Tesla’s new Roadster patent doesn’t do what Elon said it would (and that’s good)
Tesla filed for a patent which looks like it could be the promised “SpaceX package” which it will supposedly include on its oft-delayed next-gen Roadster. But will the system let the Roadster “fly,” as CEO Elon Musk has promised?
In 2017, at Tesla’s Semi unveiling, Tesla pulled one of its few-ever Jobsian “one more thing”s and unveiled the next-gen Tesla Roadster, which caught everyone by surprise.
The idea, at the time, was for the Roadster to provide a “hard-core smack down to gasoline powered cars,” and our speculative technical analysis of the announced specs suggested that this could certainly be the case. The car was slated for a 2020 release.
However, 8 years later, you may have noticed that you have not seen a next-gen Tesla Roadster on the road yet. So we will have to wait to see if all those promised statistics will bear out, or if it’s all just smoke and mirrors.
Other than a few spottings of Franz von Holzhausen taking the Roadster prototype out in public or a model parked at the Petersen museum, all we’ve ever heard about the car is that it’s “in development” or “close to finalized“, over and over and over again. Heck, even Tesla seems to forget about it sometimes.
But today, we got the first positive verification of progress on a probable Tesla Roadster performance improvement that we’ve seen in a long time – or maybe ever.
It comes in the form of a patent filed with the US patent office which seems to show something somewhat similar to the “SpaceX package” that CEO Elon Musk has referred to repeatedly, claiming that the car will use “cold gas thrusters” to “fly.”
How Musk described Tesla’s “SpaceX package”
The point of the SpaceX package was always to add additional performance that is not attainable by traction alone.
Currently, a lot of electric cars have so much torque that they are “traction-limited,” which is to say, their tires cannot possibly accelerate them in any direction any faster than they currently do. You can add more power or bigger brakes, but it doesn’t matter, the limiting factor is the tires (and the weight…).
So you have to find other creative ways to get more performance. Lots of cars do this with aerodynamic surfaces like wings/spoilers to add downforce, which pushes the car to the ground so the tires can work a little harder. But there are limits to how much downforce you can add, and what speeds it works at.
This is where the SpaceX package would come in – it would presumably add additional thrust in a given direction, adding acceleration in whichever direction you choose.
The way that Musk has described it in the past, using “cold gas thrusters,” made it seem like there would be thrusters strategically placed around the vehicle to provide either forward or lateral acceleration, or deceleration in order to help the car stop.
However, Musk also described the car as being able to “fly,” which makes no sense whatsoever.
As mentioned above, downforce is an effective way to get more performance out of a vehicle when you are otherwise traction-limited. But flying would take upforce, not downforce, and that’s not a term anyone uses because it’s totally useless for any performance benefit and there’s absolutely no reason anyone would ever want to do that to a car – unless you’re trying to play a trick on Mark Webber or something.
(Yes, I’m aware of the jumping Yangwang U9. That’s a demo of active suspension, which does add performance benefit, and using that system to “jump” doesn’t add any unnecessary weight or complexity to the active suspension system, unlike downward-pointed thrusters which would be wholly unnecessary beyond providing a demo).
Thankfully, someone who knows how physics works showed up and reason has prevailed, and it looks like the system, as proposed, doesn’t do any of that nonsense Elon Musk was talking about. Instead, it does what it should have done all along – it acts as a “fan car,” a concept that has existed in automotive circles since the early 1970s.
Tesla’s actual patent shows old “fan car” tech, with a twist
There have been several “fan cars” or “ground effect cars” in the past, which operate with powerful fans to blow air out from underneath the vehicle, combined with side skirts underneath the car to reduce the amount of air that can replace it. This creates a low-pressure vacuum effect, and “sucks” the car to the ground (more accurately, ambient air pressure from above pushes the car to the ground, physics teachers please do not email me about how nothing sucks in physics).
Tesla’s patent shows a design that looks very similar to concepts that we’ve seen before in the automotive realm, but with some new tech applied. Have a look:
It has the fans and the side skirts, just as one would expect. And it shows the rough design of what the system might look like – a hexagonal-ish shape underneath the vehicle, with fans presumably at the rear of the vehicle to exhaust air to create the vacuum effect.
Tesla goes on to say that these skirts and fans could be controlled automatically by vehicle systems in order to offer different performance benefits in different situations. This is where we start to see the new tech – like adding the modern concept of active aerodynamics to the concept of fan cars.
Rather than deploying the skirts the same way in all modes, there could be different modes for a prepared track surface which is known to be high quality and flat, or for a more uneven road surface where you might not be able to create as secure of a seal with the maximum-downforce configuration.
This is an issue with fan cars – they only work on the right kind of surface. If air leaks in to the vacuum region under the vehicle, you can’t really create as much negative pressure as you’d like. That’s why the side skirts are necessary, but of course that doesn’t work if there are potholes, unsecured manhole covers, and the like.
Tesla also says the system could have different configurations for low- and high-speed operations, adjust the skirts based on vehicle weight transfer, or potentially detect upcoming road conditions and modify configuration based on what the car sees ahead. And mention of deploying the skirts based on GPS position lends itself to the idea that Tesla could create specific settings to optimize performance for track use, or even individual corners on tracks.
Is this the “SpaceX Package,”or something else?
Tesla has said for years that the Roadster would have a “SpaceX package” to increase the performance even further than the specs it mentioned in the original unveiling event. This was meant to use expertise from SpaceX, another company Musk runs, and whose primary facility is sited on the same Hawthorne, CA property as Tesla’s Design Studio.
At least one of the designers listed on Tesla’s “fan car” patent, David Lemire, worked at both Tesla and SpaceX in the past, before leaving and then returning to Tesla as a senior engineer on Tesla’s “new programs” team.
However, there is no mention in the document of “fly,” “flight,” “thruster,” “rocket” or “lift.” Nothing like the “cold gas thrusters” package that Musk has spent years telling us will make the car fly – and in fact, the exact opposite, as this will suck the car to the ground, not make it fly at all.
This could mean that Tesla has another idea in mind which will use thrusters, and will be applied in addition to this “fan car” idea.
Theoretically, adding lateral thrusters around the car could still add a performance benefit over and above the fan car idea, so these could be used in tandem, though it would add a lot of complexity to the vehicle. But these may or may not be worth the added weight – and they definitely wouldn’t be worth the weight if they’re directed in such a way to make the car able to “fly.”
Or it could be that the “fan car” patent will be applied to cars like the Model S Plaid, which has set racing records, and Tesla has another trick up its sleeve for the Roadster.
Or… this is what the SpaceX package was all along, and Musk was just running his mouth about the car flying. Which would be the best option, to be honest, because it’s dumb to pretend that flight would add any performance benefits to a sportscar.
Regardless, the fan car idea is an actual interesting performance idea, and it would actually work, unlike some of the previous public statements made by Tesla’s CEO. So it’s nice to see some sort of progress that could be applied to a performance car, after so many years of waiting.
But… does it matter anymore?
With so many performance EVs, does this matter?
The problem is that in the intervening 8 years since the Roadster was first introduced, some other electric cars with truly wild specs have already hit the road, and have delivered the “hard core smack down” that Tesla promised.
We’ve got the Rimac Nevera R, a 2,078hp electric car that can hit 300km/h (186mph) a full 3.5 seconds faster than a Bugatti Chiron Super Sport. We’ve got the Lotus Evija X, which set the third-fastest Nurburgring lap ever, only beaten by two one-off, track-only, purpose-built racecars (one of which is a hybrid, the other is electric).
And in the realm of actual consumer-available vehicles, we have the Xiaomi SU7 Ultra – made by a smartphone company, mind you – with 1,548hp and record-setting performance of its own.
So anybody who tells you these days that EVs aren’t fast is just… embarrassingly wrong. They’ve had their head in the sand for at least 19 years. It’s honestly a bit boring at this point.
So, what’s left for Tesla to do? The smack down has been delivered, and delivered by many other companies, startups and otherwise. I mean, heck, we’ve got a company that went from making phones to beating Porsche on its home track in the course of less than three years worth of development. Everyone is aware of how easy it is to beat complex, inefficient gas engines at this point.
A fan car seems like it could be a worthy addition to this menagerie, another way to deliver the smack down, as none of the above EVs have leveraged this particular type of active aerodynamics for a performance benefit, so Tesla could have something unique here….. oh, wait.
It turns out that someone else has done an electric fan car already. The McMurtry Spierling already has this idea, and it’s an absolute beast. It’s already the fastest car ever at Goodwood thanks to the 2,000kg of downforce that it makes with the huge fans underneath the roughly 1,000kg vehicle, even at 0mph where traditional aerodynamic surfaces provide no benefit whatsoever.
And if it seems interesting that one of those numbers is bigger than the other, well, yes, McMurtry has done that too – it briefly drove the car upside down just to show off how much downforce its fans can make, which we would say might qualify as “the most epic demo ever.”
That said, the Spierling is just one application of the idea, and it’s not like more cars can’t try something similar.
Also, it looks like Tesla’s solution would add a lot of adaptibility that McMurtry’s doesn’t have. Not only is the Spierling a purpose-built, track-focused single-seat racecar whereas the Roadster would be a regular roadgoing sportscar, but also Tesla’s flexible solution described in the patent would allow travel on less track-prepped terrain.
This would make the concept of a fan car much more practical for real life – as long as you’re not somewhere where you wouldn’t want to spray high-velocity pebbles out of the back of your vehicle. Maybe there’s a reason nobody has done this on a consumer vehicle yet (that said, Tesla includes a filter to stop the spray of dust and pebbles in the patent).
But in terms of real-life applications, there is also the consideration of driver skill. Drivers of performance vehicles get used to their car’s limits and learn where those limits are. But with a presumably enormous amount of adjustable downforce, those limits could change drastically based on road conditions.
We could see this being a dangerous situation if drivers think they’re in max-downforce mode but aren’t, and suddenly find mid-turn that the car is a lot less capable than they thought it was. So we’ll have to see if this mode is track-only or what.
For now, the main question is whether Tesla will ever make this thing, given that it’s already five years late. Any takers?
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Environment
Altman, Huang and the last-minute negotiations that sealed the $100 billion OpenAI-Nvidia deal
Sam Altman, CEO of OpenAI (L), and Jensen Huang CEO of Nvidia.
Reuters
ABILENE, Texas – Sam Altman had a deadline. OpenAI’s CEO was headed to Texas to unveil his company’s next big infrastructure push, and Nvidia CEO Jensen Huang wanted in on the action.
Through a series of hurried negotiations, late-night calls and last-minute contract tweaks, the two giants of artificial intelligence struck a $100 billion partnership on Monday, hours before Altman boarded his flight to Abilene, a city of about 130,000 residents roughly 180 miles west of Dallas.
It helped that Huang and Altman had been part of President Donald Trump’s state visit to the U.K. a week earlier, allowing the president to be briefed on the agreement days in advance.
The deal, which Huang described to CNBC as “monumental in size,” marks a watershed moment in the tech industry, as capital and influence are increasingly concentrated in the hands of the two companies closest to the heart of the artificial intelligence boom.
Huang now presides over the world’s most valuable public company, worth nearly $4.5 trillion after gaining $170 billion following Monday’s announcement, while Altman runs the most prominent startup on the planet, valued at half a trillion dollars.
OpenAI’s ascent to the forefront of generative AI has relied on Nvidia’s high-powered graphics processing units (GPUs). Now the companies are more intimately linked than ever, as they plan to carve a path to jointly building the next wave of AI supercomputing facilities.
“You should expect a lot from us in the coming months,” Altman told CNBC’s Jon Fortt in an interview at Nvidia’s Silicon Valley headquarters on Monday. “There are three things that OpenAI has to do well: we have to do great AI research, we have to make these products people want to use, and we have to figure out how to do this unprecedented infrastructure challenge.”
Altman and Huang negotiated their pact largely through a mix of virtual discussions and one-on-one meetings in London, San Francisco, and Washington, D.C., with no bankers involved, according to people close to the talks who declined to be named because they weren’t authorized to speak publicly on the matter.
The arrangement calls for Nvidia to invest $10 billion at a time in OpenAI, the company behind ChatGPT. As the buildout unfolds, Nvidia will also supply the cutting-edge processors powering a host of new data centers.
While OpenAI gets more intimate with Nvidia, it has to maneuver through a number of high-stakes relationships with other key partners.
OpenAI only informed Microsoft, its principal shareholder and primary cloud provider, a day before the deal was signed, the people familiar with the matter said. Earlier this year, Microsoft lost its status as OpenAI’s exclusive provider of computing capacity.
The pact also comes less than two weeks after a disclosure from Oracle indicated that OpenAI agreed to spend $300 billion in computing power with the company over about five years, starting in 2027. At the start of the year, OpenAI joined Stargate, a multibillion-dollar project announced by President Trump and backed by Oracle and SoftBank, to build out next-generation AI infrastructure.
Going forward, all of OpenAI’s infrastructure projects will fall under the Stargate umbrella.
Representatives from Microsoft, Oracle and SoftBank didn’t immediately respond to requests for comment.
Nvidia and OpenAI provided scant details about where and when the buildout will take place, other than to say that the first of the 10 gigawatt sites will go online in the back half of next year.
Executives said they’ve reviewed between 700 and 800 potential locations since unveiling Stargate in January. In the months that followed, they fielded a flood of proposals from developers across North America offering land, power, and facilities. That list has been narrowed as OpenAI weighs energy availability, permitting timelines, and financing terms, the company said.
In Monday’s announcement, OpenAI described Nvidia as a “preferred” partner. But executives told CNBC that it’s not an exclusive relationship, and the company is continuing to work with large cloud companies and other chipmakers to avoid being locked in to a single vendor.
OpenAI CEO Sam Altman and Nvidia CEO, Jensen Huang arrive to attend the State Banquet during U.S. President Donald Trump’s state visit, at Windsor Castle, in Windsor, Britain, September 17, 2025.
Phil Noble | Reuters
For Nvidia, the investment in OpenAI is historic in size, but it’s just a big piece of a rapidly expanding portfolio.
Last week, Nvidia put $5 billion into Intel as part of a joint venture to co-develop data center and PC chips with the troubled chipmaker. Nvidia also said it invested close to $700 million in U.K. data center startup Nscale, a move that resembles Nvidia’s backing of U.S. AI infrastructure provider CoreWeave, which held its IPO in March.
Tranches of money
The financing structure for the OpenAI deal is designed to avoid hefty dilution. The initial $10 billion tranche is locked in at a $500 billion valuation and expected to close within a month or so once the transaction has been finalized, people familiar with the matter said. Nine successive $10 billion rounds are planned, each to be priced at the company’s then-current valuation as new capacity comes online, they said.
The relationship between Nvidia and OpenAI long predates the launch of ChatGPT in 2022.
Back when OpenAI was still a small nonprofit research lab and Nvidia was best known for building graphics chips for video games, Huang personally delivered his company’s first DGX supercomputer to OpenAI’s office in 2016. At the time, the startup was located in San Francisco’s Mission District, in a building that’s now home to Elon Musk’s xAI.
Almost a decade and trillions of dollars in value later, Huang and Altman are perhaps the most significant power players in the tech industry.
In October of last year, Nvidia formalized its financial stake in OpenAI, joining a $6.6 billion funding round that valued the company at $157 billion. A month later, in Tokyo, OpenAI executives met with SoftBank CEO Masayoshi Son to brainstorm what to call their next phase of expansion. Out of that session came “Stargate,” a codename that has since become shorthand for OpenAI’s most ambitious buildout plans.
Stargate now encompasses every major deal for compute capacity, including this week’s partnership with Nvidia. Securing the rights to the name required some careful maneuvering, but OpenAI has embraced it as the banner for its long-term infrastructure strategy.
The $100 billion commitment from Nvidia represents only part of what’s required for the planned 10-gigawatt buildout. OpenAI will lease Nvidia’s chips for deployment, but financing the broader effort will require other avenues. Executives have called equity the most expensive way to fund data centers, and they say the startup is preparing to take on debt to cover the remainder of the expansion.
As OpenAI’s compute necessities increase, a big question is where the company will host its workloads, which have to date been largely housed in Microsoft Azure. Taking the work in-house would push OpenAI closer to operating as a first-party cloud provider, a market led by Amazon Web Services, followed by Azure, Google and Oracle.
Executives have openly floated the idea, suggesting it may not be far off. Some even indicated to CNBC that a commercial cloud offering could emerge within a year or two, once OpenAI has secured enough compute to cover its own needs. For now, demand for training frontier models leaves little capacity to spare, but OpenAI isn’t done looking for new opportunities.
As Altman and Huang hammered out details of the arrangement that was announced this week, OpenAI’s infrastructure team was in Tokyo meeting with SoftBank’s Son to discuss broader financing and manufacturing support.
The parallel talks underscored the scale of Altman’s ambition, and the web of global players now involved in bringing it to life.
Blink Charging (Nasdaq: BLNK) has struck a deal with Hubject to make charging easier for EV drivers across North America.
The agreement will bring Blink into Hubject’s intercharge eRoaming platform as a charge point operator. That means electric mobility service providers (eMSPs) and their customers in the US, Canada, and Mexico will soon have access to Blink’s charging stations through their existing apps. In turn, Blink drivers will gain better access to stations connected through Hubject’s network.
Hubject, which already connects more than 1 million charging points and 2,750 partners worldwide, expects the integration to strengthen its North American presence by adding Blink’s wide-ranging network of chargers, from Level 2 workplace stations to DC fast charging. Blink, meanwhile, anticipates more customers will plug in, thanks to Hubject’s reach.
“Our collaboration with Blink marks an important step in expanding our North American intercharge network,” said Trishan Peruma, CEO of Hubject North America. “By integrating Blink’s network into our eRoaming platform, we aim to help reduce barriers that have historically complicated EV charging and to support the continued growth of EV adoption across the United States, Canada, and Mexico.”
Blink Charging’s president and CEO Mike Battaglia added, “Connecting the Blink Network to Hubject’s platform will allow more drivers to benefit from interoperable charging while traveling.”
The integration will use the industry-standard OCPI protocol to keep billing and communication between networks secure and reliable. Deployment is planned in phases throughout 2025, with full integration targeted for the end of the year.
Read more: Blink just made it a lot easier to find its charging stations
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