269 research outputs found
Vision-based macroscopic pedestrian models
International audienceWe propose a hierarchy of kinetic and macroscopic models for a system consisting of a large number of interacting pedestrians. The basic interaction rules are derived from earlier work where the dangerousness level of an interaction with another pedestrian is measured in terms of the derivative of the bearing angle (angle between the walking direction and the line connecting the two subjects) and of the time-to-interaction (time before reaching the closest distance between the two subjects). A mean-field kinetic model is derived. Then, three different macroscopic continuum models are proposed. The first two ones rely on two different closure assumptions of the kinetic model, respectively based on a monokinetic and a von Mises-Fisher distribution. The third one is derived through a hydrodynamic limit. In each case, we discuss the relevance of the model for practical simulations of pedestrian crowds
Quantifying the biomimicry gap in biohybrid systems
Biohybrid systems in which robotic lures interact with animals have become
compelling tools for probing and identifying the mechanisms underlying
collective animal behavior. One key challenge lies in the transfer of social
interaction models from simulations to reality, using robotics to validate the
modeling hypotheses. This challenge arises in bridging what we term the
"biomimicry gap", which is caused by imperfect robotic replicas, communication
cues and physics constrains not incorporated in the simulations that may elicit
unrealistic behavioral responses in animals. In this work, we used a biomimetic
lure of a rummy-nose tetra fish (Hemigrammus rhodostomus) and a neural network
(NN) model for generating biomimetic social interactions. Through experiments
with a biohybrid pair comprising a fish and the robotic lure, a pair of real
fish, and simulations of pairs of fish, we demonstrate that our biohybrid
system generates high-fidelity social interactions mirroring those of genuine
fish pairs. Our analyses highlight that: 1) the lure and NN maintain minimal
deviation in real-world interactions compared to simulations and fish-only
experiments, 2) our NN controls the robot efficiently in real-time, and 3) a
comprehensive validation is crucial to bridge the biomimicry gap, ensuring
realistic biohybrid systems
Informative and misinformative interactions in a school of fish
It is generally accepted that, when moving in groups, animals process
information to coordinate their motion. Recent studies have begun to apply
rigorous methods based on Information Theory to quantify such distributed
computation. Following this perspective, we use transfer entropy to quantify
dynamic information flows locally in space and time across a school of fish
during directional changes around a circular tank, i.e. U-turns. This analysis
reveals peaks in information flows during collective U-turns and identifies two
different flows: an informative flow (positive transfer entropy) based on fish
that have already turned about fish that are turning, and a misinformative flow
(negative transfer entropy) based on fish that have not turned yet about fish
that are turning. We also reveal that the information flows are related to
relative position and alignment between fish, and identify spatial patterns of
information and misinformation cascades. This study offers several
methodological contributions and we expect further application of these
methodologies to reveal intricacies of self-organisation in other animal groups
and active matter in general
Predicting long-term collective animal behavior with deep learning
Deciphering the social interactions that govern collective behavior in animal
societies has greatly benefited from advancements in modern computing.
Computational models diverge into two kinds of approaches: analytical models
and machine learning models. This work introduces a deep learning model for
social interactions in the fish species Hemigrammus rhodostomus, and compares
its results to experiments and to the results of a state-of-the-art analytical
model. To that end, we propose a systematic methodology to assess the
faithfulness of a model, based on the introduction of a set of stringent
observables. We demonstrate that machine learning models of social interactions
can directly compete against their analytical counterparts. Moreover, this work
demonstrates the need for consistent validation across different timescales and
highlights which design aspects critically enables our deep learning approach
to capture both short- and long-term dynamics. We also show that this approach
is scalable to other fish species
Modeling Collective Animal Behavior with a Cognitive Perspective: A Methodological Framework
The last decades have seen an increasing interest in modeling collective animal behavior. Some studies try to reproduce as accurately as possible the collective dynamics and patterns observed in several animal groups with biologically plausible, individual behavioral rules. The objective is then essentially to demonstrate that the observed collective features may be the result of self-organizing processes involving quite simple individual behaviors. Other studies concentrate on the objective of establishing or enriching links between collective behavior researches and cognitive or physiological ones, which then requires that each individual rule be carefully validated. Here we discuss the methodological consequences of this additional requirement. Using the example of corpse clustering in ants, we first illustrate that it may be impossible to discriminate among alternative individual rules by considering only observational data collected at the group level. Six individual behavioral models are described: They are clearly distinct in terms of individual behaviors, they all reproduce satisfactorily the collective dynamics and distribution patterns observed in experiments, and we show theoretically that it is strictly impossible to discriminate two of these models even in the limit of an infinite amount of data whatever the accuracy level. A set of methodological steps are then listed and discussed as practical ways to partially overcome this problem. They involve complementary experimental protocols specifically designed to address the behavioral rules successively, conserving group-level data for the overall model validation. In this context, we highlight the importance of maintaining a sharp distinction between model enunciation, with explicit references to validated biological concepts, and formal translation of these concepts in terms of quantitative state variables and fittable functional dependences. Illustrative examples are provided of the benefits expected during the often long and difficult process of refining a behavioral model, designing adapted experimental protocols and inversing model parameters
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