SpaceX has launched 7062 Starlink satellites to date.
Cell phones in even the most remote areas will soon be able to connect to the internet, using Starlink satellites.
In early 2014, SpaceX founder Elon Musk and Greg Wyler – founder of O3b Networks – were rumored to be working together to build a constellation of over 700 satellites. Called WorldVu, this constellation would be 10x larger than the size of the then-largest satellite constellation, operated by Iridium.
These discussions didn’t last long and SpaceX secretly filed an ITU application courtesy of the Norway telecom regulator under the name STEAM. Later renamed Starlink, the mission was to provide high-quality internet bandwidth in the area where a fiber connection is unfeasible. This includes rural and remote areas all over the globe, including oceans, and even in the air for commercial and military customers.
Now, years later, SpaceX and TMobile are promising to provide service in dead zones using the Earth-orbiting satellites, enough for texts and messaging apps to work. T-Mobile’s CEO Mike Sievert stated that operators of messaging apps like WhatsApp or iMessage will need to work with T-Mobile and Starlink for their services to recognize the satellite connection and work with it once it launches.
The move continues an aggressive debut of Starlink's service that has been making headlines around the world due to a rapid launch cadence, interventions in natural disasters, and the technology's critical role on the battlefield in Ukraine. While this article was being edited, SpaceX announced the TMobile deal, launched two Falcon 9 Starlink missions, activated the service in Norway, and announced a deal to provide Starlink on Royal Caribbean cruises.
The buzz might make it seem like Starlink is a new invention but beaming the internet using satellites isn’t a novel idea. Companies like HughesNet, Iridium, and Telesat already have satellites up in space servicing the unserviceable areas, but Starlink is fundamentally different from existing constellations. Traditional companies have just 4-5 huge satellites in geostationary orbit, where each of them services a large area of the globe. Geostationary orbit is a special orbit of Earth above 36,000 kilometers where the satellite’s orbit period is equal to the rotation of Earth, which allows the satellite to appear stationary relative to an observer on Earth.
Satellites in geostationary orbit allow planet-wide coverage with fewer satellites but the connection is usually spotty and the ping is very poor, mostly because of the large distance between the satellite and the receiver.
Starlink is attempting to fix these common issues by launching a large number of satellites — 12,000 — to Low Earth orbit. This not only significantly reduces the distance that the signal needs to travel from the receiver but also makes it easier to mitigate space debris as satellites in LEO can easily deorbit. Those in geostationary orbit are too far from the Earth to deorbit and have to be placed in a special orbit that lies away from common operational orbits, known as the graveyard orbit.
SpaceX first tested Starlink tech when they launched two identical test satellites named Tintin A and Tintin B in 2018. A year later, the company launched their first batch of 60 satellites. Used only for testing, SpaceX was able to communicate with all 60 but lost contact with 3. By October, Elon publicly tested the network when he sent his first tweet using Starlink.
The launch of the operational satellites began in November 2019. After the company placed sufficient satellites to provide internet in certain parts of the US, it introduced a paid beta service called “Better Than Nothing Beta,” charging $499 for the user terminal with an expected service of 50 to 150 Mbps and latency from 20 to 40ms. By January 2021, the beta service was extended to other countries, starting with the United Kingdom.
Washington is the home of Starlink’s research and development facility and was one of the first states to receive the beta services in the US. As part of that initiative, the Hoh Tribe became one of the first users of SpaceX’s broadband. Located in a remote part of the state, Starlink allowed the tribe of 28 households and 116 people to access a high-speed internet connection.
"It seemed like out of nowhere, SpaceX came up and just catapulted us into the 21st century," said Melvinjohn Ashue, vice chairman of the Hoh Tribe. "Our youth are able to do education online and participate in videos. Telehealth is no longer going to be an issue." At a time when the whole world was reeling from the effects of the COVID-19 pandemic, reliable access to an internet connection couldn’t have come at a better time.
At the same time as schools were being closed due to the COVID outbreak, the Wise County Public Schools in Virginia received Starlink terminals to connect the students with high-speed and low-latency broadband. This enabled over 90 Wise County families to have access to online educational resources.
The word from Virginia spread and a similar effort took place in the Appalachian Region in the US as the Appalachian Council for Innovation raised capital through a public-private partnership to connect students in the American Central Appalachian Mountains who were underserved by the terrestrial internet providers.
As the company iteratively improved their services and increased its coverage area with every launch, they prioritized extending the beta service to the emergency responders and areas without internet. In September 2020 as west coast wildfires wrecked numerous rural areas, Starlink helped both locals and emergency workers. One of the towns was Malden in Washington, where Starlink was supporting emergency responders who helped rebuild the scorched town.
The impact was not limited to the US. Starlink partnered with the Brazilian Government to operate satellites in the Amazon rainforest to connect over 19,000 unconnected schools in rural areas and monitor the forest. SpaceX’s satellite internet was also introduced in Tonga in February of this year when the teams provided emergency relief during the Hunga Tonga-Hunga eruption and tsunami disaster.
Starlink’s capability to provide internet isn’t limited to the ground. In 209, US Air Force Research Laboratory demonstrated that Starlink was able to clock over 610 Mbits/s of data rate onboard the Beechcraft C-12 Huron flight. They also successfully tested the terminal on a Lockheed AC-130 aircraft. In 2020, the Air Force used Starlink during a live-fire exercise to support their advanced battlefield management systems by connecting it to a variety of aerial and terrestrial assets, including the Boeing KC-135 Stratotanker.
Starlink became a critical asset in Ukraine as the Russians invaded, demonstrating how satellite internet can be used in a modern conflict. SpaceX was in talks to bring Starlink to Ukraine well before the war to improve connectivity in the vast rural regions, however, the war accelerated the process significantly when the vice prime minister and Minister of Digital Transformation of Ukraine, Mykhailo Fedorov, tweeted a request for Starlink terminals and the service to be activated in the country. In around 10 hours, Elon confirmed that the service was active in Ukraine with the first batch of terminals arriving after just 2 days.
SpaceX continued to upgrade its services to better suit the war. A firmware update enabled terminals to be powered by a car’s cigarette lighter. The company also devised a solution to Russian attempts to interfere with the Starlink signals. Dave Tremper, director of electronic warfare at the Pentagon, praised the speed with which SpaceX evaded that jamming with a software update. “How they did that was eye-watering to me,” he said at a conference on defence technology, lamenting that US military equipment was not so flexible. “We need to be able to have that agility.”
This speedy, widespread rollout of Starlink had been an unplanned experiment in providing connectivity to people suffering the privations of war or an authoritarian government. According to Fedorov, the fighting in the Chernihiv region northeast of Kyiv destroyed 10 kilometers of cable, however, a local ISP was able to bring all the people in the area online with a single Starlink terminal.
By April, SpaceX sent over 50k terminals to Ukraine to replace the internet services destroyed by Russia. Starlink played a key role in Ukraine’s new artillery fire coordination systems which gave Ukraine a surprising superiority in the initial months of the War. What enabled such reliable and low-latency high-speed service in remote and war-torn areas is the sheer number of Starlink satellites in orbit and SpaceX’s ability to get them to orbit as fast as possible.
Out of this, only 2822 of them are operational or slowly raising themselves in the desired orbit. The launch of so many Starlink satellites in such a short amount of time is possible because of SpaceX’s high launch cadence and low turnaround time of its workhorse rocket: The Falcon 9.
On average, SpaceX is launching a Falcon 9 every 6.4 days, most of them being Starlink missions. In the first quarter of this year alone, SpaceX has placed nearly 1.16 tonnes of cargo in orbit, most of them being Starlink satellites.
The company aims to set up the Starlink constellation in two phases. Under phase 1, the satellites will be placed at 4 different altitudes — varying between 540 kilometers to 570 kilometers — with different inclinations to provide worldwide coverage, aiming to complete it by March 2027. The next phase will see Starlink satellites being launched to a lower orbit of around 330 - 340 kilometers, with an estimated time of completion being November 2027.
V2 Mini (Starlink Second-Generation)
In February 2023, SpaceX launched the second-generation Starlink satellites.
SpaceX calls them “V2 Mini”. They represent a step forward in Starlink capability. V2 minis include key technologies—such as more powerful phased array antennas and the use of E-band for backhaul—which allows Starlink to provide ~4x more capacity per satellite than earlier iterations. This means Starlink can provide more bandwidth with increased reliability and connect millions of more people around the world with high-speed internet.
Among other enhancements, V2 minis are equipped with new argon Hall thrusters for on orbit maneuvering. Developed by SpaceX engineers, they have 2.4x the thrust and 1.5x the specific impulse of our first gen thrusters.
Credit: SpaceX
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
Total launches: 377
Total landings: 333
Total reflights: 308
The Falcon 9 has launched 52 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
The Autonomous Spaceport Drone Ship "Just Read The Instructions" (JRTI) is one of two recovery ships stationed in the Atlantic Ocean for SpaceX's Falcon 9 rockets. The original version of JRTI operated in the Pacific Ocean, supporting launches from Vandenberg Space Force Base in California. It was later upgraded and relocated to the East Coast, primarily operating out of Port Canaveral, Florida. Its first Atlantic Ocean mission was in June 2020, supporting the 8th Starlink launch.
JRTI is an autonomous vessel serving as a mobile landing platform, crucial to SpaceX's efforts to recover and reuse rocket components, which significantly reduces spaceflight costs. The ship's name, "Just Read The Instructions," is inspired by a spacecraft in Iain M. Banks' *Culture* series, known for its whimsical and thought-provoking names.
Equipped with a large landing platform and advanced navigation systems, JRTI uses thrusters to maintain precise positioning, even in rough seas. It works in tandem with the other SpaceX drone ship, "A Shortfall of Gravitas" (ASOG), both of which have been instrumental in SpaceX's success in landing and reusing rocket boosters.
Photo courtesy of SpaceX
Starlink Mission Patch
Grab our special edition patch while you wait for your dish.
3" x 3"
Iron on backing.
Click here to purchase one from our shop. Supplies are limited.
SLC-40 was built in the early 1960s and hosted its first launch on June 18, 1965. Since then, it has launched nearly 100 missions on the Titan III, Titan IV, and Falcon 9 rockets.
During the Titan rocket era, SLC-40 was used to launch two interplanetary missions: Mars Observer to Mars and Cassini-Huygens to Saturn.
With the Falcon 9, the pad became the first Cape Canaveral site to host a launch to the International Space Station.
The pad is located on historic Cape Canaveral Air Force Station, FL - the primary launch center for the United States.
The Florida launch site handles the vast majority of U.S. launches every year and has been the starting point of numerous history-making missions for the United States, including:
A podcast exploring the amazing milestones that changed space history, the wildest ideas that drive our future, and every development in this new Golden Age of Space.
Your support makes the Astronaut Database and Launch Tracker possible, and keeps all Supercluster content free.
SUPPORTCOPYRIGHT 2021 SUPERCLUSTER LLC