1 / 50

Wireless Technologies

Wireless Technologies. SOFYAN BASUKI Sofmae4@gmail.com 085724677888 085320900567. Wireless technology overview Cellular communications Satellite systems Wireless LAN 802.11, Bluetooth, UWB Mobility support WAP Wireless applications. Outline. Human freedom Portability v. Mobility

maili
Download Presentation

Wireless Technologies

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. Wireless Technologies SOFYAN BASUKI Sofmae4@gmail.com 085724677888 085320900567

  2. Wireless technology overview • Cellular communications • Satellite systems • Wireless LAN • 802.11, Bluetooth, UWB • Mobility support • WAP • Wireless applications Outline

  3. Human freedom • Portability v. Mobility • Objective: “anything, anytime, anywhere” • Mobility • Size, weight, power • Functionality • Content • Infrastructure required • Cost • Capital, operational Why Wireless?

  4. Worldwide Mobile Subscribers SOURCE: CTIA, iGillottResearch, 2001

  5. 4G CELLULAR 56-100 GHz 3G CELLULAR 1.5-5.2 GHz 1G, 2G CELLULAR 0.4-1.5GHz HARMFUL RADIATION LIGHT RADIO SOUND VHF = VERY HIGH FREQUENCY UHF = ULTRA HIGH FREQUENCY SHF = SUPER HIGH FREQUENCY EHF = EXTRA HIGH FREQUENCY UWB 3.1-10.6 GHz Electromagnetic Spectrum SOURCE: JSC.MIL

  6. MARITIME MOBILE FIXED BROADCAST MOBILE AERO RADIOLOCATION

  7. WIRELESS AIR LINK WIRED PUBLIC SWITCHED TELEPHONE NETWORK Wireless Telephony SOURCE: IEC.ORG

  8. ACTUAL COVERAGE AREA OF CELL 3 ACTUAL COVERAGE AREA OF CELL 1 CELL 1 OVERLAPS 6 OTHERS DIFFERENT FREQUENCIES MUST BE USED IN ADJACENT CELLS SEVEN DIFFERENT SETS OF FREQUENCIES REQUIRED Cell Clusters SOURCE: IEC.ORG

  9. MANY CELLS CAN SHARE SAME FREQUENCIES IF SEPARATED IN SPACE PATTERN CAN BE REPLICATED OVER THE ENTIRE EARTH 200 FREQUENCIES IN ONE CELL TOTAL NUMBER OFFREQUENCIES = 1400 WORLDWIDE Space Division Multiple Access (SDMA)

  10. AS PHONE MOVES FROM CELL “A” TO CELL “B”: • CELL “A” MUST HAND THE CALL OVER TO “B” • PHONE MUST CHANGE FREQUENCIES • CELL “A” MUST STOP TRANSMITTING Minimum performance contour A x y B z Cell Handover Handover threshold contour ANIMATION SOURCE: R. C. LEVINE, SMU

  11. MACROCELL: $1M FAST-MOVINGSUBSCRIBERS PICOCELLS MICROCELL: $250K SLOW-MOVINGSUBSCRIBERS GSM: 100m - 50 km 250 km/hr Cell Sizes

  12. Many users sharing a resource at the “same time” • Needed because user must share cells • FDMA (frequency division) • Use different frequencies • TDMA (time division) • Use same frequency, different times • CDMA (code division) • Use same frequency, same time, different “codes” Multiple Access

  13. Advantages: • No dynamic coordination Disadvantages: • Inflexible & inefficient if channel load is dynamic and uneven Each channel gets a band (range) of frequencies Used in traditional radio, TV, 1G cellular k1 k2 k3 k4 k5 k6 c f Frequency Division Multiplexing (FDMA) t SOURCE: NORMAN SADEH

  14. k1 k2 k3 k4 k5 k6 c FREQUENCY BAND f t Each channel gets entire spectrum for a certain (rotating) time period EACH CHANNEL OCCUPIES SAME FREQUENCY Advantage: Can assign more time to senders with heavier loads 3X capacity of FDMA, 1/3 of power consumption Disadvantage: Requires precise synchronization Time Division Multiplexing (TDMA) SOURCE: NORMAN SADEH

  15. k1 k2 k3 k4 k5 k6 c f t Each channel gets a certain frequency band for a certain amount of time. Example: GSM • Advantages: • More robust against frequency- selective interference • Much greater capacity with time compression • Inherent tapping protection • Disadvantages • Frequency changes must be coordinated Combining TDMA and FDMA SOURCE: NORMAN SADEH

  16. Time-Division Multiple Access SOURCE: QUALCOMM

  17. k1 k2 k3 k4 k5 k6 c f t • Each channel has unique“code” • All channels use same spectrumat same time but orthogonal codes • Advantages: • bandwidth efficient – code space is huge • no coordination or synchronizationbetween different channels • resists interference and tapping • 3X capacity of TDMA, 1/25 power consumption • Disadvantages: • more complex signal regeneration • Implemented using spread spectrum Code Division Multiplexing (CDMA)

  18. First • Analog, circuit-switched (AMPS) • Second • Digital, circuit-switched (GSM, Palm) 10 Kbps • Advanced second • Digital, circuit switched, Internet-enabled (WAP) 10 Kbps • 2.5 • Digital, packet-switched, TDMA (GPRS, EDGE)40-400 Kbps • Third • Digital, packet-switched, wideband CDMA (UMTS)0.4 – 2 Mbps • Fourth • Data rate 100 Mbps; achieves “telepresence” Cellular Generations

  19. CELL TRANSMITTER & RECEIVER INTERFACE TO LANDTELEPHONE NETWORKS HIERARCHY OF CELLS STOLEN, BROKEN CELLPHONE LIST LIST OF ROAMINGVISITORS PHONE ENCRYPTION, AUTHENTICATION LIST OF SUBSCRIBERS IN THIS AREA SIM: IDENTIFIES A SUBSCRIBER DATA RATE: 9.6 Kbps GSM Architecture SOURCE: UWC

  20. Integral part of GSM standard • Added to other standards as well • Uses control channel of phone • Send/Receive short text messages • Sender pays (if from mobile phone) • Phone has "email" address • SMTP Interface • Only in the US, not the rest of the world • Allows messages to be sent for free! • 3125551234@wireless.att.net • 1 BILLION SMS/day worldwide SMS – Short Message Service SOURCE: GEMBROOK SYSTEMS

  21. Bank Web Site Customer Internet Alert me to all credit card transactions greater than $100. Message from YourBank: Credit card purchase of $1245 at Joe’s HiFi. Bank Back-end Systems SMS Monitoring Application Air Credit card used Joe’s HiFi $1245 Message appears within seconds on the customer’s phone Wireless Carrier SMS Carrier Cell Tower SMS in Banking SOURCE: GEMBROOK SYSTEMS

  22. GEO MEO LEO GEO (22,300 mi., equatorial) high bandwidth, power, latency MEO high bandwidth, power, latency LEO (400 mi.) low power, latency more satellites small footprint V-SAT (Very Small Aperture) private WAN SATELLITE MAP Satellite Systems SOURCE: WASHINGTON UNIV.

  23. Geostationary Orbit SOURCE: BILL LUTHER, FCC

  24. Global Positioning System • Operated by USAF • 28 satellites • 6 orbital planes at a height of 20,200 km • Positioned so a minimum of 5 satellites are visible at all times • Receiver measures distance to satellite GPS Satellite Constellation SOURCE: NAVSTAR

  25. DISTANCE MEASUREMENTS MUST BE VERY PRECISE LIGHT TRAVELS 1018 FEET EACH MICROSECOND GPS Trilateration SOURCE: PETER DANA

  26. Benefits of AVL • Fast dispatch • Customer service • Safety, security • Digital messaging • Dynamic route optimization • Driver compliance • Sample AVL Users • Chicago 911 • Inkombank, Moscow • Taxi companies Automatic Vehicle Location (AVL) Intelligent Highway demo CA SOURCE: TRIMBLE NAVIGATION

  27. Vehicle tracking • Firemen in buildings, vital signs, oxygen remaining • Asset tracking • Baggage • Shoppers assistance • Robots • Corporate visitors • Insurance • Barges Location-Aware Applications

  28. Idea: just a LAN, but without wires • Not as easy since signals are of limited range • Unlike wired LAN, if A can hear B and B can hear C, not necessarily true that A can hear C • Uses unlicensed frequencies, low power • 802.11 from 2 Mb to 54 Mb • Bluetooth • UWB Wireless LAN

  29. Extended Range Antenna WaveLAN ISA (Industry Standard Architecture) Card WavePOINT II Transmitter Ethernet Converter Wireless LAN Components 11 Mbps WaveLAN PCMCIA Card SOURCE: LUCENT

  30. CLIENT AND ACCESS POINT WIRELESS PEER-TO-PEER BRIDGING WITH DIRECTIONAL ANTENNAS Wireless LAN Configurations MULTIPLE ACCESS POINTS + ROAMING UP TO 17 KM ! SOURCE: PROXIM.COM

  31. A standard permitting for wireless connection of: • Personal computers • Printers • Mobile phones • Handsfree headsets • LCD projectors • Modems • Wireless LAN devices • Notebooks • Desktop PCs • PDAs Bluetooth

  32. Operates in the 2.4 GHz Industrial-Scientific-Medical (ISM) (unlicensed)! band. Packet switched. 1 milliwatt (as opposed to 500 mW cellphone. Low cost. • 10m to 100m range • Uses Frequency Hop (FH) spread spectrum, which divides the frequency band into a number of hop channels. During connection, devices hop from one channel to another 1600 times per second • Bandwidth 1-2 megabits/second • Supports up to 8 devices in a piconet (two or more Bluetooth units sharing a channel). • Built-in security. • Non line-of-sight transmission through walls and briefcases. • Easy integration of TCP/IP for networking. Bluetooth Characteristics

  33. ALCATEL One TouchTM 700 GPRS, WAP ERICSSON R520 GSM 900/1800/1900 ERICSSON BLUETOOTH CELLPHONE HEADSET Bluetooth Devices NOKIA 9110 + FUJI DIGITAL CAMERA ERICSSON COMMUNICATOR

  34. Piconet = small area network • “Ad hoc” network: no predefined structure • Based on available nodes and their locations • Formed (and changed) in real time Bluetooth Piconets

  35. Scatternet Piconets Master Master / Slave Slave Piconet ScatterNet Bluetooth Scatternets SOURCE: KRISHNA BHOUTIKA

  36. “0” “1” 500 ps d d Frequency (GHz) Randomized Time Coding d = 125 ps 0 -40 Power Spectral Density (dB) Amplitude Random noise signal Time -80 Frequency (GHz) 1 2 3 4 5 • Not a sinewave, but millions of pulses per second • Time coded to make noise-likesignal • Pulse position modulation Spread Spectrum Time-Modulated Ultra-Wideband (TM-UWB) SOURCE: TIME DOMAIN

  37. PulsON, A Chip Based Solution • VERY low power: 0.01 milliwatt • Bluetooth 1 milliwatt (100 x UWB) • Cellphone 500 milliwatts (50,000 x UWB) • Range: 30 to 300 feet • Very small • Low cost • 100 Mbits/second • Up to 500 Mbps for short distances(USB speed) • No interference • Secure Ultra Wideband Properties

  38. WAP (Wireless Application Protocol) and iMode • High-level protocols that use cellular transport • WAP: • Uses WML (Wireless Markup Language) • Divides content into “cards” equal to one telephone screen • Simplified but incompatible form of HTML • To send to a WAP phone, must broadcast WML content Wireless Application Support

  39. Internet MobileNetwork Web Content Server Non Mobile Internet User WAP Gateway Mobile Terminal iNexware Database Server WAP Applications WAP simulator SOURCE: DANET

  40. Telephone, pager, email, browser, location tracking, banking, airline tickets, entertainment tickets, games • NTT DoCoMo (ドコモ means “anywhere”) • Japan is the wireless Internet leader: iMode iMode FAQ SOURCE: EUROTECHNOLOGY JAPAN K.K.

  41. Sits on top of packet voice/data transport • As of July 31, 2003, > 39 million subscribers • 28,000 new ones per day • 26% of Japan • >3000 “official” sites • >1000 application partners • >40,000 unofficial sites • Fee based on amountof data transmitted iMode SOURCES: XML.COM, EUROTECHNOLOGY.COM

  42. Phonetic text input (better for Japanese) • SLOW: 9.6 Kbps, but 3G will raise to 384 K • Uses cHTML (compact HTML) • same rendering model as HTML (whole page at a time) • low memory footprint (no tables or frames) • Standby time: 400 min., device weight 2.4 oz. (74g) iMode SOURCES: XML.COM, NTT

  43. BILLING DB INTERNET INFO PROVIDER USER DB IP IP DoCoMo Packet Network (PDC-P) iMode Servers HTTP PACKET DATA iMode Operation SOURCE: SAITO & SHIN

  44. Wireless Standards • 802.11b (2.4 GHz 300’ radius 11 Mbps) • 802.11a (5 GHz 54 Mbps incompatible with b) • 802.11g (2.4 GHz 54 Mbps backward compatible with b) • 802.20 (<3.5 GHz >1 Mbps @250 kph) • BlueTooth (2.4 Ghz 30’ radius) • GSM (9.6 Kbps) GPRS (28.8 Kbps up to 60 Kbps ) • 3G (UMTS 1.1 Mbit/s shared typically giving 80 Kbit/s ) • 4G2010? (10 Mbs? ) • UWB potential to deliver 500 Mbps over short distances SOURCE: JOHN DOWNARD

  45. Mobile growing very rapidly • Cell systems need large infrastructure • Wireless LAN does not • Content preparation is a problem • Wireless business models largely unexplored • Bandwidth, bandwidth, bandwidth Key Takeaways

  46. Q A &

  47. DATA 1 0 1 “CODE” 0 1 0 1 0 0 1 0 0 0 1 0 1 1 0 0 1 1 DATA  CODE 1 0 1 0 1 1 1 0 0 0 1 0 0 0 1 1 0 0 +1 ACTUAL SIGNAL -1 Code Division SOURCE: JOCHEN SCHILLER

  48. DATA B 1 0 0 “CODE” B 0 0 0 1 1 0 1 0 1 0 0 0 0 1 0 1 1 1 DATA  CODE 1 1 1 0 0 1 1 0 1 0 0 0 0 1 0 1 1 1 +1 ACTUAL SIGNAL B -1 Code Division SOURCE: JOCHEN SCHILLER

  49. +1 ACTUAL SIGNAL B -1 +1 ACTUAL SIGNAL A -1 +2 ACTUAL SIGNAL A+B Two CDMA Signals -2 SOURCE: JOCHEN SCHILLER

  50. +2 ACTUAL SIGNAL A+B -2 “CODE” A 0 1 0 1 0 0 1 0 0 0 1 0 1 1 0 0 1 1 +1 -1 +2 -(A+B) * CODE A -2 0 INTEGRAL Recovering Data A From A+B 1 1 SOURCE: JOCHEN SCHILLER

More Related