Exalt conducted a live demonstration comparing the performance of its ExtendAir 5 GHz point-to-point microwave radio to the latest 802.11n Wi-Fi Ethernet bridge under varying conditions of path fading and interference. Three tests were conducted: 1) comparing resilience to path fading, 2) comparing resilience to interference, and 3) measuring link recovery time. ExtendAir exhibited better resilience in both path fading and interference, with recovery times under 2 seconds compared to over 7 seconds for 802.11n. ExtendAir was able to deliver higher throughput with better resilience to impairments, translating to longer transmission distances and lower equipment costs compared to 802.11n Wi-Fi.
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ExtendAir® vs 802.11n Wi-Fi®
The Detailed Results
At 4G World in September 2009, Exalt conducted a live demonstration of the company’s new
ExtendAir® 5 GHz point-to-point microwave radio to compare its performance to that of the
latest and best-in-class 802.11n Wi-Fi Ethernet bridge. The purpose was to evaluate the
performance of each system under a variety of path fading and interference conditions.
Demonstration Set-up
In order to fairly compare the performance of ExtendAir vs. a leading 802.11n Wi-Fi Ethernet
bridge, two identical links were made established via direct RF cable connections. This was
done to provide a controlled RF environment for the test. Both paths had the exact same
level of fixed attenuation, and variable attenuation was provided to simulate similar path
fading conditions. Both the ExtendAir and 802.11n radios were configured for each test
according to the settings shown in the tables below. In addition, a third 5 GHz radio was
used to introduce an interfering carrier to both paths simultaneously. Throughput was
measured using a layer 2 SmartBits® tester with 1536-byte sized packets and compared in
real-time as tests were performed.
Three separate tests were conducted for each of two unique throughput scenarios: 1) full
sustained throughput, which is the maximum throughput that each system is able to deliver
and 2) equivalent sustained throughput of 100 Mbps.
The first test compared resiliency to path fading conditions. The objective was to determine
the amount of fading in dB that the systems could endure before the target throughput could
no longer be maintained. Paths were gradually faded until a noteworthy degradation in
throughput for each system was observed.
The second test compared resiliency to an interfering carrier affecting both paths on the
same channel. The objective was to determine the amount of interference in dB that the
systems could endure before the required throughput could no longer be maintained.
The third and final test measured link recovery time after completely dropping both links
through fading or interference conditions, and then simultaneously restoring the link by
removing the fade or interference condition.
Connection Diagram
The paths were established according to the following diagram. Each path had 66dB of fixed
attenuation and also included 50 dB variable attenuators to simulate link fading conditions.
The interfering carrier was modeled using an Exalt EX-5i radio with 46 dB of fixed
attenuation to each of the two 802.11n polarizations and the ExtendAir path, plus a 50 dB
variable attenuator to control the level of interference inserted into all paths. For the path
fading tests, this variable attenuator was set at 50 dB, providing a total attenuation of 96
dB.
Full Throughput Test Radio Configuration
Radio Configurations ExtendAir 802.11n
Channel bandwidth 33 MHz 20 MHz (x2)
Modulation 64 QAM Not configurable
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3. whether either or both polarizations were subjected to interference.
As with the path fade tests, ExtendAir exhibits 3-4dB better resiliency to interference than
802.11n. The result of this difference was readily observable: by the time the interference
started affecting ExtendAir, the 802.11n link had already dropped. Because 802.11n and
other Wi-Fi systems cannot reliably sustain a link at full throughput under these conditions,
Wi-Fi systems must utilize adaptive modulation in an attempt to maintain a connection at
the expense of lower throughput.
Link Recovery Time at Full Sustained Throughput
Both the ExtendAir and 802.11n links were individually subjected to severe path fading and
interference conditions in order to cause the links to drop. In each case,
when the impairment was removed the ExtendAir link recovered in less than two seconds
while the 802.11n link recovered only after seven seconds. This indicates that under identical
path impairment conditions, ExtendAir is not only more resilent than 802.11n, but it also
recovers faster when affected by path fading or interference.
Path Fade Measurements at 100 Mbps Throughput
In this test, the configuration of the ExtendAir radio was modified to provide approximately
the same throughput as the 802.11n radio. By simply changing the radio’s modulation from
64QAM to 16QAM, ExtendAir delivered 108 Mbps as measured by the SmartBits tester. As
with the previous path fade test, the paths were gradually faded until a measureable
throughput impact was observed.
For a sustained throughput of approximately 100 Mbps, ExtendAir exhibited 9dB better
resiliency to path fading conditions than 802.11n. This is due to ExtendAir’s ability to deliver
the required throughput at 16QAM modulation instead of 802.11n’s required 64QAM. This
performance advantage means that ExtendAir can achieve more than twice the distance as
802.11n or that antenna size can be reduced from a 6 ft. (1.8m) diameter to a 2 ft. (60cm)
diameter, yielding significant cost savings. For a given link distance at 100 Mbps sustained
throughput, ExtendAir provides nearly ten times the transmission resiliency in faded path
conditions than the best 802.11n radio.
Interference Measurements at Equivalent Sustained Throughput
The same interference test was performed for the 100Mbps throughput comparison with
ExtendAir configured for 108 Mbps, comparable to the maximum of 104 Mbps provided by
the 802.11n radio. Once again, the interfering signal was injected by gradually reducing the
attenuation in the interfering signal path.
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4. In this configuration, ExtendAir also exhibited 9 dB better interference rejection than did the
802.11n radio. Furthermore, before the ExtendAir link was even affected by the interfering
signal, the 802.11n link had dropped. This demonstrates that at the 100 Mbps throughput
level, ExtendAir delivers nearly ten times higher interference rejection than the best 802.11n
radio on the market. Simply put, ExtendAir can provide fast and reliable connections where
Wi-Fi and OFDM radios can’t.
Link Recovery Time at 100Mbps Throughput
As with the previous link recovery test, the ExtendAir link recovered in less than two
seconds while the 802.11n link recovered after approximately seven seconds. This link
recovery behavior is clearly consistent regardless of the throughput or the type of link
impairment experienced by both systems.
Conclusions
Exalt demonstrated that ExtendAir can deliver guaranteed performance and throughput
under severe link fading and interference conditions, significantly outperforming the leading
802.11n OFDM Wi-Fi Ethernet bridge in both the path fading and interference rejection tests.
The results indicate that at full throughput, ExtendAir can provide an additional link fade
margin of 2-3 dB while providing approximately 4dB additional interference rejection. At the
same 100Mbps throughput, ExtendAir provided 9dB better fade margin and interference
rejection than the 802.11n system.
These performance advantages translate directly into higher availability, longer
paths, significantly lower antenna sizes, and lower costs.
ExtendAir also delivers significantly higher maximum throughput than is possible with the
latest 802.11n Wi-Fi technology.
Finally, ExtendAir delivers the performance detailed above at about the same price of an
802.11n link.
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