Abstract
Range sensors are currently present in countless applications related to perception of the environment. In mobile robots, these devices constitute a key part of the sensory apparatus and enable essential operations, that are often addressed by applying methods grounded on probabilistic frameworks such as Bayesian filters. Unfortunately, modern mobile robots have to navigate within challenging environments from the perspective of their sensory devices, getting abnormal observations (e.g., biased, missing, etc.) that may compromise these operations. Although there exist previous contributions that either address filtering performance or identification of abnormal sensory observations, they do not provide a complete treatment of both problems at once. In this work we present a statistical approach that allows us to study and quantify the impact of abnormal observations from range sensors on the performance of Bayesian filters. For that, we formulate the estimation problem from a generic perspective (abstracting from concrete implementations), analyse the main limitations of common robotics range sensors, and define the factors that potentially affect the filtering performance. Rigorous statistical methods are then applied to a set of simulated experiments devised to reproduce a diversity of situations. The obtained results, which we also validate in a real environment, provide novel and relevant conclusions on the effect of abnormal range observations in these filters.
Highlights
Range sensors are nowadays present in numerous tasks involving perception of the environment
Our aim is to assess the impact of abnormal observations from range sensors on the performance of Bayesian filters
We state the main hypotheses that we aim to test with our study, discuss the obtained results from the application of rigorous statistical methods, and provide experimental validation of such results in a real environment with a mobile robot
Summary
Range sensors are nowadays present in numerous tasks involving perception of the environment. These devices are employed within a wide variety of applications related to industrial manufacturing [1], autonomous driving [2] and robotics [3], among many other fields. One of the most well-known shortcomings has to do with the impossibility of getting an exact value of any distance, since all the measurable quantities of the physical world are subjected to some degree of unpredictability This issue has been extensively treated and it is traditionally addressed by applying estimation theory [3]. There exist numerous kinds of estimators depending on the nature of the stochastic process to be considered (please refer to Reference [3] for a more in-depth treatment)
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