Alcatel-Lucent adds networking to enhance the cloud
Alcatel-Lucent has developed an architecture that addresses the networking aspects of cloud computing. Dubbed CloudBand, the system will enable operators to deliver network-enhanced cloud services to enterprise customers. Operators can also use CloudBand to deliver their own telecom services.
“As far as we know there is no other system that bridges the gap between the network and the cloud"
Dor Skuler, Alcatel-Lucent
Alcatel-Lucent estimates that moving an operator's services to the cloud will reduce networking costs by 10% while speeding up new service introductions.
“As far as we know there is no other system that bridges the gap between the network and the cloud," says Dor Skuler, vice president of cloud solutions at Alcatel-Lucent.
In an Alcatel-Lucent survey of 3,500 IT decision makers, the biggest issue stopping their adoption of cloud computing was performance. Their issues of concern include service level agreements, customer experience, and ensuring low latency and guaranteed bandwidth.
Using CloudBand, a customer uses a portal to set such cloud parameters as the virtual machine to be used, the hypervisor and the operating system. Users can also set networking parameters such as latency, jitter, guaranteed bandwidth and whether a layer two or layer three VPN is used, for example. The user can even define where data is stored if regulation dictates that the data must reside within the country of origin.
Architecture
CloudBand uses an optimisation algorithm developed at Alcatel-Lucent's Bell Labs. The algorithm takes the requested cloud and networking settings and, knowing the underlying topology, works out the best configuration.
“This is a complex equation to optimise,” says Skuler. “All these resources - all different and in different locations - need to be optimised; the network needs to be optimised, I also have the requirements of the applications and I want to optimise it on price.” Moreover, these parameters change over time.
"We recommend service providers have tiny clouds that look like one logical cloud yet have different attributes"
According to Alcatel-Lucent, operators have an advantage over traditional cloud service providers in owning and being able to optimise their networks for cloud. Operators also have lots of locations - central offices and exchanges - distributed across the network where they can site cloud nodes.
Having such distributed IT resources benefits the end user by having more localised resources even though it makes the optimisation task of the CloudBand algorithm more complicated. “We recommend service providers have tiny clouds that look like one logical cloud yet have different attributes,” says Skuler.
At the heart of the architecture is the management and orchestration system (See diagram). The system takes the output of the optimisation algorithm, and provisions the cloud resources - moving the virtual machine to a particular site, turning it on, assuring its performance, checking the service level agreement and creating the required billing record.
Once assigned a service is fixed, but in future CloudBand will adapt existing services as new services are set up to ensure continual cloud optimisation.
Benefits
"Not every [telecom] service can be virtualised but overall we believe we can shave 10% out of the cost of the network,” says Skuler.
Alcatel-Lucent has already implemented its application store software, content management applications and digital media for use in the cloud. Skuler says video, IP Multimedia Subsystem (IMS) and the applications that run on the IMS architecture can also be moved to the cloud, while Alcatel-Lucent's lightRadio wireless architecture, announced earlier this year, can pool and virtualise cellular base station resources.
But Skuler says that the real benefit for operators moving services to the cloud is agility: operators will be able to introduce new cloud-based services in days rather than months. This will reduce time-to-revenue and costs while allowing operators to experiment with new services.
CloudBand will be ready for trialling in operators’ labs come January. The system will be available commercially in the first half of 2012.
DSL: Will phantom channels become real deployments?
Alcatel-Lucent is promoting its DSL Phantom Mode technology as a complement to fibre-to-the-x (FTTx) technology. Operators can use the technology to continue to extend services offerings to existing DSL subscribers as they roll out FTTx over the next decade or more.
But one analyst believes the technology could take years to commercialise and questions whether the announcement is not sending a wrong message to the industry by providing an alternative to fibre.
“The investment required to upgrade DSL is quite small”
Stefaan Vanhastel, Alcatel-Lucent
What has been achieved?
The 300Mbps data rate is achieved using two copper wire pairs between the access equipment and a DSL modem although three DSL ports are required at each end. The rate drops to 100Mbps when the reach is extended to 1km. In comparison very high speed Digital Subscriber Line 2’s (VDSL2) data rate over a single line ranges from 20 to 40Mbps over 1km.
None of the three techniques that Alcatel-Lucent uses – bonding, vectoring and the phantom mode that creates an extra virtual channel alongside the two bonded pairs - is new. What the company claims is that it is the first to combine all three for DSL.
In March Ericsson announced it had achieved 500Mbps over 500m but it used six bonded pairs and vectoring only.
Why is the Phantom Mode important?
The significance of the announcement, according to Alcatel-Lucent, is that operators can continue to offer existing DSL customers new bandwidth-intensive services as they roll out FTTx.
“Rolling out FTTx will take a significant amount of time,” says Stefaan Vanhastel, director of product marketing, wireline networks at Alcatel-Lucent. “Operators are looking to reuse their copper infrastructure in the short-to-medium term - the next 5 to 10 years.”
An operator must have a central office or cabinet equipment 1km or less from the user’s residence as well as having two wire pairs per building or residence. “In many countries two pairs are available,” says Vanhastel.
However, one analyst questions the development and promotion of such copper-enhancing technology.
“I think Alcatel is being disingenuous when they say "fiber will take long to implement, this is an intermediary solution’,” says the analyst, who asked not to be named. “They know full well that customers would see this as a way to hold back on deploying fibre.
“Ultimately to me this is schizophrenia at work. Alcatel-Lucent wants to be all things to all service providers and may be sending the wrong message to the market that they need not invest to sustain the bandwidth demand growth, which is suicidal both for service providers and for Alcatel-Lucent in the long run.”
Alcatel-Lucent does believe operators will invest in DSL alongside FTTx.
“The investment required to upgrade DSL is quite small,” says Vanhastel. “Even with two ports it is a bargain; you get the investment back in one or two months.”
Even operators more advanced in their FTTx deployments will want to offer new higher bandwidth services such as high-definition TV to all their customers.
“What are you going to do? Offer your services to just 50% of your customers?” says Vanhastel “They [the remaining customers] will go elsewhere.”
Method used
The Bell Labs research arm of Alcatel-Lucent has used three techniques to enhance DSL’s speed and reach performance.
- Bonding: The combination of copper line pairs to boost the number of channels – in this case two are bonded - and hence the data rate between access equipment and the DSL modem.
- Vectoring: Noise cancellation techniques using digital signal processing to improve the overall signal-to-noise performance. “It involves measuring the noise on all the lines and generating anti-phase – the inverse signal – such that the two cancel out,” says Vanhastel.
- Phantom mode: The phantom mode technology uses two physical wires to create a third virtual one. The technology was first proposed in the 1880s as a way to add an extra virtual telephone line.
Two physical pairs and the third phantom one. Source: Alcatel-Lucent
Using the phantom mode, only two wire pairs are needed to connect the end equipment. The information on the third “virtual” line is shared over the two physical channels. Using analogue electronics, the data on the third channel is processed and recovered. “We add and subtract through the use of a bunch of transformers,” says Vanhastel. Where the circuitry is placed, whether in the DSLAM access equipment or elsewhere, is to be decided.
To create the virtual wire, a modem supporting three-pair bonding is required. In addition the chipset in the DSL modem must have sufficient processing performance to execute vectoring on three channels. That's because adding the phantom mode degrades the performance of all the channels due to crosstalk. The crosstalk is removed between the channels using vectoring.
What next?
The technology needs to be brought to market. “At the earliest it will be 2012,” says Vanhastel.
But the analyst points out that the technology is lab tested: “Between test labs and implementation, count a significant number of years.”
The concept could even be extended using more wire pairs. The relationship is (N-1) phantom channels for N wire pairs i.e. 1 virtual channel with two pairs, 2 with 3 pairs etc.
Alcatel-Lucent says it has already completed two VDSL2 bonding trials in Asia Pacific, while three operators are undertaking VDSL2 vectoring tests in their labs and will move to testing in the field using a single line this year.
“Bonding is here today, vectoring will be 2011 and the phantom mode will be after that,” says Vanhastel.
OFC/NFOEC 2010: Technical paper highlights
Here is a sample of some of the noteworthy papers.
Optical transmission
Nortel’s Next Generation Transmission Fiber for Coherent Systems details how various fibre parameters impact coherent system performance. This is important for existing 40 and 100Gbps systems and for future ones based on even higher data rates.
In 40G and 100G Deployment on 10G Infrastructure: Market Overview and Trends, Coherent Versus Conventional Technology, Alcatel-Lucent discusses 40G and 100G deployment strategies over 10G infrastructures based on a trial using live commercial traffic.
Two papers demonstrate possible future optical modulation steps.
In Ultra-High Spectral Efficiency Transmission, Bell Labs Alcatel-Lucent details the generation, transmission and coherent detection of 14-Gbaud polarization-division multiplexed, 16-ary quadrature-amplitude-modulation (16-QAM) signals achieving spectral efficiencies as high as 6.2 b/s/Hz.
Meanwhile, NEC Labs America and AT&T Labs address 112.8-Gb/s PM-RZ-64QAM Optical Signal Generation and Transmission on a 12.5GHz WDM Grid. The optical signal was sent over 2x40km using an 8-channel WDM using 12.5GHz grid spacing.
Photonic integration
In High Performance Photonic Integrated Circuits for Coherent Fiber Communication, Chris Doerr of Bell Labs, Alcatel-Lucent presents how photonic integration can benefit high-speed transmission. In particular, how optical integration can be used to tackle the complex circuitry needed for coherent systems to reduce the area, cost, and power consumption of optical coherent transceivers.
Another photonic integration development is the CMOS-Integrated Low-Noise Germanium Waveguide Avalanche Photodetector Operating at 40Gbps from IBM T.J. Watson Research Center. The avalanche photodiode has a gain-bandwidth-product above 350GHz operating at 3V. The avalanche photodetector is monolithically integrated into CMOS.
Optical access
An update will be given on the EU’s Seventh Framework programme for WDM-PON, dubbed Sardana - Scalable Advanced Ring-based passive Dense Access Network Architecture. The paper, Results from EU Project SARDANA on 10G Extended Reach WDM PONs, details the integration of WDM metro and PON access technologies to implement ring protection, 100km reach and up to 1024 users served at 10Gbps using a passive infrastructure.
In 44-Gb/s/λ Upstream OFDMA-PON Transmission with Polarization-Insensitive Source-Free ONUs, NEC Labs America details its work on colourless 44-Gb/s/λ upstream OFDMA-PON transmission using polarization-insensitive, source-free ONUs.
Green telecom and datacom
There are other, more subtle developments at OFC/NFOEC. Two papers from Japan have ‘Green’ in the title, highlighting how power consumption is increasingly a concern.
High Performance “Green” VCSELs for Data Centers from Furukawa Electric Co. Ltd details how careful design can achieve a 62% power conversion efficiency in the 1060nm VCSEL.
The second paper tackles power consumption in access networks. Key Roles of Green Technology for Access Network Systems from NTT Labs in Japan addresses the ITU-T’s standardisation activities. Optics for flow and interconnect
In Optical Flow Switching, Vincent Chan of MIT will discuss 'optical flow switching' that promises significant growth, power-efficiency and cost-effective scalability of next-generation networks.
Meanwhile Bell Labs, Lucent Technologies has a paper entitled Photonic Terabit Routers: The IRIS Project, detailing the results of the DARPA-MTO funded program to develop a router with an all-optical data plane and a total capacity of more than 100 Tbps.
Another important topic is optical interconnect. Low Power and High Density Optical Interconnects for Future Supercomputers from IBM Research reviews the status and prospects of technologies required to build low power, high density board and chip level interconnects needed to meet future supercomputers requirements.
NFOEC papers
There are also some noteworthy NFOEC papers bound to stir interest:
- Google reviews the optical communication technologies required to support data center operations and warehouse-scale computing.
- Verizon shares lessons learned during the five years of Verizon’s FiOS and the need to continually evolve product and service offerings.
- AT&T details the key decisions required in defining its new 100G backbone.
There is a comprehensive OFC/NFOEC preview in the February issue of IEEE Communications magazine, click on the "conference preview" tab.