CWNA Guide to Wireless LANs, Second Edition (Modified Spring 2007)

1. CWNA Guide to Wireless LANs, Second Edition(Modified Spring 2007) Chapter Three How Wireless Works

2. Objectives • Explain the principals of radio wave transmissions • Describe RF loss and gain, and how it can be measured • List some of the characteristics of RF antenna transmissions • Describe the different types of antennas • Understanding principles of radio wave transmission is important for: • Troubleshooting wireless LANs • Creating a context for understanding wireless terminology CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

3. What Are Radio Waves? • Electromagnetic wave: Travels freely through space in all directions at speed of light • Radio wave: When electric current passes through a wire it creates a magnetic field around the wire • As magnetic field radiates, creates an electromagnetic radio wave • Spreads out through space in all directions • Can travel long distances • Can penetrate non-metallic objects CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

4. Analog vs. Digital Transmissions Analog Signal = A signal that has continuously varying voltages, frequencies, or phases. All amplitude values are present from minimum to maximum signal levels. Digital Signal = A signal in which information is carried in a limited number of different discrete states or levels; High/Low, One/Zero, 1/0 CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

5. Analog vs. Digital Transmissions • Analog Transmission use analog carrier signals and analog modulation. • Digital Transmission use analog carrier signals and digital modulation. • Modem (MOdulator/DEModulator): Used when digital signals must be transmitted over analog medium • On originating end, converts distinct digital signals into continuous analog signal for transmission • On receiving end, reverse process performed • WLANs use digital modulation of analog signals (carrier signal) CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

6. Frequency • Frequency: f= Rate at which an event occurs f =1/T • Cycle: Changing event that creates different radio frequencies • When wave completes trip and returns back to starting point it has finished one cycle • Period: T=The time to complete one cycle T=1/f • Hertz (Hz): Cycles per second • Kilohertz (KHz) = thousand hertz • Megahertz (MHz) = million hertz • Gigahertz (GHz) = billion hertz CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

7. Frequency and Period CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

8. Frequency CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

9. Electrical terminology CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

10. Modulation • Carrier signal is a continuous electrical signal • Carries no information • Three types of modulations enable carrier signals to carry information • Height of signal • Frequency of signal • Relative starting point • Modulation can be done on analog or digital transmissions CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

11. Analog Modulation • Amplitude: Height of carrier wave • Amplitude modulation (AM): Changes amplitude so that highest peaks of carrier wave represent 1 bit while lower waves represent 0 bit • Frequency modulation (FM): Changes number of waves representing one cycle • Number of waves to represent 1 bit more than number of waves to represent 0 bit • Phase modulation (PM): Changes starting point of cycle • When bits change from 1 to 0 bit or vice versa CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

12. Analog Modulation Amplitude modulation (AM) – Carrier frequency varies in amplitude Frequency modulation (FM) – Carrier frequency varies in frequency Phase modulation (PM) –Carrier varies in phase CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

13. Digital Modulation • Advantages over analog modulation: • Better use of bandwidth • Requires less power • Better handling of interference from other signals • Error-correcting techniques more compatible with other digital systems • Unlike analog modulation, changes occur in discrete steps using binary signals • Uses same three basic types of modulation as analog Amplitude shift keying (ASK) CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

14. Digital Modulation Frequency shift keying (FSK) Phase shift keying (PSK) CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

15. Radio Frequency Behavior: Gain • Gain: Positive difference in amplitude between two signals • Achieved by amplification of signal • Technically, gain is measure of amplification • Can occur intentionally from external power source that amplifies signal • Can occur unintentionally when RF signal bounces off an object and combines with original signal to amplify it CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

16. Radio Frequency Behavior: Gain (continued) Figure 3-16: Gain CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

17. Radio Frequency Behavior: Loss • Loss: Negative difference in amplitude between signals • Attenuation • Can be intentional or unintentional • Intentional loss may be necessary to decrease signal strength to comply with standards or to prevent interference • Unintentional loss can be cause by many factors CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

18. Radio Frequency Behavior: Loss (continued) Figure 3-18: Absorption CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

19. Radio Frequency Behavior: Loss (continued) Figure 3-19: Reflection CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

20. Radio Frequency Behavior: Loss (continued) Figure 3-20: Scattering CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

21. Radio Frequency Behavior: Loss (continued) Figure 3-21: Refraction CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

22. Radio Frequency Behavior: Loss (continued) Figure 3-22: Diffraction CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

23. Radio Frequency Behavior: Loss (continued) Figure 3-23: VSWR CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

24. RF Measurement: RF Math • RF power measured by two units on two scales: • Linear scale: • Using milliwatts (mW) • Reference point is zero • Does not reveal gain or loss in relation to whole • Relative scale: • Reference point is the measurement itself • Often use logarithms • Measured in decibels (dB) • 10’s and 3’s Rules of RF Math: Basic rule of thumb in dealing with RF power gain and loss CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

25. RF Measurement: RF Math (continued) Table 3-3: The 10’s and 3’s Rules of RF Math CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

26. RF Measurement: RF Math (continued) • dBm: Reference point that relates decibel scale to milliwatt scale • Equivalent Isotropically Radiated Power (EIRP): Power radiated out of antenna of a wireless system • Includes intended power output and antenna gain • Uses isotropic decibels (dBi) for units • Reference point is theoretical antenna with 100 percent efficiency CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

27. RF Measurement: WLAN Measurements • In U.S., FCC defines power limitations for WLANs • Limit distance that WLAN can transmit • Transmitter Power Output (TPO): Measure of power being delivered to transmitting antenna • Receive Signal Strength Indicator (RSSI): Used to determine dBm, mW, signal strength percentage Table 3-4: IEEE 802.11b and 802.11g EIRP CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

28. Antenna Concepts • Radio waves transmitted/received using antennas Figure 3-24: Antennas are required for sending and receiving radio signals CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

29. Characteristics of RF Antenna Transmissions • Polarization: Orientation of radio waves as they leave the antenna Figure 3-25: Vertical polarization CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

30. Antenna Characteristics CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

31. Characteristics of RF Antenna Transmissions (continued) • Wave propagation: Pattern of wave dispersal Figure 3-26: Sky wave propagation CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

32. Characteristics of RF Antenna Transmissions (continued) Figure 3-27: RF LOS propagation CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

33. Characteristics of RF Antenna Transmissions (continued) • Because RF LOS propagation requires alignment of sending and receiving antennas, ground-level objects can obstruct signals • Can cause refraction or diffraction • Multipath distortion: Refracted or diffracted signals reach receiving antenna later than signals that do not encounter obstructions • Antenna diversity: Uses multiple antennas, inputs, and receivers to overcome multipath distortion CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

34. Characteristics of RF Antenna Transmissions (continued) • Determining extent of “late” multipath signals can be done by calculating Fresnel zone Figure 3-28: Fresnel zone CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

35. Characteristics of RF Antenna Transmissions (continued) • As RF signal propagates, it spreads out • Free space path loss: Greatest source of power loss in a wireless system • Antenna gain: Only way for an increase in amplification by antenna • Alter physical shape of antenna • Beamwidth: Measure of focusing of radiation emitted by antenna • Measured in horizontal and vertical degrees CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

36. Characteristics of RF Antenna Transmissions (continued) Table 3-5: Free space path loss for IEEE 802.11b and 802.11g WLANs CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

37. Antenna Types and Their Installations • Two fundamental characteristics of antennas: • As frequency gets higher, wavelength gets smaller • Size of antenna smaller • As gain increases, coverage area narrows • High-gain antennas offer larger coverage areas than low-gain antennas at same input power level • Omni-directional antenna: Radiates signal in all directions equally • Most common type of antenna CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

38. Antenna Types and Their Installations • Semi-directional antenna: Focuses energy in one direction • Primarily used for short and medium range remote wireless bridge networks • Highly-directional antennas: Send narrowly focused signal beam • Generally concave dish-shaped devices • Used for long distance, point-to-point wireless links CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

39. Antenna Issues (cont.) • Antennas have gain in particular directions • Direction other than the main intended radiation pattern, are typically related to the main lobe gain CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

40. Antenna Gain • If the gain of an antenna goes up, the coverage area or angle goes down • Coverage areas or radiation patterns are measured in degrees • Angles are referred to as beamwidth • Horizontal measurement • Vertical measurement CCRI J. Bernardini

41. Antenna Theory • A theoretical isotropic antenna has a perfect 360º vertical and horizontal beamwidth • This is a reference for ALL antennas CCRI J. Bernardini

42. Side View (Vertical Pattern) Vertical Beamwidth New Pattern (with Gain) Top View (Horizontal Pattern) Antenna Theory- Dipole • Energy lobes are ‘pushed in’ from the top and bottom • Higher gain • Smaller vertical beamwidth • Larger horizontal lobe • Typical dipole pattern CCRI J. Bernardini

43. High Gain Omni-Directionals • More coverage area in a circular pattern • Energy level directly above or below the antenna will become lower CCRI J. Bernardini

44. Side View (Vertical Pattern) Top View (Horizontal Pattern) Directional Antennas • Lobes are pushed in a certain direction, causing the energy to be condensed in a particular area • Very little energy is in the back side of a directional antenna CCRI J. Bernardini

45. WLAN Antenna Locations and Installation • Because WLAN systems use omni-directional antennas to provide broadest area of coverage, APs should be located near middle of coverage area • Antenna should be positioned as high as possible • If high-gain omni-directional antenna used, must determine that users located below antenna area still have reception CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

46. Summary • A type of electromagnetic wave that travels through space is called a radiotelephony wave or radio wave • An analog signal is a continuous signal with no breaks in it • A digital signal consists of data that is discrete or separate, as opposed to continuous • The carrier signal sent by radio transmissions is simply a continuous electrical signal and the signal itself carries no information CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

47. Summary (continued) • Three types of modulations or changes to the signal can be made to enable it to carry information: signal height, signal frequency, or the relative starting point • Gain is defined as a positive difference in amplitude between two signals • Loss, or attenuation, is a negative difference in amplitude between signals • RF power can be measured by two different units on two different scales CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini

48. Summary (continued) • An antenna is a copper wire or similar device that has one end in the air and the other end connected to the ground or a grounded device • There are a variety of characteristics of RF antenna transmissions that play a role in properly designing and setting up a WLAN CWNA Guide to Wireless LANs, Second EditionCCRI J. Bernardini