Human cues used to improve computer user-friendliness. Lijun Yin wants computers to understand inputs from humans that go beyond the traditional keyboard and mouse. "Our research in computer graphics and computer vision tries to make using computers easier," says the Binghamton University computer scientist. "Can we find a more comfortable, intuitive and intelligent way to use the computer? It should feel like you're talking to a friend. This could also help disabled people use computers the way everyone else does. " Yin's team has developed ways to provide information to the computer based on where a user is looking as well as through gestures or speech. To some extent, that's already possible. Yin says the next step would be enabling the computer to recognize a user's emotional state.
"Computers only understand zeroes and ones," Yin says. He's partnering with Binghamton University psychologist Peter Gerhardstein to explore ways this work could benefit children with autism. Imagine if a computer could understand when people are in pain. iCub RobotCub ~ Official Site. iCub Robot Eye Tracking. AI. Robotics. Researchers Give Robots the Capability for Deceptive Behavior.
Georgia Tech Regents professor Ronald Arkin (left) and research engineer Alan Wagner look on as the black robot deceives the red robot into thinking it is hiding down the left corridor. (Click image for high-resolution version. Credit: Gary Meek) A robot deceives an enemy soldier by creating a false trail and hiding so that it will not be caught. While this sounds like a scene from one of the Terminator movies, it’s actually the scenario of an experiment conducted by researchers at the Georgia Institute of Technology as part of what is believed to be the first detailed examination of robot deception.
We have developed algorithms that allow a robot to determine whether it should deceive a human or other intelligent machine and we have designed techniques that help the robot select the best deceptive strategy to reduce its chance of being discovered,” said Ronald Arkin, a Regents professor in the Georgia Tech School of Interactive Computing. Memristor Processor Solves Mazes Memristors are the fourth fundamental building block of electronic circuits, after resistors, capacitors and inductors. They were famously predicted in the early 1970s but only discovered 30 years later at HP Labs in Palo Alto, California.
Memristors are resistors that “remember” the state they were in, which changes according to the current passing through them. They are expected to revolutionise the design and capabilities of electronic circuits and may even make possible brain-like architectures in silicon, since neurons behave like memristors. Today, we see one of the first revolutionary circuits thanks to Yuriy Pershin at the University of South Carolina and Massimiliano Di Ventra at the University of California, San Diego, two pioneers in this field. Mazes are a class of graphical puzzles in which, given an entrance point, one has to find the exit via an intricate succession of paths, with the majority leading to a dead end, and only one, or few, correctly “solving” the puzzle. Artificial Intelligence News.
Artificial Intelligence - Computer Science - Sciences - news. Stanford Artificial Intelligence Laboratory. MIT Computer Science and Artificial Intelligence Laboratory. Video: Japan's New Goateed Geminoid Robot Is Uncomfortably Realistic. Programmed DNA Robot Goes Where Scientists Tell It | Nanotechnology | LiveScience. A tiny robot made from strands of DNA could pave the way for mini-machines that can dive into the human body to perform surgeries, among other futuristic applications. While DNA-based robots have been made before, this latest real-life micromachine is the first one that researchers have successfully programmed to follow instructions on where to move. Once assembled, the robot can take multiple steps without any outside help, according to lead researcher Andrew Turberfield, a professor at the University of Oxford.
"Turberfield's group has figured out a beautiful way to automate the movement of a strand of DNA along a track," said William Sherman, an associate scientist at Brookhaven National Laboratory, who was not involved in the study. DNA bots When thinking about robots, many of us picture humanlike machines with metal moving parts, like Rosie from "The Jetsons. " DNA bots operate along similar lines, but on the molecular scale with chemical versions of motors and sensors.