Category: hardware

Asus’ Spatial Vision 3D tech is debuting on two laptops in Q2 this year: the ProArt Studiobook 16 3D OLED (H7604) and Vivobook Pro 16 3D OLED (K6604). The laptops each feature a 16-inch, 3200×2000 OLED panel with a 120 Hz refresh rate. The OLED panel is topped with a layer of optical resin, a glass panel, and a lenticular lens layer. The lenticular lens works with a pair of eye-tracking cameras to render real-time images for each eye that adjust with your physical movements. In a press briefing, an Asus spokesperson said that because the OLED screens claim a low gray-to-gray response time of 0.2 ms, as well as the extremely high contrast that comes with OLED, there’s no crosstalk between the left and right eye’s image, ensuring more realistic looking content. However, Asus’ product pages for the laptops acknowledge that experiences may vary, and some may still suffer from “dizziness or crosstalk due to other reasons, and this varies according to the individual.” Asus said it’s looking to offer demos to users, which would be worth trying out before committing to this unique feature.

On top of the lenticular lens is a 2D/3D liquid crystal switching layer, which is topped with a glass front panel with an anti-reflective coating. According to Asus, it’ll be easy to switch from 2D mode to 3D and back again. When the laptops aren’t in 3D mode, their display will appear as a highly specced OLED screen, Asus claimed. The laptops can apply a 3D effect to any game, movie, or content that supports 3D. However, content not designed for 3D display may appear more “stuttery,” per a demo The Verge saw. The laptops are primarily for workers working with and creating 3D models and content, such as designers and architects. The two laptops will ship with Spatial Vision Hub software. It includes a Model Viewer, Player for movies and videos, Photo Viewer for transforming side-by-side photos shot with a 180-degree camera into one stereoscopic 3D image, and Connector, a plug-in that Asus’ product page says is compatible with “various apps and tools, so you can easily view any project in 3D.”

Lenovo specs the displays with 10,000:1 contrast and 1920×1080 pixels per eye. The glasses are also TUV-certified for low blue light and flicker reduction, according to Lenovo. Much more time is needed to explore and challenge the Micro OLED displays before I pass final judgment. But the combination of smaller pixels and, from what I saw thus far, strong colors, should accommodate screens so close to the eyes. More broadly speaking, brightness can be a concern with OLED technologies, but the small demo I saw fared well in a sun-flushed room.

I used the Glasses T1 while it was connected to an Android smartphone via its USB-C cable, but it’s also supposed to work with PCs, macOS devices, and, via an adapter sold separately, iPhones. […] With no processor or battery, it’s easier for the glasses to stay trim. There are also no sensors or cameras like the Lenovo ThinkReality A3, announced last year, has. Other T1 features include a pair of speakers (one near each temple) and the ability to add prescription lenses. […] The Glasses T1 are expected to be available in select markets in 2023 after debuting in China (as the Lenovo Yoga Glasses) this year. Lenovo didn’t set a price, but I was told it’s hoping to keep the glasses under $500.

The good news is that every three years, the US Copyright Office holds hearings to discuss potential exemptions. Right to repair advocates are hoping Congress will schedule this year’s hearing soon. Wiens also highlighted the passing of the Freedom to Repair Act [PDF] introduced earlier this year as critical for addressing Section 1201 and creating a permanent exemption for repairing tech products.

Apple’s self-service repair program launched last month marked a huge step forward for the right to repair initiated by a company that has shown long-standing resistance. Wiens applauded the program, which provides repair manuals for the iPhone 12, 13, and newest SE and will eventually extend to computers. He emphasized how hard it is for iFixit to reverse-engineer such products to determine important repair details, like whether a specific screw is 1 or 1.1 mm. […]

Wiens envisioned a world where gadgets not only last longer but where you may also build relationships with local businesses to keep your products functioning. He lamented the loss of businesses like local camera and TV repair shops extinguished by vendors no longer supplying parts and tools. […] He also discussed the idea of giving gadgets second and even third lives: An aged smartphone could become a baby monitor or a smart thermostat. “I think we should be talking about lifespans of smartphones in terms of 20, 25 years,” Wiens said.
The livestream of the discussion can be viewed here.

Schnell said that Dell isn’t making the modules and has worked with memory companies as well as Intel on this. In the future, a person with a CAMM-equipped laptop will be able to buy RAM from any third party and install it in the laptop. Yes, initially, Dell will likely be the only place to get CAMM upgrades, but that should change as the standard scales up and is adopted by other PC makers. The new memory modules are also built using commodity DRAMs just like conventional SO-DIMMs.

In fact, Dell points out, it’s not even “proprietary” on its own laptops. The first Precision workstations that come with CAMM will also eventually be offered with conventional SO-DIMMs using an interposer. Mano Gialusis, product manager for Precision workstations, said the interposer option goes into the same CAMM mount, too. With CAMM now a reality, Dell’s next step is to get it in front of JEDEC, the memory standards organization, to make it available to others, he said. Why not create a standard from scratch? Schnell said its far easier to get a standard minted once it’s proven to work rather than trying to simply create something anew every time. The report goes on to say that Dell does hold patents on the CAMM design “and there will be royalties,” but “no standard can go forward through JEDEC unless the licensing is not anti-competitive, is reasonably priced, and cannot discriminate against a company.”

The lack of chip inventory leaves auto manufacturers and other chip users with “no room for error,” Commerce Secretary Gina Raimondo said Tuesday as she presented the findings. “A covid outbreak, a storm, a natural disaster, political instability, problem with equipment — really anything that disrupts a [chip-making] facility anywhere in the world, we will feel the ramifications here in the United States of America,” she said. “A covid outbreak in Malaysia has the potential to shut down a manufacturing facility in America.”

“The reality is Congress must act,” Raimondo added, urging lawmakers to pass a proposal for $52 billion in federal subsidies to incentivize construction of chip factories. “Every day we wait, we fall further behind.” The Senate passed the measure last year. The legislation has been tied up for months in the House, though House Democrats are expected to introduce their version of the legislation as soon as this week. Industry executives say federal funding is likely to create more long-term supply of chips but not to alleviate the short-term shortages because chip factories take years to build.

With a collection of salvaged and homemade equipment, Zeloof produced a chip with 1,200 transistors. He had sliced up wafers of silicon, patterned them with microscopic designs using ultraviolet light, and dunked them in acid by hand, documenting the process on YouTube and his blog. “Maybe it’s overconfidence, but I have a mentality that another human figured it out, so I can too, even if maybe it takes me longer,” he says… His chips lag Intel’s by technological eons, but Zeloof argues only half-jokingly that he’s making faster progress than the semiconductor industry did in its early days. His second chip has 200 times as many transistors as his first, a growth rate outpacing Moore’s law, the rule of thumb coined by an Intel cofounder that says the number of transistors on a chip doubles roughly every two years.

Zeloof now hopes to match the scale of Intel’s breakthrough 4004 chip from 1971, the first commercial microprocessor, which had 2,300 transistors and was used in calculators and other business machines. In December, he started work on an interim circuit design that can perform simple addition….

Garage-built chips aren’t about to power your PlayStation, but Zeloof says his unusual hobby has convinced him that society would benefit from chipmaking being more accessible to inventors without multimillion-dollar budgets. “That really high barrier to entry will make you super risk-averse, and that’s bad for innovation,” Zeloof says.

[Professor Andrea Morello of UNSW, who led the work] et al achieved 1-qubit operation fidelities up to 99.95 percent, and 2-qubit fidelity of 99.37 percent with a three-qubit system comprising an electron and two phosphorous atoms, introduced in silicon via ion implantation. A Delft team in the Netherlands led by Lieven Vandersypen achieved 99.87 percent 1-qubit and 99.65 percent 2-qubit fidelities using electron spins in quantum dots formed in a stack of silicon and silicon-germanium alloy (Si/SiGe). A RIKEN team in Japan led by Seigo Tarucha similarly achieved 99.84 percent 1-qubit and 99.51 percent 2-qubit fidelities in a two-electron system using Si/SiGe quantum dots.

The UNSW and Delft teams certified the performance of their quantum processors using a sophisticated method called gate set tomography, developed at Sandia National Laboratories in the U.S. and made openly available to the research community. Morello had previously demonstrated that he could preserve quantum information in silicon for 35 seconds, due to the extreme isolation of nuclear spins from their environment. But the trade-off was that isolating the qubits made it seemingly impossible for them to interact with each other, as necessary to perform actual computations. Today’s paper describes how his team overcame this problem by using an electron encompassing two nuclei of phosphorus atoms. The three papers from the UNSW team, Delft team and RIKEN group in Tokyo can be found at their respective links.