (RAN). (Contd..)

  48. ROAMING • When a UMA-enabled subscriber moves outside the range of an unlicensed wireless network to which they are connected, the UNC and handset facilitate roaming back to the licensed outdoor network. This roaming process is completely transparent to the subscriber.

  49. HANDOVER • Handover in: The mobile station moves from macro network to a UMAN. • Handover out: The mobile station moves from UMAN to macro network. • Handover UMA: The mobile station moves with in a UMAN or from UMAN to UMAN.

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