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The implementation of Wireless LANs (WLAN) has become the cornerstone of many organizations’ mobile computing initiatives. The pervasive WLAN is the primary technology platform for increasing the productivity of your mobile and distributed knowledge workers. An efficient and optimized WLAN  implementation  improves  communication  flows, enables rapid access to senior management and enhances collaboration.  All  of  these  benefits  provide  competitive advantages that can positively affect your business.
Although  your  WLAN  architecture  may  appear  sound  on paper,  testing  the  actual  system  across  the  technology stack and from end-to-end is essential to ensure that your WLAN  implementation  provides  the  essential  capabilities required to deliver the promised business benefits. Building
a WLAN infrastructure from scratch or extending an existing implementation can present issues and risks that need to be  addressed  through  a  robust  and  effective  WLAN  test strategy.

Despite the existence of the IEEE 802.11 standards-based WLAN  market,  there  is  still  no  guarantee  that  a  WLAN infrastructure constructed from multi-vendor, or even single vendor, hardware and software will provide a seamless and transparent  platform  for  end-to-end  business  processes.
Some of the issues that need to be addressed are:
 Wireless technology continues to outpace the capacity
of  industry  interoperability  consortia  to  provide
comprehensive certification programmes;
 Operational  risks  can  be  mitigated  by  implementing  a
homogeneous,  single  vendor  solution  but  enhanced
business  benefits  may  only  be  realized  from  a
heterogeneous, multi-vendor solution;

 There is no single approach to building and operating
enterprise scale WLANs and new architectures continue
to be developed;
 Physical implementation needs to consider the impact
of  RF  interference  on  the  operational  mode  and  the
performance of the WLAN;
 Latency  caused  by  roaming  and  re-authentication,
especially for real-time applications such as VoIP.

Types of Testing

Functional Testing
Functional  testing  should  be  performed  at  all  level  of  the technology stack, as failure at any level has the potential to disrupt the availability of applications to their users.

Protocol Level Testing
Protocol  level  testing  generally  involves  comparing network traffic to a specification or standard.  Often such specifications  or  standards  include  bit-level  protocol descriptions. Wireless client adapters and wireless access
points need to be tested at this level to ensure compliance with  the  protocols  that  the  devices  are  designed  to support. In the wireless medium, protocol level testing involves the expert  use  of  wireless  protocol  analyzer(s)  that  allow  the tester to see what is happening at Layers 2-7 of the OSI model.  Testing at this level is exacting work that requires the  ability  to  understand  and  interpret  the  published specification  or  standard  and  compare  it  to  the  captured network traffic. The following is typical of the output from a protocol analyzer and shows the low level nature of this type of testing:
==== 802.11 packet (encrypted) ====
08 41 02 01 00 40 96 21 DC 83 00 40 96 28 8D DC FF FF
FF FF FF FF A0 38 00 01 15 00 EB B1 C7 6A B1 96 B2 16
58 C4 04 5E 2D 6A F3 4B 92 EB FC FC ED 70 98 D0 64
6C 5E BB 1A DD D4 2A 26 2A 8B EF C2 41 67 75 9D FB
FE 5D 4E CA A0 45 6D 7C 36 22 22 7D D0 BD 09 16 1D
E6 41 D9 94 BE 9B 53 C5 CB
==== CK (basic CKIP key) ====
19 59 8D F5 EF 19 59 8D F5 EF 19 59 8D F5 EF 19
==== PK (permuted key) ====
00 01 15 E6 8B D6 03 23 0B 6A 60 B9 F4 EB 46 99
==== 802.11 packet decrypted ====
08 41 02 01 00 40 96 21 DC 83 00 40 96 28 8D DC FF FF
FF FF FF FF A0 38 00 01 15 00 AA AA 03 00 40 96 00 02
2F F1 C0 A6 00 00 00 C0 08 06 00 01 08 00 06 04 00 01
00 40 96 28 8D DC A1 2C EE 03 00 00 00 00 00 00 A1 2C
EE 14 21 BD D8 23 21 BD A8 AC 52 E1 01 00 00 00 28
AC 0F 82 46 86 F9 D9

Compatibility Testing
The  802.11  wireless  world  is  governed  by  standards. However the different wireless components do not always interoperate  well.    Within  a  single  WLAN  infrastructure there  may  be  many  combinations  of  client  adapters  and wireless access points. Even if the model numbers of the
components are the same, there may be different software versions deployed within the devices. Compatibility testing is  required  to  prove  that  the  chosen  devices  do  actually work together as expected.

Security Testing
Wireless  networks  are  becoming  more  popular  in  the corporate  environment.    As  such,  corporate  network administrators  rightfully  insist  on  making  the  network  as secure  as  possible.    A  secure  wireless  strategy  includes encryption,  authentication,  and  key  management.
Encryption  ranges  from  static  WEP  to  rotating  keys generated  by  the  access  point.    The  wireless  network can authenticate the wireless user or client using a variety of  authentication  protocols  and  backend  systems.    Key management refers to the mechanism being employed to rotate the keys.  Some of the most common systems and
mechanism that are deployed are:
 Microsoft Internet Authentication Service (IAS)
 Cisco Access Control Server (ACS)
 Key Management:
• Cisco Centralized Key Management (CCKM)
• WPA
• WPA2

802.1x  Extensible  Authentication  Protocol  (EAP)  of  all
kinds
 EAP-TLS (certificate-based authentication)
 EAP-GTC  (password  or  token-based
authentication)
 PEAP
 EAP-FAST
 LEAP

Quality of Service Testing
One  of  the  ways  that  wireless  networking  has  evolved surrounds  the  use  of  multimedia  applications  (voice, video,  etc)  over  the  wireless  medium.    Such  applications require  guaranteed  access  to  the  network  in  order  that the  audio/video  stream  is  of  an  acceptable  quality.    The
mechanism employed to ensure the quality of multimedia communications  over  the  network  is  called  “Quality  of Service” (QoS) and is implemented on a wireless network using  the  Wi-Fi  Multimedia  (WMM)  functionality.    WMM is  based  on  a  subset  of  the  IEEE  802.11e  WLAN  QoS draft  standard.    The  implementation  of  WMM  is  judged by  generating  known  traffic  types  on  the  network  and validating correct behavior in terms of priority values in the packets and traffic flow through the network.

End-to-End Testing
A comprehensive WLAN test strategy will include full end-to-end  business  process  testing  within  the  test  WLAN environment allowing business risk mitigation before WLAN deployment occurs on site. Due to the many configurations that may need to be tested, this is essentially application
regression testing. Regression testing is the form of testing most  amenable  to  test  automation.  Consideration  needs to  be  given  to  the  feasibility  of  test  automation  and  the potential  cost  and  quality  benefits  that  may  be  obtained through test automation.

Performance Testing
A common measure of wireless performance is throughput. Regardless  of  the  802.11  band  (a/b/g),  wireless  client adapter  vendors  are  concerned  with  throughput  as  a performance  metric  and  point  of  comparison.    In  the wireless world, range is simulated by adding attenuation to the antenna on the wireless access point.
Wireless throughput is a function of multiple factors, most notably:
 Distance  between  the  client  adapter  and  the  access point  (often  simulated  in  the  test  environment  by introducing attenuation to the wireless signal)
 Noise in the environment
 Relative  orientation  of  the  client  and  access  point
antennas The  curve  of  throughput  versus  distance  (attenuation)
varies  from  adapter  to  adapter.    Even  a  single  adapter’s
throughput curve varies with the implemented antenna and
its orientation.

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