mrv market segmentation cagr, and trends july 2014
TRANSCRIPT
TREX 2015 Workshop
Netherlands = Finland ?
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Agenda
Introduction MRV
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Digital Video distribution
WDM & Programmable Optical Networks
Cross Connect Technology
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Founded in 1988 and headquartered in Chatsworth, CA, USA
Public trading since 1992 - NASDAQ, MRVC
>400 employees worldwide
3 R&D centers in USA and Israel
>1000 global customers – Packet and Optical portfolio - Complete solution for Metro Networks
– Over $2B of field-proven installed base of optical and packet solutions
MRV overview
MRV is a global leader in converged packet and optical solutions that empowers
the optical edge for service providers & enterprises.
Compelling Market Innovative Solutions Global Customer Base
MRV DNA
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• Make the complex simple.
• Enable intelligent service delivery.
• Visualize network capability.
• Packet and optical expertise in the same company.
• Reduce number of network elements.
• Enable new services and revenue streams.
• Improve time to revenue.
TREX
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WDM &Programmable Optical Networks
Wavelength Division Multiplexing
A method for simultaneously transmitting multiple data channels over a single fiber optical link, where each data channel is transmitted using a unique wavelength (color).
Rate and Protocol independent
– Appropriate for data, voice, video, storage (fiber channel)
– Digital video optics are supported
– Up to 100 Gigabit
Physically separated data streams
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WDMWDM
ITU Wavelengths
1550 nm
ITU Wavelengths
1550 nm
WDM Optical Solutions by MRV
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Regional and National
Backbones
Meshed networks– Transport for SP/carriers
– Packet Optical Ethernet
– Automated provisioning
– Management and restoration
Optical enterprise Networks
Consolidated networks– Flexible connectivity
– Multi protocol
– Meet application requirements
– Future proof
Data and storage solutions
Interconnection datacenters– Scalable
– High performance services
– Optical protection
– Cloud infrastructures
Optical networks are not as “programmable” as packet networks
– A transponder is a transponder – a physical device that cannot be virtualized
– A wavelength is a wavelength – the dimensions and features cannot be programmed
– A fiber is a fixed physical entity
Advanced in optical layer programmability developed for service provider networks are migrating to switching networks
– Software-definable optical ports, speeds, protocols, and wavelengths
– Advanced modulation and detection schemes, especially at 100Gbps and higher
– Flexible wavelength grid
– Dynamic wavelength routing via ROADMs
Flexible Optical Networks
Flexible Ports
Flexible Wavelengths
Flexible Modulation
100Mbps – 10Gbps 10Gbps – 100Gbps 100Gbps +
Goal: Make the optical layer “virtual” to higher layers
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Tunable lasers
Rate-adaptive optics
Protocol-definable transponders
Generally, this is the most mature of the enabling technologies, so prices are already affordable
Programmable speeds, protocols and wavelengths
Center Wavelength
Signal Speed Signal Format
Ethernet Fibre Channel
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Tunable SFP+
Full C-band wavelength tunable
50Ghz spacing
Rates from 8 Gbps to 11,3 Gbps
DMR10G transponder
Full C-band wavelength tunable
50Ghz spacing
Tunable signal speed from 1 GBE to 10Gbps
Tunable signal format
– Ethernet, FibreChannel, STM, Infiniband and others
Originally developed for long-haul 100Gbps networks, this technology is being adapted to shorter reach links
– Multiple amplitude levels, multiple phases, multiple polarizations (e.g. DP-QPSK) and integrated digital signal processing
– 100Gbps customer and router-to-router links are becoming common
Evolving programmability: Tune the modulation based on the span requirements
– Integrated digital signal processing introduces programmability for the first time at Layer 0
– Tune for distance, bandwidth, spectrum, etc.
This is the least mature of the enabling technologies and full flexibility not generally available
– Moving beyond 100Gbps, which will help lower the costs at 100Gbps
Advanced modulation and detection schemes
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100 Gbps Coherent CFP
Full C-band wavelength tunable
50Ghz spacing
Programmable dispersion and reach
Real World Internet Exchange 100G Example
8x1
00
G
8x1
00
G
8x1
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G
8x1
00
G
8x100G
8x100G
Upgraded links between core sites• Initial upgrade to
4x100G• Network design to
upgrade to 8x100GUpgraded links to primary remoteDWDM used to minimize fiber costs
4-node Core Ring
4-node Core Ring
Satellite Site
Redundant Interconnect
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WDM increasingly an option within and outside the internet exchange
WDM has traditionally been a rigid, fixed technology
New, flexible wavelength grids have been developed that will allow programmability at the WDM layer
– No longer a fixed 50GHz grid
– 12.5GHz channels defined that can be combined arbitrarily
– Especially useful for higher bandwidth channels
– Essential for flexible modulation schemes
Technology already exists and is deployed
Flexible Wavelength Grid
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Once WDM is introduced, routing of optical wavelengths is essential for complete flexibility
Reconfigurable Optical Add Drop Multiplexers allow all optical wavelength re-routing
– Colorless, directionless, and contentionless (CDC) technologies
– Recently developed, but now widely deployed
Dynamic ROADMs
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OD Family
New generation technology
Remarkably flexible and smart
Various chassis types
Optimized for today’s technology and the evolution of tomorrow’s technology
Supporting rates from T1 to 100G, WDM and ROADM, and multiple service types
Intelligent and easy to deploy and operate
Incredibly power efficient
Industry leading bandwidth density
Up to 16x 100G in single chassis
Target applications include fiber optimization, datacenter interconnect, high capacity transport and carrier networks
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OD Flexibility
Flexible shelf
– Highest density for today’s 10G
– Flexible to support today’s 100G and ROADM
– Adaptable to next generation technology
Flexible transponders
The power of ONE transponder
GbE10GbE
SONET/SDHFibre ChannelDigital Video
Any rate
Any format
Any protection
Reduce complexityReduce spares
Increase capabilities
DMR10G Redundancy
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OD 100G and ROADM
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100G transponders
• CFP based transponder/converter
• CFP interfaces
• Access
• OTU4 100G (> 9.4dB)
• Transparent and OTN/FEC flavors
• PM & OTN OAM&P
• PRBS link testing
100G hybrid muxponder
• 40G and 10G hybrid muxponder
• QSFP and SFP+ access interfaces
• CFP based OTU4 100G interface
• High gain FEC > 9.4 dB
• PM & OTN OAM&P
• PRBS link testing
Flexgrid CD WSS ROADM
• Flexgrid WSS ROADM
• Colorless and directionless
• Low insertion loss
• Per wavelength power equalization
• 2 and 4-Degrees
Future of 100G
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100G moves to the metro
100G Transceivers become compact
DWDM is in CFP2 format, will be QSFP28
Optical transceivers become Control Plane programmable
Match your specific network
Programmable number of carriers
Programmable Rate 100G/200G and … 400G
Programmable Modulation Scheme: DPSK/QPSK/16QAM/64QAM
Programmable FEC to match the specific network needs
Reach or latency or power consumption or…
100G integrates into Dynamic Optical Networks
Programmable path - thru the dynamic ROADM network
Programmable rates and optical parameters to match the
network and it’s selected path
Beyond 100G Optics
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Mainstream
Simplicity
Low power
Compact
Dense
High Performance
Flexibility
Programmability
Adaptability
Dynamic
Transport
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100G and beyond
100G is mainstream “10G-like”
High volume
Simple plug’n play
Cost effective
Low power transponder less 25W
Compact small form factor
High density & low granularity
– 12-15 transponders/3RU
– ~40 transponders/10RU
100G/200G/400G
Flexible line rate
Programmable parameters that adapt to the specific deployment needs (reach, capacity, etc.)
Flexible functionality
– 200G or dual 200G or…400G
High capacity optical link
Lower granularity
Higher power and size
Cross Connect TechnologyMedia Cross ConnectOptical Cross Connect
What is a Cross Connect?
Layer 1, Physical Layer Switch
– Route media electronically or optical
Provides programmable mappings
– any-port to any-port,
– wire-speed connectivity
– non-blocking switching back plane
Port mappings can be made one-to-one or one-to-many
Protocol independent - data rate specific
100% transparent with virtually no latency (ns)
Variety of chassis types and interface blades
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Media Cross Connect
Modular system
– Various chassis densities
– Interface blades fits in all chassis
Chassis ranges from 36 to 288 ports
– Can be combined to make >2000 port system
Optical and copper interface blades
– RJ-45, SFP and SFP+
– Ranging from 100Mbps to 10 Gbps
Protocol independent
– Data rate specific
Hot swappable
Configuration by management
– Several management options
Front to back cooling
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Optical Cross Connect
All optical switch
– Piezo Steering technology
96 ports
– Singlemode fiber
– LC connectors
Protocol and date rate independent
– Supports 100Gbps and beyond
Low insertion loss
– < 2 dB
Dark fiber switching
– Doesn’t require end system devices to configure connections
Configuration by management
– Several management options
– Same management as Media Cross Connect
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Optical Cross Connect Technology
Piezo Steering technology
– an optical beam is collimated and steered from an input array ("send" side) to an output array ("receive" side).
– Electrical signals to the piezoelectric elements control the pointing
Advantages of Beam-steering technology
– Very clean optical path:
• The very simple optical train, consisting of fiber and two collimators, offer a very low loss and extremely high optical performance
– High force, high stiffness drive train
• Compared to 3D MEMS devices, the system is far less susceptible to shock, vibration, or other environmental disturbances
– High resolution positioning & control
• Extremely accurate sense and tune provides maximum power throughput
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Collimating Lens
Beam Steering optics
Cross Connect Management Options
Same management for MCC and OCC
Command Line Interface
– Industry standard CLI
– Serial, Telnet, SSH
SNMP
– V1,2,3
Scripting
– TCL-Based API
PathFinder GUI
– Single chassis application
– Mapping Efficiencies
– Graphical representation of topology
Commercial 3rd Party Automation Software
– Spirent
• Test Center
• iTest
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Use cases for Cross Connect Technology
Lab Automation
Equipment sharing
Interoperability testing
Network/fault simulation
System test/validation
Media conversion
Proof of concept labs
Support labs/NOC
Training centers
Video matrix distribution/multicast traffic
Network monitoring
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Automated topology configuration– Save and recall topologies
– Reserve and schedule equipment
– Execute tests automatically
Automated testing– More test coverage in less time
– More accurate and repeatable tests
– Eliminates human error and re-test
– Reduces capital and operational expense
Cross Connect Cornerstone to Test Automation
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Tampere
Helsinki
Amsterdam
Los Angeles
Connect the physical layer using software commands
– Point to point: uni- or bi directional
– Point to multi point
– Port mirroring
Equipment Sharing
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Distance/Delay Testing
– Test over long-haul links for transmission delay effects
– Dynamically create different fiber lengths
Line Delay Protocol Testing
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Optical Cross Connect
Multicast 1 to N at wire speed– Video distribution using digital video SFP’s
Digital Video Distribution
Digital Video Pluggable Optics
Digital Video SFP can be used to transport digital video over different media
– Fiber for transport over longer distances
Unidirectional traffic
– Separate Transmit and Receive SFP
Various protocols and rates supported
– SDI
– HD-SDI
– 3G SDI
– PAL, Secam, NTSC
– 270Mbps, 1.001Gbps, 1.485Gbps, 2.970Gbps
Distribution of digital video over WDM networks
Multicast 1:N digital vide streams using Cross Connect technology
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Thank You