Mobile Communication Technology. WiMAX. according to IEEE. ZigBee. Bluetooth m LAN. WiFi x <10m PAN. IEEE 802.

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1 Range of Wireless Data choices Wide Area Networks 2G and 3G cellular data systems etropolitan Area Networks , Wiax - wireless broadband Local Area Networks /a/b/g/, wireless LAN ersonal Area Networks (Bluetooth ), & eriel Huggard 4ICT , delivered by D.Lewis Current Wireless Technologies Wireless technology ower mw Range meters BW Rate bps EDGE 2.5G G 600 ~ kHz/ channel 384k 1xEVDO 3G CDA 600 ~ Hz/ channel Wiax 250 ~ Hz/ channel g WiFi 50 25Hz/ channel a Bluetooth Hz/ channel <1 eriel Huggard 4ICT , delivered by D.Lewis Network cales AN x <10m LAN m AN km WAN 2G, 3G 2km/link national areas eriel Huggard 4ICT , delivered by D.Lewis obile Communication Technology according to IEEE Local wireless networks WLAN WiFi b a g h i/e/ /w ersonal wireless nw WAN ZigBee Bluetooth a/b a/b Wireless distribution networks WAN (Broadband Wireless Access) + obility WiAX (obile Broadband Wireless Access) eriel Huggard 4ICT , delivered by D.Lewis

2 Applications obile data services provide wide ranging mobile access to and to the Web, leveraging the mobile network voice infrastructure. Wiax: wireless broadband access E.g. bridge to WiFi hot spots, or rural users WiFi: faster & web access on shorter range: e.g. homes, offices, hotspots Bluetooth: short range cable replacement eriel Huggard 4ICT , delivered by D.Lewis Comparison: infrared vs. radio transmission Infrared uses IR diodes, diffuse light, multiple reflections (walls, furniture etc.) Advantages simple, cheap, available in many mobile devices no licenses needed simple shielding possible Disadvantages Example interference by sunlight, heat sources etc. many things shield or absorb IR light low bandwidth IrDA (Infrared Data Association) interface available everywhere Radio typically using the license free I band at 2.4 GHz Advantages experience from wireless WAN and mobile phones can be used coverage of larger areas possible (radio can penetrate walls, furniture etc.) Disadvantages very limited license free frequency bands shielding more difficult, interference with other electrical devices Example any different products eriel Huggard 4ICT , delivered by D.Lewis Bluetooth Idea Universal radio interface for ad-hoc wireless connectivity Interconnecting computer and peripherals, handheld devices, DAs, cell phones replacement of IrDA Embedded in other devices, goal: 5/device (2005: 16/U bluetooth) hort range (10 m), low power consumption, license-free 2.45 GHz I Voice and data transmission, approx. 1 bit/s gross data rate One of the first modules (Ericsson). eriel Huggard 4ICT , delivered by D.Lewis History Bluetooth 1994: Ericsson (attison/haartsen), C-link project Renaming of the project: Bluetooth according to Harald Blåtand Gormsen [son of Gorm], King of Denmark in the 10 th century 1998: foundation of Bluetooth IG, (was: ) 1999: erection of a rune stone at Ercisson/Lund ;-) 2001: first consumer products for mass market, spec. version 1.1 released 2005: 5 million chips/week pecial Interest Group Original founding members: Ericsson, Intel, IB, Nokia, Toshiba Added promoters: 3Com, Agere (was: Lucent), icrosoft, otorola > 2500 members Common specification and certification of products eriel Huggard 4ICT , delivered by D.Lewis

3 History and hi-tech 1999: Ericsson mobile communications AB reste denna sten till minne av Harald Blåtand, som fick ge sitt namn åt en ny teknologi för trådlös, mobil kommunikation. eriel Huggard 4ICT , delivered by D.Lewis Characteristics 2.4 GHz I band, 79 (23) RF channels, 1 Hz carrier spacing Channel 0: 2402 Hz channel 78: 2480 Hz G-FK modulation, 1- mw transmit power FH and TDD Frequency hopping with 1600 hops/s Hopping sequence in a pseudo random fashion, determined by a master Time division duplex for send/receive separation Voice link CO (ynchronous Connection Oriented) FEC (forward error correction), no retransmission, 64 kbit/s duplex, pointto-point, circuit switched Data link ACL (Asynchronous ConnectionLess) Asynchronous, fast acknowledge, point-to-multipoint, up to kbit/s symmetric or 723.2/57.6 kbit/s asymmetric, packet switched Topology Overlapping piconets (stars) forming a scatternet eriel Huggard 4ICT , delivered by D.Lewis and the real rune stone Located in Jelling, Denmark, erected by King Harald Blåtand in memory of his parents. The stone has three sides one side showing a picture of Christ. Inscription: "Harald king executes these sepulchral monuments after Gorm, his father and Thyra, his mother. The Harald who won the whole of Denmark and Norway and turned the Danes to Christianity." Btw: Blåtand means of dark complexion (not having a blue tooth ) This could be the original colors of the stone. Inscription: auk tani karthi kristna (and made the Danes Christians) eriel Huggard 4ICT , delivered by D.Lewis iconet Collection of devices connected in an ad hoc fashion One unit acts as master and the others as slaves for the lifetime of the piconet aster determines hopping pattern, slaves have to synchronize Each piconet has a unique hopping pattern articipation in a piconet = synchronization to hopping sequence Each piconet has one master and up to 7 simultaneous slaves (> 200 could be parked) =aster =lave =arked =tandby eriel Huggard 4ICT , delivered by D.Lewis

4 Forming a piconet All devices in a piconet hop together aster gives slaves its clock and device ID Addressing Hopping pattern: determined by device ID (48 bit, unique worldwide) hase in hopping pattern determined by clock Active ember Address (AA, 3 bit) arked ember Address (A, 8 bit) eriel Huggard 4ICT , delivered by D.Lewis Bluetooth protocol stack audio apps. NW apps. vcal/vcard telephony apps. mgmnt. apps. TC/UD BNE I OBEX AT modem commands TC BIN D Control RFCO (serial line interface) Audio Logical Link Control and Adaptation rotocol (L2CA) Link anager Host Controller Interface Baseband Radio AT: attention sequence OBEX: object exchange TC BIN: telephony control protocol specification binary BNE: Bluetooth network encapsulation protocol D: service discovery protocol RFCO: radio frequency comm. eriel Huggard 4ICT , delivered by D.Lewis catternet Linking of multiple co-located piconets through the sharing of common master or slave devices Devices can be slave in one piconet and master of another Communication between piconets Devices jumping back and forth between the piconets iconets (each with a capacity of 720 kbit/s) =aster =lave =arked =tandby eriel Huggard 4ICT , delivered by D.Lewis Frequency selection during data transmission 625 µs f k f k+1 f k+2 f k+3 f k+4 f k+5 f k+6 t f k f k+3 f k+4 f k+5 f k+6 t f k f k+1 f k+6 t eriel Huggard 4ICT , delivered by D.Lewis

5 Baseband iconet/channel definition Low-level packet definition Access code Channel, device access, e.g., derived from master acket header 1/3-FEC, active member address (broadcast + 7 slaves), link type, alternating bit ARQ/EQ, checksum 68(72) bits access code packet header payload 4 64 (4) preamble sync. (trailer) bits A address type flow ARQN EQN HEC eriel Huggard 4ICT , delivered by D.Lewis ACL ayload types payload (0-343) header (1/2) payload (0-339) CRC (2) D1 header (1) payload (0-17) 2/3 FEC CRC (2) DH1 header (1) payload (0-27) CRC (2) (bytes) D3 header (2) payload (0-121) 2/3 FEC CRC (2) DH3 header (2) payload (0-183) CRC (2) D5 header (2) payload (0-224) 2/3 FEC CRC (2) DH5 header (2) payload (0-339) CRC (2) AUX1 header (1) payload (0-29) eriel Huggard 4ICT , delivered by D.Lewis CO payload types payload (30) HV1 audio (10) FEC (20) HV2 audio (20) FEC (10) HV3 audio (30) DV audio (10) header (1) payload (0-9) 2/3 FEC CRC (2) (bytes) eriel Huggard 4ICT , delivered by D.Lewis Baseband data rates ACL ayload User ymmetric Asymmetric Header ayload max. Rate max. Rate [kbit/s] Type [byte] [byte] FEC CRC [kbit/s] Forward Reverse 1 slot D /3 yes DH no yes slot D /3 yes DH no yes slot D /3 yes DH no yes AUX no no HV1 na 10 1/3 no 64.0 CO HV2 na 20 2/3 no 64.0 HV3 na 30 no no 64.0 DV 1 D 10+(0-9) D 2/3 D yes D D Data edium/high rate, High-quality Voice, Data and Voice eriel Huggard 4ICT , delivered by D.Lewis

6 Baseband link types olling-based TDD packet transmission 625µs slots, master polls slaves CO (ynchronous Connection Oriented) Voice eriodic single slot packet assignment, 64 kbit/s full-duplex, point-to-point ACL (Asynchronous ConnectionLess) Data Variable packet size (1,3,5 slots), asymmetric bandwidth, point-to-multipoint ATER CO ACL CO ACL CO ACL CO ACL f 0 f 4 f 6 f 8 f 12 f 14 f 18 f 20 LAVE 1 f 1 f 7 f 9 f 13 f 19 LAVE 2 f 5 f 21 f 17 eriel Huggard 4ICT , delivered by D.Lewis Baseband states of a Bluetooth device standby unconnected detach inquiry page connecting transmit AA connected AA active park A hold AA sniff AA low power tandby: do nothing Inquire: search for other devices age: connect to a specific device Connected: participate in a piconet ark: release AA, get A niff: listen periodically, not each slot Hold: stop ACL, CO still possible, possibly participate in another piconet eriel Huggard 4ICT , delivered by D.Lewis Robustness low frequency hopping with hopping patterns determined by a master rotection from interference on certain frequencies eparation from other piconets (FH-CDA) Retransmission ACL only, very fast Forward Error Correction CO and ACL Error in payload (not header!) NAK ATER A C C F H LAVE 1 B D E LAVE 2 G G eriel Huggard 4ICT , delivered by D.Lewis Example: ower consumption/cr BlueCore2 Typical Average Current Consumption (1) VDD=1.8V Temperature = 20 C ode CO connection HV3 (1s interval niff ode) (lave) 26.0 ma CO connection HV3 (1s interval niff ode) (aster) 26.0 ma CO connection HV1 (lave) 53.0 ma CO connection HV1 (aster) 53.0 ma ACL data transfer 115.2kbps UART (aster) 15.5 ma ACL data transfer 720kbps U (lave) 53.0 ma ACL data transfer 720kbps U (aster) 53.0 ma ACL connection, niff ode 40ms interval, 38.4kbps UART 4.0 ma ACL connection, niff ode 1.28s interval, 38.4kbps UART 0.5 ma arked lave, 1.28s beacon interval, 38.4kbps UART 0.6 ma tandby ode (Connected to host, no RF activity) 47.0 µa Deep leep ode(2) 20.0 µa Notes: (1) Current consumption is the sum of both BC212015A and the flash. (2) Current consumption is for the BC212015A device only. (ore: ) eriel Huggard 4ICT , delivered by D.Lewis

7 Example: Bluetooth/U adapter (2002: 50, 2005: 16) eriel Huggard 4ICT , delivered by D.Lewis L2CA logical channels lave aster lave L2CA baseband L2CA L2CA 2 d 1 1 d d d d 1 1 d d 2 baseband baseband signalling ACL connectionless connection-oriented eriel Huggard 4ICT , delivered by D.Lewis L2CA - Logical Link Control and Adaptation rotocol imple data link protocol on top of baseband Connection oriented, connectionless, and signalling channels rotocol multiplexing RFCO, D, telephony control egmentation & reassembly Up to 64kbyte user data, 16 bit CRC used from baseband Qo flow specification per channel Follows RFC 1363, specifies delay, jitter, bursts, bandwidth Group abstraction Create/close group, add/remove member eriel Huggard 4ICT , delivered by D.Lewis L2CA packet formats Connectionless DU bytes length CID=2 payload Connection-oriented DU bytes length CID payload ignalling command DU 2 2 bytes length CID=1 One or more commands code ID length data eriel Huggard 4ICT , delivered by D.Lewis

8 ecurity User input (initialization) IN (1-16 byte) airing IN (1-16 byte) E 2 Authentication key generation (possibly permanent storage) E 2 link key (128 bit) Authentication link key (128 bit) E 3 Encryption key generation (temporary storage) E 3 encryption key (128 bit) Encryption encryption key (128 bit) Keystream generator Keystream generator payload key Ciphering payload key Cipher data Data Data eriel Huggard 4ICT , delivered by D.Lewis Additional protocols to support legacy protocols/apps. RFCO Emulation of a serial port (supports a large base of legacy applications) Allows multiple ports over a single physical channel Telephony Control rotocol pecification (TC) Call control (setup, release) Group management OBEX Exchange of objects, IrDA replacement WA Interacting with applications on cellular phones eriel Huggard 4ICT , delivered by D.Lewis D ervice Discovery rotocol Inquiry/response protocol for discovering services earching for and browsing services in radio proximity Adapted to the highly dynamic environment Can be complemented by others like L, Jini, alutation, Defines discovery only, not the usage of services Caching of discovered services Gradual discovery ervice record format Information about services provided by attributes Attributes are composed of an 16 bit ID (name) and a value values may be derived from 128 bit Universally Unique Identifiers (UUID) eriel Huggard 4ICT , delivered by D.Lewis rofiles Represent default solutions for a certain usage model Applications Vertical slice through the protocol stack Basis for interoperability Generic Access rofile ervice Discovery Application rofile Cordless Telephony rofile Intercom rofile erial ort rofile rofiles Headset rofile Additional rofiles Dial-up Networking rofile Advanced Audio Distribution Fax rofile AN Audio Video Remote Control LAN Access rofile Basic rinting Generic Object Exchange rofile Basic Imaging Object ush rofile Extended ervice Discovery File Transfer rofile Generic Audio Video Distribution ynchronization rofile Hands Free Hardcopy Cable Replacement rotocols eriel Huggard 4ICT , delivered by D.Lewis

9 I band interference any sources of interference icrowave ovens, microwave lightning , b, g, , Home RF Even analog TV transmission, surveillance Unlicensed metropolitan area networks OLD NEW Levels of interference hysical layer: interference acts like noise pread spectrum tries to minimize this FEC/interleaving tries to correct AC layer: algorithms not harmonized E.g., Bluetooth might confuse Fusion Lighting, Inc. eriel Huggard 4ICT , delivered by D.Lewis vs.(?) /Bluetooth Bluetooth may act like a rogue member of the network Does not know anything about gaps, inter frame spacing etc. f [Hz] b 0 byte 3 channels IF discusses these problems roposal: Adaptive Frequency Hopping a non-collaborative Coexistence echanism Real effects? any different opinions, publications, tests, formulae, Results from complete breakdown to almost no effect Bluetooth (FH) seems more robust than b (D) t (separated by installation) channels (separated by hopping pattern) DIF IF DIF IF DIF DIF DIF 500 byte byte byte 500 byte byte byte 500 byte byte DIF IF DIF IF DIF IF DIF IF DIF IF ummary: WAN: -1 Bluetooth Data rate ynchronous, connection-oriented: 64 kbit/s Asynchronous, connectionless kbit/s symmetric / 57.6 kbit/s asymmetric Transmission range O (ersonal Operating pace) up to 10 m with special transceivers up to m Frequency Free 2.4 GHz I-band ecurity Challenge/response (AFER+), hopping sequence Availability Integrated into many products, several vendors Connection set-up time Depends on power-mode ax. 2.56s, avg. 0.64s Quality of ervice Guarantees, ARQ/FEC anageability ublic/private keys needed, key management not specified, simple system integration pecial Advantages/Disadvantages Advantage: already integrated into several products, available worldwide, free I-band, several vendors, simple system, simple ad-hoc networking, peer to peer, scatternets Disadvantage: interference on Iband, limited range, max. 8 devices/network&master, high set-up latency eriel Huggard 4ICT , delivered by D.Lewis eriel Huggard 4ICT , delivered by D.Lewis WAN: future developments : Coexistance Coexistence of Wireless ersonal Area Networks (802.15) and Wireless Local Area Networks (802.11), quantify the mutual interference : High-Rate tandard for high-rate (20bit/s or greater) WANs, while still lowpower/low-cost Data Rates: 11, 22, 33, 44, 55 bit/s Quality of ervice isochronous protocol Ad hoc peer-to-peer networking ecurity Low power consumption Low cost Designed to meet the demanding requirements of portable consumer imaging and multimedia applications eriel Huggard 4ICT , delivered by D.Lewis

10 WAN: future developments 2 everal working groups extend the standard a: Alternative HY with higher data rate as extension to Applications: multimedia, picture transmission b: Enhanced interoperability of AC Correction of errors and ambiguities in the standard c: Alternative HY at GHz Goal: data rates above 2 Gbit/s Not all these working groups really create a standard, not all standards will be found in products later eriel Huggard 4ICT , delivered by D.Lewis WAN: future developments : Low-Rate, Very Low-ower Low data rate solution with multi-month to multi-year battery life and very low complexity otential applications are sensors, interactive toys, smart badges, remote controls, and home automation Data rates of kbit/s, latency down to 15 ms aster-lave or eer-to-eer operation Up to 254 devices or simpler nodes upport for critical latency devices, such as joysticks CA/CA channel access (data centric), slotted (beacon) or unslotted Automatic network establishment by the AN coordinator Dynamic device addressing, flexible addressing format Fully handshaked protocol for transfer reliability ower management to ensure low power consumption 16 channels in the 2.4 GHz I band, 10 channels in the 915 Hz U I band and one channel in the European 868 Hz band Basis of the ZigBee technology eriel Huggard 4ICT , delivered by D.Lewis