HughesNet’s move to offer 100 Mbps speeds brings it closer to its industry rival, SpaceX’s Starlink, which ranges between 25 to 220 Mbps.
HughesNet’s Jupiter 3 satellite, although geostationary and considerably farther away, rivals Starlink with its size and capacity. The ultra-high-density satellite operates in Ka-band frequencies with 300 spot beams, efficiently allocating and directing signals for better coverage.
Hughes, a pioneer in satellite-delivered internet service since the 1990s, continues to earn recognition.
The company launched 23 of its Starlink internet satellites on a Falcon 9 rocket that had flown 18 times before, breaking its own record for the most flights by a single booster.
SpaceX has achieved a new milestone in its quest to reuse rockets and reduce the cost of spaceflight. The company launched 23 Starlink internet satellites on a Falcon 9 rocket that had flown 18 times before, breaking its record for the most flights by a single booster.
A team of researchers, led by Professor Hyong-Ryeol Park from the Department of Physics at UNIST has introduced a technology capable of amplifying terahertz (THz) electromagnetic waves by over 30,000 times. This breakthrough, combined with artificial intelligence (AI) based on physical models, is set to revolutionize the commercialization of 6G communication frequencies.
Collaborating with Professor Joon Sue Lee from the University of Tennessee and Professor Mina Yoon from the Oak Ridge National Laboratory, the research team successfully optimized the THz nano-resonator specifically for 6G communication using advanced optimization technology.
The research findings have been published in the online version of Nano Letters.
This timelapse of future technology begins with 2 Starships, launched to resupply the International Space Station. But how far into the future do you want to go?
Tesla Bots will be sent to work on the Moon, and A.I. chat bots will guide people into dreams that they can control (lucid dreams). And what happens when humanity forms a deeper understanding of dark energy, worm holes, and black holes. What type of new technologies could this advanced knowledge develop? Could SpaceX launch 100 Artificial Intelligence Starships, spread across our Solar System and beyond into Interstellar space, working together to form a cosmic internet, creating the Encyclopedia of the Galaxy. Could Einstein’s equations lead to technologies in teleportation, and laboratory grown black holes.
SpaceX is aiming to launch another batch of Starlink v2 Mini satellites from the Space Launch Complex 40 launchpad. This Booster, B1058, will try to launch and land for a record-breaking 19th time.\ \ Window Opens: December 22nd at 11PM EST (04:00 UTC on the 23rd)\ Window Closes: December 23rd at 3:31AM EST (08:31 UTC)\ Primary T0: December 22nd at 11:00PM EST (04:00 UTC on the 23rd)\ \ Mission: F9 launch of 23 Starlink v2 Mini satellites \ Target orbit: 285km perigee, 293km apogee, 43 degree inclination.\ Booster: B1058-19; 49d 3h 22min 40s turnaround\ Booster history: Demo-2, Anasis II, SL v1.0–12, CRS-21, Transporter-1, SL v1.0–20, SL v1.0–23, SL v1.0–26, SL 4–1, Transporter-3, SL 4–8, SL 4–17, SL 4–21, SL 4–2, SL 4–37, SL 6–5, SL 6–17, SL 6–26.\ Booster recovery: Droneship Just Read The Instructions (JRIT) located 629km downrange\ Fairing recovery: Bob\ Rocket trajectory: Southeast passing north of Bahamas\ Stubby nozzle: NO\ Stats: \ · SpaceX’s 95th launch of the year and the 6th launch of the month\ · 262nd Falcon orbital launch since Amos 6, F9’s 282nd orbital flight.\ · SpaceX’s 161st launch from SLC-40\ · 71st landing on JRTI out of 72 attempts\ · 181st successful landing since the last failed one\ · 55th launch dedicated to Starlink Gen 2 and 129th launch dedicated to Starlink overall.\ · First Falcon booster to fly for a 19th time\ \ Forum: https://forum.nasaspaceflight.com/ind…\ \ ⚡ Become a member of NASASpaceflight’s channel for exclusive discord access, fast turnaround clips, and other exclusive benefits. Your support helps us continue our 24/7 coverage. ⚡\ \ 🔍 If you are interested in using footage captured by this stream, please review our content use policy: https://www.nasaspaceflight.com/conte…
Quanta Magazine’s full list of the major computer science discoveries from 2023.
In 2023, artificial intelligence dominated popular culture — showing up in everything from internet memes to Senate hearings. Large language models such as those behind ChatGPT fueled a lot of this excitement, even as researchers still struggled to pry open the “black box” that describes their inner workings. Image generation systems also routinely impressed and unsettled us with their artistic abilities, yet these were explicitly founded on concepts borrowed from physics.
But what would it actually mean to transfer your mind from “meat space” to cyberspace, and how could it be done? The basic idea rests on several assumptions, says Angela Thornton, a researcher at the Horizon Centre for Doctoral Training at University of Nottingham, who is also partnered with the Carboncopies Foundation, a non-profit that focuses on “whole brain emulation” and the creation of substrate-independent minds. “It assumes that we could replicate our brain [with] a certain level of understanding of how it works,” she says. “Not necessarily knowing all the detail, but enough to be able to emulate it.” Then, she adds, we have to make the assumption that the “mind” (i.e. the abstract part of us that thinks, remembers, imagines and senses) naturally emerges from the structures of the physical brain.
This is a lot to take on, which is partly why current brain emulation research is still stuck at the level of worms and, in more advanced studies, mice. Whether you agree with them or not, though, the arguments to take experiments further – toward larger mammals and, finally, humans – are quite obvious. For one, we could theoretically ‘live’ forever as a disembodied consciousness (or at least until the machines that hosted our virtual minds were destroyed), and continue interacting with our loved ones after they’ve passed as well. It’s possible that this could also go some way to solving the alleged population crisis, while limiting the impact of our physical bodies on the planet’s finite resources.
Scattered across the web are communities of programmers working to revive this seemingly outdated approach. Anchored in the concept of “HTML Energy,” a term coined by artists Laurel Schwulst and Elliott Cost, the movement is anything but a superficial appeal to retro aesthetics. It focuses on the tactile process of coding in HTML, exploring how the language invites self-expression and empowers individuals to claim their share of the web. Taking shape in small Discord channels and digital magazines, among other spaces, the HTML Energy movement is about celebrating the human touch in digital experiences.
Today, the majority of the internet is optimized for social engagement, e-commerce, and streaming. Most internet traffic is concentrated in a small number of sites, all of which are owned by the same handful of companies. From lengthy ads to aggressive cookie settings, minor obstacles and nuisances are baked in. Users are constantly reminded that their access to the internet is conditional on the monetary interests of a few. The situation with X (formerly known as Twitter) perfectly encapsulates this state of internet ownership: it only took one executive to spark a mass exodus from the platform and to fragment its long-lived communities.
However, despite the monopolistic landscape of Big Tech, one fundamental reality continues to justify the internet’s democratic reputation: anyone can publish a website for free with HTML. With an abundance of real estate, the web technically has space for everyone. It’s just a matter of traffic.
A team of international scientists have developed an ultra-high speed signal processor that can analyze 400,000 real time video images concurrently, according to a paper published in Communications Engineering.
The team, led by Swinburne University of Technology’s Professor David Moss, have developed a processor that operates more than 10,000 times faster than typical electronic processors that operate in Gigabyte/s, at a record 17 Terabits/s (trillion bits per second).