The speaker describes his work as “multifractal social psychology” which looks at individuals and groups as swarms and fluid systems interacting across scales.
He argues that embodied cognition involves the body and actions playing a central role in learning and perception, not just the brain.
Probabilistic epigenesis describes development as involving multiple interacting layers and variables that fluctuate over time, like turbulent systems.
Vector autoregression can model the interactions between multiple endogenous variables and show how multifractality spreads through a system.
Hand movements during cognitive tasks show different multifractal patterns depending on the task, indicating cascade dynamics at play.
When tapping to an unpredictable metronome, humans match the multifractal structure, indicating they can absorb environmental structure.
Infant kicking shows an upstream flow of multifractality from ankle to knee to hip, suggesting an exploratory process.
Bee colony movements show multifractal structure that predicts colony membership, indicating its role in group coordination.
At aggregation sites for slime mold aggregation, larger events promoted smaller events’ fractality, while the reverse was true at non-aggregation sites.
Multifractal movements may coordinate information across the body to support task performance and information transfer.
The speaker describes his work as “multifractal social psychology” which looks at individuals and groups as swarms and fluid systems interacting across scales.
He argues that embodied cognition involves the body and actions playing a central role in learning and perception, not just the brain.
Probabilistic epigenesis describes development as involving multiple interacting layers and variables that fluctuate over time, like turbulent systems.
Vector autoregression can model the interactions between multiple endogenous variables and show how multifractality spreads through a system.
Hand movements during cognitive tasks show different multifractal patterns depending on the task, indicating cascade dynamics at play.
When tapping to an unpredictable metronome, humans match the multifractal structure, indicating they can absorb environmental structure.
Infant kicking shows an upstream flow of multifractality from ankle to knee to hip, suggesting an exploratory process.
Bee colony movements show multifractal structure that predicts colony membership, indicating its role in group coordination.
At aggregation sites for slime mold aggregation, larger events promoted smaller events’ fractality, while the reverse was true at non-aggregation sites.
Multifractal movements may coordinate information across the body to support task performance and information transfer.
https://www.youtube.com/watch?v=P89WTmNBjBk