aerospace
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One of the new space startups with the loftiest near-term goals has raised $130 million in a Series B round that demonstrates investor confidence in the scope of its ambitions: Axiom Space, which has been tapped by NASA to add privately developed space station modules to the ISS, announced the new funding led by C5 Capital.
This is the latest in a string of high-profile announcements for Axiom, which was founded in 2016 by a team including space professionals with a history of demonstrated expertise working on the International Space Station. Eventually, Axiom hopes to go from adding the first private commercial modules to the existing station, to creating their own, wholly private on-orbital platforms — for research, space tourism and more.
Axiom announced the people who will take part in its first-ever private astronaut launch to the ISS, which is set to fly next January using a SpaceX Dragon spacecraft and Falcon 9 rocket. Axiom is the service provider for the mission, brokering the deal for the private spacefarers and setting up training and mission profile. That should be the first time we see a crew made up entirely of private individuals (i.e. not astronauts selected, trained and employed by their respective national government) make its way to the station.
The company was also in discussions with Tom Cruise about filming at least part of an upcoming film aboard the ISS, and it’s in development with a production company on a forthcoming competition reality show that will see contestants vie for a spot on a private flight to the station.
Axiom is emerging as the leading linkage between private human spaceflight and the existing infrastructure and industry, covering both public sector partners like NASA, and the “rails” of the bourgeoning industry — SpaceX and its ilk. It’s been focused on this unique opportunity longer than most in the private market, and it has all the relationships and in-house expertise to make it work.
This new, significant injection of capital will help the company hire, as well as boost its ability to construct the pieces of its forthcoming private space station modules, as well as its eventual station itself. The Houston-based company aims to put its ISS modules on the station by 2024, and it has raised $150 million to date.
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Five years ago I landed the Solar Impulse 2 in Abu Dhabi after flying around the globe powered solely by solar energy, a first in aviation history.
It was also a milestone in energy and technology history. Solar Impulse was an experimental plane, weighing as little as a family car and using 17,248 solar cells. It was a flying laboratory, full of groundbreaking technologies that made it possible to produce renewable energy, store it and use it when necessary in the most efficient manner.
The time has come to use technology again to address the climate crisis affecting us all. As we enter the most crucial decade of climate action — and most likely our last chance to limit global warming to 1.5°C — we need to ensure that clean technologies become the only acceptable norm. These technologies exist now and they can be profitably implemented at this crucial moment.
Hundreds of clean tech solutions exist that protect the environment in a profitable way,
Here are just four innovations from our solar-powered plane that the market can start using now before it’s too late.
The building sector is one of the largest energy consumers in the world. Next to a reliance on carbon-heavy fuels for heating and cooling, poor insulation and associated energy loss are among the main reasons.
Inside Solar Impulse’s cockpit, insulation was crucial for the plane to fly at very high altitudes. Covestro, one of our official partners, developed an ultra-lightweight and insulating material. The cockpit insulation performance was 10% higher than the standards at the time because the pores in the insulating foam were 40% smaller, reaching a micrometer scale. Thanks to its very low density of fewer than 40 kilograms per cubic meter, the cockpit was ultra-lightweight.
This technology and many others exist. We now need to ensure that all market players are motivated to make hyperefficient building insulation their standard operating procedure.
Solar Impulse was first and foremost an electric airplane when it flew 43,000 km without a single drop of fuel. Its four electric motors had a record-beating efficiency of 97%, far ahead of the miserable 27% of standard thermal engines. This means that they only lost 3% of the energy they used versus 73% for combustion propulsion. Today, electric vehicle sales are soaring. According to the International Energy Agency, when Solar Impulse landed in 2016, there were approximately 1.2 million electric cars on the road; the figure has now risen to over 5 million.
Nevertheless, this acceleration is far from enough. Power sockets are still far from replacing petrol pumps. The transport sector still accounts for one-quarter of global energy-related CO2 emissions. Electrification must happen much more quickly to reduce CO2 emissions from our tailpipes. To do so, governments need to boost the adoption of electric vehicles through clear tax incentives, diesel and petrol engine bans, and major infrastructure investments. 2021 should be the year that puts us on a one-way road to zero-emission vehicles and puts thermal engines in a dead end.
To fly for several days and nights, reaching a theoretically endless flight potential, Solar Impulse relied on batteries that stored the energy collected during the day and used it to power its engines during the night.
What was made possible with Si2 on a small scale should guide the way to future-proofing power-generation systems that are made up entirely of renewable energy. In the meantime, microgrids, like those used in Si2, could benefit off-grid systems in remote communities or energy islands, allowing them to abolish diesel or other carbon-heavy fuels already today.
On a larger scale, we are looking at smart grids. If all “stupid grids” were replaced by smart grids, it would allow cities, for example, to manage production, storage, distribution and consumption of energy and to cut peaks in energy demand that would reduce CO2 emissions dramatically.
Solar Impulse’s philosophy was to save energy instead of trying to produce more of it. This is why the relatively small amount of solar energy we collected became enough to fly day and night. All the airplane parameters, including wingspan, aerodynamics, speed, flight profile and energy systems, had therefore been designed to minimize energy loss.
Unfortunately, this approach still stands out against the inefficiency of most of our energy use today. Even though the IEA found energy efficiency improved by an estimated 13% between 2000 and 2017, it is not enough. We need bolder action by policymakers to encourage investors. One of the best ways to do so is to put strict energy efficiency standards in place.
For example, California has set efficiency standards on buildings and appliances, such as consumer electronics and household appliances, estimated to have saved consumers more than $100 billion in utility bills. These measures are as good for the environment as they are for the economy.
When we used all these different innovations to build Solar Impulse, they were groundbreaking and futuristic. Today, they should define the present; they should be the norm. Next to the technologies mentioned above, hundreds of clean tech solutions exist that protect the environment in a profitable way, many of which have received the Solar Impulse Efficient Solution Label.
Just as for the Si2 technologies, we must now ensure that they enter the mainstream market. The faster we scale them, the faster we will set our economy on track to achieve the Paris Agreement goals and attain sustainable economic growth.
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The recent Databricks funding round, a $1 billion investment at a $28 billion valuation, was one of the year’s most notable private investments so far.
For Databricks signaled its IPO readiness by disclosing to TechCrunch last year that it had scaled its revenue run rate from $200 million to $350 million in a year, so the new capital looked like the capstone on its private fundraising before an eventual public debut.
The Exchange explores startups, markets and money. Read it every morning on Extra Crunch, or get The Exchange newsletter every Saturday.
But I did have a few questions, starting with the price of the round.
At a $28 billion valuation and ARR of $425 million, Databricks is valued at around 66x top line. That’s steep, if not the highest number we can dredge up on the public markets. Of course, for Databricks shareholders, seeing the value of their stock rise so quickly is hardly a bad thing. They are hardly going to complain about having more paper wealth.
But what about the investor perspective? Does the price really make sense? The Exchange caught up with Battery Ventures’ Dharmesh Thakker earlier this week to discuss a number of things, one of which was Databricks’ round and pricing. Thakker is named in the Databricks Series D funding announcement, which brought Battery into the company.
What was surprising about our conversation was not that Thakker was bullish on Databricks — a company that he and his firm have backed since its $140 million, 2017 round when the company was worth just under $1 billion. What surprised me was that he thinks its new $28 billion valuation might be a little low.
Intriguing, yeah? So this morning for both of us, I’ve pulled out quotes from our chat to help explain how Thakker views the market for Databricks, unicorns at scale more broadly through the lens of risk-adjusted investing, and the scale of the market some unicorns are playing in.
At the close, we’ll remind ourselves what Databricks CEO Ali Ghodsi told TechCrunch when we asked him the same question. Let’s go!
Here’s how the valuation part of my chat with the Battery Ventures’ investor went down:
The Exchange: I want to talk about Databricks, because I spoke to [CEO] Ali [Ghodsi] yesterday about this round, and hot damn, it’s a lot of money at a valuation that is roughly 64x ARR, give or take. I don’t understand the price, and I know it’s a boring thing to talk about. [It’s a] great company, I get their market, I’ve talked to them a bunch, I know their revenue numbers. [But] I don’t understand the price, and I was hoping you could tell me why I’m being too conservative.
Dharmesh Thakker: I, for what it’s worth, think [the price] fair. If anything, I think it is on the lower end — he could have done better, frankly. But I think it comes down to three major things, right?
One is the addressable market. Just think about the addressable market of data. If there’s a trillion dollars spent in software or technology, I think you and I would be both hard pressed to say, almost all of that [isn’t] influenced by some data-oriented decisioning. Whether it’s digital transformation, whether it’s analytics, data is everywhere. So the TAM is massive … I think you and I both agree on that, whether it is $20 billion or $80 billion — it’s massive.
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Soon all tech news will be fintech news, all fintech news will be trading platform news and all trading platform news will concern the business mechanics of such services.
So, after looking into Robinhood’s fourth-quarter payment for order flow (PFOF) revenues this morning, we’re back with a related story. This time, however, we’re talking about Public.
Public, like Robinhood, is a zero-cost trading service. Its founders have worked to build a community-first platform, including offering ways to let groups chat about their investments.
And like Robinhood, Public has seen its growth skyrocket in recent days. Company representatives told TechCrunch today it was seeing “steady ~30%” month-over-month growth until Thursday, when “new user signups went up 20x.”
Both share strong backing from investors: Robinhood raised billions in new capital this week to ensure it has enough cash to meet clearinghouse deposit requirements. It managed to do so in part because its Q4 2020 numbers show that its PFOF business is ticking along nicely.
Public, flush with a recent $65 million Series C, took a different tack this morning and announced it would “stop participating in the practice of Payment for Order Flow.”
To which we say … all right.
On one level, this is neat. Public is not going to sell its order flow to market makers for fees. That’s good for users, but how will it make up the lost revenue? Tips, which will prove an interesting experiment in monetization.
TechCrunch asked the company if it believes tips will compensate for PFOF revenue, to which founders Leif Abraham and Jannick Malling replied via email that they were “optimistic that the difference will be offset by the optional tipping feature.”
However, dropping payment for order flow is only so brave a move from Public. After all, Public was not making Robinhood-level amounts of fetti from its PFOF business. Indeed, as we wrote when Public raised its Series C:
Before chatting with Public, I dug into its trading partner Apex’s filings to learn about its payment for order flow results from its recent filings. The resulting sums are somewhat modest for Apex’s collected clients. This means that Public’s revenue metrics, a portion of the aggregate sums, are even more unassuming.
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New space startup bluShift wants to bring a new kind of propellant to the small satellite launching market, with rockets powered by bio-derived rocket fuels. These differ from traditional fuels in that they offer safety advantages during handling, and ecological advantages during production and use. The startup has been working on its solid rocket biofuel since its founding in 2014, and has received grants from the Maine Technology Institute and NASA’s Small Business Innovation Research (SBIR) program to refine its fuel formula and rocket engine design to help it get to this point.
The company achieved a milestone on Sunday with its first rocket launch — a low-altitude flight of a small sounding rocket, called Stardust 1.0. It’s a single-stage prototype, which can only carry 18 lbs of payload and is designed to achieve suborbital space. That may not seem like much, but it is enough to put small research equipment up into suborbital space, at costs that put launches within range for small companies and academic institutions.
Image Credits: Knack Factory/Courtesy Aerospace
Stardust 1.0 is designed to be reusable, though it’s still a prototype, and the company is also working on Stardust 2.0, which is a second prototype that’s expected to increase the payload capacity and act as the primary building block for its subsequent production commercial rockets, including Starless Rogue, a two-stage launcher for suborbital missions, and Red Dwarf, a three-stage, 66-lb capacity launch vehicle that can reach low Earth orbit.
Sunday’s launch looked like it might not have been on track to go well at first, with an initial attempt seeing the rocket’s ignition light — but without a takeoff. After resetting for a second try, there wasn’t any ignition. Finally the rocket did take off late in the day, with a flight that the company said “went perfectly” on a follow-up call with media.
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Virgin Orbit isn’t slowing down after joining the exclusive club of small launch companies that have made it to orbit — the company just announced that it’s flying a payload on behalf of the Royal Netherlands Air Force (RNAF). This is the first-ever satellite being put up by the Dutch Ministry of Defense, and it’s a small satellite that will act as a test platform for a number of different communications experiments.
The satellite is called BRIK-II — not because it’s the second of its kind, but rather because it’s named after Brik, the first airplane ever owned and operated by the RNAF. This mission is one of Virgin Orbit’s first commercial operations after its successful test demonstration and will fly sometime later this year. It’s also being planned as a rideshare mission, with other payloads expected to join — likely from the U.S. Department of Defense, which is working with Virgin Orbit’s dedicated U.S. defense industry subsidiary VOX Space on planning what they’ll be adding to the mission load out.
This upcoming mission is actually a key demonstration of a number of Virgin Orbit’s unique advantages in the launch market. For one, it’ll show how the U.S. DOD and its ally defense agencies can work together in the space domain when launching small communications satellites. Virgin Orbit is also going to use the mission as an opportunity to show off its “late-load integration” capabilities — effectively, how it can add a payload to its LauncherOne rocket just prior to launch.
For this particular flight, there’s no real reason to do a late-load integration, since there’s plenty of lead time, but part of Virgin’s appeal is being able to nimbly add satellites to its rocket just before the carrier jet that flies it to its take-off altitude leaves the runway. Demonstrating that will go a long way to help illustrate how it differentiates its services from others in the launch market, such as Rocket Lab and SpaceX.
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German drone technology startup Wingcopter has raised a $22 million Series A – its first significant venture capital raise after mostly bootstrapping. The company, which focuses on drone delivery, has come a long way since its founding in 2017, having developed, built and flown its Wingcopter 178 heavy-lift cargo delivery drone using its proprietary and patented tilt-rotor propellant mechanism, which combines all the benefits of vertical take-off and landing with the advantages of fixed-wing aircraft for longer distance horizontal flight.
This new Series A round was led by Silicon Valley VC Xplorer Capital, as well as German growth fund Futury Regio Growth. Wingcopter CEO and founder Tom Plümmer explained to the in an interview that the addition of an SV-based investor is particularly important to the startup, since it’s in the process of preparing its entry into the U.S., with plans for an American facility, both for flight testing to satisfy FAA requirements for operational certification, as well as eventually for U.S.-based drone production.
Wingcopter has already been operating commercially in a few different markets globally, including in Vanuatu in partnership with Unicef for vaccine delivery to remote areas, in Tanzania for two-way medical supply delivery working with Tanzania, and in Ireland where it completed the world’s first delivery of insulin by drone beyond visual line of sight (BVLOS, the industry’s technical term for when a drone flies beyond the visual range of a human operator who has the ability to take control in case of emergencies).
Wingcopter CEO and co-founder Tom Plümmer. Credit: Jonas Wresch
While Wingcopter has so far pursued a business as an OEM manufacturer of drones, and has had paying customers eager to purchase its hardware effectively since day one (Plümmer told me that they had at least one customer wiring them money before they even had a bank account set up for the business), but it’s also now getting into the business of offering drone delivery-as-a-service. After doing the hard work of building its technology from the ground up, and seeking out the necessary regulatory approvals to operate in multiple markets around the world, Plümmer says that he and his co-founders realized that operating a service business not only meant a new source of revenue, but also better-served the needs of many of its potential customers.
“We learned during this process, through applying for permission, receiving these permissions and working now in five continents in multiple countries, flying BVLOS, that actually operating drones is something we are now very good at,” he said. This was actually becoming a really good source of income, and ended up actually making up more than half of our revenue at some point. Also looking at scalability of the business model of being an OEM, it’s kind of […] linear.”
Linear growth with solid revenue and steady demand was fine for Wingcopter as a bootstrapped startup founded by university students supported by a small initial investment from family and friends. But Plümmer says the company say so much potential in the technology it had developed, and the emerging drone delivery market, that the exponential growth curve of its drone delivery-as-a-service model helped make traditional VC backing make sense. In the early days, Plümmer says Wingcopter had been approached by VCs, but at the time it didn’t make sense for what they were trying to do; that’s changed.
“We were really lucky to bootstrap over the last four years,” Plümmer said. “Basically, just by selling drones and creating revenue, we could employ our first 30 employees. But at some point, you realize you want to really plan with that revenue, so you want to have monthly revenues, which generally repeat like a software business – like software as a service.”
Wingcopter 178 cargo drone performing a delivery for Merck.
Wingcopter has also established a useful hedge regarding its service business, not only by being its own hardware supplier, but also by having worked closely with many global flight regulators on their regulatory process through the early days of commercial drone flights. They’re working with the FAA on its certification process now, for instance, with Plümmer saying that they participate in weekly calls with the regulator on its upcoming certification process for BVLOS drone operators. Understanding the regulatory environment, and even helping architect it, is a major selling point for partners who don’t want to have to build out that kind of expertise and regulatory team in-house.
Meanwhile, the company will continue to act as an OEM as well, selling not only its Wingcopter 178 heavy-lift model, which can fly up to 75 miles, at speeds of up to 100 mph, and that can carry payloads up to around 13 lbs. Because of its unique tilt-rotor mechanism, it’s not only more efficient in flight, but it can also fly in much windier conditions – and take-off and land in harsher conditions than most drones, too.
Plümmer tells me that Wingcopter doesn’t intend to rest on its laurels in the hardware department, either; it’s going to be introducing a new model of drone soon, with different capabilities that expand the company’s addressable market, both as an OEM and in its drones-as-a-service business.
With its U.S. expansion, Wingcopter will still look to focus specifically on the delivery market, but Plümmer points out that there’s no reason its unique technology couldn’t also work well to serve markets including observation and inspection, or to address needs in the communication space as well. The one market that Wingcopter doesn’t intend to pursue, however, is military and defense. While these are popular customers in the aerospace and drone industries, Plümmer says that Wingcopter has a mission “to create sustainable and efficient drone solutions for improving and saving lives,” and says the startup looks at every potential customer and ensures that it aligns with its vision – which defense customers do not.
While the company has just announced the close of its Series A round, Plümmer says they’re already in talks with some potential investors to join a Series B. It’s also going to be looking for U.S. based talent in embedded systems software and flight operations testing, to help with the testing process required its certification by the FAA.
Plümmer sees a long tail of value to be built from Wingcopter’s patented tilt-rotor design, with potential applications in a range of industries, and he says that Wingcopter won’t be looking around for any potential via M&A until it has fully realized that value. Meanwhile, the company is also starting to sow the seeds of its own potential future customers, with training programs in drone flights and operations it’s putting on in partnership with UNICEF’s African Drone and Data Academy. Wingcopter clearly envisions a bright future for drone delivery, and its work in focusing its efforts on building differentiating hardware, plus the role it’s playing in setting the regulatory agenda globally, could help position it at the center of that future.
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SpaceX has set a new all-time record for the most satellites launched and deployed on a single mission, with its Transporter-1 flight on Sunday. The launch was the first of SpaceX’s dedicated rideshare missions, in which it splits up the payload capacity of its rocket among multiple customers, resulting in a reduced cost for each but still providing SpaceX with a full launch and all the revenue it requires to justify lauding one of its vehicles.
The launch today included 143 satellites, 133 of which were from other companies who booked rides. SpaceX also launched 10 of its own Starlink satellites, adding to the already more than 1,000 already sent to orbit to power SpaceX’s own broadband communication network. During a launch broadcast last week, SpaceX revealed that it has begun serving beta customers in Canada and is expanding to the UK with its private pre-launch test of that service.
Customers on today’s launch included Planet Labs, which sent up 48 SuperDove Earth imaging satellites; Swarm, which sent up 36 of its own tiny IoT communications satellites, and Kepler, which added to its constellation with eight more of its own communication spacecraft. The rideshare model that SpaceX now has in place should help smaller new space companies and startups like these build out their operational on-orbit constellations faster, complementing other small payload launchers like Rocket Lab, and new entrant Virgin Orbit, to name a few.
This SpaceX launch was also the first to deliver Starlink satellites to a polar orbit, which is a key part of the company’s continued expansion of its broadband service. The mission also included a successful landing and recovery of the Falcon 9 rocket’s first-stage booster, the fifth for this particular booster, and a dual recovery of the fairing halves used to protect the cargo during launch, which were fished out of the Atlantic ocean using its recovery vessels and will be refurbished and reused.
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Virgin Orbit is wasting no time in 2021 getting back to active flight testing: The company has a window for its next orbital demonstration launch attempt that opens on Sunday, January 10, and that continues throughout the rest of the month. This follows an attempt last year made in May, which ended before the LauncherOne rocket reached orbit — shortly after it detached from the Cosmic Girl carrier aircraft, in fact.
While that mission didn’t go exactly as Virgin Orbit had hoped, it was a significant milestone for the small satellite launch company, and helped gather a significant amount of data about how the vehicle performs in flight. LauncherOne was able to briefly light its rocket booster before safety systems on board automatically shut it down. The company had been looking to fly this second test before the end of last year, but issues including COVID-19 meant that they only got as far as the wet dress rehearsal (essentially a run-through of everything leading up to the flight with the vehicles fully fueled).
This next mission will once again attempt an orbital launch, and this time, the stakes are somewhat higher because actual customer payloads from NASA are on board. They include a number of small satellite science experiments and demonstrations, and while they’re specifically selected for the mission profile (meaning it’s not a tremendous loss if the launch fails), it still would make everyone happiest to actually get them to their target destination.
The nature of the launch window means that Virgin Orbit will likely wait for conditions to be as good as possible before taking off from the Mojave Air and Space Port in California, so take that January 10 date as the earliest possible launch time, but not necessarily the most likely. If successful, Virgin Orbit will join a select group of private small launch vehicles that have made it to orbit, so the industry will definitely be watching the next time Cosmic Girl takes off with LauncherOne attached.
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Japanese startup Astroscale has shipped its ELSA-d spacecraft to the Baikonur Cosmodrome in Kazahkstan, where it will be integrated with a Soyuz rocket for a launch scheduled for March of next year. This is a crucial mission for Astroscale, since it’ll be the first in-space demonstration of the company’s technology for de-orbiting space debris, a cornerstone of its proposed space sustainability service business.
The ELSA-d mission by Astroscale is a small satellite mission that will demonstrate two key technologies that enable the company’s vision for orbital debris removal. First will be a targeting component, demonstrating an ability to locate and dock with a piece of space debris, using positioning sensors including GPS and laser locating technologies. That will be used by a so-called “servicer” satellite to find and attach to a “target” satellite launched at the same time, which will stand in for a potential piece of debris.
Astroscale intends to dock and release with the “target” using its “servicer” multiple times over the course of the mission, showing that it can identify and capture uncontrolled objects in space, and that it can maneuver them for controlled de-orbit. This will basically prove out the feasibility of the technology underlying its business model, and set it up for future commercial operations.
In October, Astroscale announced that it had raised $51 million, making its total raised to date $191 million. The company also acquired the staff and IP of a company called Effective Space Solutions in June, which it will use to build out the geostationary servicing arm of its business, in addition to the LEO operations that ELSA-d will demonstrate.
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