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High capacity microwave communications

High capacity microwave communications. For Defense Embedded Systems 2012. July 2012. Yoav Mor Product Manager. The #1 Wireless Backhaul Specialist. Innovation. Experience. Commitment. > 500,000 Radios since 2004. US $445.3M In 2011. Field Proven Experience. 1200 Professionals.

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High capacity microwave communications

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  1. High capacity microwave communications For Defense Embedded Systems 2012 July 2012 Yoav Mor Product Manager
  2. The #1 Wireless Backhaul Specialist Innovation Experience Commitment >500,000 Radios since 2004 US $445.3M In 2011 Field Proven Experience 1200 Professionals
  3. What we do Short Haul 100Mb/s-1Gb/s Long Haul> 1Gb/s Indoor Unit All Outdoor All Indoor RF Unit Ceragon provides high-capacity, point-to-point wireless communication for backhauling advanced voice & data services
  4. CompanyHistory 1996:     Founded as Giganet 2000:     Renamed Ceragon Networks 2000: IPO on NASDAQ and ticker CRNT 2007:     Secondary offering 2009:     Reaches #1 specialist position in radio link shipments 2011:     Acquires NeraNetworksMerged company is #1 wireless backhaul specialist, offering: long haul solutions short haul solutions full turnkey services offering
  5. We Know Our Business Revenues ($mm) 9.8% operating margin Non-GAAP Net Income($mm)
  6. Market Trends in Microwave for Defense
  7. Main microwave requirements for defense applications Reliability from a network that can withstand harsh environments Availability and network robustness Low latency for Network Enabled Capabilities Secure links and encryption Portable/compact solutions High power ODU Scalability and flexibility
  8. Trends in defense Warfare is not network centric. It's commander centric. And that commander is enabled by networks. US General David Petraeus, Commander, U.S. Forces Afghanistan
  9. Proliferation of deployable/semi mobile access networks
  10. Secure and reliable telecommunication infrastructure Digital Microwave communication offers a reliable and secure transmission of sensitive information Reliable No physical media which could be affected by physical factors like ice, flood or street excavation. Secure The microwave signal in licensed frequency bands are very difficult to intercept Extremely narrow “beam” making interception difficult
  11. Tactical Applications Rugged – with tailored enclosure Rapid field deployment using tripod direct mounting for the ODU and antenna Low power consumption (optional power backup) Light weight Designed to withstand extreme temperatures, vibrations, and more
  12. Strategic Applications Defense Challenge: Build an army military grade long microwave backbone Connecting the Philippines islands with many over the water links with distances of up to 100km Cost-effective voice, data, and video conferencing services to satisfy command and control requirements Solutions 36 hops 1+1 all indoor 7 GHz Link Interface: STM-1 Why Ceragon? High power split configuration 1+1 Integrated offering through a channel with networking, terminal and support
  13. Orleans Ave North London Canal North 2.6 km 17th Street North 3.3 km 3.8 km 4.2 km 2.3 km Orleans Ave South London Canal South 17th Street South US Army Corps of EngineersHurricane Katrina Recovery Interfaces:FE+NxT1 Capacity: 50 Mbps over 10 MHz Modulation: 64 QAM Frequency: 11 GHz Configuration: 1+1 Hot Standby New Orleans, Louisiana
  14. Addressing the capacity crunch
  15. Market Drivers – Bandwidth Hunger is Ever Increasing Everything can be mobile - We expect wireline experience from the wireless networks Video Cloud Computing M-2-M From local to remote IT infrastructure – taking the office with you Video applications are the key drivers M-2-M will hit $12B in 2020 Mobile Data is Exploding Source: Cisco VNI 2012
  16. Capacity Demands 2012 - 2018 LTE is already here – demands are knonwn, LTE-A numbers are more speculative TriCells (Macro sites) Tail Aggregation Downlink: 135Mbps peak, 86Mbps busy time mean Uplink: 51Mbps peak, 89Mbps busy time mean Dimensioning guidelines (Max {peak, N x busy time mean}) Considering extreme scenario (N ≤ 20) 2018* 2018* 2012 LTE-A LTE-A 2012 10Gbps 1 Gbps LTE LTE 1.5 Gbps 135 Mbps Maintaining LTE’s tail % agg’ Available channel bandwidth Available channel bandwidth Practical View 300Mbps Practical View 3 – 4Gbps * LTE-A numbers
  17. Increase Capacity in Microwave Links: 5 Steps
  18. Use more spectrum, efficiently More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization 250 MHz 250 MHz in E-Band 112MHz 112MHz 28 28 28 …. N x 28MHz bonded 56MHz New Spectrum: 26, 28, 31, 42 GHz 70-80 GHz 56MHz 28 28MHz More channel bandwidth, and channel bonding
  19. Efficient Carrier Bonding Techniques (MC-ABC) More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization 4x40 MHz: aggr. 1.48 Gbps 8 4 9 5 1 4 Ch4 7 3 8 4 7 3 Ch3 Ch2 6 2 7 3 6 2 5 1 6 2 5 1 Ch1 370Mbps@512QAM per carrier Incoming Packet Flow – GBE port Outgoing Packet Flow – GBE port P4 P3 P2 P1 P4 P3 P2 P1 8 7 6 5 4 3 2 1 9 8 7 6 5 4 3 2 1 7 6 5 4 3 2 1 8 7 6 5 4 3 2 1 9 8 7 6 5 4 3 2 1 7 6 5 4 3 2 1 Bytes of P3 Bytes of P2 Bytes of P1 Bytes of P3 Bytes of P2 Bytes of P1
  20. Multi-Carrier Adaptive Bandwidth Control More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization
  21. Integration trends More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization Next Gen. 1998 2005 2008 SoC lead to fully functional integrated multi carrier radios Additional reduction of form-factor & cost
  22. Physics 101: More bits per symbol More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization 2048, 4096,.... 1024QAM constallation 16QAM,... 256QAM... BPSK, QPSK
  23. Meeting the practical limits of physics More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization Increasing modulation complexity meets natural limits From 256 to 1024 QAM, capacity increase is theoretical 25% (assuming no additional coding) System gain penalty about 7dB Requires “interference free” environment - can it work in field? *: typical figures for 1dB threshold degradation
  24. ACM – Adaptive Coding and Modulation More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization
  25. ACM with Adaptive Power vs. Plain ACM More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization Transmit Output Power 22 dBm Adaptive 18 dBm Standard (fixed power) 256 QAM 64 QAM QPSK Adaptive Adaptive Modulation Adaptive Power Typical other Vendors’ ACM Adaptive Power ACM vs. common (fixed Tx power) ACM example displayed for 18-23 GHz link
  26. Use Spectrum Where Needed More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization Aggregating channels Downstream Upstream Aggregation Network Tail site Asymmetrical channel within FDD frequency plan Aggregation/ Hub site
  27. Use Spectrum Where Needed More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization
  28. Use Spectrum Where Needed More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization 150Mbps link, usually needs 2 x 28MHz channels (FDD) Symmetrical links f6’ f5’ f8’ f7’ DL f3 f4 DL f5 f6 f7 f8 UL UL f1’ f4’ f2’ f3’ f4 7MHz x 16 = 112MHz Asymmetrical f1 f2 f4’ f2’ f3’ f1 f2 f3 DL DL UL UL f1’ Note: Each block is a 7MHz channel 7MHz x 8 = 56MHz
  29. XPIC More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization Transmit More Than Once on the Same Carrier v h
  30. Line-of-Sight (LOS) MIMO More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization 4 x Capacity of the same Channel Using the a single channel to quadruplethe capacity 2 x Dual Carrier units at each site Each unit has a small form factor Simpledirect mount installation V f1 f1' H V H f1 f1' SITE 1 SITE 2
  31. Focus on the important bits…. More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization IPv6 adds more packet headers and overheads Multi-Layer Header Compression Payload compression Site A Site B Header Payload Header Payload CH CP CH CP CH CP CP CH CH = Compressed Header CP = Compressed Payload
  32. Transmit the payload More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization
  33. Efficient Use of Capacity More Spectrum Spectral efficiency Spatial Efficiency Traffic Boosting Network Utilization
  34. Major Takeaways Capacity requirements increase Rapid wireless technology evolution – Access and backhaul Ceragon is a key player in wireless backhaul innovation
  35. Yoav Moryoavm@ceragon.com+972-54-4785545 Thank You
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