Chapter 6: Connecting Through a Wireless Network

1. Chapter 6: Connecting Through a Wireless Network

2. Current Wireless Networking Technologies • Two drawbacks of wire-based networking • Tangle of wires connecting computer and peripherals • Cost of pulling wires through walls, ceilings, floors • Wireless technology resolves many wire-based issues • Wireless media are forms of electromagnetic radiation • Three major current wireless networking technologies • Radio wave technologies (short range and a popular option) • Infrared technologies (short range) • Terrestrial and satellite microwave technologies (long range) Hands-on Networking Fundamentals

3. A Short History of Wireless Networks • Wireless standards develop in parallel with ham radio • Telecommunications Act of 1996 • IEEE 802.11 standard set in 1997 • A few of the entities influencing standards • IEEE (Institute of Electrical and Electronics Engineers) • IETF (International Engineering Task Force) • ISO (International Organization for Standardization) Hands-on Networking Fundamentals

4. Wireless Network Support Organizations • Wi-Fi Alliance • Offers a certification program to vendors • Tests wireless devices so they can be certified to meet IEEE 802.11 standards • Devices that pass the testing can display the Wi-Fi CERTIFIED insignia Hands-on Networking Fundamentals

5. Radio Wave Technologies • Frequency ranges of various transmission types • Network signals are transmitted over higher frequencies than local radio station broadcasts • AM: 535–1605 kilohertz (kHz) • FM: 88–108 megahertz (MHz) • Network: 902-928 MHz, 2.4-2.4835 GHz, 5-5.825 GHz • Directional signal transmitted between buildings • Transmission involves sending and receiving antennas • Wave is short in length and low-power (1-10 watts) • Suitable for line-of-sight transmission • Signal goes from point to point on earth's surface • Limitations due to interruptions, such as hills • Data capacity range: 1 Mbps to over 300 Mbps Hands-on Networking Fundamentals

6. Spread Spectrum • Spread spectrum technology for packet transmissions • Spreads transmission over adjoining frequencies (allows for greater bandwidth use) • Frequency range: 902–928 MHz range • Data transfer range: 1–600 Mbps Hands-on Networking Fundamentals

7. Radio Wave Technologies • Disadvantages to radio wave communications • Wireless networks are more susceptible to interference (such as interference caused by certain building materials and by surrounding electrical devices) • Some wireless frequencies are shared by amateur radio operators, the US military, and cell phone companies – can cause interference • Interference from natural obstacles • Inadequate security • Other radio wave technologies include Bluetooth, HiperLAN, Infrared, WiMAX, HiperMAN, and cellular phone Hands-on Networking Fundamentals

8. IEEE 802.11 Radio Wave Networking • IEEE 802.11 group: most influential wireless standards • Includes 802.11a, 802.11b, 802.11g, and 802.11n • Communication with 802.11 devices is non-proprietary • Features of 802.11 standards • Encompass either fixed or mobile wireless stations • Involve two kinds of communications • Asynchronous: discrete units with a start and stop bit • Synchronous: signal has timing restrictions • Support SNMP protocol and network authentication • Operate at two lower OSI layers: Data Link and Physical • Recognize indoor and outdoor wireless communication Hands-on Networking Fundamentals

9. Wireless Components • Three components: transceiver, access point, antenna • Wireless NIC (WNIC): transceiver card • Functions as transmitter and receiver • Operates at Physical and Data Link layers of OSI model • May be internal (PCI card), a removable CardBus, or external (USB key fob) • Most are compatible with the Microsoft Network Driver Interface Specification (NDIS) • Enables support for multiple protocols • Essential to the function of WNICs Hands-on Networking Fundamentals

10. Wireless Components • Access point: interfaces WNICs and a cabled network (allows wireless devices to communicate with non-wireless devices) • May support the following types of network interfaces: AUI, 10Base2, 10BaseT, 100Base technologies, 1000Base technologies, 40 GB Ethernet technologies, 100 GB Ethernet technologies, FDDI, Cable modem port, or DSL telecommunications port • Antenna: device that radiates and receives radio waves • Both WNICs and access points employ antennas • Most are either directional or omnidirectional Hands-on Networking Fundamentals

11. Directional Antenna • Sends radio waves in one main direction • Amplifies signal better than omnidirectional antenna • Gain: amplification of radiated signal • Application: transmitting signals between buildings • Each building has an antenna • Antennas connected to access points • Signal has more gain in one direction • Small portion of signal is radiated outward Hands-on Networking Fundamentals

12. Hands-on Networking Fundamentals Figure 6-2 Directional antenna

13. Omnidirectional Antenna • Radiates radio waves in all directions • Diffused signal likely has less gain than directional type • Most often used on an indoor network • Mobile users need to send and receive in all directions • Signals moving over shorter distances require less gain • Omnidirectional antenna deployed varies with device • WNIC on portable devices use a snap-on antenna • Access point for indoor network • May have a snap-on antenna • May connect to antenna using cable • Outdoor access point connects to antenna via a cable Hands-on Networking Fundamentals

14. Hands-on Networking Fundamentals Figure 6-3 Omnidirectional antennas

15. Wireless Networking Access Methods • Two access methods: priority-based and CSMA/CA • Priority-based access • Access point device functions as a point coordinator • Point coordinator establishes contention-free period during which it polls stations to see which devices need to transmit • Intended for time sensitive communications • Voice, video, and videoconferencing are examples • Carrier Sense Multiple Access with Collision Avoidance (CSMA/CA) • Also called the distributed coordination function • CSMA/CA works to avoid collisions • Coordinate nodes using DIFS delay and backoff time Hands-on Networking Fundamentals

16. Interference • Interference may corrupt data transmission • Many sources of interference • Natural: weather, solar flares, mountains • Artificial: other wireless communications, buildings Hands-on Networking Fundamentals

17. Transmission Speeds • Transmission speeds are defined through four standards: 802.11a, 802.11b, 802.11g, 802.11n • Correspond to the Physical layer of the OSI model • There are two newer very-high-speed wireless LAN standards under development: • 802.11ac • 802.11ad Hands-on Networking Fundamentals

18. 802.11g • Supports three transmission methods on the 2.4 GHz band • OFDM (native mode) • Similar to OFDM under 802.11a (different bands) • Minimum speed: 6 Mbps • Maximum speed: 54 Mbps • Complementary Code Keying (CCK) • Used with DSSS for backward compatibility with 802.11b • Minimum speed: 1 Mbps • Maximum speed: 11 Mbps • Packet Binary Convolution Code (PBCC) • Unofficial extension used with 802.11b • Offers speeds of 22 Mbps and 33 Mbps Hands-on Networking Fundamentals

19. 802.11g • Restrictions and considerations using 802.11g • Devices must support minimum speeds by standard • Speed values: 1, 2, 5.5, 6, 11, 12, and 24 Mbps • Slightly shorter range than 802.11b • More access points may be needed • Smaller bandwidth (90 MHz) than 802.11a or 802.11b • No more than three access points in given area • Devices combine with 802.11b devices on one LAN • Advantage: retain earlier investment in 802.11b • Disadvantage: lowers network performance Hands-on Networking Fundamentals

20. 802.11n • Uses a technology called multiple-input multiple-output (MIMO) with spatial multiplexing • Uses multiple antennas at the transmitting and receiving devices • Spatial multiplexing – means a device can transmit and receive two or more data streams over one channel within a frequency • Multiple frames can be aggregated together in one transmission • 802.11n uses smaller sized ACK frames (8 bytes) and one ACK can be used to verify receipt of multiple frames (called a block ACK) Hands-on Networking Fundamentals

21. 802.11n • Number of times a channel must be acquired and released is significantly reduced due to frame aggregation, making it more efficient than other 802.11 technologies • Can use 20 and 40 MHz channels within the 2.4 and 5 GHz bands • Can be up to four simultaneous data streams per 20 or 40 MHz channel for a top speed of 600 Mbps • At this writing, most 802.11n devices have a top speed of 300+ Mbps • Factors such as distance, obstacles, and electrical interference can affect actual throughput Hands-on Networking Fundamentals

22. 802.11ac • Currently under development at this writing • Designed around the technologies used by 802.11n • MIMO is expanded into multiuser MIMO or MU-MIMO • Frames sent to and from multiple users can be sent simultaneously on the same channel • Expands transmission capabilities to use the 80 MHz channel for even wider bandwidth Hands-on Networking Fundamentals

23. 802.11ad • Also under development at this writing • Targeted at accomplishing transmission speeds of roughly 7 Gbps • Operates using the 60 MHz channel • Designed for shorter transmission distances (likely to be restricted by walls • Manufacturers are looking at 802.11ad for Wi-Fi based phone communications and HD movies on big-screen wireless TVs Hands-on Networking Fundamentals

24. 802.11a, 802.11b, 802.11g and 802.11n Compared • 802.11a, 80211g, and 802.11n standards offer greater speed • Range varies per standard • 802.11a devices transmit up to 18 meters • 802.11b devices reach over 91 meters • 802.11g devices transmit between 30 and 100 meters • 802.11n devices can reach up to 200 meters Hands-on Networking Fundamentals

25. 802.11a, 802.11b, 802.11g and 802.11n Compared • Uses for 802.11a, 802.11g and 802.11n devices • Applications requiring high bandwidth (voice and video) • In small areas with high concentration of users (lab) • 802.11b devices are used when bandwidth is not critical • 802.11n is a much better and more versatile alternative than 802.11a, 802.11b, or 802.11g Hands-on Networking Fundamentals

26. 802.11 Deployment Tips • Do not place an access point against a wall or floor • If possible, place the access point in a main or central location • If the access point cannot be centrally located, consider extending the signal by using a wireless repeater or by replacing an omnidirectional antenna with a directional antenna • Avoid placing the access point on or inside a metal cabinet or shelf • Remove sources of interference such as microwave ovens, cordless phones, etc… Hands-on Networking Fundamentals

27. 802.11 Deployment Tips • Consider replacing internal WNICs that do not have external antennas with WNICs that have them • Replace any 802.11a, 802.11b and 802.11g devices with 802.11n devices (or with 802.11ac as these become available • Use the 5 GHz band and 40 MHz channels for 802.11n access points • Purchase devices with multiple antennas for more data streaming capability Hands-on Networking Fundamentals

28. 802.11 Security Techniques • Methods attackers can use to infiltrate: • Identify wireless network targets by using: • Antenna: vary by directionality and gain • Wireless NIC: connects to antenna • Global positioning system (GPS): locates target • War-driving software: passes data from antenna to GPS • Use network sniffer to capture packets • Purpose: capture ids or passwords, conduct espionage • Man-in-the-middle attack: interception of message • 802.11 standards offers several security approaches Hands-on Networking Fundamentals

29. Open System Authentication • Allows any two stations to authenticate each other • Simple method • Sender requests authentication from destination • Authentication is complete when receiver verifies request • Provides very little security • Used by default by many vendor devices Hands-on Networking Fundamentals

30. Shared Key Authentication and Wired Equivalent Privacy (WEP) • Two stations use the same WEP encryption key • Consists of key, checksum, initialization information • Total key length is 64- or 128-bits • 128-bit key supports superior 128-bit encryption • Up to four WEP keys can be stored in key index • Authenticating using shared key and WEP • Sender requests authentication from another station • Contacted station sends back challenge text • Sender encrypts challenge text, returns to challenger • If returned text properly decoded, verification sent Hands-on Networking Fundamentals

31. Wi-Fi Protected Access (WPA) • Uses WEP-like features, but encrypted keys change • Key changes make WPA more secure than WEP • WPA2 is latest version • Uses Advanced Encryption Standard (AES) • Considered “government grade security” • The private key can be either 128, 192, or 256 bits in length • Preshared key (PSK) is a WPA enhancement • Targeted for home and small networks that do not have additional enterprise network security measures Hands-on Networking Fundamentals

32. Wi-Fi Protected Access (WPA) • Setting up PSK network security • Enter a password or passphrase (master key when installing access point) • After the password is entered, WPA is automatically activated • All wireless devices must use the same passphrase • When configuring WPA or WPA2 there can be two options: • Personal – typically used on home or small networks • Enterprise – coordinates security through an enterprise-wide Remote Authentication Dial-Up User Service (RADIUS) server Hands-on Networking Fundamentals

33. Service Set Identifier • SSID: identification value up to 32 characters in length • Value defines logical network for all member devices • Examples of SSIDs • Series of random characters • String identifying network purpose, such as "Atmospheric Research" • SSID often configured by default • Ensure that vendor default is replaced • Use SSID value difficult to guess Hands-on Networking Fundamentals

34. 802.1X and 802.11i Security • 802.1X: wireless and wired authentication approach • Port-based form of authentication • Ports over which connection is made act in two roles • Uncontrolled: allows unauthenticated communications • Controlled: allows only authenticated communications • Node roles: supplicant and authenticator • Disadvantage: authentication process not encrypted • 802.11i adds three features to enhance 802.1x • Temporal Key Integrity Protocol (TKIP) • Advanced Encryption Standard (AES) • Robust Secure Network (RSN) Hands-on Networking Fundamentals

35. Using Authentication to Disconnect • Two stations disconnect when: • Either sends a deauthentication notice • Deauthentication notice results in instant termination • Two communicating stations cannot be inadvertently disconnected by another nonauthenticated station Hands-on Networking Fundamentals

36. 802.11 Network Topologies • Independent basic service set (IBSS) topology • Consist of two or more stations in direct communication • Peer-to-peer communication between WNICs on nodes • Stations are often added on impromptu basis • Extended service set (ESS) topology • Deploys one or more access points • Enables more extensive area of service than the IBSS • Network sizes range from small to large • IBSS network is easy to expand into an ESS network • Avoid combining both networks in same proximity Hands-on Networking Fundamentals

37. Hands-on Networking Fundamentals Figure 6-14 ESS wireless topology

38. Multiple Cell Wireless LANs • Occur when an ESS topology employs two or more access points • Cell: broadcast area around single access point • Roaming: ability to move wireless device across cells • Cells must be configured with same frequency, speed, security • Inter-Access Point Protocol (IAPP) • Enables a mobile station to move among cells • Encapsulates UDP and IP for roaming communications • Enables existing access points to be notified and exchange information when a new access point is attached to a network Hands-on Networking Fundamentals

39. Alternative Radio Wave Technologies • Popular alternatives to 802.11 group • Bluetooth • HiperLAN • Each of these is a wireless specification developed and supported by specific vendors Hands-on Networking Fundamentals

40. Bluetooth • Defined through the Bluetooth Special Interest Group • Characteristics • Uses Frequency Hopping Spread Spectrum (FHSS) • Frequency hopping: transmissions hop among 79 frequencies • Occurs in 2.4 GHz range (2.4–2.4835 GHz) • Uses high wattage transmissions that can reach up to 100 meters • Can use asynchronous or synchronous communication • Bluetooth v. 3 offers the optional high speed specification which can transmit up to 24 Mbps Hands-on Networking Fundamentals

41. Bluetooth • Bluetooth v. 4 offers three operating environments: • High-speed: implements Bluetooth version 3+HS • Low-energy: used for sensors such as in-home glucose monitors, pedometers, watches, and remote control devices • Can transmit at up to 1 Mbps at a range of about 100 meters • Classic: encompasses the older versions of Bluetooth from 1.1 – 3.0 (excluding 3.0+HS) with a maximum data rate of approximately 1 Mbps Hands-on Networking Fundamentals

42. Bluetooth • Bluetooth devices are divided into three classes based on range: • Class 1: up to about 100 meters • Typically used for network-type applications such as wireless access points • Class 2: up to about 10 meters • Typically used for wireless devices such as keyboards, mice, microphones, and audio devices • Class 3: up to about 1 meter • Typically used for close range transmissions such as medical monitoring devices, watches, and exercise monitoring Hands-on Networking Fundamentals

43. Bluetooth • Bluetooth uses time division duplexing (TDD) • Packets are sent in alternating directions using time slots • One of three encryption modes can be configured: • Mode 1: no encryption is used • Mode 2: communications that are addressed are encrypted but broadcasts are not encrypted • Mode 3: all communications are encrypted used a 128-bit encryption master key • Stream cipher encryption is used for Bluetooth Hands-on Networking Fundamentals

44. HiperLAN • High-Performance Radio Local Area Network • Features of second version, HiperLAN2 • Transmits at up to 54 Mbps in the 5 GHz range • Compatible with Ethernet • Supports Data Encryption Standard (DES) • Supports Quality of Service (QoS) • HiperLAN2 operates in two modes • Direct: peer-to-peer similar to 802.11 IBSS topology • Centralized: certain access points centralize control • Both HiperLAN2 modes use TDD Hands-on Networking Fundamentals

45. Infrared Technologies • Broadcasts in single direction or all directions • Advantages of infrared medium • Inexpensive • Difficult to intercept • Not susceptible to RFI or EMI • Disadvantages of infrared medium • Slow data transmissions (between 1 and 16 Mbps) • Does not penetrate walls • Experiences interference from strong visible light • Diffused infrared: reflects infrared light from ceiling • Defined by IEEE 802.11R standard • Communication with pulse position modulation (PPM) Hands-on Networking Fundamentals

46. Hands-on Networking Fundamentals Figure 6-15 Diffused infrared wireless communications

47. Wireless MANs • Based on IEEE 802.16 standard (WiMAX) • Provides connectivity up to 75 Mbps • Has a reach of up to 30 miles • WiMAX called connection for "last mile" • Connects home or office to wired network provider • Implementing WiMAX for rural office • Install wireless communication at network provider • Include a directional or omnidirectional antenna • Connect directional antenna to wireless router in office • Point office antenna to provider's antenna Hands-on Networking Fundamentals

48. Wireless MANs • WiMAX operates in the 2 to 66 GHz range • In the US most WiMAX networks at the 2.3, 2.5, 3.5, 3.65, and 5.8 GHz frequencies • The IEEE 802.16 standard provides connectivity up to 75 Mbps with a reach of up to 48 kilometers (30 miles) • In many installations the actual distance is 8-16 kilometers (5-10 miles) • WiMAX can be a cost-effective way to create a network over several miles Hands-on Networking Fundamentals

49. Microwave Technologies • Work in one of two ways: terrestrial and satellite • Have theoretical bandwidth up to 720 Mbps and beyond Hands-on Networking Fundamentals

50. Terrestrial Microwave • Characteristics of transmission • Between two directional parabolic antennas (dishes) • Performed in ranges of 4–6 GHz and 21–23 GHz • Require the operator to obtain an FCC license • Uses of terrestrial microwave transmission • Where cabling costs are too high • Where cabling and wireless options not possible • Example: between two large buildings in a city Hands-on Networking Fundamentals