We give an approximate solution to the difficult inverse problem of inferring the topology of an unknown network from given time-dependent signals at the nodes. For example, we measure signals from individual neurons in the brain, and infer how they are inter-connected. We use Maximum Caliber as an inference principle. The combinatorial challenge of high-dimensional data is handled using two different approximations to the pairwise couplings. We show two proofs of principle: in a nonlinear genetic toggle switch circuit, and in a toy neural network
Identifying the structure and dynamics of synaptic interactions between neurons is the first step to...
<div><p>Identifying the structure and dynamics of synaptic interactions between neurons is the first...
The study of networks has become increasingly important in many disciplines ranging from physics to ...
We give an approximate solution to the difficult inverse problem of inferring the topology of an unk...
We address the problem of estimating the effective connectivity of the brain network, using the inpu...
One major challenge in neuroscience is the identification of interrelations between signals reflecti...
The aim of this manuscript is to present a non-invasive method to recover the network structure of a...
Abstract — The reconstruction of the links among coupled dynamical systems can be handled in many wa...
Motivated by the fact that transfer functions do not contain structural information about networks, ...
Extracting complex interactions (i.e., dynamic topologies) has been an essential, but difficult, ste...
Complex systems are increasingly studied as dynamical systems unfolding on complex networks, althoug...
Reconstructing network connectivity from the collective dynamics of a system typically requires acce...
Reconstructing network connectivity from the collective dynamics of a system typically requires acce...
One of the paramount challenges in neuroscience is to understand the dynamics of individual neurons ...
Inferring the network topology from the dynamics of interacting units constitutes a topical challeng...
Identifying the structure and dynamics of synaptic interactions between neurons is the first step to...
<div><p>Identifying the structure and dynamics of synaptic interactions between neurons is the first...
The study of networks has become increasingly important in many disciplines ranging from physics to ...
We give an approximate solution to the difficult inverse problem of inferring the topology of an unk...
We address the problem of estimating the effective connectivity of the brain network, using the inpu...
One major challenge in neuroscience is the identification of interrelations between signals reflecti...
The aim of this manuscript is to present a non-invasive method to recover the network structure of a...
Abstract — The reconstruction of the links among coupled dynamical systems can be handled in many wa...
Motivated by the fact that transfer functions do not contain structural information about networks, ...
Extracting complex interactions (i.e., dynamic topologies) has been an essential, but difficult, ste...
Complex systems are increasingly studied as dynamical systems unfolding on complex networks, althoug...
Reconstructing network connectivity from the collective dynamics of a system typically requires acce...
Reconstructing network connectivity from the collective dynamics of a system typically requires acce...
One of the paramount challenges in neuroscience is to understand the dynamics of individual neurons ...
Inferring the network topology from the dynamics of interacting units constitutes a topical challeng...
Identifying the structure and dynamics of synaptic interactions between neurons is the first step to...
<div><p>Identifying the structure and dynamics of synaptic interactions between neurons is the first...
The study of networks has become increasingly important in many disciplines ranging from physics to ...