TY - JOUR
T1 - A basic phase diagram of neuronal dynamics
AU - Li, Wenyuan
AU - Ovchinnikov, Igor V.
AU - Chen, Honglin
AU - Wang, Zhe
AU - Lee, Albert
AU - Lee, Houchul
AU - Cepeda, Carlos
AU - Schwartz, Robert N.
AU - Meier, Karlheinz
AU - Wang, Kang L.
N1 - Publisher Copyright:
© 2018 Massachusetts Institute of Technology.
PY - 2018/9/1
Y1 - 2018/9/1
N2 - The extreme complexity of the brain has attracted the attention of neuroscientists and other researchers for a long time. More recently, the neuromorphic hardware has matured to provide a new powerful tool to study neuronal dynamics. Here, we study neuronal dynamics using different settings on a neuromorphic chip built with flexible parameters of neuron models. Our unique setting in the network of leaky integrate-andfire (LIF) neurons is to introduce a weak noise environment.We observed three different types of collective neuronal activities, or phases, separated by sharp boundaries, or phase transitions. From this, we construct a rudimentary phase diagram of neuronal dynamics and demonstrate that a noise-induced chaotic phase (N-phase), which is dominated by neuronal avalanche activity (intermittent aperiodic neuron firing), emerges in the presence of noise and its width grows with the noise intensity. The dynamics can be manipulated in this N-phase. Our results and comparison with clinical data is consistent with the literature and our previous work showing that healthy brain must reside in the N-phase.We argue that the brain phase diagram with further refinement may be used for the diagnosis and treatment of mental disease and also suggest that the dynamics may be manipulated to serve as a means of new information processing (e.g., for optimization). Neuromorphic chips, similar to the one we used but with a variety of neuron models, may be used to further enhance the understanding of human brain function and accelerate the development of neuroscience research.
AB - The extreme complexity of the brain has attracted the attention of neuroscientists and other researchers for a long time. More recently, the neuromorphic hardware has matured to provide a new powerful tool to study neuronal dynamics. Here, we study neuronal dynamics using different settings on a neuromorphic chip built with flexible parameters of neuron models. Our unique setting in the network of leaky integrate-andfire (LIF) neurons is to introduce a weak noise environment.We observed three different types of collective neuronal activities, or phases, separated by sharp boundaries, or phase transitions. From this, we construct a rudimentary phase diagram of neuronal dynamics and demonstrate that a noise-induced chaotic phase (N-phase), which is dominated by neuronal avalanche activity (intermittent aperiodic neuron firing), emerges in the presence of noise and its width grows with the noise intensity. The dynamics can be manipulated in this N-phase. Our results and comparison with clinical data is consistent with the literature and our previous work showing that healthy brain must reside in the N-phase.We argue that the brain phase diagram with further refinement may be used for the diagnosis and treatment of mental disease and also suggest that the dynamics may be manipulated to serve as a means of new information processing (e.g., for optimization). Neuromorphic chips, similar to the one we used but with a variety of neuron models, may be used to further enhance the understanding of human brain function and accelerate the development of neuroscience research.
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U2 - 10.1162/neco_a_01103
DO - 10.1162/neco_a_01103
M3 - Letter
C2 - 29894659
AN - SCOPUS:85051627462
SN - 0899-7667
VL - 30
SP - 2418
EP - 2438
JO - Neural Computation
JF - Neural Computation
IS - 9
ER -