search.noResults

search.searching

note.createNoteMessage

search.noResults

search.searching

orderForm.title

orderForm.productCode
orderForm.description
orderForm.quantity
orderForm.itemPrice
orderForm.price
orderForm.totalPrice
orderForm.deliveryDetails.billingAddress
orderForm.deliveryDetails.deliveryAddress
orderForm.noItems
@fibresystemsmag | www.fibre-systems.com


FOCUS TECHNOLOGY


Facebook launches Voyager, the first white box transponder


By Pauline Rigby I


t’s optical networking hardware, Jim, but not as we know it: Facebook has unveiled Voyager, which it describes as the industry’s first white-box transponder and IP/MPLS


routing solution. Te announcement was made at the first ever summit of the Telecom Infra Project (TIP) at Facebook’s headquarters at Menlo Park, California, in November. With TIP, Facebook plans to apply the open


source ideas that have been so successful in its Open Compute Project for servers, in the networking space. Te principles are the same: by separating hardware from soſtware, it will allow innovation to get to market much faster. Voyager is the first product to be released


from TIP’s Open Optical Packet Transport project group, which was only initiated six months’ earlier – testament to Facebook’s assertion that this approach will speed up innovation. Writing on the Facebook engineering blog,


Ilya Lyubomirsky, Brian Taylor, and Hans- Juergen Schmidtke from Facebook’s engineering team explained why optical transmission needs a makeover. ‘By unbundling the hardware and soſtware in existing “black box” systems, which include transponders, filters, line systems, and control and management soſtware, we can advance each component independently and deliver even more bandwidth with greater cost efficiency,’ they explained. To this end, Voyager is a one-rack-unit


(1RU) transponder device that features 12 x 100Gb/s QSFP28 client ports and 4 x 200Gb/s capacity on the line side. Te box takes in client data signals such as 100 Gigabit Ethernet from switches or routers, and packages these signals into the proper signalling format for metro or long-haul transmission. ‘We believe that Voyager is powerful enough to support metro and long-haul data centre interconnect applications,’ Facebook said. Laboratory measurements using early


Voyager units configured for 200G per wavelength using 16QAM modulation delivered a maximum transmission distance of 180km. Te coherent modem also supports


adaptable FEC strength, and flexible modulation (QPSK/8QAM/16QAM) for optimising capacity vs. reach trade-offs. Te coherent transmission hardware, which


includes digital signal processing (DSP) ASICs and complex optoelectronic components, typically accounts for much of the cost of such a transponder system, and thus is a prime target for cost reduction. Tese components are a maturing technology, with recent advancements in integrating functions that drive down the power, size and cost, Facebook noted. Voyager uses the DSP ASIC and optics


module (AC400) from Acacia Communications with their open development environment. ‘Te soſtware that runs the transponder is traditionally bundled with the hardware, and innovation happens only at the system level. By opening up the transponder, Voyager will enable greater innovation at the component level,’ the blog said. On the soſtware side, Voyager is designed


with an open line system comprising Yang soſtware data models of each component in the system, and an open northbound soſtware


By separating hardware from software, it will allow innovation to get to market much faster


interface (NETCONF, Triſt, etc.) to the control plane soſtware. Tis allows multiple applications to run on top of the open soſtware layer, through which operators can create DWDM system control algorithms and network management systems to suit their own requirements. Other contributors to Voyager include


Broadcom, whose Tomahawk switch ASIC (the same switch ASIC found in Wedge 100, Facebook’s top-of-rack switch) is used to aggregate 100 Gigabit Ethernet client signals. Facebook also worked with Lumentum to develop a terminal amplifier specification, with Celestica on the supply chain, and with


Facebook Voyager


Snaproute on the network element soſtware stack. Facebook has already successfully tested


Voyager in field trials with Equinix in the US and MTN in South Africa. Preliminary results showed zero packet loss and significant overall cost savings due to this disaggregated hardware and soſtware networking model, Equinix reported. Optical networking equipment vendors


ADVA Optical Networking and Coriant have also pledged their support. ADVA will sell Voyager boxes along with supporting network management soſtware and services, to provide customers with a complete solution. Coriant is expanding its networking soſtware to include support for Voyager in its Light IP architecture, which disaggregates routing functions. Now Facebook plans to contribute the


design of Voyager to TIP, and release the soſtware to open source. Tis will allow any interested party to continue the development of any aspect of the specification or create new products based upon it. TIP’s Open Optical Packet Transport project group aims to have the first soſtware control and network management systems for its open line system and transponder complete by the end of the year, according to the group charter. We can expect to hear more about this in


months to come as TIP continues to gather momentum, notably among carriers. At the summit, TIP announced that it would build the first TIP Ecosystem Acceleration Center in South Korea, co-sponsored with SK Telecom. It also welcomed 11 new members to the project, including several Tier-1 carriers: Bell Canada, du, NBN, Orange, Telia, and Telstra – bringing the total number of participants to more than 300.l


Issue 14 • Winter 2017 FIBRE SYSTEMS 17


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40