jfruh writes "Stratasys, one of the world's biggest 3D printer manufacturers, routinely uses 3D-printed objects as displays for its booths at trade shows. The problem: It's been using objects designed by popular designer Asher Nahmias, whose creations are licensed under a noncommercial Creative Commons license — and he says Stratasys's use violates the licensing terms. This is just one example of how the nascent 3D printing industry is having to grapple with the IP implications of creating physical objects out of downloadable designs. Another important problem: IP law distinguishes between purely decorative and useful objects, but how should the digital files that provide a design for those objects be treated?" The models are copyrighted and licensed NC, but what about the resulting object? Precedent seems to imply that the resulting object cannot be controlled (e.g. the output of a GPLed program is not GPLed, so why should executing a program on a 3D printer be any different?).
Slashdot stories can be listened to in audio form via an RSS feed, as read by our own robotic overlord.
An anonymous reader writes "Google today announced it is bringing its Cloud Print project to Windows. The company has launched both a driver and a service, both of which are available for download now from Google Tools. For those who don't know, Google Cloud Print connects Cloud Print-aware applications (across the Web, desktop, and mobile) to any printer. It integrates with the mobile versions of Gmail and Google Docs, and is also listed as a printer option in the Print Preview page of Chrome." One of the things that annoys me about Android: having to print through the Cloud (tm) when I have an Internet Printing Protocol CUPS server on the same network as my phone connected to a printer ten feet from me. It wouldn't be so bad if the Google Cloud Print libraries weren't proprietary and did something like IPP proxying instead of using a similarly proprietary API.
MojoKid writes "Convertible laptops and ultrabooks had a big presence this year with the release of Windows 8. At CES, Lenovo revealed its ThinkPad Helix which it marketed as having a 'groundbreaking "rip and flip" design' that enables this 11.6-inch ultrabook to transform into a powerful Windows 8 tablet with Intel vPro technology for the enterprise. The ThinkPad Helix lets you work in four different modes: laptop, tablet, stand, and tablet+. When attached to the Enhanced Keyboard Dock in laptop mode, you'll get additional battery life and additional ports as well as Lenovo's ThinkPad Precision keyboard, a five button trackpad that supports Windows 8 features, and a traditional ThinkPad TrackPoint. ... The ThinkPad Helix features an 11.6-inch Full HD 1080p IPS (In-Plane Switching) 10-point multi-touchscreen with pen touch input and Gorilla Glass for protection. Lenovo claims the ThinkPad Helix will run for up to 8 hours on a single charge. Performance-wise, the new ThinkPad tablet convertible doesn't have a ton of horsepower, but the machine will get by well enough handling light multimedia and office app use with relative ease." The "stand" mode is just the tablet part mounted away from the keyboard, tablet+ similarly just the tablet part folded over the dock giving it a longer battery life and more ports. It comes at a price though: ~$1800.
An anonymous reader writes "Scientists at the University of California, Berkeley have designed a super-thin flexible skin that lights up when touched. 'Thinner than a sheet of paper, the skin is made from layers of plastic and a pressure-sensitive rubber. A conductive silver ink, organic LEDs, and thin-film transistors made from semiconductor-enriched carbon nanotubes are sandwiched between the layers. Applying pressure sends a signal through the rubber that ultimately turns on the LEDs, which light up in red, green, yellow or blue. Instead of using the material to create bodysuits for Burning Man or other illuminated party tricks, scientists suggest that it might be used for smart wallpapers, health-monitoring devices, or in robotics. The type of interactive pressure sensor developed by the Berkeley scientists could also be useful in artificial skin for prosthetic limbs'"
cylonlover writes "Researchers at ETH Zurich have demonstrated an amazing capability for small robots to self-assemble and take to the air as a multi-rotor helicopter. Maximilian Kriegleder and Raymond Oung worked with Professor Raffaello D'Andrea at his research lab to develop the small hexagonal pods that assemble into flying rafts. The true accomplishment of this research is that there is not one robot in control – each unit in itself decides what actions to take to keep the group in the air in what's known as Distributed Flight Array."