Abstract

Human-aware navigation is an essential requirement for autonomous robots in human-coexisting environments. The goal of conventional navigation is to find a path for a robot to pass through safely and efficiently without colliding with human. Note that if such a path cannot be found, the robot stops until a path is clear. Thus, such collision-avoidance based passive navigation does not work in a congested or narrow space. To avoid this freezing problem, the robot should induce humans to make a space for passing by an adequate inducement method, such as body movement, speech, and touch, depending on the situation. A robot that deliberately clears a path with such actions may make humans uncomfortable, so the robot should also utilize inducements to avoid causing negative feelings. In this study, we propose a fundamental framework of interactive navigation with situation-adaptive multimodal inducement. For a preliminary study, we target a passing scenario in a narrow corridor where two humans are standing and adopt a model-based approach focusing on common parameters. The suitable inducement basically varies depending on the largest space through which a robot can pass, distance between the robot and a human, and human behavior such as conversing. We thus develop a situation-adaptive inducement selector on the basis of the relationship between human–robot proximity and allowable inducement strength, considering robot efficiency and human psychology. The proposed interactive navigation system was tested across some contextual scenarios and compared with a fundamental path planner. The experimental results indicated that the proposed system solved freezing problems, provided a safe and efficient trajectory, and improved humans’ psychological reaction although the evidence was limited to robot planner and hardware design we used as well as certain scenes, contexts, and participants.

Highlights

  • Robot navigation is one of the most important functions for human-symbiotic autonomous mobile robots that are expected to provide various services such as logistics [1], housework for elderly or handicap people [2, 3], personal assistance in an office [4], and attending to a person in a museum or airport lobby [5]

  • It is better to adopt a variety of subjects, but to reduce the influence of this difference as much as possible, we choose 11 subjects who are the third-year students majoring in mechanical engineering at Waseda University who were knowledgeable about robotics

  • We modeled them on the basis of observation of human–human relationships, since this study is a preliminary study of an interactive navigation framework with situationadaptive multimodal inducement

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Summary

Introduction

Robot navigation is one of the most important functions for human-symbiotic autonomous mobile robots that are expected to provide various services such as logistics [1], housework for elderly or handicap people [2, 3], personal assistance in an office [4], and attending to a person in a museum or airport lobby [5]. In many real-world situations, a path to a goal without any physical contact with humans and/or obstacles is sometimes difficult to find, in human-crowded spaces In this case, the robot either makes no forward progress or takes extreme evasive action to avoid collisions [16]. The conventional approach that finds a collision-free path will not enable the robot to coordinate with humans even when it tries to pass through a narrow corridor, and this will cause the freezing problem [24,25,26,27] To solve this problem, the robot needs the ability to cooperate with humans.

Related and Required Works
Inducement for Conveying Intent in Robot Navigation
Required Work
Inputs
Outputs
Process
Pre-processing
Human and Environmental Information
Space Categorization
Region Categorization
Trajectory
Visual Inducement
Auditory Inducement
Haptic Inducement
Total System
Robot Specification
Concept
Situations and Robot Behaviors
9: Acceptance of passive touch
Evaluation Methods
Objective Evaluation
Subjective Evaluation
Acceptance of passive touch
Summary
Discussions and Required Future Works
Conclusion

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