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Rocket Lab will try to recover the booster of its Electron rocket for the first time on its next launch

Rocket Lab is set to complete a crucial test for its rocket reusability program during its next mission, which is currently set to take place sometime in mid-November, with a launch widow that opens on November 16. This is a bit of a surprise, because the launch company said that it would be doing this on its 17th flight, and the next launch is actually its 16th, but the company had a succinct answer for why it moved up the timetable.

I know we said flight 17 for recovery but… pic.twitter.com/N3HDdCwPFD

— Rocket Lab (@RocketLab) November 5, 2020

This isn’t the first test Rocket Lab has performed in pursuit of reusability — after announcing in August 2019 its intent to recover and refly the Electron booster, something Rocket Lab founder and CEO Peter Beck originally said wasn’t in the cards for the company, Rocket Lab has tested reentry guidance and control systems, as well as the parachute to be used to slow the booster’s descent once it’s back in Earth’s atmosphere.

In a video released today, Beck explained the reasoning behind even attempting to recover the boosters (essentially to increase the company’s rate of production by eliminating the need to build a new booster for every flight) and also the reasons why it wasn’t in the original plan (the Electron is too small to allow for an engine-powered boost back like the ones Falcon 9 and Blue Origin’s New Shepard uses).

But Beck and team realized they could use an unconventional approach that involves flipping the rocket around and angling it such that it survives reentry, paired with a drogue parachute deployment and primary parachute combo that slows it enough that a helicopter can catch it midair as it drifts. This recovery attempt won’t include that midflight snag, but will instead hopefully see the booster land itself gently enough on the ocean’s surface, slowed by the chute, allowing a recovery team to pick it up.

Beck says that the helicopter catch part is actually not his biggest concern, since the company has previously demonstrated that part of its approach works in practice. Instead, it’s ensuring that they’re just able to actually get the stage after it deploys its orbital cargo to begin with.

If Rocket Lab can recover this first stage, that will put it well-within striking distance of putting an operational recovery system in place, hopefully leading to less time between launches and potentially lower operational costs down the line.

No matter how the launch works out, we’ll get the chance to go over the attempt and next steps with Beck at our inaugural TC Sessions: Space event in December, where he’s joining us on our virtual stage for a fireside chat.

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Microsoft debuts Azure Space to cater to the space industry, partners with SpaceX for Starlink data center broadband

Microsoft is taking its Azure cloud computing platform to the final frontier — space. It now has a dedicated business unit called Azure Space for that purpose, made up of industry heavyweights and engineers who are focused on space-sector services, including simulation of space missions, gathering and interpreting satellite data to provide insights and providing global satellite networking capabilities through new and expanded partnerships.

One of Microsoft’s new partners for Azure Space is SpaceX, the progenitor and major current player in the so-called “New Space” industry. SpaceX will be providing Microsoft with access to its Starlink low-latency satellite-based broadband network for Microsoft’s new Azure Modular Datacenter (MDC) — essentially an on-demand container-based data center unit that can be deployed in remote locations, either to operate on their own or boost local capabilities.

Image Credits: Microsoft

The MDC is a contained unit, and can operate off-grid using its own satellite network connectivity add-on. It’s similar in concept to the company’s work on underwater data centres, but keeping it on the ground obviously opens up more opportunities in terms of locating it where people need it, rather than having to be proximate to an ocean or sea.

The other big part of this announcement focuses on space preparedness via simulation. Microsoft revealed the Azure Orbital Emulator today, which provides in a computer emulated environment the ability to test satellite constellation operations in simulation, using both software and hardware. It’s basically aiming to provide as close to in-space conditions as are possible on the ground in order to get everything ready for coordinating large, interconnected constellations of automated satellites in low Earth orbit, an increasing need as more defense agencies and private companies pursue this approach versus the legacy method of relying on one, two or just a few large geosynchronous spacecraft.

Image Credits: Microsoft

Microsoft says the goal with the Orbital Emulator is to train AI for use on orbital spacecraft before those spacecraft are actually launched — from the early development phase, right up to working with production hardware on the ground before it takes its trip to space. That’s definitely a big potential competitive advantage, because it should help companies spot even more potential problems early on while they’re still relatively easy to fix (not the case on orbit).

This emulated environment for on-orbit mission prep is already in use by Azure Government customers, the company notes. It’s also looking for more partners across government and industry for space-related services, including communication, national security, satellite services including observation and telemetry and more.

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Rocket startup Astra’s first orbital launch attempt ends early due to first-stage burn failure

Alameda-based rocket launch startup Astra finally got the chance to launch its first orbital test mission from its Alaska-based facility on Saturday, after the attempt had been delayed multiple times due to weather and other issues. The 8:19 PM PT lift-off of Astra’s ‘Rocket 3.1’ test vehicle went well – but the flight ended relatively shortly after that, during the first-stage engine burn and long before reaching orbit.

Astra wasn’t expecting to actually reach orbit on this particular flight – it has always said that its goal is to reach orbit within three test flights of Rocket, and prior to this first mission, said that the main goal was to have a good first-stage burn on this one specifically. This wasn’t a nominal first-stage burn, of course, since that’s when the failure occurred, but the company still noted in a blog post that “the rocket performed very well” according to their first reviews of the data.

pic.twitter.com/PGYv26ZqrF

— Jennifer Culton (@CultonJennifer) September 12, 2020

The mission ended early because of what appears to be a bit of unwanted back-and-forth wobbling in the rocket as it ascended, Astra said, which caused an engine shutdown by the vehicle’s automated safety system. That’s actually also good news, since it means the steps Astra has taken to ensure safe failures are also working as designed. You can see in the video above that the light of the rocket’s engines simply go out during flight, and then some time later there’s a fireball from its impact on the ground.

It’s worth noting that most first flights of entirely new rockets don’t go entirely as planned – including those by SpaceX, whose founder and CEO Elon Musk expressed his encouragement to the Astra team on Twitter. Likewise, Rocket Lab’s Peter Beck also chimed in with support. Not to mention that Astra has been operating under extreme conditions, with just a six-person team on the ground in Alaska to deploy the launch system, which was set up in under a week, due to the COVID-19 crisis.

Astra will definitely be able to get a lot of valuable data out of this launch that it can use to put towards improving the chances of its next try going well. The company notes that it expects to review said data “over the next several weeks” as it proceeds towards the second flight in this series of three attempts. Rocket 3.2, the test article for that mission, is already completed and awaiting that try.

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Join us Wednesday, September 9 to watch Techstars Starburst Space Accelerator demo day live

The 2020 class of Techstars Starburst Space Accelerator is graduating with an official demo day on Wednesday at 10 a.m. PDT (1 p.m. EDT), and you can watch all the teams present their startups live via the stream above. This year’s class includes 10 companies building innovative new solutions to challenges either directly or indirectly related to commercial space.

Techstars Starburst is a program with a lot of heavyweight backing from both private industry and public agencies, including from NASA’s JPL, the U.S. Air Force, Lockheed Martin, Maxar Technologies, SAIC, Israel Aerospace Industries North America and The Aerospace Corporation. The program, led by managing director Matt Kozlov, is usually based locally in LA, where much of the space industry has significant presence, but this year the demo day is going online due to the ongoing COVID-19 situation.

Few, if any, programs out there can claim such a broad representation of big-name partners from across commercial, military and general civil space in terms of stakeholders, which is the main reason it manages to attract a range of interesting startups.  This is the second class of graduating startups from the Starburst Space Accelerator; last year’s batch included some exceptional standouts like in-orbit refueling company Orbit Fab (also a TechCrunch Battlefield participant), imaging microsatellite company Pixxel and satellite propulsion company Morpheus.

As for this year’s class, you can check out a full list of all 10 participating companies below. The demo day presentations begin tomorrow, September 9 at 10 a.m. PDT/1 p.m. PDT, so you can check back in here then to watch live as they provide more details about what it is they do.

Bifrost

A synthetic data API that allows AI teams to generate their own custom datasets up to 99% faster — no tedious collection, curation or labelling required.
founders@bifrost.ai

Holos Inc.

A virtual reality content management system that makes it super easy for curriculum designers to create and deploy immersive learning experiences.
founders@holos.io

Infinite Composites Technologies

The most efficient gas storage systems in the universe.
founders@infinitecomposites.com

Lux Semiconductors

Lux is developing next generation System-on-Foil electronics.
founders@luxsemiconductors.com

Natural Intelligence Systems, Inc.

Developer of next-generation pattern-based AI/ML systems.
leadership@naturalintelligence.ai

Prewitt Ridge

Engineering collaboration software for teams building challenging deep tech projects.
founders@prewittridge.com

SATIM

Providing satellite radar-based intelligence for decision makers.
founders@satim.pl

Urban Sky

Developing stratospheric microballoons to capture the freshest, high-res earth observation data.
founders@urbansky.space

vRotors

Real-time remote robotic controls.
founders@vrotors.com

WeavAir

Proactive air insights.
founders@weavair.com

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India’s first Earth-imaging satellite startup raises $5 million; first launch planned for later this year

Bengaluru-based Pixxel is getting ready to launch its first Earth imaging satellite later this year, with a scheduled mission aboard a Soyuz rocket. The roughly one-and-a-half-year-old company is moving quickly, and today it’s announcing a $5 million seed funding round to help it accelerate even more. The funding is led by Blume Ventures, Lightspeed India Partners, and growX ventures, while a number of angel investors participated.

This isn’t Pixxel’s first outside funding: It raised $700,000 in pre-seed money from Techstars and others last year. But this is significantly more capital to invest in the business, and the startup plans to use it to grow its team, and to continue to fund the development of its Earth observation constellation.

The goal is to fully deploy said constellation, which will be made up of 30 satellites, by 2022. Once all of the company’s small satellites are on orbit, the Pixxel network will be able to provide globe-spanning imaging capabilities on a daily basis. The startup claims that its technology will be able to provide data that’s much higher quality when compared to today’s existing Earth-imaging satellites, along with analysis driven by PIxxel’s own deep learning models, which are designed to help identify and even potentially predict large problems and phenomena that can have impact on a global scale.

Pixxel’s technology also relies on very small satellites (basically the size of a beer fridge) that nonetheless provide a very high-quality image at a cadence that even large imaging satellite networks that already exist would have trouble delivering. The startup’s founders, Awais Ahmed and Kshitij Khandelwal, created the company while still in the process of finishing up the last year of their undergraduate studies. The founding team took part in Techstars’ Starburst Space Accelerator last year in LA.

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Rocket startup Skyrora achieves a successful sub-orbital launch from Scottish island

This past weekend was a busy one for rocket launches, including for new launch companies hoping to join the ranks of SpaceX and Rocket Lab as private, operational space launch providers. Edinburgh-based Skyrora achieved a significant milestone for its program, successfully launching its Skylark Nano rocket from an island off the coast of Scotland on Saturday.

Skyrora has been developing its launch system with a goal of devouring affordable transportation for small payloads. The company has flown its Skylark Nano twice previously, including a first launch back in 2018, but this is the first time it has taken off from Shetland, a Scottish site that is among three proposed commercial spaceports to be located in Scotland.

Skylark Nano is a development spacecraft that Skyrora created while it works on its Skylark-L and Skyrora XL orbital commercial launch vehicles. Nano doesn’t reach space — it flies to a height of around 6KM (roughly 20,000 feet) but it does help the company demonstrate its propulsion technologies, and also gather crucial information that helps it in developing its Skylark L suborbital commercial launch craft, as well as Skyrora XL, which will aim to serve customers with orbital payload needs.

Skylark L is currently in development, and Skyrora recently achieved a successful full static test fire of that rocket. The goal is to begin launching commercially from a U.K.-based spaceport as early as 2022.

Skyrora’s approach is also unique because it employs both additive manufacturing (3D printing) in construction of its vehicles and uses a kerosene fuel developed from discarded plastic waste that the company claims produces fewer emissions than traditional rocket fuel.

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Spaceflight Industries to sell its satellite rideshare launch business to Japan’s Mitsui & Co. and Yamasa

Spaceflight Industries, owner of both Spaceflight, Inc. and BlackSky, is selling the Spaceflight, Inc. portion of its business to Japanese industrial megacorporation Mitsui & Co, and Yamasa both of which will co-own the company in a 50/50 joint venture after its closing. The deal will see Spaceflight continue to operate as an independent business based in the U.S. and headquartered in Seattle, with the same mission of providing rideshare launch services for small satellite payloads.

Meanwhile, Spaceflight Industries will use the funds generated from the sale (the terms of the deal were not disclosed) to re-invest in its BlackSky business. BlackSky is an Earth observation company that deals in geospatial intelligence, and that currently operates four satellites in orbit, with eight more planned to join its constellation sometime later this year.

The deal also means that Mistui & Co, which is one of Japan’s largest businesses and which operates in a variety of sectors including infrastructure, energy production, IT, food, consumer products, mining, chemicals and more, will now be in the rocket launch rideshare business as well. Mitsui also has an aerospace arm that includes a space business which provides satellite development, launch and operation services, but noted in a press release that Spaceflight will become “the cornerstone” of its space strategy pending close of the deal.

Spaceflight, Inc. has been offering its services since 2010, and has launched a total of 271 satellites on 29 separate rocket launches, with 10 missions set to take place in 2020 alone. The company’s business seems poised to grow as more launch providers and more small satellite operators enter the market, with many predictions indicating sharp uptakes in orbit-based businesses to come over the next decade.

This arrangement is perhaps indicative of things to come in the space industry, as more young companies look at their overall business and determine how best to delineate things to continue their growth and return funds on investment to stay on mission. SpaceX, for instance, has confirmed it’s looking at spinning out its Starlink business and taking that public, a move that could generate significant funds for it to then funnel back into its core launch business in pursuit of its goals of making humans multi-planetary.

The deal still has to undergo review by the Committee on Foreign Investment in the United States (CFIUS) because there’s a national security interest involved, given Spaceflight’s past work. This is expected to take multiple months, and the companies say they anticipate the deal will close sometime during Q2 2020 if everything is approved.

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SpaceX cautions on launch regulation that outpaces innovation

During the Federal Aviation Administration’s (FAA) 23rd annual Commercial Space Transportation Conference in Washington, D.C., one panel focused on the changing regulatory environment when it comes to private launch activities, and how those are integrated into existing rules and practices for managing commercial air transportation. Panelist Caryn Schenewerk, SpaceX senior counsel and senior director of space flight policy, emphasized that while the company always does the utmost to ensure safety in everything it does, the company also wants to focus on the actual state of the industry today and how it needs to grow as various partners work to establish new rules for the growing commercial launch sector.

“When aviation started, the Wright brothers weren’t flying over major populated cities,” Schenewerk pointed out. “They were outside Paris in an unpopulated field, and they were at Kitty Hawk on unpopulated beaches. And they were in Ohio in unpopulated areas.”

Schenewerk was directly addressing comments made by other panelists, and specifically ALPA Aviation Safety Chair Steve Jangelis, that suggested the emerging commercial launch industries may be looking far ahead to when they’re launching from spaceports located near populated areas, and launching with much more frequency than they are today. In general, Jangelis was advocating for laying the groundwork now for high levels of cooperation and integration between aviation traffic management and rocket launch operators.

Schenewerk was reluctant to concede any kind of direct equivalency between the commercial air transportation industry and the space launch sector, given their relative dissimilarity.

She noted that in terms of sheer volume, there’s a massive difference, with roughly 40 to 50 launches set for 2020 compared to millions of flights for commercial air. Airlines also use essentially the same small handful of airframes from suppliers like Boeing and Airbus, while each launch company has their own, very different vehicle with different conditions for launch and flight. Overall, she suggested then that anticipating some potential future state where the industries were more similar could result in stifling progress toward that ultimate goal.

“I hope we get to that million launches at some point, but when we are at that point, it’s going to be because we worked our way up the safety trajectory in a way that allows us to operate that way,” Schenewerk said. “Today, SpaceX can’t fly from a spaceport in the middle of the country, because we won’t get through the safety approval. We literally will not be licensed by the FAA to operate from that site, because we will then be flying over large populations of people — and we aren’t at that level of reliability and safety in this industry to fly over large populations of people with these kinds of rockets. Could we get there someday? Yeah, we can get there someday when we’ve had a million flights, and a million prove-outs of our capability, when we have such repeatability that we’re in that level.”

Ultimately, Schenewerk’s comments and Jangelis’ responses illustrate that there are still a lot of places where younger companies and emerging technologies like reusable rocket launches are conflicting with the views of more established industries and players operating in some shared spaces.

FAA Administrator Steve Dickson also addressed the agency’s ongoing work to establish launch rules, which were released as a draft last year and which Dickson said will likely be finalized sometime this fall, once the FAA has incorporated industry comments and feedback.

“Let’s think about that big vision, that big day when lots of things are happening,” Schenewerk said. “But let’s also not yell at our kid for not being able to fly an airplane when they can barely walk — and I think that’s where we are right now: We’re still figuring out how to walk and run in this industry.”

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Kepler will build its small satellites at a new manufacturing facility in Toronto

Satellite communications startup Kepler will manufacture its small satellites going forward at a new 5,000-square-foot facility in Toronto, Ontario, Canada . The company is working with partners, including the Canadian Space Agency and the University of Toronto, on the new facility, which will also incorporate design and development of its satellites in addition to manufacturing.

Already, Kepler operates two satellites currently in orbit, and has demonstrated the capabilities of its technology by delivering a high-speed internet data connection to the North Pole for the first time late last year. These spacecraft were designed by Kepler, but manufactured via third-parties through contracting agreements. With the new facility, Kepler says it’ll be able to “vertically integrate the development, production and testing of its future spacecraft.”

This will help the startup achieve its goal of producing, launching and operating a constellation of 140 satellites in total, which will provide high-bandwidth connectivity aimed for use in a range of industries, including agriculture, transportation and maritime shipping and logistics, to name a few. This new in-house facility will support mass production of the small satellites it requires to build out its fleet, while providing cost benefits versus outsourcing over time.

The small satellite industry is one of the parts of commercial space that has seen the biggest increase in demand, especially since relatively affordable launch vehicles like SpaceX’s Falcon 9 have expanded the pool of potential companies building and operating satellites and constellations. Bringing satellite manufacturing in-house puts Kepler in rare company as one of the few small sat companies that owns the whole stack, which should be a big competitive advantage relative to the market going forward.

In terms of when the facility will be putting out satellites that Kepler plans to actually launch, the company currently plans to launch its final demonstration satellite, which is already built under its prior contractor arrangement, this spring. Then, it intends to launch the first commercial satellites produced by this new facility starting this summer, with an additional two launches planned for later in the year.

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NASA taps startup Axiom Space for the first habitable commercial module for the Space Station

NASA has selected Houston-based Axiom Space, a startup founded in 2016, to build the first commercial habitat module for the International Space Station (ISS). This module will be used as a destination for future commercial spaceflight missions, potentially housing experiments, technology development and more performed by commercial space travelers taking rides up to the ISS via human-rated spacecraft like the SpaceX Crew Dragon and Boeing Starliner, once those start regular operational service.

Axiom Space was founded in 2016, and is led by co-founder and CEO Michael T. Suffredini, who previously acted as program manager for the ISS at NASA’s Johnson Space Center. The company boasts a lot of ex-NASA talent on its small team, and eventually it plans to make its in-space modules the basis of its own private space station, after first attaching them to the ISS while it’s still operating. NASA has extended the planned service life of the ISS, but the plan of the agency’s current leadership is to eventually encourage private orbital labs and commercial facilities as an ultimate replacement.

In 2018, Axiom teamed up with designer Philippe Starck (yes, the same one who famously designed a luxury yacht for Apple founder Steve Jobs) to provide a look at what their future space station modules might look like, including crew quarters with interactive displays and a cupola that provides a breathtaking view of Earth and surrounding space.

This ISS module may not be a full-fledged private space station, but it is a step in NASA’s goal of further commercializing the existing space station and ultimately paving the way for more commercial activity in low Earth orbit. Axiom’s mandate also includes providing “at least one habitable commercial module,” with the implication being that it might be awarded extensions to build more in the future. Next up for the new partners is negotiating terms and price for a contract for the module, which will also include a timeline for delivery.

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