Social robot

While robots have often been described as possessing social qualities (see for example the tortoises developed by William Grey Walter in the 1950s), social robotics is a fairly recent branch of robotics. Since the early 1990s artificial intelligence and robotics researchers have developed robots which explicitly engage on a social level. Notable researchers include Cynthia Breazeal, Tony Belpaeme, Aude Billard, Kerstin Dautenhahn, Yiannis Demiris, Hiroshi Ishiguro, Maja Mataric, Javier Movellan, Brian Scassellati and Dean Weber. Also related is the Kansai engineering movement in Japanese science and technology --- for social robotics, see especially work by Takayuki Kanda, Hideki Kozima, Hiroshi Ishiguro, Micho Okada, Tomio Watanabe, and P. Ravindra S. De Silva.

Designing an autonomous social robot is particularly challenging, as the robot needs to correctly interpret people's action and respond appropriately, which is currently not yet possible. Moreover, people interacting with a social robot may hold very high expectancies of its capabilities, based on science fiction representations of advanced social robots. As such, many social robots are partially or fully remote controlled to simulate advanced capabilities. This method of (often covertly) controlling a social robot is referred to as a Mechanical Turk or Wizard of Oz, after the character in the L. Frank Baum book. Wizard of Oz studies are useful in social robotics research to evaluate how people respond to social robots.

A robot is defined in the International Standard of Organization as a reprogrammable, multifunctional manipulator designed to move material, parts, tools or specialized devices through variable programmed motions for performance of a variety of tasks. As a subset of robots, social robots perform any or all of these processes in the context of a social interaction. The nature of the social interactions is immaterial and may range from relatively simple supportive tasks, such as passing tools to a worker, to complex expressive communication and collaboration, such as assistive healthcare. Hence, social robots are asked to work together with humans in collaborative workspaces. Moreover, social robots start following humans into much more personal settings like home, health care, and education.

Social interactions are likely to be cooperative, but the definition is not limited to this situation. Moreover, uncooperative behavior can be considered social in certain situations. The robot could, for example, exhibit competitive behavior within the framework of a game. The robot could also interact with a minimum or no communication. It could, for example, hand tools to an astronaut working on a space station. However, it is likely that some communication will be necessary at some point.

Two suggested [1] ultimate requirements for social robots are the Turing Test to determine the robot's communication skills and Isaac Asimov's Three Laws of Robotics for its behavior. The usefulness to apply these requirements in a real-world application, especially in the case of Asimov's laws, is still disputed[2] and may not be possible at all). However, a consequence of this viewpoint is that a robot that only interacts and communicates with other robots would not be considered to be a social robot: Being social is bound to humans and their society which defines necessary social values, norms and standards.[3] This results in a cultural dependency of social robots since social values, norms and standards differ between cultures.

This brings us directly to the last part of the definition. A social robot must interact within the social rules attached to its role. The role and its rules are defined through society. For example, a robotic butler for humans would have to comply with established rules of good service. It should be anticipating, reliable and most of all discreet. A social robot must be aware of this and comply with it. However, social robots that interact with other autonomous robots would also behave and interact according to non-human conventions. In most social robots the complexity of human-to-human interaction will be gradually approached with the advancement of the technology of androids (a form of humanoid robots) and implementation of a variety of more human-like communication skills [4]

Researches have investigated user engagement with a robot companion. Literature present different models regarding this concern. An example is a framework that models both causes and effects of engagement: features related to the user's non-verbal behaviour, the task and the companion's affective reactions to predict children's level of engagement.[5]

The increasingly widespread use of more advanced social robots is one of several phenomena expected to contribute to the technological posthumanization of human societies, through which process “a society comes to include members other than ‘natural’ biological human beings who, in one way or another, contribute to the structures, dynamics, or meaning of the society.”[6]

One of the most well-known social robots currently in development is Sophia, developed by Hanson Robotics. Sophia is a social humanoid robot that can display more than 50 facial expressions, and is the first non-human to be given a United Nations title.

SoftBank Robotics has developed multiple social, semi-humanoid robots which are frequently used in research, including Pepper and Nao. Pepper is used both commercially and academically, as well as being used by consumers in over a thousand homes in Japan.

Other notable examples of social robots include ASIMO by Honda and Kaspar, designed by University of Hertfordshire to help children with autism learn responses from the robot through games and interactive play.[7] Anki's robots Cozmo and Vector also fell into the category of hyped social robots, but all were shut down between 2018 and 2019.

Social robots do not necessarily have to be humanoid. The most famous example of a non-humanoid social robot is Paro the seal.

• hitchBOT (decapitated in Philadelphia)
• Kismet
• Joe Robot
• Tico

• Walter, W. Grey (May 1950). "An Imitation of Life". Scientific American. pp. 42–45.
• Dautenhahn, Kerstin (1994). Gaussier, P.; Nicoud, J. D. (eds.). "Trying to Imitate - a Step Towards Releasing Robots from Social Isolation". Proceedings: From Perception to Action Conference. Lausanne, Switzerland: IEEE Computer Society Press: 290–301. doi:10.1109/FPA.1994.636112. ISBN 0-8186-6482-7.
• Dautenhahn, Kerstin (1995). "Getting to know each other - artificial social intelligence for autonomous robots". Robotics and Autonomous Systems. 16 (2–4): 333–356. doi:10.1016/0921-8890(95)00054-2.
• Breazeal, Cynthia L. (2002). Designing Sociable Robots. MIT Press. ISBN 0-262-02510-8.
• Fong, Terrence; Nourbakhsh, Illah R.; Dautenhahn, Kerstin (2003). "A survey of socially interactive robots". Robotics and Autonomous Systems. 42 (3–4): 143–166. doi:10.1016/S0921-8890(02)00372-X.

• International Journal of Social Robotics
• Interaction Studies: Social Behaviour and Communication in Biological and Artificial Systems

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