11.2. Definining PPPoE links

A PPPoE link is defined by a ppp top-level object. To create or edit PPPoE links in the web user interface, select the "Interface" category icon - - under the section headed "PPPoE settings" you will see the list of existing ppp objects (if any), and an "Add" link.

For most situations, configuring a PPPoE link only requires that you specify the physical port number, or alternatively, a port group name (see Section 6.2), that the router/modem is connected to and the login credentials i.e. username and password. The port number or port group name is specified via the port attribute on the ppp object, and credentials are specified via the username and password attributes.

If you are connecting multiple routers/modems via a VLAN capable switch to a single FB2500 port, you will also need to specify the VLAN used for the FB2500 to router/modem layer 2 connection - this is done by setting the value of the vlan attribute too.

As an example, if you were to connect a single modem/router directly to port 4 on your FB2500 (i.e. not using VLANs), then the configuration needed, shown as an XML fragment, would be :-

  <ppp port="4" username="..." password="..."/>

You may also want to give the PPPoE link a name, by setting the name attribute - you can then reference the link in, for example, a profile (see Section 9.2.2.1).

There are a number of additional options (see below), but for most configurations this is all you need. It causes the FB2500 to connect and set a default route for internet access via the PPP link.

11.2.1. IPv6

If your ISP negotiates IPv6 on the link, then a default route is set for IPv6 traffic down the line. You just need to configure your LAN subnet to have the IPv6 block your ISP has assigned to you.

11.2.2. Additional options

11.2.2.1. MTU and TCP fix

Normally PPPoE operates with a maximum packet size of 1492 bytes - this is due to the 8 byte PPPoE header that is used, and the normal 1500 byte payload limit of an Ethernet packet. The FB2500 includes an option to set the PPPoE MTU, so that when used with equipment capable of jumbo frames (such as BT FTTC and FTTP services) this allows use of slightly larger frames to provide a 1500 byte MTU. To achieve this, simply set the mtu attribute to a value of 1500. By default the tcp-mss-fix attribute is also set, which means when working with a smaller MTU such as 1492, any connections that try and establish 1500 byte links are adjusted on the fly to be the lower MTU. This avoids problems with a lot of corporate and bank web sites that do not handle MTU and ICMP correctly. Typically your ISP will be doing this TCP fix for you as well.

Testing has been done which confirms setting mtu="1500" works correctly on BT FTTC lines.

Note

Testing using a Zyxel P660R in bridge mode confirms that BT 21CN ADSL lines will negotiate 1500 byte MTU, but it seems the Zyxel will not bridge more than 1496 bytes of PPP payload. If you select more than 1492 MTU and have problems it could be that some device connecting you to the access concentrator cannot handle the larger packets (such as a bridge or a switch). For this reason the default MTU is 1492.

11.2.2.2. Service and ac-name

The PPPoE protocol allows multiple services to be offered, and the service setting can be used to select which is available. This is rarely needed and should be ignored unless you know what you are doing. If specified, even as an empty string, then only matching services will be selected.

The name specified via the ac-name attribute is the name of the PPPoE endpoint (access controller). In some cases there may be a choice of endpoints and setting this causes one to be selected by name. Again, this is rarely needed, and if specified will only match the name you specify. On Be PPPoE lines, for example, you could select a specific LAC by name if you wanted to.

11.2.2.3. Logging

The PPP connection status, and PPP negotiation can be logged by setting the log attribute to a valid log target. This can be useful for debugging.

11.2.2.4. Speed and graphs

As discussed in Chapter 10, graphs allow you to visual connections, in terms of their state, traffic rates and patterns etc. By setting the graph attribute, you can cause the state of the line, data transferred each way, and current packet loss and latency to be recorded on a graph. This normally operates in slow mode (an LCP every 16 seconds) but by setting the slow attribute to false you can monitor a line every second. **TBC is this correct ; do we not use lcp-rate now?**

Once you are graphing the PPPoE connection, you can set traffic shaping to control speed (see Section 10.1.2). Alternatively, a PPPoE connection is something you can set a speed limit on directly - setting the speed attribute will control the speed of traffic sent to the Internet - this is mainly used when bonding PPP links.