CityLearn: Diverse Real-World Environments for Sample-Efficient Navigation Policy Learning

Abstract: <div>Visual navigation tasks in real-world environments often require both self-motion and place recognition feedback. While deep reinforcement learning has shown success in solving these perception and decision-making problems in an end-to-end manner, these algorithms require large amounts of experience to learn navigation policies from high-dimensional data, which is generally impractical for real robots due to sample complexity. In this paper, we address these problems with two main contributions. We … Show more

“…Thirdly, the rise of mobile robots operating in the open world, e.g., selfdriving cars, and the inherent challenge of their long term autonomy. Pertaining to the last point, recognizing places by vision is regarded as a key component for localization and navigation, being used for loop-closure in SLAM algorithms in GPS denied environments as well as an input to learn navigation policies [1] under different conditions. Remarkably, the development of visual localization in robotics is also paving the way for new applications of VPR, such as assistive technologies for people with visual impairments [2].…”

A Survey on Deep Visual Place Recognition

“…Thirdly, the rise of mobile robots operating in the open world, e.g., selfdriving cars, and the inherent challenge of their long term autonomy. Pertaining to the last point, recognizing places by vision is regarded as a key component for localization and navigation, being used for loop-closure in SLAM algorithms in GPS denied environments as well as an input to learn navigation policies [1] under different conditions. Remarkably, the development of visual localization in robotics is also paving the way for new applications of VPR, such as assistive technologies for people with visual impairments [2].…”

A Survey on Deep Visual Place Recognition