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Showing posts with the label spatial division multiplexing

Firmina - The Other Atlantic Leviathan

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 Like Anjana , Firmina is a content provider project. Google is the owner and bank for the 16 fibre pair (main trunk) spatial division multiplexing cable. The subsea network will connect the Myrtle Beach, South Carolina cable landing station to a Telxius CLS in Praia Grande (near Sao Paulo) and two other landings in Uruguay and Argentina. I think Google picked South Carolina because it represents a good latency compromise as some of the traffic is destined for Miami and some for Ashburn Equinix. It also improves the Google network's overall resiliency and its cloud infrastructure. I have noticed that Google has a tendency to run its fibre pairs at lower transmission speeds than Facebook. The design transmission rate for this system is 15 Tbps per pair whereas Facebook's Anjana is 20 terabits. So Firmina's design aggregate transmission rate day one is 240 Tbps. A quarter of a petabit.  Telxius has purchased a fibre pair on life-of-system IRU. I expect others will be looking

Equiano: The West African ISP Buyer's Guide

Equiano is a Google cable. A 12 fibre pair spatial division multiplexing system designed to do at least 12 Tbps per pair. This cable is a must-have for African ISPs as it connects the three key telecom hubs of Portugal (Lisbon Equinix (LS1)), Nigeria (the Open Access Data Center (OADC) in Lagos), and South Africa (Capetown Teraco (CT1) in South Africa), has massive capacity and is vastly more reliable than older African cables.  Equiano not only connects the key telecom hubs essential to West Africa's Internet, but is also buried two meters deep and avoids the dangerous undersea areas like the Congo canyon and Le Trou Sans Fin that have caused many subsea outages. Le Trou experienced a debris slide this Spring that caused 4 African cables (SAT3, Mainone, WACS, and ACE) to be severed in the Ivory Coast's territorial waters. Equiano saved West Africa's Internet from a complete subsequent meltdown as its capacity was used to reroute traffic to Lisbon or South Africa. Equiano&#

The RAMAN Cable's Impact On The Indian Market: The Sea Turns Blue

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Technology: Spatial Division Multiplexing. Fibre Pairs: 16.  Business Model: Consortium & Open Cable.  Fibre Pair Throughput: NA. Consortium Leaders: Google, Sparkle, Omantel.  Wholesale Capacity Players: Sify, Sparkle.  A point: Marseille Interxion.  Z point: Sify CLS, Mumbai.  Raman is the cable that could break open India's tightly controlled international capacity market. The cable is named after Indian physicist Chandrasekhara Venkata Raman who received the Nobel prize in 1930 for discovering that some of the light traversing a transparent medium is scattered and changes both wavelength and amplititude. This happens to be why the sea is blue. This 16 pair SDM cable will link Mumbai to Oman, Saudi Arabia, Djibouti, and Jordan. Raman is striking in two respects. First, it is really an integrated part of the Blue-Raman cable that will function as an single network connecting Marseille to Mumbai and will be priced as a single, seamless capacity provider. It will bypass Egypt

New Subsea Cables RFS 2025: Unitirreno

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Most subsea cables connect countries, but increasingly we are seeing cables that serve only a single country for a variety of reasons.Either the country is not contiguous like Indonesia or the Philippines or the country is exceptionally large with isolated densely populated cities like Australia. Or it is sparsely settled like Alaska's coast which has no significant land infrastructure like roads or gas pipes to serve as telecom rights of way.  Unitirreno belongs to the former category. This SDM (spatial division multiplexing) 24 fibre pair cable will link Italy's principal territories, the Boot, Sicily, and Sardinia. The design throughput per fibre pair is 20 terabits or 480 terabits per second for the cable. Unitirreno, if built, will be a very high capacity system. Nearly half a petabit.  Here is the company's key sales pitch and commercial justifications: 1. Unitirreno cuts the latency in half between Sicily and Genoa and provides a completely diverse path to the terre

New Subsea Cables RFS 2025: Echo

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Transmission Technology: Spatial Division Multiplexing.  Length: 16,026 kilometers. Almost 10,000 US miles. Consortium Members: Google and Facebook. Type of Consortium: Open cable model.  Construction Status: Behind schedule due to permitting delays for Indonesian waters. Fifty-fifty control probably also slowed decision making.  Number of Fibre Pairs: Main trunk has 12. Estimated RFS: 1st or 2nd quarter 2025. Day One Aggregate Throughput: 144 Tbps.  Salient Features: First low latency, direct cable between Singapore and USA with no intermediate breakouts. One Indonesian branching unit. No telecom carrier consortium members. Amazon and Facebook land the cable themselves in Singapore and California.  Google announced  announced the 12 fibre pair SDM Echo project in early 2021 with a planned 2023 launch. However, permitting delays have slowed construction and the project is now expected to be RFS 2025. In addition, it is highly plausible that the 50-50 Facebook/Google control split sl

The New Subsea Cable RFS 2025 Series: Airraq

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Airraq is a new subsea cable connecting important Alaskan Coast communities. Not surprisingly, most remote, sparsely populated areas in the US are bandwidth famished. Because Alaska shares no border with the Continental US, subsea cables are used to connect it to the lower 48 US states with satellite and microwave back haul the usual Last Mile connectivity in remote cities and villages. Coastal cables like Airraq are used to aggregate traffic and then hand it off to the international cables that haul it down the British Columbia coast to Washington or Oregon. The coastal aggregation cables effectively eliminate the Middle and Last Mile congestion since most communities lie on the coast or next to inland rivers.  This new cable is a 12 fibre pair, spatial division multiplexing system (SDM) landing in three locations and then using terrestrial arteries to reach cities and towns. Despite being SDM, the throughput levels are relatively low ranging from 1.6 Tbps to 3.2 Tbps, which is reason