Biochemists and computer scientists at the University of Washington two years ago launched an ambitious project harnessing the brainpower of computer gamers to solve medical problems. Results published this week in the journal Nature show more than 55,000 players have played protein-folding Tetris, and beat the world’s most powerful computers on problems that required radical moves, risks and long-term vision.
Using a home’s electrical wiring as a giant copper antenna enables extremely low-power wireless sensors that run for decades on a single watch battery. The device could be used for low-cost medical monitoring or home sensing systems.
You’ve heard about flower power. What about tree power? It turns out that it’s there, in small but measurable quantities. There’s enough power in trees for University of Washington researchers to run an electronic circuit.
UW engineers have built an insectlike robot with hundreds of tiny legs. Compared to other such robots, the UW model excels in its ability to carry heavy loads – more than seven times its own weight – and move in any direction.
New findings from computer modeling indicate some exoplanets might fluctuate between being habitable and being inhospitable to life because of forces exerted by giant neighbors with eccentric orbits.
University of Washington engineers are developing the first device able to transmit American Sign Language over U.S. cellular networks. The tool is just completing its initial field test by participants in a UW summer program for deaf and hard-of-hearing students.
Electrodes attached to the surface of the human brain show that imagining movements to control a computer cursor generates larger-than-life brain signals in less than 10 minutes of training.
New research solves nagging issues in the theory of how cold dark matter let the universe evolve into the galaxy-rich cosmos we see today.
Using tourist photos downloaded from the Web, computer scientists created a digital version of Rome in about a day.
A new organic material lets both positive and negative charges flow efficiently. It permits a simpler design of organic electronics, using a single material for transporting positive and negative charges.