1 Introduction to Wireless Networking Geier Book (Chapter 1) Dayem Book (Chapter 2)

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Presentation transcript:

1 Introduction to Wireless Networking Geier Book (Chapter 1) Dayem Book (Chapter 2)

2 Outline History Wireless Network Architecture Benefits of Wireless Networks Concerns of Wireless Communication Wireless Spectrum

3 History of Wireless Networks Progress of transmission: fire and smoke used by Indians ==> messenger on horseback ==> telephone line ==> networks Traditional networks (LAN, MAN, WAN) have provided great convenience: in office, hotel room, or home. But you cannot utilize the service unless you are physically connected to a LAN or a telephone line. ALOHANET by Univ. of Hawaii: 7 campuses over 4 islands; star-like structure centered at the Oahu island.

4 (cont.) In 80 ’ s, amateur radio hobbyists built TNC (terminal node controller) to interface “ hams ” radio equipment and their computers.

5 Progress of Wireless Comm. (cont.) In 1985, FCC authorized the use of ISM bands for Industrial, Scientific, and Medical for commercial development. ISM bands = 902MHz and 5.85 GHz ISM is very attractive to vendors because NO obtaining FCC license is required. In 80 ’ s, small-size computers started to appear. laptop, palmtop, PDA Wireless LAN products populate

6 Standardization and Promotion wireless LAN: IEEE standard was finalized in July IEEE a, b, e, g, i, r, etc. wireless WAN: Packet radio networks (e.g., RAM) Personal Communication Service (PCS): 1.9 GHz sold $7.7 billion to TV company in 1995 by VP Al Gore. $15 billion in 1996.

7 Wireless Network Architecture General functions of networks: bit pipe of data MAC for sharing of a common medium synchronization and error control routing OSI reference model: Fig. 1.2 wireless LAN/MAN/WAN layers: Fig. 1.3

8 Wireless Network Interface Card Functionality: modulation: translate baseband signal to a suitable analog form amplification: raise signal strength synchronization: carrier sense (Fig. 1.6) error checking:

9 Antenna Concept propagation pattern: radiation power: typically less than a few watts gain: degree of amplification omni-directional = 1 directional > 1 (good for longer distance) example: watering your lawn direction: omnidirectional or directional

10 Communication Channel Air Pure nitrogen and oxygen are effective for transmission. rain, fog, snow are obstacles. Space Water

11 Benefits of Wireless Networks Mobility: Example: talking on a cordless phone vs. cord phone. Installation in Difficult-to-Wire Areas: rivers, freeways, old building Hazard materials (such as asbestos particles) when drilling. Right-of-way restrictions in some city to dig ground. Reduced Installation Time: It may take months to receive right-of-way approvals. Increased Reliability: cable vs. cable-less Long-term savings: never need re-cabling

12 Wireless Network Concerns Interference Issues Power Management Electricity in battery is a limited resource. modes control: System Interoperability e.g., IEEE standard

13 Security Concerns Security Threats: Radio waves can easily penetrate walls. One can passively retrieve your radio signal without being noticed (Fig. 1.10). Electronic sabotage: someone maliciously jam your wireless network

14 Installation Issues Wireless coverage as a contour: Fig Intra-system interference: e.g., between access points Inter-system interference: e.g., from external Bluetooth, which is also on 2.4 GHz

15 Health Risks So far, no conclusive answer yet!! Radio is safer than cellular phones!! Wireless network is even safer as it operates at 50~100 milliwatts, compared to 600mw~3w of cellular phones. US Detp. of Food and Drug classifies risks into 4 classes: class I: wireless LAN, supermarket scanner class III: wireless MAN (could damage eyes if watching directly) class IV: laser scalpel

16 Wireless Spectrum (LAN vs. WAN)

17 Wireless MAP Where do we spend our time? office (wireless LAN and wireless PBX) residential, public area (PHS, CT-2) mobile (GSM, GPRS, 3G)

18 Wireless WAN vs. LAN Wireless WAN: transmission speed: 10K-1M real-time voice supported: circuit-switching ubiquitous coverage roaming speed: vehicular Wireless LAN: transmission speed: > 1Mbps packet-switching coverage: a few hundred meters roaming speed: pedestrian

19 Wireless WAN Examples cellular: now moving from analog to digital paging: one-way alerting packet-radio: data service (RAM, Mobitex) satellite: low earth-orbit system Motorola ’ s Iridium system: 66 satellites Qualcomm and Microsoft: > 800 satellites cordless: smaller cells (DECT) PCS: voice + data

20 The Radio Spectrum 10 3

21 Radio Spectrum (cont.) We separate frequencies as “ extremely low ”, “ very low ”, “ medium ”, “ high ”, “ very high ”, “ ultra high ”, “ microwave region ”, “ infrared region ”, “ visible light region ”, and “ X-ray ”. Audio: 20 Hz to 20 KHz AM radio station: 1 MHz FM and TV: 100 MHz

22 Cell Size vs. Throughput Cell sizes can vary from tens of meters to thousands of kilometers. Data rates may range from 0.1 K to 50 Mbps Examples: LAN: high rate (11 M), small range (50 m) Satellite: low rate (10 K), extremely large range (1000 Km) Paging: very low rate (1 Kbps), large cell (10s of Km)

23 Examples: (cont.) Packet Radio Networks: cell size can be 10s of km data rate: 10 to 20 Kbps CT-2: cell size: 100 meters date rate: order of 10 Kbps PCS: cell size: 100 meters to 10s of km data rate: order of 100 Kbps

24 Summary smaller cell size implies higher data rate, less power consumption, more handovers, and more frequency reuse