Moonblink distributes the finest in wireless, Wi-Fi, and video surveillance equipment
Menu Spacer
Home      About Us      Services      Leasing Options      Blog      Shopping Cart      Contact Us
Facebook LinkedIn Twitter YouTube
Menu Spacer
Need help planning and designing your wireless or video surveillance network? Call our experts at (877) 623-5223. Menu Bottom Spacer
Product Search
Spacer
Spacer
Product Categories
Wireless Bridge PTP
Wireless Broadband
WiMAX Equipment
Mesh Networking
Wi-Fi Networking
Video Surveillance
Wireless Antennas
Cables and Accessories
Discontinued
Spacer

All Manufacturers
AvaLAN Wireless
Axis Communications
BridgeWave Communications
Cambium Networks
Exalt Communications
Fantom Wireless
Firetide
IQinVision
mWAVE Antennas
Photon Antenna
Proxim Wireless
PureWave Networks
Radio Waves Antennas
SAF Tehnika
Tellabs
Transtector
ValuePoint Networks
Xirrus





dMystifying the dB

The basic unit of measurement used in Wi-Fi radio signals is the decibel or dB for short. The "B" is in honor of Alexander Graham Bell, the Scottish-born inventor responsible for much of today's acoustical devices.

by Michael Young
President of Young Design, Inc.
[August 23, 2001]

Understanding decibels and their use in Wi-Fi radio systems is not rocket science, but a calculator will prove to be one of your most reliable tools in the field. If you're not the do-it-yourself type, YDI has set up a calculations page that could make short work of your ciphering and sums. Either way, it pays to make sure you're speaking the same dB language when it comes to pricing gear from fixed wireless vendors. Don't get lost in the tech jargon´┐Żlearn how the speak the language today.

dB (decibel)
The difference (or ratio) between two signal levels; used to describe the effect of system devices on signal strength. For example, a cable has 6 dB signal loss or an amplifier has 15 dB of gain. This is useful since signal strengths vary logarithmically, not linearly. Since the dB scale is a logarithmic measure, it produces simple numbers for large-scale variations in signals. It is very useful because adding and subtracting whole numbers can calculate system gains and losses.

Every time you double (or halve) the power level, you add (or subtract) 3 dB to the power level. This corresponds to a 50 percent gain or reduction. 10 dB gain/loss corresponds to a tenfold increase/decrease in signal level. A 20 dB gain/loss corresponds to a hundred-fold increase/decrease in signal level. In other words, a device (like a cable) that has 20 dB loss through it will lose lots of its signal by the time it gets to the other side. Thus, big variations in signal levels are easily handled with simple digits. (Back to top)

dBm (dB milliWatt)
A signal strength or power level; 0 dBm is defined as 1 mW (milliWatt) of power into a terminating load such as an antenna or power meter. Small signals are negative numbers (e.g. -83 dBm). For example, typical 802.11b WLAN cards have +15 dBm (32mW) of output power. They also spec a -83 dBm RX sensitivity (minimum RX signal level required for 11Mbps reception). Additionally, 125 mW is 21 dBm, and 250 mW is 24 dBm. (Back to top)

dBd (dB dipole)
The gain an antenna has over a dipole antenna at the same frequency. A dipole antenna is the smallest, least gain practical antenna that can be made. The term dBd (sometimes just called dB) generally is used to describe antenna gain for antennas that operate under 1GHz (1000Mhz). The reason why the gain of many antennas, especially VHF/UHF antennas, is measured in dBd is because antenna manufacturers calibrate their equipment using a simple dipole antenna as the standard. Then they replace it with the antenna they are testing. The difference in gain (in dB) is reference to the signal from the dipole. (Back to top)

dBi (dB isotropic)
The gain a given antenna has over a theoretical isotropic (point source) antenna. Unfortunately, an isotropic antenna cannot be made in the real world, but it is useful for calculating theoretical fade and System Operating Margins. The gain of Microwave antennas (above 1 GHz) is generally given in dBi. A dipole antenna has 2.14 dB gain over a 0 dBi isotropic antenna. So if an antenna gain is given in dBd, not dBi, add 2.15 to it to get the dBi rating. For example, if an omni antenna has 5 dBd gain, it would have 5 + 2.15 = 7.15 dBi gain.

Note: If an antenna gain is just specified in dB from a manufacturer, be sure to ask if it is dBi or dBd. If they cannot tell you or do not know the difference, then you should consider buying from another vendor! (Back to top)

EIRP (Effective Isotopic Radiated Power)
Effective Isotropic Radiated Power is defined as the effective power found in the main lobe of a transmitter antenna relative to an Isotropic radiator which has 0 dB of gain. It is equal to the sum of the antenna gain (in dBi) plus the power (in dBm) into that antenna. For example, if a 12 dBi gain antenna is fed with 15 dBm of power has an Effective Radiated Power (ERP) of:

12 dBi + 15dBm = 27 dBm (500 mW).

With an amp that has 24 dBm (250mW) output; maximum allowed by the FCC into a 12 dBi omni.

12 dBi + 24dBm = 36 dBm (4 Watts), which is the same as 1W (+30 dBm) into a 6 dBi omni.

6 dBi + 30 dBm = 36 dBm (4 Watts).

But it is much better to have a higher gain omni antenna since, while the ERP is the same, a higher gain antenna has the gain on receive as well. This is where you really need it since most of your clients will not be equipped with amplifiers.

Note: The ERP is found in the main lobe only. If you are using a high-gain omni-directional antenna, the radiation pattern is very flat and narrow (like a pancake). If the antenna is too high, the main lobe will actually shoot over the heads of your customers. But oftentimes you need great height to clear an obstacle from the WiPOP antenna to your customers! A solution is to use down-tilt sector antennas. They have more gain than omni-antennas and the main lobe can be focused into the desired coverage area. Doing this also defines a "cell" that will prevent radio coverage all the way to the horizon. This has the benefit of not only minimizing interference at the WiPOP from distant signals, but also will enable you to re-use the frequency at another cell several miles away. (Back to top)

FSL (free space loss)
Free Space Loss is defined as the loss that a radio signal experiences when traveling through free space. The formula at 2.4 GHz is:

FSL = 104.2 + 20 log D
Where: D = Distance in miles
Example: At 5 miles FSL is 118 dB

Rule of Thumb: Every time you double (or halve) the distance from the transmitter to the receiver, the signal level is lowered (or increased) by 6dB. (Back to top)

System Operating Margin (SOM)
System Operating MarginSystem Operating Margin (also referred to as Fade Margin) is defined as the difference between the received signal level (in dBm) and the receiver sensitivity (in dBm) needed for error free reception. For example, if the received signal level is -71 dBm and the receiver sensitivity is -83dBm (typical for a 11Mbps WLAN), then the SOM is:

-71dBm - (-83 dBm) = 12 dB SOM

This should work if there is not bad interference. YDI recommends 10 dB SOM or more. 20 dB is excellent.

Note: If your Wireless Internet Point of Presence (WiPOP) is amplified and your customer's WLAN card or AP is not, then the SOM needs to be calculated from the remote site back to the WiPOP This is because the remote site has the weakest TX signal in the system.


Request a quote!
View Current Promotions
Promotions Button
Webinar Wednesdays Schedule
Webinar Schedule Button
Resources
Webinar Recordings
Press Releases
Payment and Returns
SALE: Used Equipment





  All rights reserved. Copyright Moonblink Communications 2014