Amazon Leo, formerly known as Project Kuiper, is Amazon’s low Earth orbit satellite-internet initiative designed to provide broadband access to regions that lack reliable connectivity. The new name “Leo” refers directly to low Earth orbit (LEO), the orbital regime where the constellation operates. The system will use a constellation of more than 3,000 satellites operating about 590–630 kilometers (366–391 miles) above Earth, supported by gateway ground stations and global fiber infrastructure. Its goal is to serve unserved and underserved populations, including individuals, schools, hospitals, businesses, and government agencies in remote or infrastructure-limited areas. Development began in 2018 and received FCC approval in 2020. The first two prototype satellites launched in October 2023, and Amazon has since deployed more than 150 operational satellites as part of early constellation build-out.

Amazon Leo is managed by Amazon’s Devices and Services division, with satellites manufactured in Kirkland, Washington, and launch integration handled at the Kennedy Space Center in Florida. Amazon has secured more than 80 launch missions with ULA, Arianespace, Blue Origin, and SpaceX. SpaceX, which operates Starlink, is one of Amazon Leo’s direct competitors in the satellite-internet market. FCC regulations require Amazon to place at least half of its constellation in orbit by July 2026 and complete deployment by July 2029. The satellites incorporate optical inter-satellite laser links to increase throughput and reduce latency.

To reach customers, Amazon Leo uses three categories of user terminals: the compact Leo Nano offering speeds around 100 Mbps; the mid-range Leo Pro supporting roughly 400 Mbps; and the enterprise-grade Leo Ultra, capable of up to 1 Gbps. Amazon plans limited service availability for select enterprise users by late 2025, expanding in 2026 as more satellites reach orbit. The spacecraft are designed with debris-mitigation and astronomical-impact-reduction measures, including controlled deorbiting procedures and brightness-management practices.

Courtesy of Amazon.

Falcon 9 is a reusable, two-stage rocket designed and manufactured by SpaceX for the reliable and safe transport of people and payloads into Earth orbit and beyond.

Falcon 9 is the world’s first orbital-class reusable rocket.

Stats

Completed missions: 565

Total landings: 519

Total reflights: 487

The Falcon 9 has launched 71 humans into orbit since May 2020

Specs

Height: 70 m / 229.6 ft

Diameter: 3.7 m / 12 ft

Mass: 549,054 kg / 1,207,920 lb

Payload to Low Earth Orbit (LEO): 22,800 kg / 50,265 lb

Payload to Geostationary Transfer Orbit (GTO): 8,300 kg / 18,300 lb

Payload to Mars: 4,020 kg / 8,860 lb

On January 24, 2021, Falcon 9 launched the first ride-share mission to Sun Synchronous Orbit. It was delivering a record-setting 143 satellites to space. And while this was an important mission for SpaceX in itself, it was also the moment Falcon 9 overtook United Launch Alliance’s Atlas V for the total number of consecutive successful launches.

SpaceX’s Falcon 9 had become America’s workhorse rocket, launching 31 times in 2021. It has already beaten that record this year, launching almost an average of once a week. While most of the launches deliver Starlink satellites to orbit, the company is still launching the most commercial payloads to orbit, too.

Falcon 9 is a medium-lift launch vehicle, with the capability to launch over 22.8 metric tonnes to low earth orbit. Unlike any other rocket, its first stage lands back on Earth after separating from its second stage. In part, this allows SpaceX to offer the cheapest option for most customers with payloads that need to reach orbit.

Under its ride-share program, a kilogram can be placed in a sun-synchronous orbit for a mere 1.1 million dollars, far cheaper than all other currently operating small satellite launch vehicles.

The reusability and fast booster turnaround times have made Falcon 9 the preferred choice for private companies and government agencies. This has allowed SpaceX to capture a huge portion of the launch market.

Photo courtesy of Jenny Hautmann for Supercluster.

Space Launch Complex 40 (SLC-40) is one of two launch sites leased by SpaceX at Cape Canaveral Space Force Station (CCSFS) in Florida, specifically designed for preparing and launching Falcon 9 rockets. Constructed in the early 1960s, SLC-40 was initially used for 55 Titan III and Titan IV rocket launches, including the Cassini-Huygens mission to Saturn. The pad was active from June 18, 1965, to April 30, 2005.

SpaceX began leasing SLC-40 in 2007, converting it to support Falcon 9 rockets. The pad was first upgraded to accommodate the original version of Falcon 9 and later received another upgrade in 2013 to handle the larger, reusable Falcon 9 rocket. On September 1, 2016, an explosion during a Falcon 9 fueling test caused severe damage to the pad. It was rebuilt rapidly, with construction completed in just 10 months, from mid-February to late November 2017. SLC-40 resumed operations with the successful launch of a Dragon capsule to the International Space Station on December 15, 2017.

After adding a crew access arm to the launch tower, SpaceX launched their first crewed mission from SLC-40 on Saturday, September 28th 2024 for NASA's Crew-9 mission to the International Space Station.

Under SpaceX’s management, SLC-40 has been the site of numerous significant missions. Notable launches include the first all-commercial Dragon mission to the International Space Station, NASA’s DSCOVR mission, the Transiting Exoplanet Survey Satellite (TESS) for NASA and MIT, the first satellite for Turkmenistan, the classified Zuma mission for Northrop Grumman and the U.S. government, the first GPS-III satellite, and the Beresheet lunar lander for Israel. Additionally, in September 2024, SLC-40 will host its first crewed launch with SpaceX’s Crew-9 mission, marking a new milestone for the pad.

Cape Canaveral is a major launch site with four currently active launch pads for Atlas V, Delta IV Heavy, Falcon 9, and Minotaur rockets. Located on Florida’s east coast, it offers extensive access to space for a variety of missions, including those targeting the Space Station, Geostationary Earth Orbit, the Moon, interplanetary destinations, and polar trajectories. The site’s location ensures that launches occur over the open Atlantic Ocean, minimizing risks to populated areas.

Cape Canaveral is often confused with or referred to alongside NASA’s Kennedy Space Center on Merritt Island. While they are separate installations, both play pivotal roles in the U.S. space program. Cape Canaveral has a storied history of significant space missions, including the launch of the first U.S. Earth satellite, Explorer 1, in 1958; the first U.S. astronaut, Alan Shepard, in 1961; the first U.S. astronaut in orbit, John Glenn, in 1962; the launch of the first two-person U.S. spacecraft, Gemini 3, in 1965; and the first U.S. uncrewed lunar landing mission, Surveyor 1, in 1966.

SLC-40 and Cape Canaveral continue to be integral to SpaceX’s ambitious launch schedule and the broader U.S. space program, supporting a wide range of missions and contributing to advancements in space exploration.

Photo courtesy of Jenny Hautmann for Supercluster

A Shortfall of Gravitas" (ASOG) is one of SpaceX’s Autonomous Spaceport Drone Ships, designed to recover Falcon 9 rocket boosters at sea. Operating primarily in the Atlantic Ocean from Port Canaveral, Florida, ASOG joined SpaceX’s fleet in 2021. It plays a crucial role in SpaceX's reusability program, enabling the recovery and refurbishment of rocket boosters for future missions.

The name "A Shortfall of Gravitas" is inspired by science fiction author Iain M. Banks' Culture series, known for its playful and philosophical ship names. ASOG is fully autonomous, capable of sailing to its designated landing area and maintaining position without the need for a tugboat. Equipped with advanced thrusters, it ensures precise positioning even in challenging weather conditions and features a large landing platform for booster recovery.

ASOG is essential for missions requiring high velocities or distant orbits where landing on solid ground is not feasible. By recovering boosters at sea, ASOG helps SpaceX reduce costs and enhance the sustainability of spaceflight.

Photo courtesy to Jenny Hautmann for Supercluster