Submitted by Soupjoe5 t3_yspniw in Futurology
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Although the company, which has its origins in making animated figures for the entertainment industry, can construct highly realistic faces, Ameca’s phizog is designed deliberately to look how people might expect a robot from the world of science fiction to appear. It has a grey complexion, visible joints and no hair. It therefore avoids falling into the “uncanny valley”, an illusion that happens when an artificially created being shifts from looking clearly not human into something more real, but not quite real enough. At this point people feel disturbed by its appearance. Comfort levels rise again as similarity to a human becomes almost perfect.
Some roboticists do, however, seek such perfection. Besides assisting people, robots can also act as their avatar representatives. Ishiguro Hiroshi, director of the Intelligent Robotics Laboratory at Osaka University, in Japan, has built one in his own image. He recently unveiled another, which resembles Kono Taro, Japan’s digital minister. The idea is that people either speak through their avatar with their own voice, or through someone else’s voice modified to sound like them. Mr Kono’s avatar will, apparently, be used to stand in for the minister at public-relations functions.
Ameca could also work as an avatar. Though less humanlike, its conversation is more compelling. That loquaciousness comes from an external “brain” in the form of an ai program called a large language model. It interacts with this over a wi-fi connection and the Internet. Engineered Arts is also working on hardware and software to allow the latest developments in computer vision to be incorporated quickly into its robots. And, as Mr Jackson readily admits, Ameca needs work in other areas, too. Asked if it can walk, the robot replies: “Unfortunately not, but I hope to soon. Until then I am bolted to the floor.” A set of experimental legs stands ready in a nearby corner.
Different strokes
Different companies are coming from different directions in their approaches to making humanoid robots. Mr Jackson, born into a family of artists involved in automatons, gravitated naturally towards producing modern versions of them for the likes of theme parks, museums and the film industry. These have steadily evolved in sophistication. Some work as interactive guides. Others are used as research platforms by universities. During the covid lockdown, when business dried up, the firm threw all of its resources at developing Ameca, its most advanced model yet.
Other developers, like Tesla, are able to organise far bigger efforts—but not always successfully, as the case of Honda, a Japanese carmaker, shows. At one point, Honda’s diminutive humanoid robot asimo was considered the world’s most advanced. The firm started work on this project in the 1980s, and although asimo could walk—albeit clumsily—interpret voice commands and move objects, Honda shut the project down in 2018 to concentrate instead on more practical forms of robotics, such as mobility devices for the elderly.
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Other roboticists have turned a hobby into a business. Shadow Robot, a firm in London that makes one of the most dexterous human-like robot hands available, traces its roots to hobbyists meeting in the attic of its founder’s home. Most robot developers, however, have emerged from universities. One of the best known is Boston Dynamics, which began at the Massachusetts Institute of Technology. Atlas, its Hulk-like humanoid, has become an Internet video sensation—running, jumping and performing backflips. But Atlas is principally a research project, and at present would be too expensive to put into production. The company does sell a walking robot, but it is a four-legged one called Spot, which resembles a dog.
One of a bipedal robot’s advantages is that it should, in principle, be able to go wherever a person can. That includes navigating uneven surfaces and walking up and down steps. Digit, made by Agility Robotics of Corvallis, Oregon, is actually able to do this.
Digit is based on a walking torso called Cassie, which was developed at Oregon State University using machine-leaning studies of human locomotion. It set a world record in May as the fastest robot to run 100 metres. (It did so in 24.7 seconds, some way behind Usain Bolt’s 9.6.)
Unlike Cassie, Digit has a chest, arms and hands of a sort—though no fingers. In place of a head it has a lidar, an optical analogue of radar that builds up a three-dimensional model of the world around it using lasers. Digit is not designed to be humanoid, says Jonathan Hurst, Agility’s Chief Technology Officer. It is, rather, a “human-centric” robot intended as a tool for people to use to achieve more things.
One of Digit’s first roles is likely to be in a distribution centre run by an online retailer or freight company. Some already use automated goods-handling, but usually in areas fenced off to keep people out, in order to avoid injuries. Elsewhere, tasks remain labour intensive. By being designed to work safely alongside people, Digit could start changing this—for instance, by moving and stacking crates. It could then progress to unloading trucks. Eventually, it might even make home deliveries, carrying items from a van to the doorstep. Ultimately, the aim is for a user to be able to instruct the robot by talking to it.
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Agility plans to produce Digit in volume by 2024. It is working with several big, though unnamed, delivery outfits, on ways in which Digit could work safely with people. If someone is detected by the robot’s sensors it pauses and then navigates around him or her. Nevertheless, says Dr Hurst, the robot will soon acquire a simplified face to help signal its intentions. An animated set of eyes, for instance, will look in a particular direction to indicate which way it is heading, and a glance at someone will show it has detected them.
Do no harm
Such safety systems will be needed for robots to interact successfully with people. At present, the use of robots is governed mainly by standard safety and product liability rules. Some argue, though, that special robot-specific laws will be required to ensure they are operated safely. As every scifi buff knows, Isaac Asimov laid out a set of these eight decades ago. They are:
• A robot may not injure a human being or, through inaction, allow a human being to come to harm.
• A robot must obey the orders given to it by human beings, except where such orders would conflict with the First Law.
• A robot must protect its own existence as long as such protection does not conflict with the First or Second Laws.
But, as every scifi buff also knows, Azimov’s storylines often revolve around these laws not quite working as planned.
About his Digits, Dr Hurst says, “My opinion is that they are very safe. But we need real statistics and a regulatory environment to prove this.”
For his part, Mr Musk said that Optimus would contain a device that could be used as an off switch if necessary. Although the robot itself would be connected to wi-fi, the switch would not, so that it was isolated to prevent remote interference.
As far as the Amecas’ safety is concerned, Mr Jackson is taking an engineering approach. He observes that one reason human limbs avoid injuring others is by being firm and floppy at the same time. Unfortunately, the small, powerful actuators needed to emulate this in robots do not yet exist. He is working on that, though, for it will be of little use teaching an Ameca social graces if it then commits the faux pas of bashing into you.
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