The 2700 model has a USB port that can be used with a 3G dongle for connectivity and/or fallback. The FireBrick 2500 does not have a USB port. By using a 3G dongle with 1 or more FTTC/ADSL lines from AAISP you'll be able to fall back to using 3G in the case of the FTTC/ADSL going down - this includes routing of your public IPv4 blocks and IPv6 blocks (IPv6 via a tunnel). -note, 4G dongles may have a problem with routing public IPs to the FireBrick as they act as a NAT device. In these cases using a L2TP tunnel will enable the IPs to be routed.
Working 3G Dongles
Dongles do vary, and drivers may need to be written to support a particular dongle. Contact us if you have one which is not working. The following dongles are known to work on a FireBrick 2700:
- Huawei E156G (Available from AAISP)
- ZOOM model 4598 (Discontinued)
- Huawei E353 (Three branding)
- Huawei E170 (BT Branding)
- Huawei E1752Cu (O2 Branding)
- ZTE MF112 (Three branding)
Working 4G Dongles
ZTE 823 (02 branding, or direct from Amazon etc work)
Unknown not yet working
- Huawei E3272 LTE Surf-Stick (Still Testing)
- Huawei E3276S-920 (Still Testing)
- Alcatel One-touch L850 (Still Testing)
- Alcatel One-Touch 800 (Does not work, seems to only support RNDIS Interface which FireBrick does not support)
Many 4G LTE dongles work by acting as an Ethernet device and perform NAT between the mobile network and the interface presented to the FireBrick. These types of dongles should work OK. If your A&A IP blocks are needed to be routed to the FireBrick whilst on 4G then using L2TP would be a way to achieve this. We'll be expanding this section with more details and information as we test further dongles.
A Note on Bonding 3G and 4G LTE SIMs
Multiple USB Dongles can used via a USB hub - however, the benefits of bonding multiple 3G are small, as you'll typically be contending with yourself and so there will be little or no added bandwidth. Using multiple dongles with SIMs from different providers may provide extra resilience in the case of one having a problem.
If you have an AAISP data SIM, the FireBrick can be configured to use this as a backup connection, by using a 3G dongle plugged into the USB port. Any routed legacy IPv4 blocks will continue to work across this link, but so far IPv6 isn't supported (without using a tunnel). The example below is all you need to get the dongle configured. If your main broadband connection goes down, the FireBrick will automatically switch to use the 3G connection, then back again once your main connection is back.
<usb> <dongle username="email@example.com" password="secret"/> </usb>
Tunneled IPv6 Fallback
If using AAISP, then the options for IPv6 routing on the Control Pages allow an IPv6 block to be routed to a tunnel endpoint if the main routing (i.e. ADSL/FTTC) goes down. This means IPv6 can be routed to the 3G dongle if the main broadband(s) go down. The MTU will be limited though. For more configuration options see FireBrick 2700 Configuration.
LAN Interface for IPv6 tunnel over 3G dongle (with MTU 1500):
<interface name="LAN" port="LAN" ra-client="false"> <subnet ip="2001:8b0::1/64 10.0.0.1/24" ra="true" ra-mtu="1480" ra-dns="2001:8b0::2020 2001:8b0::2021"/> </interface>
LAN Interface for IPv6 tunnel over 3G dongle (with MTU 1492):
<interface name="LAN" port="LAN" ra-client="false"> <subnet ip="2001:8b0::1/64 10.0.0.1/24" ra="true" ra-mtu="1472" ra-dns="2001:8b0::2020 2001:8b0::2021"/> </interface>
Connect to AAISP over PPPoE session (3G dongle tweaks and NAT):
<ppp name="AAISP" port="WAN" username="firstname.lastname@example.org" password="secret" nat="true" lcp-rate="1" lcp-timeout="5" graph="AAISP" log="default"/>
Connect to AAISP over 3G dongle (with NAT):
<dongle name="AAISP-3G" username="email@example.com" password="secret" nat="true" graph="AAISP-3G" log="default"/>
3G dongle IPv6 default route using IPv4 tunnel:
<route ip="::/0" gateway="184.108.40.206" comment="IPv6 default route using IPv4 tunnel"/>
Turning the dongle off outside of office hours
Sometimes we don't want the dongle to be online 24x7 and want it turned off outside of office hours. This example brings the dongle online for quick fallback during office hours, and leaves it powered up but disconnected. Fallback still works outside of office hours but takes a few seconds longer to set up. Note that both <usb> and <dongle> elements can be based on profiles. Leaving <usb> active but disabling <dongle> will leave the dongle powered up but disconnected. Disabling <usb> will physically turn off the USB port and therefore also the dongle. Cold starts take a lot longer!
<usb> <dongle name="AAISP-3G" username="firstname.lastname@example.org" password="secret" graph="AAISP-3G" profile="AAISP-3G"/> </usb> <profile name="Office-Hours" comment="Office hours"> <time days="Mon Tue Wed Thu Fri" start="08:00:00" stop="18:00:00"/> </profile> <profile name="No-DSL" ppp="ADSL1 ADSL2" invert="true"/> <profile name="AAISP-3G" or="Office-Hours No-DSL" comment="Backup active during office hours, or if there is no DSL outside of office hours"/>
This example is taken from a site which has 2 ADSL lines - hence the No-DSL profile being based on ADSL1 and ADSL2 being up. The AAISP-3G profile is then active during office hours, but it will become active if both of the ADSL lines are down outside of office hours.
Ping test example of falling back
Here we ping an IP on the LAN, behind the FB2700, and get the ADSL router to re-sync. The ADSL went down, the 3G kicked in with only a single ping lost, then shortly after the ADSL came back on and took over the routing again.
64 bytes from 81.187.xx.xxx: icmp_req=120 ttl=57 time=17.6 ms 64 bytes from 81.187.xx.xxx: icmp_req=121 ttl=57 time=18.1 ms 64 bytes from 81.187.xx.xxx: icmp_req=122 ttl=57 time=17.0 ms 64 bytes from 81.187.xx.xxx: icmp_req=123 ttl=57 time=20.4 ms 64 bytes from 81.187.xx.xxx: icmp_req=124 ttl=57 time=17.3 ms 64 bytes from 81.187.xx.xxx: icmp_req=125 ttl=57 time=17.2 ms 64 bytes from 81.187.xx.xxx: icmp_req=126 ttl=57 time=17.3 ms From 220.127.116.11 icmp_seq=132 Time to live exceeded 64 bytes from 81.187.xx.xxx: icmp_req=133 ttl=57 time=792 ms <- Now on 3G 64 bytes from 81.187.xx.xxx: icmp_req=134 ttl=57 time=291 ms 64 bytes from 81.187.xx.xxx: icmp_req=135 ttl=57 time=451 ms 64 bytes from 81.187.xx.xxx: icmp_req=136 ttl=57 time=426 ms 64 bytes from 81.187.xx.xxx: icmp_req=137 ttl=57 time=338 ms Some successful pings omitted as it took a while to sync again. 64 bytes from 81.187.xx.xxx: icmp_req=180 ttl=57 time=176 ms 64 bytes from 81.187.xx.xxx: icmp_req=181 ttl=57 time=276 ms 64 bytes from 81.187.xx.xxx: icmp_req=182 ttl=57 time=216 ms 64 bytes from 81.187.xx.xxx: icmp_req=183 ttl=57 time=174 ms 64 bytes from 81.187.xx.xxx: icmp_req=184 ttl=57 time=212 ms 64 bytes from 81.187.xx.xxx: icmp_req=187 ttl=57 time=16.3 ms <- Now back on ADSL! 64 bytes from 81.187.xx.xxx: icmp_req=188 ttl=57 time=16.5 ms 64 bytes from 81.187.xx.xxx: icmp_req=189 ttl=57 time=16.2 ms 64 bytes from 81.187.xx.xxx: icmp_req=190 ttl=57 time=16.5 ms 64 bytes from 81.187.xx.xxx: icmp_req=191 ttl=57 time=16.6 ms 64 bytes from 81.187.xx.xxx: icmp_req=192 ttl=57 time=16.0 ms 64 bytes from 81.187.xx.xxx: icmp_req=193 ttl=57 time=16.8 ms
You can tell when the swap over happened as the latency increases and then decreases again when the DSL came back online.
Reset the USB controller and re-detect everything from scratch:
Show dongle information: