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Gaming giant Valve has responded to reports that it is rejecting games from Steam that contain content created with artificial intelligence. Specifically, some developers have reported that Valve is blocking games from Steam if the developers cannot prove they have the underlying asset rights.

Valve reacted to this with a public statement shared with GameSpot. The company said it believes AI will have a role to play in the future of game development. At the same time, Valve said the “legal uncertainty” surrounding AI might prove to be a sticking point in the near future as AI evolves.

“We are continuing to learn about AI, the ways it can be used in game development, and how to factor it in to our process for reviewing games submitted for distribution on Steam,” Valve said. “Our priority, as always, is to try to ship as many of the titles we receive as we can. The introduction of AI can sometimes make it harder to show a developer has sufficient rights in using AI to create assets, including images, text, and music. In particular, there is some legal uncertainty relating to data used to train AI models. It is the developer’s responsibility to make sure they have the appropriate rights to ship their game.”

Valve said AI is a “constantly evolving” piece of technology, and it is not attempting to discourage the use of it on Steam. In fact, Valve said it is now “working through” how to incorporate AI into the existing Steam review policies, and right now, this means some games have been blocked.

“Stated plainly, our review process is a reflection of current copyright law and policies, not an added layer of our opinion. As these laws and policies evolve over time, so will our process,” Valve said. “We welcome and encourage innovation, and AI technology is bound to create new and exciting experiences in gaming. While developers can use these AI technologies in their work with appropriate commercial licenses, they can not infringe on existing copyrights.”

Finally, Valve said it doesn’t normally refund app submission payments, but in this case–for titles involving the use of AI–developers can be refunded as Valve works through its review process.

AI has been a major topic in the wider technology space and video games specifically in recent times. Microsoft partnered up with ChatGPT and reportedly invested $10 billion into the AI company. Microsoft Gaming CEO Phil Spencer believes AI will be a positive, additive force in gaming. Strauss Zelnick, the head of GTA parent company Take-Two, believes in AI as well, but he doesn’t think a rival developer could use it to make a genuine GTA competitor anytime soon. PUBG creator Brendan Greene’s new game, meanwhile, is using advanced machine-learning to create massive and realistic open worlds.

Outside of the video game space, Hollywood writers are now on strike due in part to concerns about AI and what role the technology could play in scriptwriting.

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• A SpaceX-backed startup’s electric flying became the first to get approval for flight tests.
• Alef Aeronautics is already taking pre-orders for the car that will start at $300,000.
• Alef CEO Jim Dukhovny previously told CNBC he expected the car to be available in 2025.

A fully electric flying car that’ll cost about $300,000 just won approval to start testing on the road – and in the air. 

Alef Aeronautics, a Californian automaker, said in a press release it had received a Special Airworthiness Certification from the Federal Aviation Administration (FAA) for the Model A. 

It’s the first such approval for a flight-capable car, according to the startup, which has been backed by the likes of SpaceX.

Alef CEO Jim Dukhovny said: “It allows us to move closer to bringing people an environmentally friendly and faster commute, saving individuals and companies hours each week. This is one small step for planes, one giant step for cars.”

Due to evolving FAA restrictions tied to the unprecedented capabilities of flying cars, Alef said its certification limits the locations and purpose for which it is permitted to fly.

The company aimed to produce the first flying car with both street driving and vertical take-off capabilities. It’s designed to fit within existing urban infrastructure for driving and parking.

The flying car is able to take off vertically or horizontally, and can carry up to two people. It’s expected to have a road range of 200 miles and a flying range of 110 miles.

Buyers can pay a $150 deposit to join the general queue, or $1,500 to get priority access when deliveries start. 

About 440 people paid deposits in the final three months of 2022, Alef said in January.

In December, Dukhovny told CNBC Make It that customers could expect to see their cars in the sky by 2025.

Alef wasn’t the only flying car and air taxi company to make a major regulatory breakthrough in recent days.

On Wednesday, shares in flying taxi comapny Joby Aviation soared 44% after it also received a Special Airworthiness Certificate from the FAA.  

In a small seaside town in northeast Japan, factory workers are disassembling old batteries from the world’s first mass-market electric cars and preparing them for a second life. Reusing batteries could help the auto industry live up to its promise to make a truly green transition. But it’s time-consuming and, for now, unprofitable.

Early models of Nissan Motor Co.’s all-electric Leaf, which first went on sale almost 13 years ago, have started to reach the end of their life spans. In an effort to make the end of the cars’ lives as green as their operation was, their used batteries are collected at Nissan dealerships in the US and Japan and sent to the factory in Namie, Fukushima, a town devastated in 2011 by a tsunami and a nuclear disaster.

Engineers at the plant, operated by 4R Energy Co. — Nissan’s joint venture with trading house Sumitomo Corp. — spend hours on each battery pack before shipping them out, mostly to be used again in another electric vehicle but sometimes to be repurposed in other devices, such as backup generators.

Collecting and reusing EV batteries keeps them from being discarded in landfills, where they might release toxins, or from being melted and pulled apart for their metals, which can be hazardous when done improperly. It also would reduce the industry’s reliance on the mining of costly rare-earth elements such as lithium and cobalt and cut down on the carbon emissions involved in making EV batteries — the dark side of the green car business.

Moreover, creating a bigger market for used batteries could boost the secondhand market for electric cars as well, by extending their life span and bolstering their resale value, which would hasten their adoption, says Yutaka Horie, the president of 4R Energy. “For EVs to proliferate, it needs to get easier for customers to buy and sell,” Horie said as he gave a tour of the factory that opened in 2018 with local government support. Namie officials have been trying to attract industries to the area after it lost 90% of its population in the evacuations following the Fukushima disaster.

With all the nuclear reactors in the area now decommissioned, officials are seeking to host businesses dealing with renewable energy and other new technologies. Because the project would help fulfill Nissan’s goal to make EVs more sustainable and popular, profitability was never an urgent priority. But 4R hopes that with time, it will become a profitable business on its own.

At first glance, the factory doesn’t look very cutting-edge. Robots and other automation equipment, a common sight at most car factories these days, aren’t noticeable. Instead, most of the work is done manually by its nine, mostly local engineers.

A reused EV battery can cost about half the price of a new one, according to Bloomberg Intelligence analyst Tatsuo Yoshida. He says what sets Nissan apart from other EV makers is that its 4R subsidiary is concentrating on reusing batteries as opposed to recycling them. Reusing entails swapping out deteriorated cells with healthy ones to extend the life of an aged but still-working battery. When recycling a battery, its rare-earth metals and other useful parts are extracted and used to produce something new.

At 4R’s plant in Namie, the process starts by slicing open the battery packs to evaluate their condition. Each pack weighs 300 kilograms (661 pounds) and contains 48 modules, each consisting of two batteries. Once the insides are exposed, they’re plugged into a computer for an initial assessment.

Workers put the packs through a stress test in a sealed room they call the sauna, repeatedly exposing them to extremely high and low temperatures. This provides data on the extent of deterioration and the remaining range in each battery. “This data is everything,” Horie says, motioning toward the sauna.

The data, together with background information on previous owners—which sometimes can include everything from their geographies to driving history—offer insights on how EV batteries degrade over time under different environments, laying the groundwork for future improvements in battery development, he says.

This data-heavy, labor-intensive approach stands in sharp contrast to the recycling method being pursued by automakers such as Tesla and BYD, which break down end-of-life batteries and extract their raw minerals to reuse in completely new batteries. While both methods keep used batteries from ending up in the junkyard, 4R Energy’s extensive testing allows it to salvage more of what remains, meaning there’s less waste. But partly because of the data collection, the process is far more time-consuming.

Battery recycling might be easier to scale up as volume grows, but both recycling and reuse will have a role to play in the future, says BloombergNEF analyst Colin McKerracher. “Battery repurposing is often more time-consuming than recycling, but allows the company to reuse more of the battery materials,” he says.

4R won’t disclose financial details, except to say that it believes greater scale will eventually help it turn a profit. Horie says 4R’s intake has been doubling annually since 2018, and it now receives “thousands of batteries” every year. It also now has storage capacity for 2,000 batteries across three locations in Fukushima. But even with such growth, it’s unclear whether 4R will reach the scale required to turn a profit.

Nissan’s Leaf never quite took off with drivers, selling only 646,000 cars since production began in 2010. Early adopters of environmentally conscious vehicles instead went for hybrids such as the Toyota Prius, and attention in recent years has shifted to Tesla’s sleeker all-electric models.

4R Energy currently only handles old Leaf batteries, but it’s planning to expand its scale by working with other Nissan models including the Sakura, a newer EV popular in Japan. It’s also trying to turn the old batteries into a greater variety of equipment, including power storage units for wind, solar and other renewable energy.

Tooru Futami, who worked at 4R Energy following a career at Nissan developing the Leaf, says the batteries being made today have better range and longer life spans than old ones do, making it hard for used batteries to compete. But he believes this advantage will shrink over time, as long-range batteries join the recycling stream and improvements in battery performance plateau. “Over time, that gap will narrow,” says Futami, now a research fellow at the mobile gaming and e-commerce company DeNa Co. in Tokyo.

The Leaf was the front-runner, but batteries from the first Teslas and other early EVs are also nearing the end of their use, meaning battery recycling and refurbishing is just starting to take off. A recent surge in EV sales means more growth ahead. As many as 77 million EVs could be on the road by 2025, with 229 million by 2030, according to projections by BNEF.

Even in Japan, where EVs accounted for only 1.7% of passenger cars sold last year, the ground is shifting. In February, Nissan said, it will introduce 27 EV models. And Toyota Motor Corp., after years spent focusing on hybrids and gasoline cars, plans to rapidly expand EV production in the next few years.

The Japanese carmakers are still trailing far behind Tesla and others in EVs, despite their early start in the environmentally friendly category. These days, Chinese manufacturers dominate the EV battery supply chain, from mining to assembly, and their recycling capacity is also growing. Analysts say 4R Energy will eventually feel more competitive pressure.

“4R is the front-runner in Japan, but there are dozens like them in China,” says Hideki Kidohshi, a senior specialist in energy and transportation at the Japan Research Institute. He says it’s not realistic to expect financial viability for the company’s efforts right away, anyway. “It’s not about whether this business makes sense now,” he says. “It’s about lowering costs in preparation for future growth.”

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Device makers have struggled to incorporate temperature sensors into smartphones and smartwatches to turn them into medically accurate body thermometers, but researchers at the University of Washington claim they’ve come up with a way to turn an off-the-shelf smartphone into exactly that–with nothing but a new app. They’re calling it FeverPhone.

Although smart wearables like the Apple Watch Series 8 and Apple Watch Ultra can measure a user’s body temperature through newly added sensors, it’s a feature that Apple insists is not yet accurate enough to be used for medical diagnosis or treatment. Instead, both of those devices use temperature measurements to provide users with a better understanding of their sleep patterns throughout the night. Unlike heart rate readings, the Apple Watch still isn’t a digital thermometer that can make accurate temperature readings on demand.

As many of us discovered during the wilder days of the Covid-19 pandemic, non-contact digital thermometers aren’t terribly expensive, but they can quickly sell out when demand for them skyrockets. As a readily available alternative, researchers at the University of Washington turned to smartphones. One key difference: Their solution does not need any added attachments or hardware upgrades. Smartphones already rely on components called thermistors to measure the temperature of the device’s internals, including the battery, in order to activate safety precautions to ensure they don’t overheat. It’s why your iPhone will sometimes show a warning that it needs to cool down before you can safely use it again.

Thermistors, which are also used in medical-grade thermometers, can’t directly measure a user’s body temperature while inside a smartphone, but they can be used to track the amount of heat energy that has been transferred between a user and the mobile device they’re making contact with. To simulate a fevered test subject, the researchers used a sous-vide machine to heat a plastic bag full of water, and pressed the touchscreens of several different smartphones against it, including devices in protective cases, and those using screen protectors. The built-in thermistor was used to measure how quickly the device warmed up during this interaction, and that data was used to train a machine learning model powering the FeverPhone app that can estimate what a user’s body temperature is.

Using the FeverPhone app sounds easy enough, but it requires users to hold their device at its corners and press its touchscreen against their forehead for around 90 seconds. This was deemed the ideal amount of time for enough body heat to be transferred to the device, and since the forehead interaction is detected by the touchscreen, it allows the device and the app to know when a measurement is being deliberately made.

During a clinical trial at the University of Washington’s School of Medicine’s Emergency Department, the app was tested by 37 participants, which included 16 with a mild fever, and the results were compared against readings from an oral thermometer. FeverPhone was able to predict a user’s core body temperature with “an average error of about 0.41 degrees Fahrenheit (0.23 degrees Celsius),“ which is on par with the accuracy of home use thermometers, including non-contact options.

The researchers are currently working to improve the app’s accuracy by expanding the number of smartphone models that were used to train its machine learning model, as initially just three different devices were used. But they’re optimistic that it could be trained to work with smartwatches, too, which would actually work much better as their smaller size would allow them to heat up faster and allow for measurements much shorter than 90 seconds. FeverPhone may never be approved as a medical grade thermometer, but it sounds like it will be accurate enough to give users a better idea when they might actually be sick, and should be taking appropriate measures to protect themselves and others.