Subsea Cables & Internet Infrastructure

1. The Waterworth cable will link the US to South Africa with a branching unit to Brazil. It extends from South Africa to India & onto to the Pacific and the US. The total length is greater than the Earth's circumference at approximately 50,000 kilometers. 2. Subsea cable projects are taking 3 to 5 years from initial idea to commercial service. 3. US traffic goes to Europe. It's aggregated with European originated traffic and then traverses the Mediterranean Sea to reach Egypt and takes terrestrial routes (Telecom Egypt) to the Red Sea. Then the traffic flows down the Red Sea. From there it either heads to India or bypasses it with Southeast Asia being the destination. 4. In the eyes of Facebook's subsea engineering team, the standard cable routing described above creates a host of problems. First of all , the Red Sea is a single point of failure. Same holds for Egypt. Secondly, the Mediterranean Sea requires many government permits as cables inevitably goes through ter...

First Point: The Portugal and Spanish grids are tightly integrated with limited power connector to the rest of Europe. Solar and wind play a big role and both power sources suffer from what is known as frequency instability. Solar and wind generated power is much more volatile than traditional power sources. Traditional power generators have angular momentum inertia. It takes a while to up or lower the power due to the inertia in the spinning components. A natural gas turbine takes a few minutes to spin up. A nuclear reactor an hour to lower or increase output by 10% (French reactors do load following). Solar and wind create very volatile power fluctuations that can easily trigger a circuit breaker. In an isolated grid if a circuit breaker is triggered, the power in the remaining active part of the grid increases. This triggers more circuit breakers and usually brings down the entire grid. 2. The consequence of the first point is that avoiding a repeat of the Iberian Penisula outage re...

BW Group purchased the Hawaiki cable in July, 2021 from the Hawaiki Submarine Cable Limited Partnership. The Partnership's original plan was to build a sister cable known as Hawaiki Nui (Great Hawaiki). BW, a Singapore company, has pursued this idea and finally signed earlier this year a Memorandum Of Understanding with TELIN, the international cable subsidiary of the Indonesian PTT. The MOU is really the partnership or consortium agreement and typically only happens once funding has been secured and all parties are fully onboard. The fact that Hawaiki Nui cable was announced in 2021 and just achieved the critical MOU milestone tells me that it has been very difficult to get this project off the ground. My speculation is that the cable's estimated cost is very high because it requires deep burial in the shallow waters of Indonesia; moreover, a very thorough and expensive marine survey is also necessary. Another challenge is that the cable's route requires Indonesi...

The network topology was originally designed to bypass both the Red Sea and Egypt. Instead, the cable goes from Sify's Mumbai CLS to a branching unit near Bubar. It splits North to land at Barka, Oman whereas the main trunk heads Southwest to land at Salalah, Oman. Then back to sea to Djibouti, which is the Internet gateway for a group of landlocked African states like Ethiopa and South Sudan. From Djibouti it heads North through the Red Sea to come ashore at Duba, Saudi Arabia. The cable goes terrestrial from this point up to a modern carrier neutral data center at Aqaba, Jordan. Then the terrestrial route crosses into Israel and eventually terminates at the Sparkle CLS near Tel Aviv. From there it traverses the Mediterranean Sea to ultimately come ashore at Marseille and Genoa. Marseille Interxion and a Milano data center campus called Stack Infrastructure are the key European subsea cable POPs. The Genoa POP is Equinix GN1.  I am a bit disappointed because early reports suggeste...