100 Gbps Via Ethernet

Doc Ruby writes, "As reported at GigaOM, 'Infinera has bonded 10 parallel 10 Gb/s channels into one logical flow while maintaining packet ordering at the receiver,' bridging 100-Gbps ethernet over 10 10-Gbps optical WAN links. Infinera's press release is here. Further from GigaOM: 'The experimental system was set up between Tampa, Florida and Houston, Texas, and back again. A 100 GbE signal was spliced into ten 10 Gb/s streams using an Infinera-proposed specification for 100GbE across multiple links. The splicing of the signal is based on a packet-reordering algorithm developed at [UC] Santa Cruz. This algorithm preserves packet order even as individual flows are striped across multiple wavelengths.' We're all going to want our share of these 100Gbps networks. The current network retailers, mainly cable and DSL dealers, still haven't brought even 10Mbps to most homes, though they're now bringing fiber to the premises to some rich/lucky customers. Are they laying fiber that will bring them to Tbps, or will that stuff clog the way to getting these speeds ourselves?" Rumors say that what runs over Verizon's FiOS is ATM, to support their aspirations for triple-play.

Why stop there?

[tringstad]

'Infinera has bonded 10 parallel 10 Gb/s channels into one logical flow while maintaining packet ordering at the receiver,' bridging 100-Gbps ethernet over 10 10-Gbps optical WAN links.

So what's preventing them from taking 10 of these newly created 100GbE channels, applying the same technique, and producing 1TbE?

-Tommy

Re:Fiber's still the wave of the future

[iWill]

This (Infinera) is the company that makes complete wavelength-division multiplexed optical systems on a chip. They have demonstrated 40 Gbps x 40 channels = 1.6Tbps in development and currently have many 10 Gbps x 10 channel networks deployed by companies such as Level 3 (which first came online in 2004.) Also, the limiting factor in single optical channel transmission is not the transistors at each end. The real problem is the laser modulation at the transmitter as well as the response of the photdetector at the receiver. GaAs or InP transistor circuits at either end are more than capable of handling speeds in excess of 40Gbps if the laser generation/detection ever gets there.