Multi-Agent Dynamic Relational Reasoning for Social Robot Navigation
- URL: http://arxiv.org/abs/2401.12275v1
- Date: Mon, 22 Jan 2024 18:58:22 GMT
- Title: Multi-Agent Dynamic Relational Reasoning for Social Robot Navigation
- Authors: Jiachen Li and Chuanbo Hua and Hengbo Ma and Jinkyoo Park and Victoria
Dax and Mykel J. Kochenderfer
- Abstract summary: Social robot navigation can be helpful in various contexts of daily life but requires safe human-robot interactions and efficient trajectory planning.
We propose a systematic relational reasoning approach with explicit inference of the underlying dynamically evolving relational structures.
Our approach infers dynamically evolving relation graphs and hypergraphs to capture the evolution of relations, which the trajectory predictor employs to generate future states.
- Score: 55.65482030032804
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Social robot navigation can be helpful in various contexts of daily life but
requires safe human-robot interactions and efficient trajectory planning. While
modeling pairwise relations has been widely studied in multi-agent interacting
systems, the ability to capture larger-scale group-wise activities is limited.
In this paper, we propose a systematic relational reasoning approach with
explicit inference of the underlying dynamically evolving relational
structures, and we demonstrate its effectiveness for multi-agent trajectory
prediction and social robot navigation. In addition to the edges between pairs
of nodes (i.e., agents), we propose to infer hyperedges that adaptively connect
multiple nodes to enable group-wise reasoning in an unsupervised manner. Our
approach infers dynamically evolving relation graphs and hypergraphs to capture
the evolution of relations, which the trajectory predictor employs to generate
future states. Meanwhile, we propose to regularize the sharpness and sparsity
of the learned relations and the smoothness of the relation evolution, which
proves to enhance training stability and model performance. The proposed
approach is validated on synthetic crowd simulations and real-world benchmark
datasets. Experiments demonstrate that the approach infers reasonable relations
and achieves state-of-the-art prediction performance. In addition, we present a
deep reinforcement learning (DRL) framework for social robot navigation, which
incorporates relational reasoning and trajectory prediction systematically. In
a group-based crowd simulation, our method outperforms the strongest baseline
by a significant margin in terms of safety, efficiency, and social compliance
in dense, interactive scenarios.
Related papers
- Neural Interaction Energy for Multi-Agent Trajectory Prediction [55.098754835213995]
We introduce a framework called Multi-Agent Trajectory prediction via neural interaction Energy (MATE)
MATE assesses the interactive motion of agents by employing neural interaction energy.
To bolster temporal stability, we introduce two constraints: inter-agent interaction constraint and intra-agent motion constraint.
arXiv Detail & Related papers (2024-04-25T12:47:47Z) - Disentangled Neural Relational Inference for Interpretable Motion
Prediction [38.40799770648501]
We develop a variational auto-encoder framework that integrates graph-based representations and timesequence models.
Our model infers dynamic interaction graphs augmented with interpretable edge features that characterize the interactions.
We validate our approach through extensive experiments on both simulated and real-world datasets.
arXiv Detail & Related papers (2024-01-07T22:49:24Z) - Interactive Autonomous Navigation with Internal State Inference and
Interactivity Estimation [58.21683603243387]
We propose three auxiliary tasks with relational-temporal reasoning and integrate them into the standard Deep Learning framework.
These auxiliary tasks provide additional supervision signals to infer the behavior patterns other interactive agents.
Our approach achieves robust and state-of-the-art performance in terms of standard evaluation metrics.
arXiv Detail & Related papers (2023-11-27T18:57:42Z) - EvolveHypergraph: Group-Aware Dynamic Relational Reasoning for
Trajectory Prediction [39.66755326557846]
We propose a group-aware relational reasoning approach (namedHypergraph) with explicit inference of the underlying dynamically evolving relational structures.
Our approach infers explainable, reasonable group-aware relations and achieves state-of-the-art performance in long-term prediction.
arXiv Detail & Related papers (2022-08-10T17:57:10Z) - Multi-Agent Imitation Learning with Copulas [102.27052968901894]
Multi-agent imitation learning aims to train multiple agents to perform tasks from demonstrations by learning a mapping between observations and actions.
In this paper, we propose to use copula, a powerful statistical tool for capturing dependence among random variables, to explicitly model the correlation and coordination in multi-agent systems.
Our proposed model is able to separately learn marginals that capture the local behavioral patterns of each individual agent, as well as a copula function that solely and fully captures the dependence structure among agents.
arXiv Detail & Related papers (2021-07-10T03:49:41Z) - Leveraging Neural Network Gradients within Trajectory Optimization for
Proactive Human-Robot Interactions [32.57882479132015]
We present a framework that fuses together the interpretability and flexibility of trajectory optimization (TO) with the predictive power of state-of-the-art human trajectory prediction models.
We demonstrate the efficacy of our approach in a multi-agent scenario whereby a robot is required to safely and efficiently navigate through a crowd of up to ten pedestrians.
arXiv Detail & Related papers (2020-12-02T08:43:36Z) - Risk-Sensitive Sequential Action Control with Multi-Modal Human
Trajectory Forecasting for Safe Crowd-Robot Interaction [55.569050872780224]
We present an online framework for safe crowd-robot interaction based on risk-sensitive optimal control, wherein the risk is modeled by the entropic risk measure.
Our modular approach decouples the crowd-robot interaction into learning-based prediction and model-based control.
A simulation study and a real-world experiment show that the proposed framework can accomplish safe and efficient navigation while avoiding collisions with more than 50 humans in the scene.
arXiv Detail & Related papers (2020-09-12T02:02:52Z) - Human Trajectory Forecasting in Crowds: A Deep Learning Perspective [89.4600982169]
We present an in-depth analysis of existing deep learning-based methods for modelling social interactions.
We propose two knowledge-based data-driven methods to effectively capture these social interactions.
We develop a large scale interaction-centric benchmark TrajNet++, a significant yet missing component in the field of human trajectory forecasting.
arXiv Detail & Related papers (2020-07-07T17:19:56Z) - EvolveGraph: Multi-Agent Trajectory Prediction with Dynamic Relational
Reasoning [41.42230144157259]
We propose a generic trajectory forecasting framework with explicit relational structure recognition and prediction via latent interaction graphs.
Considering the uncertainty of future behaviors, the model is designed to provide multi-modal prediction hypotheses.
We introduce a double-stage training pipeline which not only improves training efficiency and accelerates convergence, but also enhances model performance.
arXiv Detail & Related papers (2020-03-31T02:49:23Z) - Social-WaGDAT: Interaction-aware Trajectory Prediction via Wasserstein
Graph Double-Attention Network [29.289670231364788]
In this paper, we propose a generic generative neural system for multi-agent trajectory prediction.
We also employ an efficient kinematic constraint layer applied to vehicle trajectory prediction.
The proposed system is evaluated on three public benchmark datasets for trajectory prediction.
arXiv Detail & Related papers (2020-02-14T20:11:13Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.