Assign WLANs unique security configurations supporting authentication, captive portal (hotspot), self registration or encryption schemes as data protection requirements dictate.
Authentication ensures that only known and trusted users or devices access a WLAN. Authentication is enabled per WLAN to verify the identity of both users and devices. Authentication is a challenge and response procedure for validating user credentials such as username, password and sometimes secret-key information.
A client must authenticate to an access point to receive resources from the network. Controllers and service platforms support EAP, EAP PSK, EAP-MAC, MAC and PSK/None authentication options.
The Extreme Networks Universal Access Points 6 GHz radios support only Wi-Fi Alliance (WFA) 6E Compliant network authentication methods. The AP3000/X and AP5010 6 GHz radios support SAE/SAE-PSK, and OWE (Opportunistic Wireless Encryption) for Open Networks.
Secure guest access to the network is referred to as captive portal access. A captive portal is guest access policy for providing guests temporary and restrictive access to the wireless network. Existing captive portal policies can be applied to a WLAN to provide secure guest access as needed.
A captive portal configuration provides secure authenticated access using a standard Web browser. Captive portals provide authenticated access by capturing and re-directing a wireless user's Web browser session to a captive portal login page where the user must enter valid credentials to access to the network. Once logged into captive portal, additional Agreement, Welcome and Fail pages provide the administrator with a number of options on captive portal screen flow and user appearance. Refer to Captive Portal for information on assigning a captive portal policy to a WLAN.
A passpoint policy provides an interoperable platform for streamlining Wi-Fi access to access points deployed as public hotspots. Passpoint is supported across a wide range of wireless network deployment scenarios and client devices. For more information, see Passpoint.
Encryption is central for WLAN security, as it provides data privacy for traffic forwarded over a WLAN. When the 802.11 specification was introduced, Wired Equivalent Privacy (WEP) was the primary encryption mechanism. WEP has since been interpreted as flawed in many ways, and is not considered an effective standalone encryption scheme for securing a wireless controller WLAN. WEP is typically used WLAN deployments designed to support legacy clients. New device deployments should use either WPA or WPA2 encryption.
Encryption applies a specific algorithm to alter its appearance and prevent unauthorized hacking. Decryption applies the algorithm in reverse, to restore the data to its original form. A sender and receiver must employ the same encryption/decryption method to inter-operate. When both TKIP and CCMP are both enabled a mix of clients are allowed to associate with the WLAN. Some use TKIP, others use CCMP. Since broadcast traffic needs to be understood by all clients, the broadcast encryption type in this scenario is TKIP.
TKIP-CCMP, WPA2-CCMP, WEP 64, WEP 128 and Keyguard encryption options are supported.
Refer to the other topics in this chapter to configure an encryption scheme for a WLAN.