We have observed a certain number of spacecraft and rocket stages #explosions in orbit. Working on simulations and testing of #fragmentation events, we were asking ourselves the following question: how #debris #clouds could be affected by the object attitude before the event? Here you can find the published paper on #CEAS #Space Journal, with a few preliminary answers to this question: https://lnkd.in/dm-rXuVS A great thank you to my co-authors Cinzia Giacomuzzo and Alessandro Francesconi. Dipartimento di Ingegneria Industriale - DII UNIPD Università degli Studi di Padova Agenzia Spaziale Italiana European Space Agency - ESA
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"Top 62 Women in Aviation & Aerospace to follow on Linkedin" Disruption DeepTech NewSpace NewSpaceEconomy Web3 RWAs Crypto Blockchain Digital SustainableWorld - Only for information , No trading & No investment advice
"Asteroid prospecting company AstroForge has been awarded the first-ever commercial license for operating and communicating with a spacecraft in deep space, ahead of its Odin mission that's set to launch and rendezvous with a near-Earth asteroid in early 2025. The license, granted by the U.S. FCC on Oct. 18, pertains specifically to setting up a communication network with radio ground stations on Earth, to enable commands to be sent up to Odin and data to be transmitted back to Earth. In this case, deep space is defined by the International Telecommunications Union as being farther than 2 million kilometers (1.2 million miles) from Earth. AstroForge's ultimate aim is to send a spacecraft to an asteroid, land on it and use an onboard refinery to mine the asteroid for precious metals. But the technology is still very much at the proof-of-concept stage. The company's first space mission, Brokkr-1, was a cubesat that launched in April 2023 and successfully reached Earth orbit. However, AstroForge mission control was unable to successfully activate the prototype refinery technology on board to demonstrate that it works in microgravity. Despite this mishap, AstroForge said on its website that the Brokkr-1 mission had been "invaluable … identifying weaknesses to resolve for our upcoming Mission 2 and providing our team with the experience of a flight campaign from concept design to on-orbit operations and all the steps in between to build, qualify and certify a vehicle for space." Odin is the company's second space mission. Despite winning the commercial license, it hasn't all been plain sailing for the new effort. In March, the original Odin spacecraft failed a vibration test, meaning that it would be vulnerable to damage during launch. The problem, said AstroForge, was that the spacecraft's baseplate, to which propulsion tanks and thrusters are attached, contained cracks resulting from its manufacture by a third party. This forced AstroForge to make the difficult decision to dump the original Odin spacecraft and accelerate in-house development on the spacecraft for its third mission, Vestri, to be used for Odin instead." Space com Asteroid-mining company AstroForge gets 1st-ever FCC license for commercial deep-space mission
Asteroid-mining company AstroForge gets 1st-ever FCC license for commercial deep-space mission
space.com
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🌌 𝗘𝗰𝗹𝗶𝗽𝘀𝗲-𝗠𝗮𝗸𝗶𝗻𝗴 𝗠𝗶𝘀𝘀𝗶𝗼𝗻 Ready for Launch on 𝗗𝗲𝗰𝗲𝗺𝗯𝗲𝗿 𝟰𝘁𝗵 ESA’s 𝗣𝗿𝗼𝗯𝗮-𝟯, the latest in its experimental series, is set to launch on 𝗗𝗲𝗰𝗲𝗺𝗯𝗲𝗿 𝟰, 𝟮𝟬𝟮𝟰, from India’s Satish Dhawan Space Centre aboard an 𝗜𝗦𝗥𝗢 𝗣𝗦𝗟𝗩-𝗫𝗟 𝗿𝗼𝗰𝗸𝗲𝘁. This mission will showcase groundbreaking formation flying and solar science technology. 🛰️ 𝗧𝗵𝗲 𝗠𝗶𝘀𝘀𝗶𝗼𝗻’𝘀 𝗖𝗼𝗿𝗲 𝗜𝗻𝗻𝗼𝘃𝗮𝘁𝗶𝗼𝗻: Proba-3 consists of 𝘁𝘄𝗼 𝘀𝗽𝗮𝗰𝗲𝗰𝗿𝗮𝗳𝘁 𝗼𝗽𝗲𝗿𝗮𝘁𝗶𝗻𝗴 in tandem to perform precise formation flying, maintaining millimeter-level accuracy. They will align 150 meters apart to simulate total solar eclipses, allowing the Coronagraph spacecraft to study the Sun’s faint corona, a million times dimmer than the Sun itself. This artificial eclipse capability is unprecedented, enabling 𝘀𝗶𝘅-𝗵𝗼𝘂𝗿-𝗹𝗼𝗻𝗴 observations per orbit at distances as close as 1.1 solar radii. By removing the need for ground-based eclipse expeditions, Proba-3 promises unparalleled solar data collection. 💻 𝗕𝗲𝘆𝗼𝗻𝗱 𝗘𝗰𝗹𝗶𝗽𝘀𝗲-𝗠𝗮𝗸𝗶𝗻𝗴: Proba-3 will also experiment with 𝗶𝗻𝗻𝗼𝘃𝗮𝘁𝗶𝘃𝗲 𝗼𝗿𝗯𝗶𝘁𝗮𝗹 𝗼𝗽𝗲𝗿𝗮𝘁𝗶𝗼𝗻𝘀. These include rendezvous techniques, distance resizing, and multi-platform instrument sharing, demonstrating the potential for modular spacecraft collaboration. 🌑 𝗢𝗿𝗯𝗶𝘁 𝗗𝗲𝘁𝗮𝗶𝗹𝘀: Proba-3 will enter a highly elliptical orbit extending over 𝟲𝟬,𝟬𝟬𝟬 𝗸𝗺, minimizing gravitational perturbations and reducing fuel requirements for formation maneuvers. This mission continues European Space Agency - ESA’s Proba legacy, pushing the boundaries of space engineering and science. #SpaceExploration #ESA #SolarScience #SpaceInnovation #OrionNews
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Manufacturing Lead Safety-Focused Manufacturing Professional| EHS Compliance, KPI Performance & Process Optimization Manufacturing & Environmental Expert | Production Management, EHS Compliance & Continuous Improvement,
India’s first solar mission, the Aditya-L1 spacecraft completed its first halo orbit around the Sun-Earth L1 point. The Aditya-L1 mission was launched on September 2, 2023 using PSLV-C57 and was inserted in its targeted halo orbit on January 6, 2024. Aditya-L1 is an Indian solar observatory at Lagrangian point L1. According to ISRO, Aditya-L1 spacecraft in the halo orbit takes 178 days to complete a revolution around the L1 point. During its travel in the halo orbit, Aditya-L1 spacecraft will be subjected to various perturbing forces that will cause it to depart from the targeted orbit, the space agency said. The major science objectives of Aditya-L1 mission are: (i) Study of Solar upper atmospheric (chromosphere and corona) dynamics. (ii) Study of chromospheric and coronal heating, physics of the partially ionized plasma, initiation of the coronal mass ejections, and flares (iii) Observe the in-situ particle and plasma environment providing data for the study of particle dynamics from the Sun. (iv) Physics of solar corona and its heating mechanism. (v) Diagnostics of the coronal and coronal loops plasma: Temperature, velocity and density. (vi) Development, dynamics and origin of CMEs. (vii) Identify the sequence of processes that occur at multiple layers (chromosphere, base and extended corona) which eventually leads to solar eruptive events. (viii) Magnetic field topology and magnetic field measurements in the solar corona. Hence, statement 3 is not correct. (ix) Drivers for space weather (origin, composition and dynamics of solar wind.
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| Materials Associate at Infinita Lab Inc.| Ex-Corrosion Intel | Co-founder & COO at GreeNext Materials | IIT B | PSCL | IIT P | UCER | UP Sainik School |
Elevating Space Exploration: The Crucial Role of Material Testing 🌌 As we venture further into the #cosmos, the reliability and safety of our spacecraft become paramount. Discover how Infinita Lab is revolutionizing the future of space travel through advanced material testing. From SpaceX’s groundbreaking Falcon 9 #rocket to the surge in #satellite deployments for global connectivity, the #space industry is experiencing unprecedented growth. But behind every successful mission lies the rigorous process of #material testing—ensuring durability, safety, and mission success under extreme conditions. #materialstesting #materialscience #researchanddevelopment #scienceandtechnology #researchers #scientists #aerospace #mechanical #nano #spacetravel https://lnkd.in/gq_fe2yM
How Material Testing Shapes the Future of Space Travel
infinitalab.medium.com
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Director of Sales - EMEA at LeoLabs • Pushing the boundaries of SSA & SDA in LEO • Augmenting Sovereignty
Events like this happen much more frequently than you can imagine. We monitor over 20,000 objects in LEO using our 10 phased array radars worldwide. We can identify and update the orbital trajectories of all of these objects several times a day. We update each conjunction event with the latest information within minutes. Time, coverage, and accuracy are essential for space safety, security and sustainability.
At approximately 06:30 UTC today (Wed, 28 Feb) we observed a close conjunction at 608 km between two non-maneuverable spacecraft: a derelict Russian satellite called COSMOS 2221 and an operational NASA satellite called TIMED. The miss distance was less than 20 m with a probability of collision (PC) of 3% to 8% at the time of closest approach (TCA). Why does this event matter? This event is notable because it is rare. In the last two years, there have been only six other events with a miss distance of less than 20 m between two intact, non-maneuverable objects. In addition, the resulting debris would have created an increased collision risk on nearby lower orbits used by large constellations and human spaceflight. Our analysis indicates that a collision between these two objects would have resulted in approximately 2,000 to 7,000 cataloged fragments. This number is derived from analyzing the total mass, spacecraft construction, relative velocity, and encounter geometry. There are nearly 12,000 fragments in LEO as of 15 Feb. This one incident could have added 50% more debris. The combined mass of COSMOS 2221 and TIMED is 2,530 kg. The relative velocity at TCA was ~14 km/s, well above the six km/s threshold for a hypervelocity event. If the two objects hit center-of-mass on center-of-mass, it could have created up to three times the objects’ combined mass (i.e., ~7,500 fragments). However, this was highly unlikely. The most likely event was that one of the object's solar arrays would clip the other object’s main body. In that case, one object would have been destroyed and the other would have been damaged. For instance, if TIMED clipped COSMOS 2221, the total fragment count could have been approximately 2,500. The PC for this event was consistently high for several days. Due to this, our team initiated full response mode and we obtained more than 25 updates on both objects 24 hours prior to TCA thanks to our global sensor network. How can this be prevented? This event and our continuous analysis illustrate the importance of frequent, high-quality measurements from LeoLabs’ global network of independent radars. These radars are linked through a computational engine that runs on cloud services, delivering data and alerts within minutes. This is critical to maintain a 24/7, comprehensive view of objects and activities in LEO. Events like this illustrate the critical need for collision avoidance but also debris mitigation and debris remediation to combat the growing risk from derelict objects in LEO. Active debris removal missions, like Astroscale’s ADRAS-J launched on 20 Feb, are promising steps in the right direction. A single collision in LEO could impact thousands of other satellites for decades. That’s why we must continue to work collaboratively and strategically to ensure this domain remains safe and secure for generations to come.
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Ahead of tomorrow's launch of the two European Proba-3 satellites, developed by European Space Agency - ESA with 🇧🇪 involvement, here are some key points to know! 🛰️ “Proba” stands for Project for On-Board Autonomy. What will the Proba-3 mission do? • Execute very precise formation flights with two satellites • Study the Sun’s Corona ☀️ Why should we study the Sun’s Corona? It is crucial for understanding how our Sun works and will help us better understand the formation of Solar Winds or Solar Weather which affect our safety on Earth. The ability ro better predict “Space Weather” will allow us to better protect electricity grids, telefommunication accuracy, navigation, and technologies and astronauts in space from violent flare-ups that disrupt Earth’s magnetosphere. ISRO - Indian Space Research Organization | BELSPO | Redwire Space | Redwire Space Europe | SPACEBEL | European Space Security and Education Centre (Redu) | Centre Spatial de Liège | OIP Space Instruments | Université catholique de Louvain | Royal Belgian Institute for Space Aeronomy | Royal Observatory of Belgium | Frank Preud'homme | Andrei Zhukov 🎥 Tune in at 11:00 AM tomorrow and watch the launch LIVE: https://lnkd.in/exEuGEg2
Watch eclipse-making Proba-3 launch
esa.int
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A must read.... a careful must read! We not only have just one Earth, we only have one Low-Earth-Orbit! That is a global commons that has to be protected.
At approximately 06:30 UTC today (Wed, 28 Feb) we observed a close conjunction at 608 km between two non-maneuverable spacecraft: a derelict Russian satellite called COSMOS 2221 and an operational NASA satellite called TIMED. The miss distance was less than 20 m with a probability of collision (PC) of 3% to 8% at the time of closest approach (TCA). Why does this event matter? This event is notable because it is rare. In the last two years, there have been only six other events with a miss distance of less than 20 m between two intact, non-maneuverable objects. In addition, the resulting debris would have created an increased collision risk on nearby lower orbits used by large constellations and human spaceflight. Our analysis indicates that a collision between these two objects would have resulted in approximately 2,000 to 7,000 cataloged fragments. This number is derived from analyzing the total mass, spacecraft construction, relative velocity, and encounter geometry. There are nearly 12,000 fragments in LEO as of 15 Feb. This one incident could have added 50% more debris. The combined mass of COSMOS 2221 and TIMED is 2,530 kg. The relative velocity at TCA was ~14 km/s, well above the six km/s threshold for a hypervelocity event. If the two objects hit center-of-mass on center-of-mass, it could have created up to three times the objects’ combined mass (i.e., ~7,500 fragments). However, this was highly unlikely. The most likely event was that one of the object's solar arrays would clip the other object’s main body. In that case, one object would have been destroyed and the other would have been damaged. For instance, if TIMED clipped COSMOS 2221, the total fragment count could have been approximately 2,500. The PC for this event was consistently high for several days. Due to this, our team initiated full response mode and we obtained more than 25 updates on both objects 24 hours prior to TCA thanks to our global sensor network. How can this be prevented? This event and our continuous analysis illustrate the importance of frequent, high-quality measurements from LeoLabs’ global network of independent radars. These radars are linked through a computational engine that runs on cloud services, delivering data and alerts within minutes. This is critical to maintain a 24/7, comprehensive view of objects and activities in LEO. Events like this illustrate the critical need for collision avoidance but also debris mitigation and debris remediation to combat the growing risk from derelict objects in LEO. Active debris removal missions, like Astroscale’s ADRAS-J launched on 20 Feb, are promising steps in the right direction. A single collision in LEO could impact thousands of other satellites for decades. That’s why we must continue to work collaboratively and strategically to ensure this domain remains safe and secure for generations to come.
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Knowledge is power, but only with optionality. Despite all our resources and technology, those managing orbital risks were effectively powerless to prevent a collision. With ~3 of these a year at ~5% probability of SHTF, we can expect a Kessler incident within 10 years. Or we can get our sh*t together, repurpose a small portion of private + public sector assets and secure our future in space.
At approximately 06:30 UTC today (Wed, 28 Feb) we observed a close conjunction at 608 km between two non-maneuverable spacecraft: a derelict Russian satellite called COSMOS 2221 and an operational NASA satellite called TIMED. The miss distance was less than 20 m with a probability of collision (PC) of 3% to 8% at the time of closest approach (TCA). Why does this event matter? This event is notable because it is rare. In the last two years, there have been only six other events with a miss distance of less than 20 m between two intact, non-maneuverable objects. In addition, the resulting debris would have created an increased collision risk on nearby lower orbits used by large constellations and human spaceflight. Our analysis indicates that a collision between these two objects would have resulted in approximately 2,000 to 7,000 cataloged fragments. This number is derived from analyzing the total mass, spacecraft construction, relative velocity, and encounter geometry. There are nearly 12,000 fragments in LEO as of 15 Feb. This one incident could have added 50% more debris. The combined mass of COSMOS 2221 and TIMED is 2,530 kg. The relative velocity at TCA was ~14 km/s, well above the six km/s threshold for a hypervelocity event. If the two objects hit center-of-mass on center-of-mass, it could have created up to three times the objects’ combined mass (i.e., ~7,500 fragments). However, this was highly unlikely. The most likely event was that one of the object's solar arrays would clip the other object’s main body. In that case, one object would have been destroyed and the other would have been damaged. For instance, if TIMED clipped COSMOS 2221, the total fragment count could have been approximately 2,500. The PC for this event was consistently high for several days. Due to this, our team initiated full response mode and we obtained more than 25 updates on both objects 24 hours prior to TCA thanks to our global sensor network. How can this be prevented? This event and our continuous analysis illustrate the importance of frequent, high-quality measurements from LeoLabs’ global network of independent radars. These radars are linked through a computational engine that runs on cloud services, delivering data and alerts within minutes. This is critical to maintain a 24/7, comprehensive view of objects and activities in LEO. Events like this illustrate the critical need for collision avoidance but also debris mitigation and debris remediation to combat the growing risk from derelict objects in LEO. Active debris removal missions, like Astroscale’s ADRAS-J launched on 20 Feb, are promising steps in the right direction. A single collision in LEO could impact thousands of other satellites for decades. That’s why we must continue to work collaboratively and strategically to ensure this domain remains safe and secure for generations to come.
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Associate Professor at Stanford University; Founding Director of Space Rendezvous Lab (SLAB) and Center for AEroSpace Autonomy Research (CAESAR)
This might be an unpopular post! I am not so impressed by the capabilities claimed and shown so far by #commercialspace in the area of spacecraft autonomy, rendezvous proximity operations and capture/docking. Low cost distributed space missions employing #SmallSats and #CubeSats I worked on in the past, such as #PRISMA and #BIROS, have gone #above and #beyond what's being demonstrated today (check our #publications here: https://lnkd.in/gs3ReFga). We need #progress. I am looking forward to see either completely #new capabilities or at least an #enhancement with respect to the state of the art or the state of practice. An example of what we should strive for is given by the #NASA #Starling mission. Kudos to the #NASA #SmallSpacecraftTechnologyProgram (Roger Hunter) for the vision and pursuit. It gave us the possibility to validate a new distributed optical navigation system through the Starling Formation-Flying Optical Experiment (StarFOX): https://lnkd.in/gq28gXcr https://lnkd.in/dhFVuYyM Imagine scaling this capability to #constellations, to #autonomous #spacebased #situational #awareness, that's our next mission, #boundless opportunities ahead. https://lnkd.in/daQ98Zij
Swarming for Success: Starling Completes Primary Mission
https://www.nasa.gov
