■ Access points■ Network unification ■ Network management ■ Network services APs in the CUWN Another type of device in a CUWN is a lightweight access point AP.. Client data travels from
Trang 1■ Access points
■ Network unification
■ Network management
■ Network services APs in the CUWN Another type of device in a CUWN is a lightweight access point (AP) The lightweight AP
is controlled and monitored by the Cisco Wireless LAN Controller (WLC) The AP com-municates using a special protocol called the Lightweight AP Protocol (LWAPP) to relay
information to the WLC about the coverage, the interference that the AP is experiencing, and client data about associations, among other pieces of information This is a manage-ment type of communication, and via LWAPP it is encrypted Client data is also sent in-side these LWAPP frame headers Client data travels from the wireless space to an AP, and then through a WLC and off to the rest of the network When client data is encapsulated into an LWAPP header, you have not only the data, but also information about the Re-ceived Signal Strength Indicator (RSSI) and signal-to-noise ratio (SNR) The WLC uses this information to make decisions that can improve coverage areas
WLCs in the CUWN
A single WLC can manage from six to 300 access points You can create groupings of controllers for more scalability This type of network could easily get out of hand if you had more than 300, 600, or 900 APs In cases such as this, a WCS application can manage
a number of controllers as well as a location appliance that can help track where devices are in the network
Note: There is obviously more to the solution that what has been discussed in this sec-tion For more information on the Unified Wireless Solution, visit http://www.cisco.com/ go/wireless This is the home page for the Cisco Unified Wireless Network Here you can dig into the white papers, configuration guides, and much more
The major point to understand is that in the CUWN, the AP uses LWAPP to exchange control message information with the controller Client data is also encapsulated into LWAPP between the AP and the controller The controller then forwards the data frames from those wireless clients to the wired network to get that traffic back and forth Features of the Cisco Controllers
One of the implemented designs of the Cisco Wireless LAN Controllers is the split MAC
design This means that you split 802 protocols between the controller and the APs On one side, the APs handle the real-time portion and time-sensitive packets On the other side, the controller handles the packets that are not time-sensitive
The AP handles the following operations:
■ Frame exchange and the handshake between clients
Key
Topic
Trang 2■ Transmits beacons
■ Buffers and transmits the frames for clients that are in power-save mode
■ Sends responses to probe requests from different clients on the network
■ Forwards notifications of received probe requests to the controller
■ Provides real-time quality information to the controller
■ Monitors all channels for noise and interference The controller handles pretty much everything else Remember that the controller handles packets that are not considered time-sensitive This includes the following:
■ Association
■ Reassociation when you have clients that are roaming
■ The authentication process
■ Frame translation
■ Frame bridging Part of the control traffic that is sent back and forth via LWAPP is information that pro-vides radio resource management (RRM) This RRM engine monitors the radio resources, performs dynamic channel assignments, provides detection and avoidance of interference, and provides the dynamic transmit power control (TPC) that was discussed in Chapter 1,
“Introduction to Wireless Networking Concepts.” Also, whenever coverage holes (such as when one AP goes down) are detected by another access point, the controller can actually adjust power settings on other APs in the area to correct the coverage hole
LWAPP can operate in two modes:
■ Layer 2 LWAPP mode:This mode deals only with MAC addresses This makes sense, because this is the only type of addressing at Layer 2 In Layer 2 mode, the AP needs to be in the same subnet as the controller and hence does not provide much flexibility for large customer installations
■ Layer 3 LWAPP mode:When operating in Layer 3 mode, the LWAPP can see and use Layer 2 addresses (MAC addresses) and Layer 3 addresses (IP addresses) Layer 3 mode LWAPP allows the network administrator to place APs in different subnet boundaries, and the protocol traverses those boundaries
Supporting Multiple Networks
Previous chapters discussed that an AP can actually advertise multiple SSIDs, which lets the AP offer guest access as well as corporate user access and maybe even access for wire-less IP phones Each Wirewire-less LAN Controller actually can support 512 different VLAN instances Remember that on the connection between the AP and the Wireless LAN Con-troller, all your wireless client data is passed via the LWAPP tunnel as it travels toward the wired domain
Trang 3To review, recall that an SSID exists only in the wireless space An SSID is then tied to a VLAN within the controller Each lightweight AP can support 512 different VLANs, but you don’t very often see that many on one AP
On the other hand, your Wireless LAN Controller can have up to 16 wireless LANs (WLAN) tied to each AP Each WLAN is assigned a wireless LAN identification (WLANID) by the controller This is a number between 1 and 16, and you don’t get to choose which one to use
So, now you have a WLAN that brings together the concept of an SSID on the wireless space and a VLAN on the wired space By having separate WLANs, you can assign differ-ent quality-of-service (QoS) policies to the type of traffic encountered on each of them
An example of this would be to have a WLAN for IP Phones and a different WLAN for regular network users
Each AP supports up to 16 SSIDs; generally, one SSID is mapped to one VLAN With that said, even though a Wireless LAN Controller can support up to 512 VLANs per AP, you see a maximum of only 16 VLANs in most situations
The CUWN Architecture
The Cisco Unified Wireless Network defines a total of five functional areas or intercon-nected elements, as shown in Figure 10-2
The five elements or components all work together It’s no longer about point products, where you can buy a standalone AP and deploy it and then later get management software to handle
it Today it is all about everything working together to create a smarter, more functional net-work To illustrate how it all comes together, consider a Cisco wireless netnet-work This type of network includes the following wireless clients (the first component of the CUWN):
■ Cisco Aironet client devices
■ Cisco-compatible client devices (not necessarily Cisco products, but still compatible)
■ Cisco Secure Services Client (SSC) The client devices get a user connected
The second component, the access point, is dynamically managed by your controllers, and they use LWAPP to communicate The AP bridges the client device to the wired net-work A number of APs that could be discussed here are as follows:
■ The 1130AG
■ The 1240AG
■ The 1250AG
■ The 1300 series bridge
■ The 1400 series bridge
■ The 1500 series outdoor mesh
Trang 4Cisco WCS Supporting
Devices (ASA, PIX, Routers, Switches, IDS)
44xx Series WLC 1130AG
Covered in Chapter 16
WCS Navigator 3750G WLAN
Controller Switch 1240AG
Location Appliance
Cisco WiSM 1250AG
Cisco 2106 WLC
1300 Series Bridge
Cisco WLCM
1400 Series Bridge
1500 Series Outdoor Mesh
Network Management
Network Services
Network Unification
CUWN Functional Areas
Access Points
Wireless Clients
Figure 10-2 CUWN Architecture
Each of these access points is discussed in further detail in the section “Access Points.”
The next functional area of the CUWN architecture—network unification—is the module that includes your controllers, including the following:
■ The 6500 series Catalyst switch Wireless Services Module (WiSM)
■ Cisco Wireless LAN Controller module (WLCM)
■ Cisco Catalyst 3750 series integrated WLC
■ Cisco 4400 series WLC
■ Cisco 2000 series WLC
Key Topic
Trang 5The next functional area of the CUWN architecture—network management—is provided
by the Cisco wireless control module
The final functional area of the CUWN architecture—network services—includes every-thing else: the self-defending network, enhanced network support, such as location serv-ices, intrusion detection and prevention, firewalls, network admission control, and all those other services
Those are the five functional areas of the CUWN The following sections highlight the topics that you will want to be the most familiar with for the CCNA Wireless exam
Client Devices The Cisco wireless clients are covered in Chapter 16, “Wireless Clients,” in greater detail However, it is still good to understand what is available When you are on a Cisco wireless network, you can actually use most vendors’ wireless clients Cisco provides wireless soft-ware called the Aironet Desktop Utility (ADU) The ADU is specifically used to manage and configure the Cisco wireless cards Those wireless cards are discussed in more detail
in Chapter 16 There is a cardbus version as well as a PCI version In addition to the ADU, another client called the Secure Services Client (SSC) can help you configure security pro-files for wired and wireless use on a Cisco network
Access Points
As previously mentioned, there are two types of access points:
■ Autonomous APs
■ Lightweight APs Some APs are built into modules and deployed in ISR routers at branch sites; other APs are deployed as just standalone devices Cisco APs are known to offer the best range and throughput in the industry, as well as a number of security features that you do not find with other vendors
Cisco APs offer multiple configuration options Some of them support external antennas, some support internal antennas, and some are to be deployed outdoors Still others are de-signed to be deployed indoors Some APs are dede-signed to be implemented for wide-area networking and bridging purposes and, while operating as a bridge, may also allow client connections The point is that Cisco APs can serve a number of purposes
The benefit of the CUWN APs is that they are zero-touch management, assuming that Layer 2 connectivity is already in place As soon as they are plugged in and powered on, you don’t have to do anything else at the AP level The models that you need to be familiar with for the CCNA Wireless exam include the 1130AG, 1240AG, 1250AG, 1300, and
1400 series wireless bridges
Note: Currently, the 1400 series bridge cannot be managed by the controller and is not considered an AP
Key
Topic
Trang 6Courtesy of Cisco Systems, Inc Unauthorized use not permitted.
Figure 10-3 Cisco 1130AG Series AP
The 1130, 1240, and 1250 can be both autonomous and lightweight APs Whereas the
1300 and 1400 series are designed to operate as bridges, the 1300 series can also sup-port wireless clients In turn, the 1400 series supsup-ports bridging only Another model is the outdoor mesh 1500 series, which supports only LWAPP, so that would be designed for a lightweight scenario only
Cisco is known for being ahead of the curve That’s where the special functionality of the 1250AG comes in The 1250AG is one of the first access points to support the 802.11n draft version 2.0 standard and is the basis for all 802.11 Wi-Fi interoperability testing For
a client vendor to get the v2.0 stamp of approval, it must be validated against the 1250, and the 1250 is the only AP used during this validation
The 1130AG The 1130AG, shown in Figure 10-3, is a dual-band 802.11 a/b or g AP that has integrated antennas
The 1130AG can operate as a standalone device or in lightweight AP mode It also can op-erate as a Hybrid Remote Edge AP (H-REAP) device An H-REAP device opop-erates on the far side of a WAN, and its controller is back at the core site
The 1130AG is 802.11i/WPA2-compliant, and it has 32 MB of RAM and 16 MB of flash memory The 1130 AP typically is deployed in office or hospital environments Naturally, the internal antennas do not offer the same coverage and distance as APs that are designed
Trang 7Courtesy of Cisco Systems, Inc Unauthorized use not permitted.
Figure 10-4 Cisco 1240AG Series AP
for external antennas Consider the 1130s They have 3 dB gain and 4.5 dB gain for the 2.4- and 5-GHz frequencies, respectively If you were to compare the 1131 to the 1242 with the 2.2 dipole antennas, you would see a larger coverage area than with the 1242 The 1240AG
The 1240AG series AP, shown in Figure 10-4, is also a dual-band 802.11 a/b or g device, similar to the 1130AG; however, it supports only external antennas
Those external antennas would connect using the RP-TNC connectors The 1240AG can operate as an autonomous AP and in lightweight AP mode Like the 1130AG, it also can operate in H-REAP mode It too is 802.11i/WPA2-compliant
The 1250 Series AP Shown in Figure 10-5, the 1250 series AP is one of the first enterprise APs to support the 802.11n draft version 2.0
Because it supports the 802.11n draft standard, you can get data rates of about 300 Mbps
on each radio and the 2-by-3 multiple input and multiple output technology The 2-by-3 is discussed in Chapter 6, “Overview of the 802.11 WLAN Protocols.” Also, because the
1250 is modular, it can easily be upgraded in the field It operates in controller-based and standalone mode and is also 802.11i/WPA2-compliant
The 1250 is designed for a more rugged type of indoor environment You might see this at more hazardous locations such as packaging plants, or in situations where you might need
Trang 8Courtesy of Cisco Systems, Inc Unauthorized use not permitted.
Figure 10-5 Cisco 1250 Series AP
to place an antenna in a hazardous location and the AP elsewhere You might see this type
of AP in factories and hospitals It has 64 MB of DRAM and 32 MB of flash memory It has 2.4-GHz and 5-GHz radios
The 1300 Series AP/Bridge The Cisco Aironet 1300 series outdoor access point/bridge, shown in Figure 10-6, is de-signed to act as an AP for clients as well as act as a bridge
The 1300 operates in only 802.11b or g modes because it does not have a 5-GHz radio It has a NEMA-4-compliant enclosure, so you can deploy it in an outdoor environment and
it can withstand the elements
The 1300 series is available in two versions—one with integrated antennas and one with antenna connectors so that you can add your own antennas to it The connectors would be 2.4-GHz antennas, because the 1300 series does not support 802.11a
You would expect to find the 1300 series on a college campus in a quad-type area with outdoor users or mobile clients You might also see it in public settings, such as a park, or
as a temporary type of network access for a trade show The 1300 requires a special power supply, provided and shipped by Cisco when the product is purchased The power supply provides power to the 1300 via coaxial You should place it indoors or at least in an enclo-sure to protect it, because it is not NEM-4-compliant The 1300 is a very good
point-to-point and point-to-point-to-multipoint-to-point bridge that can be used to interconnect buildings and to connect buildings that do not have a wired infrastructure in place
Trang 9Courtesy of Cisco Systems, Inc Unauthorized use not permitted.
Figure 10-6 Cisco 1300 Series AP
The 1400 Series Wireless Bridge The Cisco Aironet 1400 series wireless bridge, shown in Figure 10-7, is designed for outdoor environments
It has a rugged enclosure that can withstand the elements It is designed for point-to-point
or point-to-multipoint networks It can be mounted on poles, walls, or even roofs You can also change the polarization, which, depending on how the wireless bridge is mounted, could be a very important aspect of deploying this wireless bridge As far as the antennas
go, it has a high-gain internal radio, and you can also get a version of this hardware that al-lows you to do a professional installation of radios with N-type connectors This means that you can actually connect a high-gain dish The 1400 series does not support LWAPP and operates only in standalone mode
Note: Currently the 1400 series bridge cannot be managed by the controller and is not considered an AP
Cisco Access Point Summary Table 10-2 summarizes the Cisco APs
Trang 10Courtesy of Cisco Systems, Inc Unauthorized use not permitted.
Figure 10-7 Cisco 1400 Series AP
Table 10-2 Summary of Cisco APs
AP
Modes Supported Environment
Antennas Supported
802.11 Protocols Supported
Max Data Rates Supported
1130AG Autonomous/
lightweight AP.HREAP
1240AG Autonomous/
lightweight AP.HREAP
Rugged Indoor
1250 AP Autonomous/
lightweight AP
Rugged Indoor
1300 AP/bridge
Autonomous/
lightweight
AP, bridge
External
1400 Bridge only
(not an AP)
Outdoor Internal or
External
Wireless LAN Controllers The entire design of the Wireless LAN Controllers is for scalability The communication between a lightweight AP can happen over any type of Layer 2 or Layer 3 infrastructure using LWAPP There are integrated controller platforms designed for installation in switches The 3750-G actually comes as an integrated 2RU switch with either a 25 or 50
AP controller, as well as the WiSM and the WLCM These are both modular controllers