WiMAX Technology Jokkmokk May 15 2008 Pablo Vila R&D Manager Albentia Systems Networking for Communications Challenged Communities:

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Presentation transcript:

WiMAX Technology Jokkmokk May Pablo Vila R&D Manager Albentia Systems Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement:

Contents 12/09/2015www.n4c.eu2 ▪ Albentia Systems Presentation ▪ Introduction to WiMAX ▪ WiMAX for Internet access in rural access scenarios ▪ WiMAX and DTN ▪ Albentia Systems and N4C

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: Albentia Systems 12/09/2015www.n4c.eu3 ▪ Albentia Systems is the first Spanish manufacturer of WiMAX equipment ▪ Founded in 2004 and headquartered in Madrid (Spain) ▪ Member of the WiMAX Forum since 2006 ▪ Albentia Systems designs and manufactures complete WiMAX systems, including Base and Subscriber stations, and Backhaul links. ▪ Strongly oriented to delivering solutions for carrier-class services and applications, with stringent QoS requirements such as TDM, Video and VoIP. Complete in-house development HW+SW Customers in Europe, Africa and Latin America

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: WiMAX Solutions 12/09/2015www.n4c.eu4 WiMAX Base Stations WiMAX Subscriber Stations (User terminals) Backhauling equipment Point-point professional video links TDM synchronous transport radio links Network management system Standard compliance

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: R&D Experience 12/09/2015www.n4c.eu5 R&D activities: 65% of total budget Hardware design: Digital, analog, RF, mechanical design… Software design: Embedded systems, RTOS, MAC layer development, protocol stacks, management systems… Collaboration with Universities Participation in several projects related to rural broadband wireless access (mostly financed by the Spanish Government) RASWER: Satellite and WiMAX rural access networks OPENREACH: Cost-effective WiMAX infrastructure equipment for rural applications WIMAR: IPTV applications over WiMAX in rural areas Internet access to native communities in Panama (INADEH)

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: Introduction to WiMAX 12/09/2015www.n4c.eu6 Broadband Wireless Access technology based on IEEE standard Point-Multipoint Metropolitan Access Networks Outdoor application, 2-20km typical range, 10Mbps total capacity Operation in 3.5 and 5.6GHz bands (among others) QoS support for voice, video and data (triple play) Interoperability – WiMAX Forum

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: Broadband Wireless Access 12/09/2015www.n4c.eu7 Network architecture Transport vs. Access network Infrastructure vs. User terminals

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: WiMAX transport networks 12/09/2015www.n4c.eu8 WiMAX was originally intended for Access Networks Cost-effective point-point or point-multipoint transport networks can also be based on technology 5-30 Mbps, 10-40km, QoS, low power… Achievable link distance depends on many paramenters Available link budget depends on power, bandwidth, desired data rate, antennas, frequency, equipment… Free-space loss depends on distance Link Margin for special losses: Rain, snow, fading, antenna missalignement… Radio Link Availability is a function of the Link Margin High availability requires large available link budget and short distances – Higher infrastructure investment

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: BWA in rural areas 12/09/2015www.n4c.eu9 Challenging business model Large areas to cover High investment in infrastructure equipment (transport and BS) Few user terminals per Base Station – Low revenue Cost limited by infrastructure equipment CAPEX problem: Expensive infrastructure equipment OPEX problem: Expensive transport operators Other aspects make the problem even worse Power consumption, Temperature, Snow, Visibility, Link distance, Environmental constraints, Security…

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: BWA in rural areas 12/09/2015www.n4c.eu10 Solution must be based on cost-effective transport and access infrastructure equipment Still challenging if 100% coverage and high availability is required Reducing availability may help to reduce the problem DTN is required Rural BWA solution? 1) Optimized infrastructure equipment 2) Reduced availability 3) Delay Tolerant Networking

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: WiMAX and DTN 12/09/2015www.n4c.eu11 Hybrid equipment (BS/SS) for long distance mesh point-multipoint transport network Cost-effective, low power, small form factor equipment Several nodes spread across the region (50km distance) Long distances at the price of low availability Each node switches between BS or SS modes with a defined duty cycle to link with adjacent nodes (unicast or multicast) Availability of each PMP link is limited by distance, power, duty cycle, snow, temperature… DTN and routing algorithms are required Nomadic users may connect to the network using portable terminals (long reach) Moving stations (helicopter?)

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: WiMAX and DTN 12/09/2015www.n4c.eu12

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: Albentia and N4C 12/09/2015www.n4c.eu13 What Abentia Systems can do for N4C Albentia collaborates with UPM in WP6 Develop special equipment for DTN applications Develop Hybrid BS/SS stations for mesh DTN networking Provide a WiMAX platform for DTN layer and protocols Provide physical layer for DTN experimentation in a real application scenario What Albentia would like to learn from N4C Experiment new system architectures for rural BWA feasibility Understand new deployment scenarios in adverse conditions Export DTN-WiMAX concept to other rural scenarios (Panama, New Guinea, Mali, Senegal…)

Networking for Communications Challenged Communities: Architecture, Test Beds and Innovative Alliances Grant Agreement: Thank you! 12/09/2015www.n4c.eu14