FSAN close to choosing the next generation of PON
Briefing: Next-gen PON
Part 1: NG-PON2
The next-generation passive optical network (PON) will mark a departure from existing PON technologies. Some operators want systems based on the emerging standard for deployment by 2015.
“One of the goals in FSAN is to converge on one solution that can serve all the markets"
Derek Nesset, co-chair of FSAN's NGPON task group
The Full Service Access Network (FSAN) industry group is close to finalising the next optical access technology that will follow on from 10 Gigabit GPON.
FSAN - the pre-standards forum consisting of telecommunications service providers, testing labs and equipment manufacturers - crafted what became the International Telecommunication Union's (ITU) standards for GPON (Gigabit PON) and 10 Gigabit GPON (XGPON1). In the past year FSAN has been working on NG-PON2, the PON technology that comes next.
“One of the goals in FSAN is to converge on one solution that can serve all the markets - residential users, enterprise and mobile backhaul," says Derek Nesset, co-chair of FSAN's NGPON task group.
Some mobile operators are talking about backhaul demands that will require multiple 10 Gigabit-per-second (Gbps) links to carry the common public radio interface (CPRI), for example. The key design goal, however, is that NG-PON2 retains the capability to serve residential users cost-effectively, stresses Nesset.
FSAN says it has a good description of each of the candidate technologies: what each system looks like and its associated power consumption. "We are trying to narrow down the solutions and the ideal is to get down to one,” says Nesset.
The power consumption of the proposed access scheme is of key interest for many operators, he says. Another consideration is the risk associated with moving to a novel architecture rather than adopting an approach that builds on existing PON schemes.
Operators such as NTT of Japan and Verizon in the USA have a huge installed base of PON and want to avoid having to amend their infrastructure for any next-generation PON scheme unable to re-use power splitters. Other operators such as former European incumbents are in the early phases of their rollout of PON and have Greenfield sites that could deploy other passive infrastructure technologies such as arrayed waveguide gratings (AWG).
"The ideal is we select a system that operates with both types of infrastructure," says Nesset. "Certain flavours of WDM-PON (wavelength division multiplexing PON) don't need the wavelength splitting device at the splitter node; some form of wavelength-tuning can be installed at the customer premises." That said, the power loss of existing optical splitters is higher than AWGs which impacts PON reach – one of several trade-offs that need to be considered.
Once FSAN has concluded its studies, member companies will generate 'contributions' for the ITU, intended for standardisation. The ITU has started work on defining high-level requirements for NG-PON2 through contributions from FSAN operators. Once the NG-PON2 technology is chosen, more contributions that describe the physical layer, the media access controller and the customer premise equipment's management requirements will follow.
Nesset says the target is to get such documents into the ITU by September 2012 but achieving wide consensus is the priority rather than meeting this deadline. "Once we select something in FSAN, we expect to see the industry ramp up its contributions based on that selected technology to the ITU," says Nesset. FSAN will select the NG-PON2 technology before September.
NG-PON2 technologies
Candidate technologies include an extension to the existing GPON and XGPON1 based on time-division multiplexing (TDM). Already vendors such as Huawei have demonstrated prototype 40 Gigabit capacity PON systems that also support hybrid TDM and WDM-PON (TWDM-PON). Other schemes include WDM-PON, ultra-dense WDM-PON and orthogonal frequency division multiplexing (OFDM).
Nesset says there are several OFDM variants being proposed. He views OFDM as 'DSL in the optical domain’: sub-carriers finely spaced in the frequency domain, each carrying low-bit-rate signals.
One advantage of OFDM technology, says Nesset, includes taking a narrowband component to achieve a broadband signal: a narrowband 10Gbps transmitter and receiver can achieve 40Gbps using sub-carriers, each carrying quadrature amplitude modulation (QAM). "All the clever work is done in CMOS - the digital signal processing and the analogue-to-digital conversion," he says. The DSP executes the fast Fourier transform (FFT) and the inverse FFT.
"We are trying to narrow down the solutions and the ideal is to get down to one"
Another technology candidate is WDM-PON including an ultra-dense variant that promises a reach of up to 100km and 1,000 wavelengths. Such a technology uses a coherent receiver to tune to the finely spaced wavelengths.
In addition to being compatible with existing infrastructure, another FSAN consideration is compatibility with existing PON standards. This is to avoid having to do a wholesale upgrade of users. For example, with XGPON1, the optical line terminal (OLT) using an additional pair of wavelengths - a wavelength overlay - sits alongside the existing GPON OLT. ”The same principle is desirable for NG-PON2,” says Nesset.
However, an issue is that spectrum is being gobbled up with each generation of PON. PON systems have been designed to be low cost and the transmit lasers used are not wavelength-locked and drift with ambient temperature. As such they consume spectrum similar to coarse WDM wavelength bands. Some operators such as Verizon and NTT also have a large installed base of analogue video overlay at 1550nm.
”So in the 1500 band you've got 1490nm for GPON, 1550nm for RF (radio frequency) video, and 1577nm for XGPON; there are only a few small gaps,” says Nesset. A technology that can exploit such gaps is both desirable and a challenge. “This is where ultra-dense WDM-PON could come into play,” he says. This technology could fit tens of channels in the small remaining spectrum gaps.
The technological challenges implementing advanced WDM-PON systems that will likely require photonic integration is also a concern for the operators. "The message from the vendors is that ’when you tell us what to do, we have got the technology to do it’,” says Nesset. ”But they need the see the volume applications to justify the investment.” However, operators need to weigh up the technological risks in developing these new technologies and the potential for not realising the expected cost reductions.
Timetable
Nesset points out that each generation of PON has built on previous generations: GPON built on BPON and XGPON on GPON. But NG-PON2 will inevitably be based on new approaches. These include TWDM-PON which is an evolution of XG-PON into the wavelength domain, virtual point-to-point approaches such as WDM-PON that may also use an AWG, and the use of digital signal processing with OFDM or coherent ultra dense WDM-PON. ”It is quite a challenge to weigh up such diverse technological approaches,” says Nesset.
If all goes smoothly it will take two ITU plenary meetings, held every nine months, to finalise the bulk of the NG-PON2 standard. That could mean mid-2013 at the earliest.
FSAN's timetable is based on operators wanting systems deployable in 2015. That requires systems to be ready for testing in 2014.
“[Once deployed] we want NG-PON2 to last quite a while and be scalable and flexible enough to meet future applications and markets as they emerge,” says Nesset.
Challenges, progress & uncertainties facing the optical component industry
In recent years the industry has moved from direct detection to coherent transmission and has alighted on a flexible ROADM architecture. The result is a new level in optical networking sophistication. OFC/NFOEC 2012 will showcase the progress in these and other areas of industry consensus as well as shining a spotlight on issues less clear.
Optical component players may be forgiven for the odd envious glance towards the semiconductor industry and its well-defined industry dynamics.
The semiconductor industry has Moore’s Law that drives technological progress and the economics of chip-making. It also experiences semiconductor cycles - regular industry corrections caused by overcapacity and excess inventory. The semiconductor industry certainly has its challenges but it is well drilled in what to expect.
Optical challenges
The optical industry experienced its own version of a semiconductor cycle in 2010-11 - strong growth in 2010 followed by a correction in 2011. But such market dynamics are irregular and optical has no Moore's Law.
Optical players must therefore work harder to develop components to meet the rapid traffic growth while achieving cost efficiencies, denser designs and power savings.
Such efficiencies are even more important as the marketplace becomes more complex due to changes in the industry layers above components. The added applications layer above networks was highlighted in the OFC/NFOEC 2012 news analysis by Ovum’s Karen Liu. The analyst also pointed out that operators’ revenues and capex growth rates are set to halve in the years till 2017 compared to 2006-2010.
Such is the challenging backdrop facing optical component players.
Consensus
Coherent has become the defacto standard for long-haul high-speed transmission. Optical system vendors have largely launched their 100Gbps systems and have set their design engineers on the next challenge: addressing designs for line rates beyond 100Gbps.
Infinera detailed its 500Gbps super-channel photonic integrated circuit last year. At OFC/NFOEC it will be interesting to learn how other equipment makers are tackling such designs and what activity and requests optical component vendors are seeing regarding the next line rates after 100Gbps.
Meanwhile new chip designs for transport and switching at 100Gbps are expected at the show. AppliedMicro is sampling its gearbox chip that supports 100 Gigabit Ethernet and OTU4 optical interfaces. More announcements should be expected regarding merchant 100Gbps digital signal processing ASIC designs.
An architectural consensus for wavelength-selective switches (WSSes) - the key building block of ROADMs - are taking shape with the industry consolidating on a route-and-select architecture, according to analysts.
Gridless - the ROADM attribute that supports differing spectral widths expected for line rates above 100Gbps - is a key characteristic that WSSes must support, resulting in more vendors announcing liquid crystal on silicon designs.
Client-side 40 and 100 Gigabit Ethernet (GbE) interfaces have a clearer module roadmap than line-side transmission. After the CFP comes the CFP2 and CFP4 which promise denser interfaces and Terabit capacity blades. Module form factors such as the QSFP+ at 40GbE and in time 100GbE CFP4s require integrated photonic designs. This is a development to watch for at the show.
Others areas to note include tunable-laser XFPs and even tunable SFP+, work on which has already been announced by JDS Uniphase.
Lastly, short-link interfaces and in particular optical engines is another important segment that ultimately promises new system designs and the market opportunity that will unleash silicon photonics.
Optical engines can simplify high-speed backplane designs and printed circuit board electronics. Electrical interfaces moving to 25Gbps is seen as the threshold trigger when switch makers decide whether to move their next designs to an optical backplane.
The Optical Internetworking Forum will have a Physical and Link Layer (PLL) demonstration to showcase interoperability of the Forum’s Common Electrical Interface (CEI) 28Gbps Very Short Reach (VSR) chip-to-module electrical interfaces, as well as a demonstration of the CEI-25G-LR backplane interface.
Companies participating in the interop include Altera, Amphenol, Fujitsu Optical Components, Gennum, IBM, Inphi, Luxtera, Molex, TE Connectivity and Xilinx.
Altera has already unveiled a FGPA prototype that co-packages 12x10Gbps transmitter and receiver optical engines alongside its FPGA.
Uncertainties
OFC/NFOEC 2012 also provides an opportunity to assess progress in sectors and technology where there is less clarity. Two sectors of note are next-generation PON and the 100Gbps direct-detect market.
For next-generation PON, several ideas are being pursued, faster extensions of existing PON schemes such as a 40Gbps version of the existing time devision multiplexing PON schemes, 40G PON based on hybrid WDM and TDM schemes, WDM-PON and even ultra dense WDM-PON and OFDM-based PON schemes.
The upcoming show will not answer what the likely schemes will be but will provide an opportunity to test what the latest thinking is.
The same applies for 100 Gigabit direct detection.
There are significant cost advantages to this approach and there is an opportunity for the technology in the metro and for data centre connectivity. But so far announcements have been limited and operators are still to fully assess the technology. Further announcements at OFC/NFOEC will highlight the progress being made here.
The article has been written as a news analysis published by the organisers before this year's OFC/NFOEC event.