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Tag Archives: SpaceX
Colbert on SpaceX rocket launch: ‘compensating for Elon Musk’s penis’ – The Guardian
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Watch live: SpaceX counting down to launch of Intelsat satellite with NASA air quality sensor – Spaceflight Now – Spaceflight Now
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Elon Musk says running Twitter, Tesla and SpaceX has been ‘extremely tough’ – MarketWatch
- Elon Musk says running Twitter, Tesla and SpaceX has been ‘extremely tough’ MarketWatch
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SpaceX set to launch 53 more Starlink internet satellites – Spaceflight Now
“Our action will allow SpaceX to begin deployment of Gen2 Starlink, which will bring next generation satellite broadband to Americans nationwide, including those living and working in areas traditionally unserved or underserved by terrestrial systems,” the FCC wrote in its Dec. 1 order partially approving the Starlink Gen2 constellation. “Our action also will enable worldwide satellite broadband service, helping to close the digital divide on a global scale.
“At the same time, this limited grant and associated conditions will protect other satellite and terrestrial operators from harmful interference and maintain a safe space environment, promoting competition and protecting spectrum and orbital resources for future use,” the FCC wrote. “We defer action on the remainder of SpaceX’s application at this time.”
Specifically, the FCC granted SpaceX authority to launch the initial block of 7,500 Starlink Gen2 satellites into orbits at 525, 530, and 535 kilometers, with inclinations of 53, 43, and 33 degrees, respectively, using Ku-band and Ka-band frequencies. The FCC deferred a decision on SpaceX’s request to operate Starlink Gen2 satellites in higher and lower orbits.
Like the first two Gen2 launches Dec. 28 and Jan. 26, the Starlink 5-3 mission Thursday will target the 530-kilometer-high (329-mile) orbit at an inclination of 43 degrees to the equator.
SpaceX currently has nearly 3,500 functioning Starlink satellites in space, with more than 3,100 operational and roughly 300 moving into their operational orbits, according to a tabulation by Jonathan McDowell, an expert tracker of spaceflight activity and an astronomer at the Harvard-Smithsonian Center for Astrophysics.
The first-generation Starlink network architecture includes satellites flying a few hundred miles up, orbiting at inclinations of 97.6 degrees, 70 degrees, 53.2 degrees, and 53.0 degrees to the equator. Most of SpaceX’s recent Starlink launches have released satellites into Shell 4, at an inclination of 53.2 degrees, after the company largely completed launches into the first 53-degree inclination shell last year.
Shell 5 of the Starlink network was widely believed to be one of the polar-orbiting layers of the constellation, at 97.6 degrees inclination. But the name of the first Gen2 missions — Starlink 5-1, 5-2, and 5-3 — appear to suggest SpaceX has changed the naming scheme for the Starlink shells.
SpaceX’s launch team will be stationed inside Firing Room 4 at Kennedy Space Center’s Launch Control Center for the overnight countdown. SpaceX will begin loading super-chilled, densified kerosene and liquid oxygen propellants into the Falcon 9 vehicle at T-minus 35 minutes.
Helium pressurant will also flow into the rocket in the last half-hour of the countdown. In the final seven minutes before liftoff, the Falcon 9’s Merlin main engines will be thermally conditioned for flight through a procedure known as “chilldown.” The Falcon 9’s guidance and range safety systems will also configured for launch.
After liftoff, the Falcon 9 rocket will vector its 1.7 million pounds of thrust — produced by nine Merlin engines — to steer southeast over the Atlantic Ocean. SpaceX has resumed launches this winter using the southeasterly corridor from Cape Canaveral, rather than trajectories to the northeast, to take advantage of better sea conditions for landing of the Falcon 9’s first stage booster.
Throughout the summer and fall, SpaceX launched Starlink missions on paths toward the northeast from Florida’s Space Coast.
The Falcon 9 rocket will exceed the speed of sound in about one minute, then shut down its nine main engines two-and-a-half minutes after liftoff. The booster stage will separate from the Falcon 9’s upper stage, then fire pulses from cold gas control thrusters and extend titanium grid fins to help steer the vehicle back into the atmosphere.
Two braking burns will slow the rocket for landing on the drone ship “A Shortfall of Gravitas” around 410 miles (660 kilometers) downrange approximately nine minutes after liftoff. The reusable booster, designated B1069 in SpaceX’s inventory, will launch and land for the fifth time in its career Thursday.
The Falcon 9’s reusable payload fairing will jettison during the second stage burn. A recovery ship is also on station in the Atlantic to retrieve the two halves of the nose cone after they splash down under parachutes.
Landing of the first stage on Thursday’s mission will occur just as the Falcon 9’s second stage engine cut off to deliver the Starlink satellites into orbit.
Separation of the 53 Starlink spacecraft, built by SpaceX in Redmond, Washington, from the Falcon 9 rocket is expected around 64 minutes after liftoff.
The Falcon 9’s guidance computer aims to deploy the satellites into a near-circular orbit at an inclination of 43 degrees to the equator, with an altitude ranging between 202 miles and 213 miles (325-by-343 kilometers). After separating from the rocket, the 53 Starlink spacecraft will unfurl solar arrays and run through automated activation steps, then use ion engines to maneuver into their operational orbit.
ROCKET: Falcon 9 (B1069.5)
PAYLOAD: 53 Starlink satellites (Starlink 5-3)
LAUNCH SITE: LC-39A, Kennedy Space Center, Florida
LAUNCH DATE: Feb. 2, 2023
LAUNCH TIME: 2:58:20 a.m. EST (0758:20 GMT)
WEATHER FORECAST: Greater than 90% chance of acceptable weather; Low to moderate risk of upper level winds; Low risk of unfavorable conditions for booster recovery
BOOSTER RECOVERY: “A Shortfall of Gravitas” drone ship northeast of the Bahamas
LAUNCH AZIMUTH: Southeast
TARGET ORBIT: 202 miles by 213 miles (325 kilometers by 343 kilometers), 43.0 degrees inclination
LAUNCH TIMELINE:
- T+00:00: Liftoff
- T+01:12: Maximum aerodynamic pressure (Max-Q)
- T+02:28: First stage main engine cutoff (MECO)
- T+02:31: Stage separation
- T+02:38: Second stage engine ignition
- T+02:43: Fairing jettison
- T+06:41: First stage entry burn ignition (three engines)
- T+07:00: First stage entry burn cutoff
- T+08:23: First stage landing burn ignition (one engine)
- T+08:35: Second stage engine cutoff (SECO 1)
- T+08:44: First stage landing
- T+1:03:56: Starlink satellite separation
MISSION STATS:
- 201st launch of a Falcon 9 rocket since 2010
- 211th launch of Falcon rocket family since 2006
- 5th launch of Falcon 9 booster B1069
- 172nd Falcon 9 launch from Florida’s Space Coast
- 61st SpaceX launch from pad 39A
- 155th launch overall from pad 39A
- 142nd flight of a reused Falcon 9 booster
- 71st Falcon 9 launch primarily dedicated to Starlink network
- 7th Falcon 9 launch of 2023
- 8th launch by SpaceX in 2023
- 6th orbital launch attempt based out of Cape Canaveral in 2023
‘Mysterious flying spiral’ above Hawaii likely caused by SpaceX launch : NPR
A Japanese telescope captured images and video of a flying blue whirlpool shape over Hawaii on Jan. 18.
“The Subaru-Asahi Star Camera captured a mysterious flying spiral over Maunakea, Hawaii” which “seems to be related to the SpaceX company’s launch of a new satellite,” the Subaru Telescope tweeted on Jan. 19.
The telescope is mounted atop Mauna Kea, a dormant volcano in Hawaii, and is operated by The National Astronomical Observatory of Japan.
In the video, the object starts as a small white sphere flying through the night sky. It then widens into a spiral as it travels before fading into a ring shape and disappearing.
According to the telescope’s YouTube channel, a livestream viewer first noticed the event and brought it to staff’s attention. The livestream is jointly run by the telescope and Asahi Shimbun, a Japanese newspaper company.
SpaceX launched a global-positioning satellite into medium orbit at 7:24 a.m. that same day from the Cape Canaveral Space Force Station in Florida. The launch used a Falcon 9 rocket.
This isn’t the first time a SpaceX launch has created a mysterious swirl in the night sky. One was spotted above New Zealand in June on the same day as a Falcon 9 launch from the same Florida location. After another launch in April, the Subaru Telescope captured a similar image above Hawaii.
Space communities online have suggested that the spirals — and other formations, like the “space jellyfish” — occur when rockets vent their leftover fuel. The gas is expelled at a higher pressure than the atmosphere. It is then illuminated by sunlight, creating the shapes we see from down below.
SpaceX and the Subaru Telescope did not immediately respond to requests for comment.
SpaceX launches first flight of cross-country Starlink doubleheader
SpaceX ended January with and will begin February with two Starlink missions. These launches will occur two days apart from separate launch sites.
The first such mission — Starlink Group 2-6 — lifted off from Space Launch Complex 4 East (SLC-4E) at the Vandenberg Space Force Base in California, on Tuesday, Jan. 31 at 8:15 AM PST (16:15 UTC) after a delay from Monday “to allow additional time for pre-launch checkouts.” This will be followed by the Starlink Group 5-3 mission, which will launch from the historic Launch Complex 39A (LC-39A) at the Kennedy Space Center in Florida, which is currently scheduled for Thursday, Feb. 2 at 2:37 AM EST (07:37 UTC).
These two missions will serve as the sixth and seventh Falcon 9 launches of the year, and the seventh and eighth overall launches for SpaceX in 2023. Both flights will utilize flight-proven Falcon 9 boosters and feature booster recovery attempts.
Starlink Group 2-6 from Vandenberg used Falcon core B1071-7, which previously supported the launches of two missions for the United States National Reconnaissance Office (NROL-87 and NROL-85), SARah-1 for Airbus, SWOT for NASA and CNES, and two other Starlink flights. Following its launch on Tuesday morning, the first stage landed on the autonomous spaceport drone ship (ASDS) Of Course I Still Love You, stationed approximately 647 km downrange in the Pacific Ocean. The ship NRC Quest was also in position to retrieve the fairing halves for reuse.
Starlink Group 5-3 from Kennedy Space Center will utilize Falcon booster B1069-5, which has launched the CRS-24, Starlink Group 4-23, Hotbird-13F, and OneWeb #15 missions. ASDS A Shortfall of Gravitas will be on hand for first-stage recovery at an approximate downrange distance of 665 km within the Atlantic Ocean.
The launch from California — Group 2-6 — will see the deployment of 49 Starlink satellites into an orbit inclined 70 degrees with respect to the equator, at a final altitude of 570 km. The initial parking orbit was 327 km by 339 km, with Falcon 9 flying a south-southeastern trajectory.
The 570 km final orbit corresponds to the Starlink constellation’s “second shell”: an eventual grouping of 720 spacecraft spread across 36 planes, with 20 spacecraft per plane. Tuesday’s launch was only the third launch to target this second shell, as the Group 2-2, 2-3, and 2-5 missions have yet to launch. The first launch to Shell 2, Group 2-1, was deployed in September 2021.
Rendering of an ION Satellite Carrier vehicle in the midst of deploying CubeSats into low Earth orbit. (Credit: D-Orbit)
The Starlink spacecraft was not alone in the fairing for the Group 2-6 mission. An ION Satellite Carrier orbital transfer vehicle (SCV009 Eclectic Elena), developed and operated by the Italian company D-Orbit, served as a rideshare payload on Tuesday’s flight.
The ION Satellite Carrier platform features a customizable dispenser capable of hosting a combination of CubeSats of varying sizes. Throughout a mission, the vehicle can release its payloads individually, changing orbital parameters between one deployment event and the next. This adds a level of flexibility for missions that cannot be served by standard rideshare launches.
Following the launch of Starlink Group 2-6, SpaceX turns its attention to the East Coast for the launch of the Group 5-3 mission. It is expected that this mission will deploy a batch of Starlink satellites into an orbit with an inclination of 43 degrees. This means that Falcon 9 will head on a southeastern trajectory out of Florida — a common practice in the winter months as rougher seas to the north tend to complicate recovery efforts.
The satellites themselves are expected to be similar to the version 1.5 satellites that have been launched in the past few years.
A typical Starlink mission begins with the liftoff of Falcon 9 from its launchpad. The first stage’s nine Merlin 1D engines begin their ignition sequence at the T-3 second mark in the countdown, allowing them to achieve maximum thrust and pass final checks before committing to launch.
A previous mission, Starlink Group 4-37, lifts off from LC-39A in December 2022. (Credit: Julia Bergeron for NSF)
After liftoff, Falcon 9 climbs away from the launch site, pitching downrange as it maneuvers along its pre-programmed trajectory. Approximately 72 seconds into the flight, the vehicle passes through Max-Q — the point of maximum dynamic pressure, where mechanical stresses on the rocket are the greatest.
The nine first-stage engines continue to power Falcon 9 for the first two minutes and 27 seconds of the mission, until the time of main engine cutoff (MECO), at which point all nine engines shut down near-simultaneously. Stage separation normally occurs four seconds later, with the ignition of the second stage’s Merlin Vacuum engine coming about seven seconds after staging.
While the second stage continues onward to orbit with its payload, the first stage coasts upward to apogee — the highest point of its trajectory — before beginning its trip back to Earth. The booster refines its course toward the landing zone before attempting to softly touch down on the deck of one of SpaceX’s three drone ships. Using a drone ship for booster recovery allows SpaceX to launch a more massive payload on Falcon 9 than it would be able to on a return-to-launch-site mission.
In the meantime, the second stage carries on with the primary mission. After stage separation and Merlin Vacuum engine ignition, the payload fairing halves are jettisoned, thereby exposing the satellites to space. Much akin to the Falcon 9 first stage, the fairing halves can be recovered and reused, using a system of thrusters and parachutes to make a controlled descent into the ocean where they will be picked up by a recovery vessel.
Second-stage engine cutoff (SECO-1) typically takes place just over eight and a half minutes into the flight. Other engine burns to modify the deployment orbit will follow if the mission requires it, such as on Group 2-6 which used a second burn before deploying SCV009 Eclectic Elena and the Starlink satellites.
The Starlink satellites are deployed into a low orbit so any faulty or non-functional spacecraft will quickly re-enter the atmosphere and be destroyed. Working satellites will raise themselves into a more stable orbit, where they will undergo checkouts before heading to their final operational orbits.
After spacecraft separation, the second stage will perform a deorbit burn for proper disposal, ensuring that reentry takes place over the ocean.
The Starship vehicle and Super Heavy booster, undergoing a Wet Dress Rehearsal fueling test at Starbase. (Credit: SpaceX)
With two successful launches, Falcon 9 will reach a total of 200 orbital flights, with a launch success rate of 99%. These flights form part of a fast start to the year for SpaceX, which, according to CEO Elon Musk, is aiming for the ambitious goal of achieving up to 100 orbital launches in 2023. This would exceed its current record of 61 launches within a calendar year, set in 2022.
In addition to Falcon 9 and Falcon Heavy, SpaceX hopes to introduce Starship into its orbital catalog, starting this year with the first test flight of the full stack (the Starship vehicle and its Super Heavy booster). At this time, Starship is still undergoing readiness tests at the company’s Starbase testing and production facility in South Texas, with a launch date yet to be formally announced.
(Lead image: Falcon 9 lifts off from SLC-4E on the Starlink Group 2-6 mission. Credit: SpaceX)
Mysterious moving spiral appears among stars above Hawaii
A mysterious spiral formation was spotted in the night sky above Hawaii earlier this month, sparking curiosity among observers.
The spectacle, initially spotted by an observatory in Mauna Kea on Jan. 18, first looked like a traveling bright star before it morphed shapes.
It grew into a larger blob before it transformed into a dot with a spinning spiral around it, footage from the Subaru-Asahi STAR Camera shows.
The night sky whirlpool, however, is not a UFO or spaceship — but reportedly the work of billionaire Elon Musk.
The rare sighting is believed to be connected to the launch of a satellite by Musk’s Space X.
Subaru Telescope, one of the camera operators, said it believes the dazzling phenomenon is related to the satellite’s orbital deployment operation.
Defunct Satellite and Rocket Stage Nearly Collide in Potential ‘Worst-Case Scenario’
An old rocket body and military satellite—large pieces of space junk dating back to the Soviet Union—nearly smashed into each other on Friday morning, in an uncomfortable near-miss that would’ve resulted in thousands of pieces of debris had they collided.
LeoLabs, a private company that tracks satellites and derelict objects in low Earth orbit, spotted the near-collision in radar data. The company, which can track objects as tiny as 3.9 inches (10 centimeters) in diameter, operates three radar stations, two in the U.S. and one in New Zealand.
The two objects whizzed past each other at an altitude of 611 miles (984 kilometers) on the morning of Friday, January 27. LeoLabs “computed a miss distance of only 6 meters [20 feet] with an error margin of only a few tens of meters,” the company said in a tweet.
That is unbelievably close, as Harvard-Smithsonian astrophysicist Jonathan McDowell conveyed in a graphic posted to Twitter. The SL-8 rocket body (NORAD ID 16511), specifically its second stage, has been in space since 1986, while the Cosmos 2361 military satellite (NORAD ID 25590), known as Parus, launched to low Earth orbit in 1998. A collision between the two objects would have produced thousands of new debris fragments that would have lingered in Earth orbit for decades.
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The conjunction happened in an orbital “bad neighborhood” located between 590 and 652 miles (950 and 1,050 km) above the surface, according to LeoLabs. This band has “significant debris-generating potential” in low Earth orbit “due to a mix of breakup events and abandoned derelict objects,” the company explained in a series of tweets. The so-called bad neighborhood hosts around 160 SL-8 rocket bodies along with their roughly 160 payloads launched decades ago. LeoLabs says around 1,400 conjunctions involving these rocket bodies were chronicled between June and September 2022.
LeoLabs describes this type of potential collision between “two massive derelict objects” as a “worst-case scenario,” saying it would be “largely out of our control and would likely result in a ripple effect of dangerous collisional encounters.” Indeed, a collision on this scale would most certainly accelerate the ongoing Kessler Syndrome—the steady accumulation of space debris that threatens to make portions of Earth orbit inaccessible.
Related story: What to Know About Kessler Syndrome, the Ultimate Space Disaster
Near-misses in space are becoming increasingly common, whether it’s conjunctions between defunct satellites or clouds of debris that threaten the International Space Station. Avoidance maneuvers are now a steady fixture for satellite operators, with SpaceX, as an extreme example, having to perform over 26,000 collision avoidance maneuvers of its Starlink satellites from December 1, 2020 to November 30, 2022.
In addition to focusing on collision avoidance, LeoLabs recommends the implementation of debris mitigation and debris remediation efforts. This could take the form of sensible guidelines having to do with the removal of satellites once they’re been retired, as well as the introduction of debris removal technologies.
More: The FCC Wants a 5-Year Deadline to Deorbit Defunct Satellites
SpaceX Falcon 9 rockets set for Starlink double-header
A pair of SpaceX Falcon 9 rockets are on track to round out the first month of 2023 and kick off the second with a Starlink double-header.
“To complete pre-launch checkouts,” SpaceX delayed its last launch of the month by 24 hours. The first Falcon 9 rocket will launch Starlink 2-6 and a D-Orbit rideshare payload no earlier than 8:29 am PST (16:29 UTC) on Monday, January 30th. The mission will lift off from SpaceX’s Vandenberg Space Force Base (VSFB) SLC-4E pad and head southeast, skirting the California and Mexico coast. In case of bad weather or a minor technical issue, a backup window is available at 12:31 pm PST.
As few as 35.5 or 39.5 hours later, a second Falcon 9 rocket will lift off from SpaceX’s Florida-based NASA Kennedy Space Center LC-39A pad around 3:02 am EST on Tuesday, February 1st.
Starlink 2-6
Kicking off the pair, Starlink 2-6 will be SpaceX’s ninth Starlink rideshare mission since the company began manifesting third-party payloads on its internet satellite launches in June 2020. Falcon 9 will launch the mission’s main payload – a batch of 49 Starlink V1.5 satellites – to a semi-polar orbit that will see them cross Earth’s equator at an angle of 70 degrees. Ordinarily, the mission would carry 51 Starlinks, but SpaceX has removed a pair of satellites to make room for Italian space logistics company D-Orbit’s ION SCV009 spacecraft.
ION weighs around 160 kilograms (350 lb) on its own and is roughly the size of a large oven. D-Orbit designed the spacecraft to host fixed payloads and deploy rideshare satellites in orbit. It also has a propulsion system that allows it to provide “last-mile delivery services,” offering rideshare customers the ability to tweak the orbit their satellite ends up in. Space tugs like ION aim to give satellite owners some of the benefits of a dedicated rocket launch (custom orbit selection in particular) while retaining most of the cost savings rideshare launches enable.
After reaching orbit, Falcon 9 will deploy ION first, use thrusters to spin itself end over end, and then release all 49 Starlink satellites simultaneously. The spinning stage’s centrifugal force causes the satellite stack to naturally spread out within several hours. The satellites then use reaction wheels to stabilize their orientation, deploy solar panels to begin charging their batteries, and eventually use ion thrusters to climb to operational orbits.
ION SCV009 will attempt to test a new satellite separation system built by EBAD and demonstrate its ability to operate in very low Earth orbit (VLEO). The spacecraft will potentially lower itself to an altitude of 270 kilometers (170 mi).
Starlink 5-3
Starlink 5-3 will carry no rideshare payloads and will likely be nearly identical to Starlink 5-2, which SpaceX successfully launched on January 26th. The latest mission’s stack of 56 Starlink V1.5 satellites weighed 17.4 tons and was the heaviest payload SpaceX has ever launched. Starlink 5-3 is targeting the same orbit and will likely also carry 56 satellites.
Pad 39A last supported SpaceX’s fifth Falcon Heavy launch on January 15th and has been quickly converted back to its single-core Falcon 9 configuration for Starlink 5-3. After the Starlink mission, Pad 39A has at least two Dragon spacecraft launches scheduled before SpaceX will need to convert it back to a triple-booster configuration for Falcon Heavy’s sixth launch.
SpaceX is scheduled to launch Crew Dragon’s Crew-6 astronaut transport mission no earlier than February 26th, and Cargo Dragon’s Spx-27 cargo delivery mission on March 11th. Falcon Heavy is scheduled to launch the giant ViaSat-3 communications satellite no earlier than March 24th.
Tune in below around 8:25 am PST (16:25 UTC) to watch SpaceX Starlink 2-6 launch live.
