While it just missed its goal of making its maiden manned voyage at January’s CES event, Ohio-based company Workhorse’s SureFly hybrid-electric helicopter has finally lifted off for its first untethered flight. Well, it got a few feet off the ground, at least.
“A five-foot hover might not seem like a big deal, but what it does is to answer the question: Will it fly, yes or no?” CEO Steve Burns told Digital Trends.
The answer, as Burns is quick to point out, is a resounding yes. That’s exciting because the SureFly octocopter is a new kind of vehicle. It’s essentially a human-sized vertical-take-off-and-landing (VTOL) drone designed for up to two people. Its creators hope that it will both broaden and corner the market when it comes to personal flying machines.
Artificial intelligence has the potential to create trillions of dollars of value across the economy—if business leaders work to understand what AI can and cannot do.
In this episode of the McKinsey Podcast, McKinsey Global Institute partner Michael Chui and MGI chairman and director James Manyika speak with McKinsey Publishing’s David Schwartz about the cutting edge of artificial intelligence.
David Schwartz: Hello, and welcome to the McKinsey Podcast. I’m David Schwartz with McKinsey Publishing. Today, we’re going to be journeying to the frontiers of artificial intelligence. We’ll touch on what AI’s impact could be across multiple industries and functions. We’ll also explore limitations that, at least for now, stand in the way.
https://www.wired.com/…/biology-will-be-the-next-great-comp…
In some ways, Synthego looks like any other Silicon Valley startup. Inside its beige business park facilities, a five-minute drive from Facebook HQ, rows of nondescript black server racks whir and blink and vent. But inside the metal shelving, the company isn’t pushing around ones and zeros to keep the internet running. It’s making molecules to rewrite the code of life.
Crispr, the powerful gene-editing tool, is revolutionizing the speed and scope with which scientists can modify the DNA of organisms, including human cells. So many people want to use it—from academic researchers to agtech companies to biopharma firms—that new companies are popping up to staunch the demand. Companies like Synthego, which is using a combination of software engineering and hardware automation to become the Amazon of genome engineering. And Inscripta, which wants to be the Apple. And Twist Bioscience, which could be the Intel.
All these analogies to the computing industry are more than just wordplay. Crispr is making biology more programmable than ever before. And the biotech execs staking their claims in Crispr’s backend systems have read their Silicon Valley history. They’re betting biology will be the next great computing platform, DNA will be the code that runs it, and Crispr will be the programming language.
A compelling study from a team of researchers at the University of Copenhagen has demonstrated a way to completely stop a body’s ability to store fat. In experiments with mice, the team showed that genetically deleting a single enzyme resulted in the animal not being able to gain weight, even when fed a fatty diet.
An enzyme dubbed NAMPT has been connected to obesity in both human and animal models by several studies. Its presence in fat tissue has been found to increase metabolic functionality in numerous body tissues, including fat tissue, which enhances the body’s ability to store fat.
“NAMPT in fat tissue was likely once an extraordinary benefit to our ancestors but in today’s society full of high-fat, calorically-dense foods, it may now pose a liability,” says Zachary Gerhart-Hines, a corresponding author on the study.
Hughes, 34, now devotes his time to evangelizing for higher taxes on the rich, such as himself. He’s proposing that the government give a guaranteed income of $500 a month to every working American earning less than $50,000 a year, at a total cost of $290 billion a year. This is a staggering number, but Hughes points out that it equals half the U.S. defense budget and would combat the inequality that he argues is destabilizing the nation.
Chris Hughes thinks $290 billion a year is a small price to pay for equality.
The breakthrough is in its mobile joints that accurately mimic human kinetics.
Toyota has been working on humanoid robots for a while. It recently unveiled the THR-3 that’s built to test specific joints and movements by putting together a full body that can be controlled by a human operator. The robot can mimic a variety of human movements in real time. Apr.23.2018
Massive.
Giant, continent-sized storms were observed by NASA’s Juno spacecraft.
“Thanks to the amazing increase in accuracy brought by Juno’s gravity data, we have essentially solved the issue of how Jupiter rotates: The zones and belts that we see in the atmosphere rotating at different speeds extend to about 1,900 miles (3,000 km),” Tristan Guillot, of the University of Côte d’Azur in France, said in that statement, according to LiveScience.
One photograph of the planet was taken 7,659 miles above the surface in the northern hemisphere, the Express reported.
Scientists from the Max Born Institute for Nonlinear Optics and Short Pulse Spectroscopy (MBI) in Berlin combined state-of-the-art experiments and numerical simulations to test a fundamental assumption underlying strong-field physics. Their results refine our understanding of strong-field processes such as high harmonic generation (HHG) and laser-induced electron diffraction (LIED).
Strong infrared laser pulses can extract an electron from a molecule (ionization), accelerate it away into free space, then turn it around (propagation), and finally collide it with the molecule (recollision). This is the widely used three-step model of strong-field physics. In the recollision step, the electron may, for example, recombine with the parent ion, giving rise to high harmonic generation, or scatter elastically, giving rise to laser-induced electron diffraction.
One of the commonly used assumptions underlying attosecond physics is that, in the propagation step, the initial structure of the ionized electron is “washed out”, thus losing the information on the originating orbital. So far, this assumption was not experimentally verified in molecular systems.
