Los Angeles to Tokyo in 2.5 HOURS: Supersonic jet firm unveils plane that can transport 50 people at over 3000mph…
However, by the end of the decade, that time could be reduced to just two and a half hours if the vision of Florida-based supersonic jet firm Aerion comes to fruition.
This week it unveiled a ‘first glimpse’ of its AS3TM airliner, designed to transport up to 50 passengers at up to ‘Mach 4+’ — or at least 3000mph.
‘Humans are extraordinarily special’. Not new but well worth remembering.
Either way, their conclusion is that, like stick-shift cars, extraterrestrial civilizations are few and far between. The implication is that our nearest cosmic chums are at least several thousand light-years away.
You may wonder why this story has raised eyebrows. Well, it would make Homo sapiens extraordinarily special, despite the fact that the galaxy is stuffed with planets. It discomfits scientists (including me) because, historically, every time we’ve thought we occupy a privileged position in the universe, we were wrong. Remember that six centuries ago, learned folk would have assured you that Earth was the center of the cosmos.
According to the CEO of CIAM Mikhail Gordin, this is one of the most important projects in modern aviation. The use of a hybrid power plant based on the high-temperature superconducting platform, or HTSP, is designed to solve a number of technological issues that air transport is already facing, he said.
“This is what was done with the Fund of Advanced Studies – an electric airplane based on superconductivity principles,” Borisov said. The electric motor is part of the hybrid powertrain demonstrator that Russia’s Central Institute of Aviation Motors (CIAM) is developing.
An innovative electric motor based on high-temperature superconductors with a capacity of 500 kW (679 HP) was created by materials specialist Superox.
Trials of a promising superconductive aircraft electric motor started on February 5. A special flying laboratory has been created on the basis of the Yak-40 aircraft.
You are constantly adjusting your walking parameters based on the feedback you’re getting from your environment. You walk differently on a soft surface, you prepare yourself before using stairs. Meanwhile robots cannot really do that, especially exoskeletons. These robotic legs could help disabled people walk again on their own, but how could they prepare to stop, climb stairs, make a sharp turn? Scientists believe that in the future exoskeletons are going to be smart thanks to cameras and artificial intelligence.
Currently exoskeletons need to be controlled manually via smartphone applications or joysticks. This is less than ideal, because the disabled person can’t walk as intuitively as an able-bodied person can. And his or her hands are always occupied with these controls. That kind of a cognitive load is extremely tiring and can be dangerous over time. Could you imagine needing to take out your phone every time you want to climb a set of stairs or walk through a strip of sand? Scientists want to borrow a page from a book about autonomous cars and therefore are optimizing AI computer software to process the video feed to accurately recognize stairs, doors and other features of the surrounding environment.
Brokoslaw Laschowski, leader of the ExoNet research project, said: “Our control approach wouldn’t necessarily require human thought. Similar to autonomous cars that drive themselves, we’re designing autonomous exoskeletons that walk for themselves.”
Global battery recycling industries are a new beginning for old energy storage.
When your kid looks at you with those big, innocent eyeballs and asks, “Where do lithium ion electric car batteries go when they die?” Without hesitation—because kids that age still believe you know everything—you read them this article:
Mighty Volkswagen—the carmaker that certainly looks like it is going to lead the world in the production of electric cars someday—now looks like it might lead the world in recycling electric car batteries, with the announcement that it has opened its first battery recycling plant in Salzgitter, Germany. OK, at a projected 3600 batteries recycled a year, maybe it won’t lead the world, but it will certainly lead battery recycling in Lower Saxony, between Hildesheim and Braunschweig. Globally speaking, all this battery recycling stuff is still being sorted out.
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Boston Dynamics – famous for robots like Atlas, BigDog, Handle, and Spot – has now revealed Stretch, its new box-moving robot designed to support the growing demand for flexible automation solutions in the logistics industry. This debut marks the company’s official entrance into warehouse automation, a fast-growing market fuelled by increased demand in e-commerce.
Stretch is Boston Dynamics’ first commercial robot specifically designed for warehouse facilities and distribution centres, of which there are more than 150000 around the world. The multi-purpose, mobile robot is designed to tackle a number of tasks where rapid box moving is required, first starting with truck unloading and later expanding into order building. Stretch’s technology builds upon Boston Dynamics’ decades of advancements in robotics to create a flexible, easily-integrated solution that can work in any warehouse to increase the flow of goods, improve employee safety in physically difficult tasks and lower expensive automation costs.
A new type of 3D-printed battery which uses electrodes made from vegetable starch and carbon nanotubes could provide mobile devices with a more environmentally-friendly, higher-capacity source of power.
A team of engineers led from the University of Glasgow have developed the battery in a bid to make more sustainable lithium-ion batteries capable of storing and delivering power more efficiently. The battery’s design and fabrication is outlined in a paper published in the Journal of Power Sources.
Lithium-ion batteries provide a useful combination of lightweight, compact form factors and the ability to withstand many cycles of charging and discharging. That has made them ideally suited for use in a wide array of devices, including laptops, mobile phones, smart watches, and electric vehicles.
Joby Avaiation could be the first to make air taxis a reality. The company is one of the most experienced companies trying to bring urban air taxis to the mainstream. Here’s the first look at its eVTOL. https://cnet.co/2Qp0YcV
A team of researchers at the University of Georgia has created a backpack equipped with AI gear aimed at replacing guide dogs and canes for the blind. Intel has published a News Byte describing the new technology on their Newsroom page.
Technology to help blind people get around in public has been improving in recent years, thanks mostly to smartphone apps. But such apps, the team notes, are not sufficient given the technology available. To make a better assistance system, the group designed an AI system that could be placed in a backpack and worn by a blind person to give them much better clues about their environment.
The backpack holds a smart AI system running on a laptop, and is fitted with OAK-D cameras (which, in addition to providing obstacle information, can also provide depth information) hidden in a vest and also in a waist pack. The cameras run Intel’s Movidius VPU and are programmed using the OpenVINO toolkit. The waist pack also holds batteries for the system. The AI system was trained to recognize objects a sighted pedestrian would see when walking around in a town or city, such as cars, bicycles, other pedestrians or even overhanging tree limbs.
