A CONTRIBUTION TO LABORATORY PERFORMANCE
MEASUREMENTS OF IEEE 802.11 B,G WEP
POINT-TO-POINT LINKS
J. A. R. Pacheco de Carvalho
1,2
, H. Veiga
1,3
, N. Marques
1,3
, C. F. Ribeiro Pacheco
1
1
U. de Detecção Remota,
2
Dept. de Física,
3
Centro de Informática
Universidade da Beira Interior, 6201 Covilhã, Portugal
A. D. Reis
1,2,4
4
Dept. de Electrónica e Telecomunicações, Instituto de Telecomunicações
Universidade de Aveiro, 3810 Aveiro, Portugal
Keywords: Wi-Fi, WLAN, WEP Point-to-Point Links, IEEE 802.11b, IEEE 802.11g, Wireless Network Laboratory
Performance.
Abstract: Wireless communications using microwaves are increasingly important, e.g. Wi-Fi. Performance is a
fundamental issue, resulting in more reliable and efficient communications. Laboratory measurements are
made about several performance aspects of Wi-Fi (IEEE 802.11b, g) WEP point-to-point links using
available access points from Enterasys Networks (RBTR2). Through OSI levels 4 and 7, detailed results are
presented and discussed from TCP, UDP and FTP experiments, namely: TCP throughput, jitter, percentage
datagram loss and FTP transfer rate. Conclusions are drawn about link performance.
1 INTRODUCTION
Wireless communications are becoming increasingly
important for their versatility, mobility, speed and
favourable prices. It is the case of microwave and
laser based technologies, e.g. Wi-Fi and FSO,
respectively. The importance and utilization of Wi-
Fi have been growing for complementing traditional
wired networks. Wi-Fi has been used both in ad hoc
mode and infrastructure mode. In this case an access
point, AP, is used to permit communications of Wi-
Fi equipments with a wired based LAN through a
switch/router. Therefore a WLAN, based on the AP,
is formed. Wi-Fi has had an increasing presence in
the personal home, forming a WPAN, allowing
personal devices to communicate. Point-to-point and
point-to-multipoint configurations are used both
indoors and outdoors, requiring specialized
directional and omnidirectional antennas. Wi-Fi uses
microwaves in the 2.4 and 5 GHz frequency bands
and IEEE 802.11a, 802.11b and 802.11g standards
(IEEE Std 802.11-2007). Due to increasing used of
2.4 GHz band, interferences increase. The 5 GHz
band has received considerable interest, although
absorption increases and ranges are shorter.
Nominal transfer rates up to 11 (802.11b) and 54
Mbps (802.11 a, g) are specified. CSMA/CA is the
medium access control. Wireless communications,
wave propagation (Mark & Zhuang, 2003;
Rappaport 2002) and WLAN practical
implementations (Bruce & Gilster, 2002)) have been
studied. Detailed information is available about the
802.11 architecture, including performance analysis
of the effective transfer rate, where an optimum
factor of 0.42 was presented for 11 Mbps point-to-
point links (Schwartz, 2005). Wi-Fi (802.11b)
performance measurements are available for
crowded indoor environments (Sarkar & Sowerby,
2006). Performance has been a fundamentally
important issue, giving more reliable and efficient
communications. New telematic applications are
specially sensitive to performances, when compared
to traditional applications. Application
characterization and requirements have been
discussed for several cases such as voice, Hi Fi
audio, video on demand, moving images, HDTV
images, virtual reality, interactive data, static
165
A. R. Pacheco de Carvalho J., Veiga H., Marques N., Ribeiro Pacheco C. and D. Reis A. (2010).
A CONTRIBUTION TO LABORATORY PERFORMANCE MEASUREMENTS OF IEEE 802.11 B,G WEP POINT-TO-POINT LINKS.
In Proceedings of the International Conference on Wireless Information Networks and Systems, pages 165-168
DOI: 10.5220/0003031501650168
Copyright
c
SciTePress
images, intensive data, supercomputation, electronic
mail, and file transfer (Monteiro & Boavida, 2002).
E.g. requirements have been given for video on
demand/moving images (1-10 ms jitter and 1-10
Mbps throughputs) and for Hi Fi stereo audio (jitter
less than 1 ms and 0.1-1 Mbps throughputs).
Wi-Fi microwave radio signals can be easily
captured by everyone. WEP was initially intended to
provide confidentiality comparable to that of a
traditional wired network. In spite of its weaknesses,
WEP is still widely used in Wi-Fi communications
for security reasons. A shared key for data
encryption is involved. In WEP, the communicating
devices use the same key to encrypt and decrypt
radio signals.
Several performance measurements have been
made for open Wi-Fi (Pacheco de Carvalho et al.,
2008a, 2009a, 2009b), as well as WiMAX and very
high speed FSO (Pacheco de Carvalho et al., 2008b,
2008c). In the present work further Wi-Fi (IEEE
802.11 b,g) results arise, using WEP, through OSI
levels 4 and 7. There is interest in comparing two
technologies working in the 2.4 GHz bands, using
WEP in the same AP equipments. Performance is
evaluated in laboratory measurements of WEP
point-to-point links using available equipments.
The rest of the paper is structured as follows:
Chapter 2 presents the experimental details i.e. the
measurement setup and procedure. Results and
discussion are presented in Chapter 3. Conclusions
are drawn in Chapter 4.
2 EXPERIMENTAL DETAILS
In the measurements we used (Fig. 1) Enterasys
Networks RBTR2 level 2/3/4 access points
(Enterasys, 2005), equipped with IEEE 802.11 a/b/g
radio cards similar to the Agere-Systems model
0118 type, and firmware version 6.08.03, and 100-
Base-TX/10-Base-T Allied Telesis AT-8000S/16
level 2 switches (Allied Telesis, 2008). The
configuration of the access points was for minimum
transmitted power i.e. micro cell, point-to-point,
LAN to LAN mode, using the antenna which was
built in the card. Interference free communication
channels were used in the communications. WEP
encryption was activated, using 128 bit encryption
and a shared key for data encryption composed of 13
ASCII characters. No power levels above the
minimum were required, as the access points were
very close.
A laboratory setup arrangement was planned and
implemented, as shown in Fig. 2. TCP and UDP
experiments at OSI level 4, were as mentioned in
(Pacheco de Carvalho et al., 2008c), permitting
network performance results to be recorded. Both
TCP and UDP are transport protocols. TCP is
connection-oriented. UDP is connectionless, as it
sends data without ever establishing a connection.
For a TCP connection, TCP throughput was
obtained. For a UDP communication with a given
bandwidth parameter, UDP throughput, jitter and
percentage loss of datagrams were obtained. TCP
packets and UDP datagrams of 1470 bytes size were
used. A window size of 8 kbytes and a buffer size of
the same value were used for TCP and UDP,
respectively. One PC, with IP 192.168.0.2 was the
Iperf server and the other, with IP 192.168.0.6, was
the Iperf client. Jitter, which represents the smooth
mean of differences between consecutive transit
times, was continuously computed by the server, as
specified by RTP in RFC 1889. This scheme was
also used for FTP measurements, where FTP server
and client applications were installed in the PCs with
IPs 192.168.0.2 and 192.168.0.6, respectively.
The PCs were portable computers running
Windows XP. They were configured to maximize
the resources allocated to the present work. Also,
batch command files were written to enable the
TCP, UDP and FTP tests. The results were obtained
in batch mode and written as data files to the client
PC disk. Each PC had a second network adapter, to
permit remote control from the oficial IP University
network, via switch.
3 RESULTS AND DISCUSSION
The RBT-4102 access points were configured, for
each standard IEEE 802.11 b, g, with typical fixed
transfer rates (1, 2, 5.5 and 11 Mbps for 802.11b; 6,
9, 12, 18, 24, 36, 48, 54 Mbps for 802.11g). For
every fixed transfer rate, data were obtained for
comparison of the laboratory performance of the
links, measured namely at OSI levels 1, 4 and 7
using the setup of Fig. 2. For each standard and
every nominal fixed transfer rate, an average TCP
throughput was determined. This value was used as
the bandwidth parameter for every corresponding
UDP test, giving average jitter and average
percentage datagram loss. The main results are
shown in Figs. 3-6. At OSI level 1, SNR was
monitored.
In Fig. 3, polynomial fits were made to the TCP
throughput data, where R
2
is the coefficient of
determination. It is seen that the best TCP
throughputs are for 802.11g. The average values are
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2.42 and 12,61 Mbps for 802.11b and 802.11g,
respectively. In Figs. 4 and 5, the data points
representing jitter and percentage datagram loss
were joined by smoothed lines. In Fig. 4, the jitter
data are on average slightly higher (1.8+-0.1 ms ) for
802.11g than for 802.11b (1.6+-0.1 ms). Fig. 5
shows that, generally, the percentage datagram loss
data (1.2+-0.1 % on average) agree reasonably well
for both standards.
At OSI level 7 we measured FTP transfer rates
versus nominal transfer rates configured in the
access points for the IEEE 802.11b, g standards.
Every measurement was the average for a single
FTP transfer, using a binary file size of 100 Mbytes.
The results thus obtained are represented in Fig. 6.
Polynomial fits to data were made for the
implementation of each standard. It was found that
the best FTP performance was for 802.11g. These
results show the same trends found for TCP
throughput. FTP transfer rates were also measured
without WEP activation.
Generally, the results measured for WEP links at
OSI levels 4 and 7 agree reasonably well, within the
experimental errors, with corresponding data
obtained for open links.
Figure 1: Switch (A) (http://www.enterasys.com) and
access point (B) (http://www.alliedtelesis.com).
Figure 2: Laboratory setup scheme.
Figure 3: TCP throughput versus technology and nominal
transfer rate.
Figure 4: UDP – jitter results versus technology and
nominal transfer rate.
Figure 5: UDP – percentage datagram loss results versus
technology and nominal transfer rate.
Figure 6: FTP transfer rates versus technology and
nominal transfer rate.
A CONTRIBUTION TO LABORATORY PERFORMANCE MEASUREMENTS OF IEEE 802.11 B,G WEP
POINT-TO-POINT LINKS
167
4 CONCLUSIONS
In the present work a laboratory setup arrangement
was planned and implemented, that permitted
systematic performance measurements of available
access point equipments (RBTR2 from Enterasys)
for Wi-Fi (IEEE 802.11b, g) in WEP point-to-point
links.
Through OSI level 4, TCP throughput, jitter and
percentage datagram loss were measured and
compared for each standard. The best TCP
throughput was found for 802.11g. The jitter data
are on average slightly higher for 802.11g than for
802.11b. Generally, the percentage datagram loss
data agree reasonably well for both standards.
At OSI level 7, the best FTP performance was
for 802.11g. This result shows the same trends found
for TCP throughput.
Generally, the results measured for WEP links
agree reasonably well, within the experimental
errors, with corresponding data obtained for open
links.
Additional performance measurements either are
under way or are planned using several equipments
to permit several comparisons, not only in laboratory
but also in outdoor environments involving, mainly,
medium range links.
ACKNOWLEDGEMENTS
Supports from University of Beira Interior and FCT
(Fundação para a Ciência e a Tecnologia)/POCI2010
(Programa Operacional Ciência e Inovação) are
acknowledged. We acknowledge Enterasys
Networks for their availability.
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