Teletronics Technology TT-136 Ez Bridge User Manual the latest user menua1 revised

Teletronics Technology Co., Ltd. Ez Bridge the latest user menua1 revised

Users Manual Revised

Telertonics EzBridge TTN-11-208      TTN-11-208   EzBridge  User’s Guide    Version: 2.11         Last Updated: 08/11/2004
  i Federal Communication Commission Interference Statement This equipment has been tested and found to comply with the limits for a Class B digital device, pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection against harmful interference in a residential installation. This equipment generates, uses and can radiated radio frequency energy and, if not installed and used in accordance with the instructions, may cause harmful interference to radio communications. However, there is no guarantee that interference will not occur in a particular installation. If this equipment does cause harmful interference to radio or television reception, which can be determined by turning the equipment off and on, the user is encouraged to try to correct the interference by one of the following measures: l Reorient or relocate the receiving antenna. l Increase the separation between the equipment and receiver. l Connect the equipment into an outlet on a circuit different from that to which the receiver is connected. l Consult the dealer or an experienced radio/TV technician for help. FCC Caution: To assure continued compliance, (example – use only shielded interface cables when connecting to computer or peripheral devices). Any changes or modifications not expressly approved by the party responsible for compliance could void the user’s authority to operate this equipment. This transmitter must not be co-located or operating in conjunction with any other antenna or transmitter. FCC Radiation Exposure Statement This equipment complies with FCC radiation exposure limits set forth for an uncontrolled environment. This equipment should be installed and operated with minimum distance 20 cm between the radiator & your body. This device complies with Part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation.
  ii R&TTE Compliance Statement This equipment complies with all the requirements of DIRECTIVE 1999/5/CE OF THE EUROPEAN PARLIAMENT AND THE COUNCIL OF 9 March 1999 on radio equipment and telecommunication terminal equipment and the mutual recognition of their conformity (R&TTE). The R&TTE Directive repeals and replaces in the directive 98/13/EEC (Telecommunications Terminal Equipment and Satellite Earth Station Equipment) as of April 8,2000. Safety This equipment is designed with the utmost care for the safety of those who install and use it. However, special attention must be paid to the dangers of electric shock and static electricity when working with electrical equipment. All guidelines of this and of the computer manufacture must therefore be allowed at all times to ensure the safe use of the equipment. EU Countries Intended for Use The ETSI version of this device is intended for home and office use in Austria, Belgium, Denmark, Finland, France (with Frequency channel restrictions), Germany, Greece, Ireland, Italy, Luxembourg, Portugal, Spain, Sweden, The Netherlands, and United Kingdom. The ETSI version of this device is also authorized for use in EFTA member states Norway and Switzerland. EU Countries Not Intended for Use None. Potential Restrictive Use France: only channels 10, 11, 12, and 13.
  iii Table of Contents 1. Introduction ............................................................................................................................1 1.1. Overview ......................................................................................................................1 1.2. Features.......................................................................................................................1 1.3. Feature Comparison....................................................................................................3 1.4. LED Definitions ............................................................................................................3 2. First-Time Installation and Configuration...............................................................................4 2.1. Inserting the Accompanying PCMCIA WLAN Card ....................................................4 2.2. Selecting a Power Supply Method ..............................................................................4 2.3. Mounting the AP on a Wall..........................................................................................4 2.4. Preparing for Configuration .........................................................................................5 2.4.1. Connecting the Managing Computer and the AP.............................................5 2.4.2. Changing the TCP/IP Settings of the Managing Computer .............................6 2.5. Configuring the AP ......................................................................................................6 2.5.1. Entering the User Name and Password...........................................................6 2.5.2. Step 1: Selecting an Operational Mode............................................................8 2.5.3. Step 2: Configuring TCP/IP Settings ................................................................9 2.5.4. Step 3: Configuring IEEE 802.11 Settings .....................................................10 2.5.5. Step 4: Reviewing and Applying Settings.......................................................10 2.6. Deploying the AP .......................................................................................................11 2.7. Setting up Client Computers .....................................................................................11 2.7.1. Configuring IEEE 802.11b-Related Settings ..................................................11 2.7.2. Configuring TCP/IP-Related Settings .............................................................11 2.8. Confirming the Settings of the AP and Client Computers.........................................12 2.8.1. Checking if the IEEE 802.11b-Related Settings Work...................................12 2.8.2. Checking if the TCP/IP-Related Settings Work..............................................12 3. Using Web-Based Network Manager..................................................................................13 3.1. Overview ....................................................................................................................13 3.1.1. Menu Structure................................................................................................13 3.1.2. Save, Save & Restart, and Cancel Commands.............................................14 3.1.3. Home and Refresh Commands......................................................................15 3.2. Viewing Status ...........................................................................................................15 3.2.1. Associated Wireless Clients ...........................................................................15 3.2.2. Current DHCP Mappings ................................................................................16 3.2.3. System Log .....................................................................................................16 3.3. General Operations ...................................................................................................17 3.3.1. Specifying Operational Mode..........................................................................17 3.3.2. Changing Password........................................................................................18 3.3.3. Managing Firmware........................................................................................18 3.3.3.1. Upgrading Firmware by HTTP..............................................................18 3.3.3.2. Backing up and Restoring Configuration Settings by HTTP................19 3.3.3.3. Upgrading Firmware by TFTP..............................................................19 3.3.3.4. Backing up and Restoring Configuration Settings by TFTP ................21 3.3.3.5. Resetting Configuration to Factory Defaults ........................................22 3.4. Configuring TCP/IP Related Settings........................................................................23 3.4.1. Addressing ......................................................................................................23 3.4.2. DHCP Server ..................................................................................................23 3.4.2.1. Basic .....................................................................................................23 3.4.2.2. Static DHCP Mappings.........................................................................24 3.5. Configuring IEEE 802.11b-Related Settings.............................................................24 3.5.1. Communication...............................................................................................24 3.5.1.1. Basic .....................................................................................................24 3.5.1.2. Link Integrity..........................................................................................25
  iv 3.5.1.3. Association Control...............................................................................25 3.5.1.4. AP Load Balancing ...............................................................................25 3.5.1.5. Wireless Distribution System................................................................26 3.5.2. Security ...........................................................................................................29 3.5.2.1. Basic .....................................................................................................29 3.5.2.2. MAC-Address-Based Access Control..................................................30 3.5.3. IEEE 802.1x/RADIUS .....................................................................................31 3.6. Configuring Advanced Settings.................................................................................33 3.6.1. Packet Filters ..................................................................................................33 3.6.1.1. Ethernet Type Filters ............................................................................33 3.6.1.2. IP Protocol Filters .................................................................................33 3.6.1.3. TCP/UDP Port Filters............................................................................34 3.6.2. Management ...................................................................................................34 3.6.2.1. UPnP.....................................................................................................34 3.6.2.2. System Log...........................................................................................35 3.6.2.3. SNMP ....................................................................................................35 Appendix A: Default Settings ...................................................................................................37 Appendix B: Troubleshooting...................................................................................................38 B-1: Wireless Settings Problems......................................................................................38 B-2: TCP/IP Settings Problems........................................................................................39 B-3: Unknown Problems...................................................................................................40 Appendix C: Additional Information .........................................................................................42 C-1: Firmware Upgrade Using Xmodem Upgrade...........................................................42 C-2: Distances and Data Rates........................................................................................43
  1 1. Introduction 1.1. Overview The wireless access point (AP) enables IEEE 802.11b client computers to access the resources on the Ethernet network. There are 3 different model variations, Pro, Advanced, and Advanced+, which are classified in terms of features. The Pro edition provides the fewest features while the Advanced+ edition provides the most. With the sleek Web-based user interface and Windows-based user interface (Wireless Network Manager), a network administrator can easily and clearly manage the AP. In Chapter 2, we describe the steps to install and configure a newly acquired AP. Following the steps, the AP can be quickly set up to work. In Chapter 3, detailed explanation of each Web management page is given for the user to understand how to fine-tune the settings of an AP to meet his or her specific needs. In addition to  using Web-based management user interface to configure an AP, the Windows-based Wireless Network Manager can also be used to configure and monitor deployed APs. See the on-line help of Wireless Network Manager for more information. 1.2. Features l IEEE 802.11b n Operational modes u AP/Bridge.  This mode provides both Access Point and Static LAN-to-LAN Bridging functionality. The static LAN-to-LAN bridging function is supported through Wireless Distribution System (WDS). u AP Client. This mode is for Dynamic LAN-to-LAN Bridging. The AP Client automatically establishes bridge links with APs from any vendors. n 64-bit and 128-bit WEP (Wired Equivalent Privacy). For authentication and data encryption. n Enabling/disabling SSID broadcasts. When the AP is in AP/Bridge mode, the administrator can enable or disable the SSID broadcasts functionality for security reasons. When the SSID broadcasts functionality is disabled, a client computer cannot connect to the AP with an “any”  network name (SSID, Service Set ID); the correct SSID has to be specified on client computers. n MAC-address-based access control. When the AP is in AP/Bridge mode, it can be configured to block unauthorized wireless client computers based on MAC (Media Access Control) addresses. The ACL (Access Control List) can be downloaded from a TFTP server. n IEEE 802.1x/RADIUS. When the AP is in AP/Bridge mode, it can be configured to authenticate wireless users and distribute  encryption keys dynamically by IEEE 802.1x Port-Based  Network  Access Control and RADIUS (Remote Authentication Dial-In User Service). n Repeater. When the AP is in AP/Bridge mode, it can communicate with other APs or wireless bridges via WDS (Wireless Distribution System). Therefore, an AP can wirelessly forward packets from wireless clients to another AP, and then the later AP forwards the
  2 packets to the Ethernet network. n Wireless client isolation. When the AP is in AP/Bridge mode, wireless-to-wireless traffic can be blocked so that the wireless clients cannot see each other. This capability can be used in hotspots applications to prevent wireless hackers from attacking other wireless users’ computers. n AP load balancing. Several APs can form a load-balancing group. Within a group, wireless client associations and traffic load can be shared among the APs. This function is available when the AP is in AP/Bridge mode. n Transmit power control. Transmit power of the AP’s RF module can be adjusted to change RF coverage of the AP. n Link integrity. When  the AP is in AP/Bridge mode and its Ethernet LAN interface is detected to be disconnected from the wired network, all currently associated wireless clients are disassociated by the AP and no wireless client can associate with it. n Association control. When the AP is in AP/Bridge mode, it can be configured to deny association requests when it has served too many wireless clients or traffic load is too heavy. n Associated wireless clients status. When the AP is in AP/Bridge mode, it can show the status of all wireless clients that are associated with the AP. n Detachable antennas. The factory-mounted antennas can be replaced with high-gain antennas for different purposes. l DHCP client. The AP can automatically obtain an IP address from a DHCP server. l DHCP server. The AP can automatically assign IP addresses to computers or other devices by DHCP (Dynamic Host Configuration Protocol). n Static DHCP mappings. The  administrator can specify static IP address to MAC address mappings so that the specified IP addresses are always assigned to the hosts with the specified MAC addresses. n Showing current DHCP mappings. Showing which IP address is assigned to which host identified by an MAC address. l Packet Filtering. The AP provides Layer 2, Layer 3, and Layer 4 filtering capabilities. l Firmware Tools n Firmware upgrade. The firmware of the AP can be upgraded in the following methods: u Xmodem-based. Upgrading firmware over RS232. u TFTP-based. Upgrading firmware by TFTP (Trivial File Transfer Protocol). u HTTP-based. Upgrading firmware by HTTP (HeperText Transfer Protocol). n Configuration backup. The configuration settings of the AP can be backed up to a file via TFTP or HTTP for later restoring. n Configuration reset. Resetting the configuration settings to factory-default values.
  3 l Management n Windows-based Wireless Network Manager for configuring, monitoring, and diagnosing the local computer and neighboring APs. The management protocol is MAC-based. n Web-based Network Manager for configuring and monitoring the AP via a Web browser. The management protocol is HTTP (HeperText Transfer Protocol)-based. n SNMP. SNMP (Simple Network Management Protocol) MIB I, MIB II, IEEE 802.1d, IEEE 802.1x, and Private Enterprise MIB are supported. n UPnP. The AP responds to UPnP discovery messages so that a Windows XP user can locate the AP in My Network Places and use a Web browser to configure it. n Telnet. The user is enabled to manage the AP by Telnet. n System log. For system operational status monitoring. u Local log. System events are logged  to the on-board RAM of the AP and  can be viewed using a Web browser. u Remote log by SNMP trap. Systems events are sent in the form of SNMP traps to a remote SNMP management server. l Power over Ethernet (optional). Supplying power to an AP over an Ethernet cable using PowerDsine (http://www.powerdsine.com) technology (IEEE 802.3af compliant in the future). This feature facilitates large-scale wireless LAN deployment. l Hardware Watchdog Timer. If the firmware gets stuck in an invalid state, the hardware watchdog timer will detect this situation and restart the AP.  This way, the AP can provide continuous services. 1.3. Feature Comparison  Pro Advanced Advanced+ IEEE 802.1x/RADIUS  ¢ ¢ SNMP IEEE 802.1x MIB  ¢ ¢ Wireless client isolation     ¢ AP load balancing     ¢ Association control     ¢ l PoE is optional. 1.4. LED Definitions There are several LED indicators on the housing of the AP. They are defined as follows: l ALV: Alive. Blinks when the AP is working normally. l RF: IEEE 802.11b interfaces activity l LAN: Ethernet LAN interface activity l PWR: Power
  4 2. First-Time Installation and Configuration 2.1. Inserting the Accompanying PCMCIA WLAN Card For some models, the wireless interface of an AP is a WLAN PCMCIA card inserted into the PCMCIA socket labeled Wireless LAN Card. Since an AP and its accompanying WLAN PCMCIA card are placed separately within a package, you have to insert the PCMCIA card to the socket of the AP after they are taken out of the package. And then, plug the connector of the power adapter to the power jack of the AP to power it on. NOTE: Unless an AP is to be packed and moved to a distant place, don’t pluck out the PCMCIA card from the socket. 2.2. Selecting a Power Supply Method Optionally, the AP can be powered by the supplied power adapter or PoE (Power over Ethernet). The AP automatically selects the suitable one depending on your decision. To power the AP by the supplied power adapter: 1. Plug the power adapter to an AC socket.   2. Plug the connector of the power adapter to the power jack of the AP. NOTE: This product is intended to be power-supplied by a Listed Power Unit, marked “Class 2” or “LPS” and output rated “5V DC, 1 A minimum” or equivalent statement. To power the AP by PoE: 1. Plug one connector of an Ethernet cable to an available port of a PoE hub. 2. Plug the other connector of the Ethernet cable to the LAN/CONFIG port of the AP. NOTE:  The PoE capability of the bridge is PowerDsine-compatible. Please visit the Web site of PowerDsine for more information (http://www.powerdsine.com).   2.3. Mounting the AP on a Wall The AP is wall-mountable. 1. Stick the supplied sticker for wall-mounting. 2. Use a φ7.0mm driller to drill a 25mm-deep hole at each of the cross marks.   3. Plug in a supplied plastic conical anchor in each hole.   4. Screw a supplied screw in each plastic conical anchor for a proper depth so that the wireless AP can be hung on the screws.
  5 5. Hang the wireless AP on the screws.  Fig. 1. Mounting the AP on a wall. 2.4. Preparing for Configuration For you to configure an AP, a managing computer with a Web browser is needed. For first-time configuration of an AP, an Ethernet network interface card (NIC) should have been installed in the managing computer. For maintenance-configuration of a deployed AP, either a wireless computer or a wired computer can be employed as the managing computer. NOTE:  If you are using the browser,  Opera, to configure an AP, click the menu item  File, click Preferences..., click File types, and edit the MIME type, text/html, to add a file extension “.sht” so that Opera can work properly with the Web management pages of the AP. Since the configuration/management protocol is HTTP-based, you have to make sure that  the IP address of the managing computer and the IP address of the managed AP are in the same IP subnet (the default IP address of an AP is 192.168.0.1 and the default subnet mask is 255.255.255.0.) 2.4.1. Connecting the Managing Computer and the AP To connect the Ethernet managing computer and the managed AP for first-time configuration, you have two choices as illustrated in Fig. 2.
  6  Managing Computer Normal Ethernet cable Managed AP Normal Ethernet cable Ethernet Hub/Switch Cross-overEthernet cable  Fig. 2. Connecting a managing computer and an AP via Ethernet. You can use either a  cross-over Ethernet cable (included in the package) or a switch/hub with 2 normal Ethernet cables. NOTE: One connector of the Ethernet cable must be plugged into the LAN/CONFIG Ethernet jack of the AP for configuration. 2.4.2. Changing the TCP/IP Settings of the Managing Computer Use the  Windows Network Control Panel Applet to change the TCP/IP settings of the managing computer, so that the IP address of the computer and the IP address of the AP are in the same IP subnet. Set the IP address of the computer to  192.168.0.xxx (the default IP address of an AP is 192.168.0.1) and the subnet mask to 255.255.255.0. NOTE: For some versions of Windows, the computer needs to be restarted for the changes of TCP/IP settings to take effect. TIP:  After you have connected the managing computer and the AP via Ethernet, you can install Wireless Network Manager on the managing computer and use it to configure the AP without being concerned about the TCP/IP settings of the managing computer. Refer to the on-line help of Wireless Network Manager for more information. 2.5. Configuring the AP After the IP addressing issue is resolved, launch a Web browser on the managing computer. Then, go to “http://192.168.0.1” to access the Web-based Network Manager start page. TIP: For maintenance configuration of an AP, the AP can be reached by its host name using a Web browser. For example, if the AP is named  “AP”, you can use the URL “http://AP” to access the Web-based Network Manager of the AP. 2.5.1. Entering the User Name and Password Before the start page is shown, you will be prompted to enter the user name and password to gain the
  7 right to access the Web-based Network Manager. For first-time configuration, use the default user name “root” and default password “root”, respectively.  Fig. 3. Entering the user name and password. NOTE: It is strongly recommended that the password be changed to other value for security reasons. On the start page, click the General, Password link to change the value of the password (see Section 3.3.1 for more information). TIP: Since the start page shows the current settings and status of the AP, it can be saved or printed within the Web browser for future reference.  Fig. 4. The Start page.
  8 2.5.2. Step 1: Selecting an Operational Mode  Fig. 5. Operational modes settings. Go to the General, Operational Mode section, select an operational mode and  click  Save at the bottom of this page, and then you are brought back to the start page. The AP supports 2 operational modes: n AP/Bridge.  This mode provides both Access Point and  Static LAN-to-LAN Bridging functionality. The static LAN-to-LAN bridging function is supported through Wireless Distribution System (WDS). n AP Client. This mode is for Dynamic LAN-to-LAN Bridging. The AP Client automatically establishes bridge links with APs from any vendors. In either mode, the AP forwards packets between its Ethernet interface and wireless interface for wired hosts on the Ethernet side and wireless host(s) on the wireless side. There are 2 types of wireless links as specified by the IEEE 802.11 standard. n STA-AP. This type of wireless link is established between an IEEE 802.11 Station (STA) and an IEEE 802.11 Access Point (AP). An STA is usually a client computer (PC or PDA) with a WLAN network interface card (NIC). The AP Client mode is actually an STA. n WDS. This type of wireless link is established between two IEEE 802.11 APs. Wireless packets transmitted along the WDS link comply with the IEEE 802.11 WDS (Wireless Distribution System) format at the link layer. The relationships among the operational modes and the wireless link types are shown in the following table:
  9 Table 1. Operational modes vs. wireless link types.  AP/Bridge AP Client AP/Bridge WDS STA-AP AP Client STA-AP   To establish a static bridge link based on WDS, the AP/bridges at both end of the WDS link must be manually configured with each other’s MAC addresses (see Section 3.5.1.5 for more information). To establish a dynamic bridge link between an AP and an AP Client, both devices have to be configured with the same SSID and WEP settings. The AP Client automatically scans for any AP that is using the matched SSID and establishes a bridge link with the scanned AP. NOTE: Although it’s more convenient to use dynamic bridging, it has a limitation—the AP Client only can forward TCP/IP packets between its wireless interface and Ethernet interface; other type of traffic (such as IPX and AppleTalk) is not forwarded. TIP: When the AP is configured to be in AP Client, it can be used as an Ethernet-to-wireless network adapter. For example, a notebook computer equipped with an Ethernet adapter can be connected to this device with a crossover Ethernet cable for wireless connectivity to another access point. 2.5.3. Step 2: Configuring TCP/IP Settings  Fig. 6. TCP/IP settings. Go to the  TCP/IP, Addressing section to configure IP address settings. The IP address can be manually set or automatically assigned by a DHCP server on the LAN. If you are manually setting the IP address, Subnet mask, and Default gateway settings, set them appropriately, so that they comply with your LAN environment. In addition, you can specify the Host name  and Domain (DNS suffix) of the AP. When you are finished, click Save at the bottom of this page, and then you are brought back to the start page.
  10 2.5.4. Step 3: Configuring IEEE 802.11 Settings  Fig. 7. IEEE 802.11b communication settings. Go to the IEEE 802.11, Communication section to configure IEEE 802.11b-related communication settings, including Network name (SSID). The number of available RF channels depends on local regulation (FCC (US)).  The SSID of a wireless client computer and the SSID of the AP must be identical for them to communicate with each other. When you are finished, click Save at the bottom of this page, and then you are brought back to the start page. 2.5.5. Step 4: Reviewing and Applying Settings  Fig. 8. Settings changes are highlighted in red.  On the start page, you can review all the settings you have made. Changes are highlighted  in red. If they are OK, click Restart to restart the AP for the new settings to take effect.
  11 NOTE: About 7 seconds are needed for the AP to complete its restart process. 2.6. Deploying the AP After the settings have been configured, deploy the AP to the field application environment. Connect the AP to an Ethernet LAN through an Ethernet switch/hub. 2.7. Setting up Client Computers The TCP/IP and IEEE 802.11b-related settings of wireless client computers must match those of the AP. 2.7.1. Configuring IEEE 802.11b-Related Settings Before the TCP/IP networking system of a wireless client computer can communicate with other hosts, the underlying wireless link must be established between this wireless computer and an AP. To establish a wireless link to an AP: 1. Launch the configuration/monitoring utility provided by the vendor of the installed WLAN NIC. 2. Use the utility to make appropriate Operating Mode, SSID and WEP settings. NOTE: A wireless client computer must be in infrastructure mode, so that it can associate with an AP. NOTE: The SSID of the wireless client computer and the SSID of the AP must be identical. Or, in case the SSID broadcasts capability of the AP is enabled (by default), the SSID of the wireless client computer could be set to “any”. NOTE: Both the wireless client computer and the AP must have the same WEP settings for them to communicate with each other. NOTE: For better wireless security, IEEE 802.1x capability of the AP must be enabled so that only authenticated wireless users can access the wireless network. Refer to the IEEE 802.1x-related white papers on the companion CD-ROM for more information about deploying secure WLANs with IEEE 802.1x support. 2.7.2. Configuring TCP/IP-Related Settings Use Windows Network Control Panel Applet to change the TCP/IP settings of the client computers, so that the IP addresses of the client computers and the IP address of the AP are in the same IP subnet. If a client computer is originally set a static IP address, you can either change its IP address to match the IP address of the AP, or select an automatically-obtain-an-IP-address option if there is a DHCP server on the network. NOTE: For some versions of Windows, the computer needs to be restarted for the changes of TCP/IP settings to take effect.
  12 2.8. Confirming the Settings of the AP and Client Computers After you have completed deploying the AP and setting up client computers, you have to make sure the settings you have made are correct. 2.8.1. Checking if the IEEE 802.11b-Related Settings Work To check if a wireless client computer can associate with the AP: 1. Launch the configuration/monitoring utility provided by the vendor of the installed WLAN NIC. 2. Check if the client computer is associated to an access point, and the access point is the AP. If the check fails, see Appendix B-1, “Wireless Settings Problems” for troubleshooting. 2.8.2. Checking if the TCP/IP-Related Settings Work To check if a client computer can access the Internet: 1. Open a Windows Command Prompt window on the client computer. 2. Type “ping advap”, where advap is a placeholder for the IP address of the AP. Replace it with your real IP address—for example, 192.168.0.1. Then press Enter. If the AP responds, go to the next step; else, see Appendix B-2, “TCP/IP Settings Problems” for troubleshooting. 3. Type “ping default_gateway”, where default_gateway is a placeholder for the IP address of the default gateway of the wireless client computer. Then press Enter. If the gateway responds, go to the next step; else, see Appendix B-2,  “TCP/IP Settings Problems” for troubleshooting. 4. Type “ping 1st_dns_server”, where  1st_dns_server is a placeholder for the IP address of the primary DNS server of the wireless client computer. Then press Enter. If this DNS server responds, go to the next step; else, see Appendix B-2,  “TCP/IP Settings Problems” for troubleshooting. 5. Type “ping 2nd_dns_server”, where 2nd_dns_server is a placeholder for the IP address of the secondary DNS server of the wireless client computer. Then press Enter. If this DNS server responds the client should have no problem with TCP/IP networking; else, see Appendix B-2, “TCP/IP Settings Problems” for troubleshooting.
  13 3. Using Web-Based Network Manager In this chapter, we’ll explain each Web management page of the Web-based Network Manager. 3.1. Overview  Fig. 9. The Start page. 3.1.1. Menu Structure The left side of the  start page contains a menu for you to carry out commands. Here is a brief description of the hyperlinks on the menu: l Home. For going back to the start page. l Status. Status information. n Wireless Clients. The status of the wireless clients currently associated with the AP. n DHCP Mappings. Current IP-MAC address mappings of the built-in DHCP server. n System Log. System events log. l General. Global operations.
  14 n Password. For gaining rights to change the settings of the AP. n Firmware Tools.  For upgrading the firmware of the AP, backing up and restoring configuration, and configuration reset settings of the AP. l TCP/IP. TCP/IP-related settings. n Addressing. IP address settings for the AP to work with TCP/IP. n DHCP Server. Settings for the DHCP (Dynamic Host Configuration Protocol) server on the AP. l IEEE 802.11. IEEE 802.11b-related settings. n Communication.  Basic settings for the IEEE 802.11b interface of the AP to work properly with wireless clients. n Security. Security settings for authenticating wireless users and encrypting wireless data. n IEEE 802.1x/RADIUS. IEEE 802.1x Port-Based Network Access Control and RADIUS (Remote Authentication Dial-In User Service) settings for better wireless security. l Advanced. Advanced settings of the AP. n Packet Filters.  Ethernet Type Filters, IP Protocol Filters, and TCP/UDP Port Filters settings. n Management. UPnP, System Log, and SNMP settings. 3.1.2. Save, Save & Restart, and Cancel Commands  Fig. 10. Save, Save & Restart, and Cancel. At the bottom of each page that contains settings you can configure, there are up to three buttons—Save,  Save & Restart, and Cancel. Clicking  Save stores the settings changes to the memory of the AP and brings you back to the start page. Clicking Save & Restart stores the settings changes to the memory of the AP and restarts the AP immediately for the settings changes to take effect. Clicking Cancel discards any settings changes and brings you back to the start page. If you click Save, the start page will reflect the fact that the configuration settings have been changed by showing two buttons—Restart and Cancel. In addition, changes are highlighted in red. Clicking Cancel discards all the changes. Clicking  Restart restarts the AP for the settings changes to take effect.
  15  Fig. 11. Settings have been changed. 3.1.3. Home and Refresh Commands  Fig. 12. Home and Refresh. At the bottom of each status page that shows read-only information, there are two buttons—Home and Refresh. Clicking Home  brings you back to the start page. Clicking Refresh updates the shown status information. 3.2. Viewing Status 3.2.1. Associated Wireless Clients  Fig. 13. Status of associated wireless clients. On this page, the status information of each associated client, including its MAC address, IP address, user name (if the client has been IEEE 802.1x authenticated), number of bytes it has send, number of bytes it has received, and the time of its last activity, is shown.
  16 3.2.2. Current DHCP Mappings  Fig. 14. Current DHCP mappings. On this page, all the current  static or dynamic DHCP mappings are shown. A DHCP mapping is a correspondence relationship between an IP address assigned by the DHCP server and a computer or device that obtains the IP address. A computer or device that acts as a DHCP client is identified by its MAC address. A static mapping indicates that the DHCP client always obtains the specified IP address from the DHCP server. You can set static DHCP mappings in the  Static DHCP Mappings section  of the DHCP Server configuration page (see Section 3.4.2). A dynamic mapping indicates that the DHCP server chooses an IP address from the IP address pool specified by the First allocateable IP address and Allocateable IP address count settings on the DHCP Server configuration page. 3.2.3. System Log  Fig. 15. System log. System events are recorded in the memory of the AP. The logged information is useful for troubleshooting purposes. The system events are divided into several categories, and you can select which categories of events to log. See Section 3.6.2.2 for more information.
  17 3.3. General Operations 3.3.1. Specifying Operational Mode  Fig. 16. Operational modes settings. The AP supports 2 operational modes: n AP/Bridge.  This mode provides both Access Point and  Static LAN-to-LAN Bridging functionality. The static LAN-to-LAN bridging function is supported through Wireless Distribution System (WDS). n AP Client. This mode is for  Dynamic LAN-to-LAN Bridging. The AP Client automatically establishes bridge links with APs from any vendors. In either mode, the AP forwards packets between its Ethernet interface and wireless interface for wired hosts on the Ethernet side and wireless host(s) on the wireless side. There are 2 types of wireless links as specified by the IEEE 802.11 standard. n STA-AP. This type of wireless link is established between an IEEE 802.11 Station (STA) and an IEEE 802.11 Access Point (AP). An STA is usually a client computer (PC or PDA) with a WLAN network interface card (NIC). The AP Client mode is actually an STA. n WDS. This type of wireless link is established between two IEEE 802.11 APs. Wireless packets transmitted along the WDS link comply with the IEEE 802.11 WDS (Wireless Distribution System) format at the link layer. The relationships among the operational modes and the wireless link types are shown in the following table: Table 2. Operational modes vs. wireless link types.  AP/Bridge AP Client AP/Bridge WDS STA-AP AP Client STA-AP   To establish a static bridge link based on WDS, the AP/bridges at both end of the WDS link must be manually configured with each other’s MAC addresses (see Section 3.5.1.5 for more information). To establish a dynamic bridge link between an AP and an AP Client, both devices have to be configured with the same SSID and WEP settings. The AP Client automatically scans for any AP that is using the matched SSID and establishes a bridge link with the scanned AP.
  18 NOTE: Although it’s more convenient to use dynamic bridging, it has a limitation—the AP Client only can forward TCP/IP packets between its wireless interface and Ethernet interface; other type of traffic (such as IPX and AppleTalk) is not forwarded. TIP: When the AP is configured to be in AP Client, it can be used as an Ethernet-to-wireless network adapter. For example, a notebook computer equipped with an Ethernet adapter can be connected to this device with a crossover Ethernet cable for wireless connectivity to another access point. 3.3.2. Changing Password  Fig. 17. Password. On this page, you can change the user name and password for the right to modify the configuration of the bridge. The new password must be typed twice for confirmation. 3.3.3. Managing Firmware  Fig. 18. Firmware management protocol setting. Firmware management operations for the AP include  firmware upgrade,  configuration backup, configuration restore, and configuration reset. Firmware upgrade, configuration backup, and configuration restore can be achieved via HTTP or TFTP. The HTTP-based way is suggested because it’s more user friendly. However, due to different behavior of  different Web browser types and versions, HTTP-based firmware management operations may not work properly with some Web browsers. If you cannot successfully perform HTTP-based firmware management operations with your Web browser, try the TFTP-based way. TIP:  You can use Upgrade Wizard of Wireless Network Manager to upgrade firmware. See the on-line help of Wireless Network Manager for more information. 3.3.3.1. Upgrading Firmware by HTTP  Fig. 19. Firmware upgrade by HTTP. To upgrade firmware of the AP by HTTP: 1. Click Browse and then select a correct firmware .bin file. The firmware file path will be shown in the Firmware file name text box.
  19 2. Click Upgrade to begin the upgrade process. 3.3.3.2. Backing up and Restoring Configuration Settings by HTTP  Fig. 20. Firmware backup by HTTP. To back up configuration of the AP by HTTP: 1. Click Back Up. 2. You’ll be prompted to open or save the configuration file. Click Save. 3. The configuration file is named by the AP’s MAC address. For example, if the AP’s MAC address is 00-01-02-33-44-55,  the configuration backup file should be  “000102334455.hex”. Don’t change the configuration file name in the Save As dialog box. Select a folder in which the configuration file is to be stored. And then, click Save. NOTE: The procedure may be a little different with different Web browsers.  Fig. 21. Configuration restore by HTTP. To restore configuration of the AP by HTTP: 1. Click Browse and then select a correct configuration .hex file. You have to make sure the file name is the AP’s MAC address. The firmware file path will be shown in the Firmware file name text box. 2. Click Restore to upload the configuration file to the AP. 3.3.3.3. Upgrading Firmware by TFTP  Fig. 22. TFTP server settings. When use TFTP as the firmware management protocol, you can configure settings for the AP’s TFTP client to communicate with a TFTP server. If the TFTP client does not get a response from the TFTP server within a period specified by the Timeout setting, it will resend the previous request. The Max number of retries setting specifies the maximal number of resend before the TFTP client stops communicating with the TFTP server. Within the folder “Utilities” on the companion CD-ROM disk, we offered a TFTP server program
  20 (TftpSrvr.exe) for firmware upgrade. Run this program on the computer that is to serve as a TFTP server.  Fig. 23. Firmware upgrade by TFTP. To upgrade firmware of the AP by TFTP: 1. Get a computer that will be used as a TFTP server and as a managing computer to trigger the upgrade process. 2. Connect the computer and one of the LAN Ethernet switch port with a normal Ethernet cable. 3. Configure IP address of the computer so that the AP and the computer are in the same IP subnet. 4. On the computer, run the TFTP Server utility. And specify the folder in which the firmware files reside. 5. On the computer, run a Web browser and click the General, Firmware Tools hyperlink.   6. Choose TFTP as the Firmware management protocol. 7. Specify the IP address of the computer, which acts as a TFTP server. If you don’t know the IP address of the computer, open a Command Prompt, and type IpConfig, then press the Enter key.   8. Trigger the firmware upgrade process by clicking Upgrade.  Fig. 24. TFTP Server. NOTE: After the dialog box of the TFTP server program appears, be sure to specify the working
  21 folder within which the downloaded firmware files reside. NOTE: Make sure the Accept read requests check box of TFTP Server is selected. NOTE: The LAN IP address of the AP and the IP address of the TFTP server must be in the same IP subnet for TFTP to work. NOTE: Due to the unreliable nature of wireless media, it’s highly recommended that the TFTP server and the to-be-upgraded wireless AP be connected by Ethernet, and on the same LAN, so that the upgrade process would be smooth. NOTE: After the firmware is upgraded, be sure to delete the contents of the Web browser cache, so that the Web management pages can be shown correctly. NOTE: A failed upgrade may corrupt the firmware and make the AP unstartable. When this occurs, call for technical support. TIP: If you want to remotely upgrade the firmware of a deployed AP from the Internet, adjust the Timeout and Max no. of retries settings of TFTP Server for remote TFTP upgrade to succeed. 3.3.3.4. Backing up and Restoring Configuration Settings by TFTP  Fig. 25. Configuration backup/restore. To back up configuration of the AP by TFTP: 1. Get a computer that will be used as a TFTP server and as a managing computer to trigger the backup process.   2. Connect the computer and one of the LAN Ethernet switch port with a normal Ethernet cable. 3. Configure the IP address of the computer so that the computer and the AP are in the same IP subnet. 4. On the computer, run the TFTP Server utility. Select the Accept write requests check box, and specify the folder to which the configuration settings of the AP will be saved. 5. On the computer, run a Web browser and click the General, Firmware Tools hyperlink.   6. Choose TFTP as the Firmware management protocol. 7. Within the  Configuration Backup/Restore section, specify the IP address of the computer, which acts as a TFTP server. If you don’t know the IP address of the computer, open a Command Prompt, and type IpConfig, then press the Enter  key. 8. Trigger the backup process by clicking Back Up. The AP’s configuration settings will be saved as  “AaBbCcDdEeFf.hex” by the TFTP server, where  “AaBbCcDdEeFf” is the AP’s MAC address. For example, if the AP’s MAC address is 00-01-02-33-44-55, the configuration backup file will be “000102334455.hex”.
  22 NOTE: Remember to select the Accept write requests check box of TFTP Server. To restore configuration of the AP by TFTP: 1. Get a computer that will be used as a TFTP server and as a managing computer to trigger the restoring process.   2. Connect the computer and one of the LAN Ethernet switch port with a normal Ethernet cable. 3. Configure the IP address of the computer so that the computer and the AP are in the same IP subnet.   4. On the computer, run the TFTP Server utility. And specify the folder in which the configuration backup file resides. A configuration backup file is named by the AP’s MAC address. For example, if the AP’s MAC address is 00-01-02-33-44-55, the configuration backup file should be “000102334455.hex”. 5. On the computer, run a Web browser and click the General, Firmware Tools hyperlink.   6. Choose TFTP as the Firmware management protocol. 7. Within the  Configuration Backup/Restore section, specify the IP address of the computer, which acts as a TFTP server. If you don’t know the IP address of the computer, open a Command Prompt, and type IpConfig, then press the Enter  key. 8. Trigger the restoring process by clicking Restore . The AP will then download the configuration backup file from the TFTP server. NOTE: Make sure the file is a valid configuration backup file for the AP. TIP: If you want to remotely back up or restore configuration from the Internet, adjust the Timeout and Max no. of retries settings of TFTP Server for remote TFTP configuration backup/restore to succeed. 3.3.3.5. Resetting Configuration to Factory Defaults  Fig. 26. Configuration reset. Clicking the Reset button resets the device configuration to factory defaults. WARNING: Think twice before clicking the Reset button. You’ll lose all your current configuration settings.
  23 3.4. Configuring TCP/IP Related Settings 3.4.1. Addressing  Fig. 27. TCP/IP settings. The IP address of the AP can be manually set (Set Manually) or automatically assigned by a DHCP server on the LAN (Obtain from a DHCP Server). If you are manually setting the IP address, Subnet mask, and Default gateway settings, set them appropriately, so that they comply with your LAN environment. In addition, you can specify the Host name  and Domain (DNS suffix) of the AP. 3.4.2. DHCP Server 3.4.2.1. Basic  Fig. 28. Basic DHCP server settings. The AP can automatically assign IP addresses to client computers by DHCP. In this section of the management page, you can specify the Default gateway, Subnet mask, Primary DNS server, and Secondary DNS server settings that will be sent to a client at its request. Additionally, you can specify the first IP address that will be assigned to the clients and the number of allocateable IP addresses. NOTE: There should be only  one DHCP server on  the LAN; otherwise, DHCP would not work properly. If there is already a DHCP server on the LAN, disable the DHCP server functionality of the AP. NOTE: By default the DHCP server function is disabled.
  24 3.4.2.2. Static DHCP Mappings  Fig. 29. Static DHCP mappings. IP addresses of servers are often static so that clients could always locate the servers by the static IP addresses. By Static DHCP Mappings, you can ensure that a host will get the same IP address when it requests one from the DHCP server. Therefore, instead of configuring the IP address of an intranet server manually, you can configure the server to obtain an IP address by DHCP and it is always assigned the same IP address. To always assign a static IP address to a specific DHCP client: 1. Specify the MAC address of the DHCP client and the IP address to be assigned to it. Then, give a description for this mapping. 2. Select the corresponding Enabled check box. 3.5. Configuring IEEE 802.11b-Related Settings 3.5.1. Communication 3.5.1.1. Basic Basic IEEE 802.11b-related communication settings include AP functionality, Regulatory domain, Channel number, Network name (SSID), Data rate, and Transmit power.  Fig. 30. Basic IEEE 802.11b communication settings.
  25 For specific needs such as configuring the AP as a wireless LAN-to-LAN bridge, the AP functionality can be disabled, so that no wireless client can associate with the AP. The number of available RF channels depends on local regulations; therefore you have to choose an appropriate regulatory domain to comply with local regulations. The SSID of a wireless client computer and the SSID of the AP must be identical for them to communicate with each other. If there is RF interference, you may want to reduce the  Data rate for more reliable wireless transmission. In most cases, leave the setting to Auto. The transmit power of the RF module of the AP can be adjusted so that the RF coverage of the AP can be changed. 3.5.1.2. Link Integrity  Fig. 31. Link integrity settings. When the Ethernet LAN interface is detected to be disconnected from the wired network, all currently associated wireless clients are disassociated by the AP and no wireless client can associate with the AP. The detection mechanism is based on pinging the IP address specified in Reference host. 3.5.1.3. Association Control  Fig. 32. Association control settings. If the number of currently associated wireless clients exceeds the value specified in the Max number of clients setting, no more wireless client can associate with the AP. If traffic load of the AP exceeds the load specified in the Block clients if traffic load exceeds setting, no more wireless client can associate with the AP. 3.5.1.4. AP Load Balancing  Fig. 33. AP load balancing settings. Several APs can form a load-balancing group if they are set with the same Group ID. The load-balancing policy can be by Number of Users  or by Traffic Load.
  26 If the by-number-of-users policy is selected, a new wireless user can only associate with an AP that has the smallest number of associated wireless users in the group. On the other hand, if the by-traffic-load policy is selected, a new wireless user can only associate with an AP that has the less traffic load in the group. 3.5.1.5. Wireless Distribution System   LAN AP 2 Notebook Computer AP 1 WDS  Fig. 34. Wireless Distribution System. Traditionally, access points are connected by Ethernet. By Wireless Distribution System (WDS), APs can communicate with one another wirelessly. For example, in Fig. 34, AP 2 acts as an access point for the notebook computers and it forwards packets sent from the notebook computers to AP 1 through WDS. Then, AP 1 forwards the packets to the Ethernet LAN. Packets destined for the notebook computers follow a reverse path from the Ethernet LAN through the APs to the notebook computers. In this way, AP 2 plays a role of “AP repeater”.   LAN Segment 2  LAN Segment 1 Bridge 1 WDS Link Bridge 2  Fig. 35. LAN-to-LAN bridging. By WDS, two or more LAN segments can be connected wirelessly. As illustrated in Fig. 35, a pair of wireless LAN-to-LAN bridges is used to connect two LAN segments. Since the AP is WDS-enabled, it can be used as a wireless bridge. NOTE: An AP can have up to 6 WDS links to other APs or wireless bridges.
  27  Fig. 36. Wireless Distribution System settings. To enable a WDS link: 1. Specify the MAC address of the AP at the other end of the WDS link. 2. Select the corresponding Enabled check box. For example, assume you want two APs with MAC addresses 00-02-65-01-62-C5 and 00-02-65-01-62-C6 to establish a WDS link between them. On AP 00-02-65-01-62-C5, set the peer MAC address of port 1 to 00-02-65-01-62-C6 and on AP 00-02-65-01-62-C6, set the peer MAC address of port 1 to 00-02-65-01-C5. TIP: Plan your wireless network and draw a diagram, so that you know how an AP is connected to other peer APs or wireless bridges by WDS. TIP: Plan your wireless network and draw a diagram, so that you know how a bridge is connected to other peer bridges by WDS. See the following figure for an example network-planning diagram.  Fig. 37. Sample wireless bridge network topology. WARNING:  Don’t let your network topology  consisting of wireless bridges, Ethernet switches, Ethernet links, and WDS links contain loops. If any loops exist, packets will circle around the loops and network performance will be seriously degraded.
  28  Fig. 38. Network topology containing a loop. If external high-gain  directional antennas are used, it’s difficult to align the antennas when the distance between the bridges is long. To adjust the alignments of a pair of bridges’ directional antennas: 1. Connect each bridge to a computer via Ethernet. 2. Configure the date rate of each bridge to the lowest value, 1Mbps. 3. Fix the alignment of the antenna on one side. 4. Adjust the alignment of the antenna on other side by using response time information obtained from PINGing (run PING.exe) the “fixed-side” computer. 5. Fine-tune the alignment of the antenna until you get a best response time. 6. Increase the data rate of each bridge simultaneously until a maximal workable data rate is reached. You may not be able to use the highest data rate, 11Mbps, because of the distance and the gain of the antennas. Fig. 39 illustrates the idea.  Bridge 1 WDS Link Computer 1 Computer 2 Bridge 2 PING (ICMP Echo Request) ICMP Echo Reply Adjust antenna alignment  Fig. 39. Adjusting alignments of external directional antennas. NOTE: There are two antenna connectors on one side of the bridge. Connect your high-gain antenna to the connector labeled “Primary”.
  29 3.5.2. Security IEEE 802.11b security settings include SSID broadcasts, Wireless client isolation, Security mode , IEEE 802.11 Authentication algorithm, WEP keys , MAC-Address-Based Access Control. 3.5.2.1. Basic  Fig. 40. Basic IEEE 802.11b security settings. For security reasons, it’s highly recommended that the security mode be set to options other than Open System. When the security mode is set to Open System, no authentication and data encryption will be performed. Additionally, you can disable the SSID broadcasts functionality so that a wireless client computer with an “any” SSID cannot associate with the AP. When the Wireless client isolation setting is set to This AP Only, wireless clients of this AP as an AP cannot see each other, and wireless-to-wireless traffic is blocked. When the setting is set to All APs in This Subnet, traffic among wireless users of different APs in the same IP subnet is blocked. This feature is useful for WLANs deployed in public places. In this way, hackers have no chance to attack other wireless users in a hotspot. There are up to 5 security modes depending on AP model variations: l Open System. No authentication, no data encryption. l Static WEP. WEP (Wired Equivalent Privacy) keys must be manually configured. l IEEE 802.1x EAP without Encryption. The IEEE 802.1x functionality is enabled and the user-name/password-based EAP-MD5 authentication is used. No data encryption. l IEEE 802.1x EAP with Static WEP.  The IEEE 802.1x functionality is enabled and the user-name/password-based EAP-MD5 authentication is used. Data encryption is achieved by static WEP. l IEEE 802.1x EAP with Dynamic WEP.  The IEEE 802.1x functionality is enabled and dynamic WEP key distribution authentication (EAP-TLS, EAP-TTLS, or PEAP) is used. Data encryption is achieved by dynamic WEP. See Section 3.5.3 for more information about IEEE 802.1x. According to the IEEE 802.11 standard, WEP can be used for authentication and data encryption.
  30 Normally, Shared Key authentication is used if WEP data encryption is enabled. In rare cases, Open System authentication may be used when WEP data encryption is enabled. The Authentication algorithm setting is provided for better compatibility with wireless clients with various WLAN network adapters. There are three options available, including Open System, Shared Key, and Auto. When WEP is enabled by a security mode, the Key length can be specified to be 64 Bits or 128 Bits. The Selected key setting specifies the key to be used as a send-key for encrypting traffic from the AP side to the wireless client side. All 4 WEP keys are used as receive-keys to decrypt traffic from the wireless client side to the AP side. NOTE: Each field of a WEP key setting is a hex-decimal number from 00 to FF. For example, when the security mode is Static WEP and the key length is 64 Bits, you could set Key 1 to “00012E3ADF”. 3.5.2.2. MAC-Address-Based Access Control  Fig. 41. MAC-address-based access control settings. With MAC-Address-Based Access Control, you can specify the wireless client computers that are permitted or not permitted to associate with the AP. When the table type is set to inclusive, entries in the table are permitted to associate with the AP. When the table type is set to  exclusive, entries in the table are not permitted to associate with the AP. To deny wireless clients’ access to the wireless network: 1. Select Enabled from the Functionality drop-down list. 2. Set the Access control type to exclusive. 3. Specify the MAC address of a wireless client to be denied access, and then click Add. 4. Repeat Steps 3 for other wireless clients. To grant wireless clients’ access to the wireless network: 1. Select Enabled from the Functionality drop-down list. 2. Set the Access control type to inclusive. 3. Specify the MAC address of a wireless client to be denied access, and then click Add. 4. Repeat Steps 3 for other wireless clients. To delete an entry in the access control table:
  31 l Click Delete next to the entry. NOTE: The size of the access control table is 64.  Fig. 42. MAC ACL download settings. Instead of manually entering MAC addresses to the access control table one by one, you can prepare a text file that contains all the MAC addresses and put it on a TFTP server, and then command the AP to download the MAC ACL (Access Control List) file from the TFTP server.  Fig.  43 shows the contents of a sample ACL file.  Fig. 43. Sample MAC ACL file. To download a MAC ACL file from a TFTP server: 1. Specify the IP address of the TFTP server in the TFTP server IP address text box. 2. Specify the name of the MAC ACL file on the TFTP server in the MAC ACL file name  text box. 3. Click Download. 3.5.3. IEEE 802.1x/RADIUS IEEE 802.1x Port-Based Network Access Control is a new standard for solving some security issues associated with IEEE 802.11, such as lack of user-based authentication and dynamic encryption key distribution. With IEEE 802.1x and the help of a RADIUS (Remote Authentication Dial-In User Service) server and a user account database, an enterprise or ISP (Internet Service Provider) can manage its mobile users’ access to its wireless LANs. Before granted access to a wireless LAN supporting IEEE 802.1x, a user has to issue his or her user name and password or digital certificate to the backend RADIUS server by EAPOL (Extensible Authentication Protocol Over LAN). The RADIUS server can record accounting information such as when a user logs on to the wireless LAN and logs off from the wireless LAN for monitoring or billing purposes. The IEEE 802.1x functionality of the access point is controlled by the security mode (see Section
  32 3.5.2.1). So far, the wireless access point supports two authentication mechanisms—EAP-MD5 (Message Digest version 5), EAP-TLS (Transport Layer Security). If EAP-MD5 is used, the user has to give his or her user name and password for authentication. If EAP-TLS is used, the wireless client computer automatically gives the user’s digital certificate that is stored in the computer hard disk or a smart card for authentication. And after a successful EAP-TLS authentication, a session key is automatically generated for wireless packets encryption between the wireless client computer and its associated wireless access point. To sum up, EAP-MD5 supports only user authentication, while EAP-TLS supports user authentication as well as dynamic encryption key distribution.  Fig. 44. IEEE 802.1x and RADIUS. An access point supporting IEEE 802.1x can be configured to communicate with two RADIUS servers. When the primary RADIUS server fails to respond, the wireless access point will try to communicate with the secondary RADIUS server. You can specify the length  of timeout and the number of retries before communicating with the secondary RADIUS server after failing to communicate with the primary RADIUS server. An IEEE 802.1x-capable wireless access point and its RADIUS server(s) share a secret key so that they can authenticate each other. In addition to its IP address, a wireless access point can identify itself by an NAS (Network Access Server) identifier. Each IEEE 802.1x-capable wireless access point must have a unique NAS identifier.  Fig. 45. IEEE 802.1x/RADIUS settings. TIP: Refer to the IEEE 802.1x-related white papers on the companion CD-ROM for more information
  33 about deploying secure WLANs with IEEE 802.1x support. 3.6. Configuring Advanced Settings 3.6.1. Packet Filters The AP provides layer 2 (Ethernet Type Filters), layer 3 (IP Protocol Filters), and layer 4 (TCP/UDP Port Filters) filtering capabilities. The configuration processes for the filters are similar. Functionality: whether this filtering capability is enabled or disabled. Policy for matched packets: how a matched packet is processed—discard or pass. To enable a filtering rule: select the check box to the left of the rule. 3.6.1.1. Ethernet Type Filters  Fig. 46. Ethernet type filters settings. The Ethernet type filed of the MAC (Media Access Control) header of a packet incoming from the WLAN or Ethernet interface is inspected for filtering. In a rule, specify the hex-decimal Ethernet type number and give the rule a name. 3.6.1.2. IP Protocol Filters  Fig. 47. IP protocol filters settings.
  34 The protocol, source address, and destination address fields of a packet incoming from the WLAN or Ethernet interface is inspected for filtering. In a rule, specify the hex-decimal protocol number, source IP address range (Source IP Address AND Source  Subnet Mask), and destination IP address range (Destination IP Address AND Destination Subnet Mask). A source (destination) IP address range is determined by performing an AND operation on the source (destination) IP address  field and the source (destination)  subnet mask field. For example, if the source IP address field is 192.168.0.1 and the source subnet mask field is 255.255.255.0, the resultant source IP address range is 192.168.0.0 to 192.168.0.255. 3.6.1.3. TCP/UDP Port Filters  Fig. 48. TCP/UDP port filters settings. The destination port field the TCP or UDP header of a packet incoming from the WLAN or Ethernet interface is inspected for filtering. In a rule, specify the decimal  Destination Port,  Protocol type (TCP/UDP), and the name of the higher-level protocol (Application Name). 3.6.2. Management 3.6.2.1. UPnP  Fig. 49. UPnP settings. UPnP (Universal Plug and Play) enables a Windows XP user to automatically discover peripheral devices by HTTP. When the UPnP functionality is enabled, you can see the AP in My Network Places of Windows XP. The AP can be given a friend name that will be shown in My Network Places. Double-clicking the icon in My Network Places that stands for the AP will  launch the default Web browser for you to configure the AP.
  35 3.6.2.2. System Log  Fig. 50. System log settings. System events  can be logged  to the on-board RAM of the AP (Local log) or sent to a remote computer on which an SNMP trap monitor program runs (Remote log by SNMP trap). See the next subsection for more information about SNMP trap settings. The system events are divided into the following categories: n General: system and network connectivity status changes. n Built-in AP: wireless client association and WEP authentication status changes. n MIB II traps :  Cold Start,  Warm Start,  Link Up,  Link Down and  SNMP Authentication Failure. n RADIUS user authentication: RADIUS user authentication status changes. NOTE: The SNMP Authentication Failure trap is issued when using an incorrect community string to manage the AP via SNMP and the SNMP MIB II OID, snmpEnableAuthenTraps , is enabled (disabled by default). 3.6.2.3. SNMP  Fig. 51. SNMP settings. The SNMP (Simple Network Management Protocol) functionality can be disabled, and you can specify the name (used as a password) of the read-only and read-write community. In addition, up to 5 SNMP trap targets can be set in the SNMP Trap Table. To specify a trap target:
  36 1. Type the IP address of the target host. 2. Type the Community for the host. 3. Select the corresponding check box next to the IP address text box.
  37 Appendix A: Default Settings TIP: Press the Default (SF-Reset, or Soft-Reset) switch on the housing of a powered-on AP to reset the configuration settings to factory-default values. Setting Name Default Value Global   User Name root  Password root IEEE 802.11b   Regulatory Domain FCC (U.S.)  Channel Number 11  SSID wireless  SSID Broadcasts Enabled  Transmission Rate Auto  Transmit Power High  MAC Address See the label on the accompanying PCMCIA card or the label on the housing of the AP.  Security Mode Open System  Selected WEP Key Key #1  WEP Key #1 00-00-00-00-00  WEP Key #2 00-00-00-00-00  WEP Key #3 00-00-00-00-00  WEP Key #4 00-00-00-00-00  MAC-Address-Based Access Control Disabled  Access Control Table Type Inclusive  Wireless Client Isolation Disabled  AP Load balancing Disabled  Link Integrity Disabled  Association Control      Max Number of Clients 64  Block Clients if Traffic Load Exceeds Disabled LAN Interface   Method of obtaining an IP Address Set manually  IP Address 192.168.0.1  Subnet Mask 255.255.255.0  Default Gateway 0.0.0.0  DHCP Server Disabled Management   UPnP Enabled  System Log Local Log  SNMP Enabled  SNMP read community public  SNMP write community private  Telnet Enabled
  38 Appendix B: Troubleshooting Check the following first: l Make sure that the power of the AP is on and the Ethernet cables are connected firmly to the RJ-45 jacks of the AP. l Make sure that the LED ALV of the AP is blinking to indicate the AP is working. l Make sure the types of the Ethernet cables are correct. Recall that there are two types—normal and crossover. B-1: Wireless Settings Problems l The wireless client computer cannot associate with an AP. n Is the wireless client set in infrastructure mode? u Check the operating mode of the WLAN NIC. n Is the SSID of the WLAN NIC identical to that of the prospective AP? u Check the SSID setting of the WLAN NIC and of the AP. n Is the WEP functionality of the prospective AP enabled? u Make appropriate WEP settings of the client computer to match those of the AP. n Is the prospective AP within range of wireless communication? u Check the signal strength and link quality sensed by the WLAN NIC.
  39 B-2: TCP/IP Settings Problems  Default Gateway of Client Computer AP IEEE 802.11b Stage A State B Correspondent Host Stage D Client Computer DNS Server of Client Computer    Ethernet LAN  Internet  Fig. 52. Communication stages for a client to reach its correspondent host. For a wireless client computer to communicate with a correspondent host on the Internet by the host’s domain name (e.g. http://www.wi-fi.com), it first sends a DNS request to a DNS server on the Internet. The DNS request travels first to the AP, then the AP relays this request to the default gateway of the client computer. Finally, this request is forwarded by the gateway to the DNS server on the Internet. The DNS reply issued by the DNS server is transmitted back to the client computer following a reverse path. When the client computer receives the DNS reply, it knows the IP address  of the correspondent host and sends further packets to this IP address. As illustrated in Fig.  52, the communication path could be broken at some of the stages. The OS-provided network diagnostic tool, ping.exe, can be employed to find out TCP/IP-related communication problems. NOTE: If two or more NICs are installed and operating on a client computer, TCP/IP may not work properly due to incorrect entries in the routing table. Use the OS-provided command-line network tool,  route.exe, to add or delete entries from the routing table. Or, use Windows-provided Device Manager to disable unnecessary NICs. Solve the following problems in order: l The AP does not respond to ping from the client computer. n Are two or more NICs installed on the client computer? u Use the OS-provided command-line network tool, route.exe, to modify the contents of the routing table. u Use Windows-provided Device Manager to disable unnecessary NICs. n Is the underlying link (Ethernet or IEEE 802.11b) established?
  40 u Make sure the Ethernet link is OK. u Make sure the wireless settings of the wireless client computer and of the AP match. n Are the IP address of the  client computer and the IP address of the AP in the same IP subnet? u Use  WinIPCfg.exe or IPConfig.exe to see the current IP address of the client computer. Make sure the IP address of the client computer and the IP address of the AP are in the same IP subnet. u TIP: If you forget the current IP address of the AP, use Wireless Router/AP Browser to get the information (see Appendix B-3). l The default gateway of the client computer does not respond to ping from the client computer. n Solve the preceding problem first. n Are the IP address of the  AP and the IP address of the client computer in the same IP subnet? n If you cannot find any incorrect settings of the AP, the default gateway may be really down or there are other communication problems on the network backbone. l The DNS server(s) of the client computer do not respond to ping from the client computer. n Solve the preceding problems first. n If you cannot find any incorrect settings of the AP, the default gateway of the AP may be really down or there are other communication problems on the network backbone. B-3: Unknown Problems l The AP has been set to obtain an IP address automatically by DHCP. How can I know its acquired IP address so that I can manage it using a Web browser? n Use the utility, Wireless Router/AP Browser (WLBrwsr.exe), in the “Utilities” folder on the companion CD-ROM disc. This utility can discover nearby APs and show their MAC addresses and IP addresses. In addition, it can launch the default Web browser on your computer.
  41  Fig. 53. Wireless Router/AP Browser. l The AP stops working and does not respond to Web management requests. n The firmware of the AP may be stuck in an incorrect state. u Unplug the power connector from the power jack, and then re-plug the connector to restart the AP. u Contact our technical support representatives to report this problem, so that the bugs can be static in future firmware versions. n If the AP still does not work after restarting, there may be hardware component failures in the AP. u Contact our technical support representatives for repair.
  42 Appendix C: Additional Information C-1: Firmware Upgrade Using Xmodem Upgrade  Fig. 54. Xmodem Upgrade. To upgrade the firmware of AP using Xmodem Upgrade over RS232: 1. Power off the AP whose firmware will be upgraded. 2. Connect the managing PC and the AP with an RS232 Null Modem cable. 3. Select the serial port (COM1 or COM2) you use for connecting the device from the Serial port drop-down list and click Connect. 4. Chose the folder in which the firmware files reside by click Browse. 5. Power on the AP and you'll see bootup information. 6. Click Start to begin upgrade the firmware of the AP. 7. You will be prompted when the upgrade process completes. Click Erase Config to reset the configuration settings of the AP to default values.
  43 C-2: Distances and Data Rates Important Notice: Maximum distances posted below are actual tested distance thresholds. However, there are many variables such as barrier composition and construction and local environmental interference that may impact your actual distances and cause you to experience distance thresholds far lower than those we post below.  IEEE 802.11b Maximum Distance Table Environmental Condition Speed and Distance Ranges  11 Mbps 5.5 Mbps 2 Mbps 1 Mbps Open Environment: A "line-of-sight" environment with no interference or obstructions between Access Point and Users. 160 m (524 ft) 270 m (886 ft) 400 m (1312 ft) 457 m (1500 ft) Semi-Open Environment: An environment with no major obstructions such as walls or privacy cubicles between Access Point and users. 50 m (164 ft) 70 m (230 ft) 90 m (295 ft) 120 m (394 ft) Closed Environment: A typical office or home environment with floor to ceiling obstructions between Access Point and users. 25 m (82 ft) 35 m (115 ft) 45 m (148 ft) 55 m (180 ft)

Navigation menu