Carnegie Mellon University's CHIMP will have a near-human form factor and the ability to execute complex tasks in dangerous human-engineered environments. To avoid the need for complex control, the robot will maintain static rather than dynamic stability. (Source: Carnegie Mellon University)
I completely agree with you about human-like robots not being necessary for working in human-design spaces. I also think that goes for how human-like they must be in looks or operation: Some people like that similarity to humans, but some, like me, not only don't need it but find the uncanny valley effect horrific. OTOH, a lot of work has been done to help robots and humans communicate better so they can work together safely and productively. One of those things is designing robot hands to work more like ours for a number of reasons: http://www.designnews.com/author.asp?section_id=1386&doc_id=260644
It's true that clear communication and comprehension are important. Acronyms and colloquialisms can be confusing.
Back to the robots...I don't agree that robots' "perceptions and movements should be as human as possible" in order to work in a space designed for humans. Observing a cat or dog in a new space demonstrates that non-humans can navigate spaces created for humans as well as, or better than, people.
I find that using clear, widely-understood meanings for terms makes written, non-duplex communication much easier (spoken, full-duplex communication, like in a phone or F2F conversation, is of course usually a lot clearer since multiple, instant iterations are possible when needed). I also find that precision and accuracy are important in all communications.
Nadine, thanks for the comment. I interpreted, "At the end of the day, all robots are bio-mimics. Humans included." to mean what its grammar says, which is that humans are bio-mimics. It's hard to interpret that in some other way. In any case, I do agree about more precise writing and close reading.
Nadine, yes I was responding to your comment. I agree that biomimicry doesn't exclude humans: that seems obvious. I've studied biomimicry in robotics, and saying all robots are biomimics isn't accurate in that area, although it may be elsewhere. But it's such a general statement that I don't see its usefulness from robotics engineering standpoint. And saying humans are biomimics doesn't make sense to me at all, since we are biological systems. In any case, my comments specifically about biomimicry in robotics stand.
Biomimicry in robotics, at least, doesn't mean generally resembling; it means something very specific. It refers to studying particular biological systems to see how they work, and translating their neurological, muscular, skeletal, etc systems--structures and/or functions-- into mechanical and/or electronic analogs. This is much more recent than the fundamental research type of approach that goes more like: what would happen if we made a robot with three legs vs six and used XYZ actuation types. Boston Dynamics, for example, was one of the very early pioneers in patterning robots after specific animals.
Samsung's Galaxy line of smartphones used to fare quite well in the repairability department, but last year's flagship S5 model took a tumble, scoring a meh-inducing 5/10. Will the newly redesigned S6 lead us back into star-studded territory, or will we sink further into the depths of a repairability black hole?
In 2003, the world contained just over 500 million Internet-connected devices. By 2010, this figure had risen to 12.5 billion connected objects, almost six devices per individual with access to the Internet. Now, as we move into 2015, the number of connected 'things' is expected to reach 25 billion, ultimately edging toward 50 billion by the end of the decade.
NASA engineer Brian Trease studied abroad in Japan as a high school student and used to fold fast-food wrappers into cranes using origami techniques he learned in library books. Inspired by this, he began to imagine that origami could be applied to building spacecraft components, particularly solar panels that could one day send solar power from space to be used on earth.
Biomedical engineering is one of the fastest growing engineering fields; from medical devices and pharmaceuticals to more cutting-edge areas like tissue, genetic, and neural engineering, US biomedical engineers (BMEs) boast salaries nearly double the annual mean wage and have faster than average job growth.
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