Abstract
The exponentially increasing advances in robotics and machine learning are facilitating the transition of robots from being confined to controlled industrial spaces to performing novel everyday tasks in domestic and urban environments. In order to make the presence of robots safe as well as comfortable for humans, and to facilitate their acceptance in public environments, they are often equipped with social abilities for navigation and interaction. Socially compliant robot navigation is increasingly being learned from human observations or demonstrations. We argue that these techniques that typically aim to mimic human behavior do not guarantee fair behavior. As a consequence, social navigation models can replicate, promote, and amplify societal unfairness, such as discrimination and segregation. In this work, we investigate a framework for diminishing bias in social robot navigation models so that robots are equipped with the capability to plan as well as adapt their paths based on both physical and social demands. Our proposed framework consists of two components: learning which incorporates social context into the learning process to account for safety and comfort, and relearning to detect and correct potentially harmful outcomes before the onset. We provide both technological and societal analysis using three diverse case studies in different social scenarios of interaction. Moreover, we present ethical implications of deploying robots in social environments and propose potential solutions. Through this study, we highlight the importance and advocate for fairness in human-robot interactions in order to promote more equitable social relationships, roles, and dynamics and consequently positively influence our society.
Highlights
The last decade has brought numerous breakthroughs in the development of autonomous robots which is evident from the manufacturing and service industries
Novel machine learning algorithms accompanied by the boost in computational capacity and availability of large annotated datasets have primarily fostered the progress in this field
As more and more robots navigate in human spaces, they require more complex navigation models to accomplish their goals while complying with the high safety and comfort requirements
Summary
The last decade has brought numerous breakthroughs in the development of autonomous robots which is evident from the manufacturing and service industries. In learning-based mobile robot navigation, fairness behavior depends on data and on the future actions of the humans around the robot and other factors of the environment In this case, it is impractical to anticipate all the possible actions in advance during the development of these models. As humans, relearn about the physical world to react to unexpected obstacles in our path, but we develop adaptability in terms of interaction This generally prevents us from causing harm to others with our actions and enables us to correct our behavior when we encounter unfair situations. Our proposed framework facilitates diminishing bias in the behavior of the robot and generates early warnings of discrimination after the deployment It enables the adaptation of the robot’s navigation model to new cultural and social conditions that are not considered during training. We provide detailed case studies that analyze the impact of bias in different service and caregiving robot applications and discuss mitigation strategies
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