Your search keyword '"Giardina, Irene"' showing total 3 results

1. Scale-free correlations in starling flocks

Author

Cavagna, Andrea, Cimarelli, Alessio, Giardina, Irene, Parisi, Giorgio, Santagati, Raffaele, Stefanini, Fabio, and Viale, Massimiliano

Subjects

Correlation (Statistics) -- Methods, Herding behavior in animals -- Observations, Starlings -- Behavior, Animal ecology -- Research, Science and technology

Abstract

From bird flocks to fish schools, animal groups often seem to react to environmental perturbations as if of one mind. Most studies in collective animal behavior have aimed to understand how a globally ordered state may emerge from simple behavioral rules. Less effort has been devoted to understanding the origin of collective response, namely the way the group as a whole reacts to its environment. Yet, in the presence of strong predatory pressure on the group, collective response may yield a significant adaptive advantage. Here we suggest that collective response in animal groups may be achieved through scale-free behavioral correlations. By reconstructing the 3D position and velocity of individual birds in large flocks of starlings, we measured to what extent the velocity fluctuations of different birds are correlated to each other. We found that the range of such spatial correlation does not have a constant value, but it scales with the linear size of the flock. This result indicates that behavioral correlations are scale free: The change in the behavioral state of one animal affects and is affected by that of all other animals in the group, no matter how large the group is. Scale-free correlations provide each animal with an effective perception range much larger than the direct interindividual interaction range, thus enhancing global response to perturbations. Our results suggest that flocks behave as critical systems, poised to respond maximally to environmental perturbations. animal groups | collective behavior | flocking | self-organization | emergent behavior doi/ 10.1073/pnas.1005766107

Published

2010

2. Social interactions dominate speed control in poising natural flocks near criticality.

Author

Bialek, William, Cavagna, Andrea, Giardina, Irene, Mora, Thierry, Poh, Oliver, Silvestri, Edmondo, Viale, Massimiliano, and Walczak, Aleksandra M.

Subjects

BIRDS, VELOCITY, STARLINGS, COLLECTIVE behavior, STATISTICAL correlation, ENTROPY

Abstract

Flocks of birds exhibit a remarkable degree of coordination and collective response. It is not just that thousands of individuals fly, on average, in the same direction and at the same speed, but that even the fluctuations around the mean velocity are correlated over long distances. Quantitative measurements on flocks of starlings, in particular, show that these fluctuations are scale-free, with effective correlation lengths proportional to the linear size of the flock. Here we construct models for the joint distribution of velocities in the flock that reproduce the observed local correlations between individuals and their neighbors, as well as the variance of flight speeds across individuals, but otherwise have as little structure as possible. These minimally structured or maximum entropy models provide quantitative, parameter-free predictions for the spread of correlations throughout the flock, and these are in excellent agreement with the data. These models are mathematically equivalent to statistical physics models for ordering in magnets, and the correct prediction of scale-free correlations arises because the parameters- completely determined by the data-are in the critical regime. In biological terms, criticality allows the flock to achieve maximal correlation across long distances with limited speed fluctuations. [ABSTRACT FROM AUTHOR]

Published

2014

3. Statistical mechanics for natural flocks of birds.

Author

Bialek, William, Cavagna, Andrea, Giardina, Irene, Mora, Thierry, Silvestri, Edmondo, Viale, Massimiliano, and Walczak, Aleksandra M.

Subjects

STATISTICAL mechanics, BIRD behavior, STARLINGS, STATISTICAL correlation, ENTROPY, MATHEMATICAL symmetry

Abstract

Flocking is a typical example of emergent collective behavior, where interactions between individuals produce collective patterns on the large scale. Here we show how a quantitative microscopic theory for directional ordering in a flock can be derived directly from field data. We construct the minimally structured (maximum entropy) model consistent with experimental correlations in large flocks of starlings. The maximum entropy model shows that local, pairwise interactions between birds are sufficient to correctly predict the propagation of order throughout entire flocks of starlings, with no free parameters. We also find that the number of interacting neighbors is independent of flock density, confirming that interactions are ruled by topological rather than metric distance. Finally, by comparing flocks of different sizes, the model correctly accounts for the observed scale invariance of long-range correlations among the fluctuations in flight direction. [ABSTRACT FROM AUTHOR]

Published

2012