Antenna Selection for Optimal Wireless LAN Performance
This article provides an overview of antenna properties and RF propagation characteristics. It explains how choosing the right antenna is essential to achieve optimum performance in wireless systems. The article also covers current wireless antenna technologies.
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PowerPoint presentation about 'Antenna Selection for Optimal Wireless LAN Performance'. This presentation describes the topic on This article provides an overview of antenna properties and RF propagation characteristics. It explains how choosing the right antenna is essential to achieve optimum performance in wireless systems. The article also covers current wireless antenna technologies.. The key topics included in this slideshow are antenna properties, RF propagation, wireless system performance, antenna selection, wireless antenna technologies,. Download this presentation absolutely free.
1. Antenna Selection for Optimum Wireless LAN Performance Dr. Steven R. Best Cushcraft Corporation 48 Perimeter Road Manchester, NH 03108 (603) 627-7877
2. PURPOSE Overview of antenna properties and performance characteristics Overview of RF propagation characteristics Overview of how antenna properties affect wireless system performance Establish antenna selection criteria for optimum system performance Review current wireless antenna technologies
3. INTRODUCTION System designers and operators should have knowledge of antenna performance Properly selected antenna systems can improve performance and reduce cost Tutorial will provide basic knowledge of antenna performance and selection criteria. Other factors which affect antenna selection include size , appearance and $$$$$$$$$$$
4. ANTENNAS Antennas are passive devices that do not require supply power to operate They do not amplify RF Energy If 100% efficient, they will not radiate more power than is received at their input terminal Basic performance characteristics: VSWR, radiation patterns, 3 dB beamwidth, gain, polarization and bandwidth
5. VSWR Defines how closely antenna input impedance matches feed cable characteristic impedance. Impedance mismatch will reduce system efficiency.
6. RADIATION PATTERNS Provide information that describes how an antenna directs the energy it radiates Information presented in the form of a polar plot for both horizontal (azimuth) and vertical (zenith or elevation) sweeps Define quantitative aspects such as 3 dB beamwidth, directivity, side lobe levels and front to back ratio.
7. +5 0 -5 -10 -15 Description of Sweep Planes and Typical Radiation Pattern
8. Imaginary Point Source Typical Antenna
9. GAIN Accounts for overall efficiency of antenna. Efficiency reduction occurs from: VSWR mismatch Ohmic losses (energy lost as heat) Radome losses.
10. POLARIZATION Describes the orientation of the radiated waves electric field
13. RF PROPAGATION Path Loss Multipath Fading Interference and Noise Polarization Distortion Effects of earth and surrounding objects
14. PATH LOSS Path Loss (dB) = 20 log10 (4 pi r/lambda)
15. MULTIPATH FADING Result of multiple signals from the same RF source arriving at the receive site via many paths. The RF signal is time delayed, attenuated, reflected or diffracted and arrives at the receive site at a different amplitude, phase and perhaps time sequence than the direct signal. The total received signal is vector sum of direct and all multipath signals which may result in complete cancelation of direct signal.
16. INTERFERENCE AND NOISE Interference to wireless systems can occur from many sources: Atmospheric noise Galactic noise Man-made noise Radio noise Receiver noise In signal to noise calculations, noise is typically expressed as a temperature. The antenna will introduce noise as a function of the temperature of the objects it sees.
17. INTERFERENCE AND NOISE
18. POLARIZATION DISTORTION As RF waves reflect and diffract off of various objects, the orientation and sense of polarization may change.
19. EFFECTS OF EARTH AND SURROUNDING OBJECTS The earth is a dielectric body with varying conductivity and dielectric constant. It impacts antenna impedance such that Ra = Rr + Rl +Rg Energy dissipated in Rl and Rg is lost as heat and not radiated.
20. EFFECTS OF EARTH AND SURROUNDING OBJECTS +8 +3 -2 -7 -12
21. OPTIMIZING PERFORMANCE THROUGH ANTENNA SELECTION Performance Issues: Propagation Issues: VSWR Path loss Radiation patterns Multipath Gain Interference Polarization Polarization distortion Effects of earth and surrounding objects Other Issues: * Antenna cost * Antenna size Antenna appearance
22. ANTENNA TECHNOLOGY IN WIRELESS SYSTEMS Default omni antenna Higher gain omni antenna Directional yagi antenna Microstrip patch antenna
23. DEFAULT OMNI ANTENNA Mounts directly to station connector Omnidirectional Low gain (2 dBi typical) Linear polarized Low Cost
24. TYPICAL DIPOLE ANTENNA PATTERN
25. HIGHER GAIN OMNI ANTENNA Local or remote mounting Omnidirectional Higher gain (5 - 8 dBi possible) Linear polarized Low to moderate cost
26. TYPICAL 2-ELEMENT DIPOLE ANTENNA PATTERN
27. DIRECTIONAL YAGI ANTENNA Local or remote mounting Directional High gain (12 - 15 dBi or higher) Linear polarized Low to moderate cost
28. TYPICAL YAGI ANTENNA PATTERN
29. MICROSTRIP PATCH ANTENNA Local or remote mounting Directional Moderate to high gain (6 - 15 dBi or higher) Linear, dual linear or circular polarized Low to moderate cost
30. MICROSTRIP PATCH ANTENNA PATTERN E-PLANE H-PLANE