DOI chapter:
D. Förderung des wissenschaftlichen Nachwuchses
DOI chapter:II. Das WIN-Kolleg
DOI chapter:Siebter Forschungsschwerpunkt „Wie entscheiden Kollektive?“
DOI chapter:2. How does group composition influence collective sensing and decision making?
DOI Page / Citation link: https://doi.org/10.11588/diglit.61621#0303
2. Group Composition (WIN-Programm)
Q2: Implementation
Q3: Algorithm
Individuals
Q4: Adaptation
Group
Ql: Group
description
Collective mechanisms
Communication
Individual specialization
Phenotypic plasticity
Distributed
Individual Processing
Competition/policing
Activation/inhibition
Feedback
Group
Maintain homeostasis
Respond to perturbation
Allocate resources
Coordinate group response
Reproduce
Environment
Figure 2. Hierarchical analysis frameworkfor collective Systems. To compare collective behavior in
different Systems, we use complementary questions: howgroups are structured (Ql), how individual behavior
is used to implement certain collective mechanisms (Q2), how multiple collective mechanisms contribute to
group function (Q3), and how both individual andgroup behavioral algorithms are adapted to the particular
environment (Q4).
contribute to the group’s response, how function is tied to environmental cha-
racteristics, and how these particular results are related to other groups, such
as different species of social insects, group-living vertebrates such as fish, and
human organizations.
Publications:
Vishwakarma, Medhavi, Basil Thurakkal, Joachim R Spatz, and Tamal Das. 2020a. “Dyna-
mic Heterogeneity Influences the Leader-Follower Dynamics during Epithelial Wound
Closure.” Philosophical Transactions of the Royal Society B: Biological Sciences 375 (1807):
20190391. https://doi.org/10.1098/rstb.2019.0391.
Vishwakarma, Medhavi, Joachim P Spatz, and Tamal Das. 2020b. “Mechanobiology of
Leader-Follower Dynamics in Epithelial Cell Migration.” Current Opinion in Cell Bio-
logy, Cell Dynamics, 66 (October): 97 — 103. https://doi.Org/10.1016/j.ceb.2020.05.007.
Davidson, Jacob D., Medhavi Vishwakarma, and Michael L. Smith. 2021. “Hierarchi-
cal Approach for Comparing Collective Behavior across Scales: Cellular Systems to
Honey Bee Colonies.” Frontiers in Ecology and Evolution 9. https://doi.org/10.3389/
fevo.2021.581222.
303
Q2: Implementation
Q3: Algorithm
Individuals
Q4: Adaptation
Group
Ql: Group
description
Collective mechanisms
Communication
Individual specialization
Phenotypic plasticity
Distributed
Individual Processing
Competition/policing
Activation/inhibition
Feedback
Group
Maintain homeostasis
Respond to perturbation
Allocate resources
Coordinate group response
Reproduce
Environment
Figure 2. Hierarchical analysis frameworkfor collective Systems. To compare collective behavior in
different Systems, we use complementary questions: howgroups are structured (Ql), how individual behavior
is used to implement certain collective mechanisms (Q2), how multiple collective mechanisms contribute to
group function (Q3), and how both individual andgroup behavioral algorithms are adapted to the particular
environment (Q4).
contribute to the group’s response, how function is tied to environmental cha-
racteristics, and how these particular results are related to other groups, such
as different species of social insects, group-living vertebrates such as fish, and
human organizations.
Publications:
Vishwakarma, Medhavi, Basil Thurakkal, Joachim R Spatz, and Tamal Das. 2020a. “Dyna-
mic Heterogeneity Influences the Leader-Follower Dynamics during Epithelial Wound
Closure.” Philosophical Transactions of the Royal Society B: Biological Sciences 375 (1807):
20190391. https://doi.org/10.1098/rstb.2019.0391.
Vishwakarma, Medhavi, Joachim P Spatz, and Tamal Das. 2020b. “Mechanobiology of
Leader-Follower Dynamics in Epithelial Cell Migration.” Current Opinion in Cell Bio-
logy, Cell Dynamics, 66 (October): 97 — 103. https://doi.Org/10.1016/j.ceb.2020.05.007.
Davidson, Jacob D., Medhavi Vishwakarma, and Michael L. Smith. 2021. “Hierarchi-
cal Approach for Comparing Collective Behavior across Scales: Cellular Systems to
Honey Bee Colonies.” Frontiers in Ecology and Evolution 9. https://doi.org/10.3389/
fevo.2021.581222.
303