Population density techniques can be used to simulate the behavior of a population of neurons which adhere to a common underlying neuron model. They have previously been used for analyzing models of orientation tuning and decision making tasks. They produce a fully deterministic solution to neural simulations which often involve a non-deterministic or noise component. Until now, numerical population density techniques have been limited to only one- and two-dimensional models. For the first time, we demonstrate a method to take an N-dimensional underlying neuron model and simulate the behavior of a population. The technique enables so-called graceful degradation of the dynamics allowing a balance between accuracy and simulation speed while m...
Modern experimental technologies enable simultaneous recording of large neural populations. These hi...
MIIND [1] is the first publicly available implementation of population density algorithms. Like neur...
A-D: Evolution of the density at t = 5, 10, 50 s an steady state for a diffusive input (J = ±0.02, ν...
Population density methods provide promising time-saving alternatives to direct Monte Carlo simulati...
The importance of a mesoscopic description level of the brain has now been well established. Rate ba...
The importance of a mesoscopic description level of the brain has now been well established. Rate ba...
MIIND is a software platform for easily and efficiently simulating the behaviour of interacting popu...
Population density methods provide promising time-saving alternatives to direct Monte Carlo simulati...
Population density techniques are efficient simulation techniques for modeling large homogeneous pop...
A: Gain curve for quadratic-integrate-and-fire neurons. Population density techniques handle deviati...
MIIND is a neural simulator which uses an innovative numerical population density technique to simul...
The use of a population dynamics approach promises efficient simulation of large assemblages of neur...
MIIND [1] is the first publicly available implementation of population density algorithms. Like neur...
We present a method for solving population density equations (PDEs)–-a mean-field technique describi...
We propose a macroscopic approach towards realistic simulations of population activity of cortical n...
Modern experimental technologies enable simultaneous recording of large neural populations. These hi...
MIIND [1] is the first publicly available implementation of population density algorithms. Like neur...
A-D: Evolution of the density at t = 5, 10, 50 s an steady state for a diffusive input (J = ±0.02, ν...
Population density methods provide promising time-saving alternatives to direct Monte Carlo simulati...
The importance of a mesoscopic description level of the brain has now been well established. Rate ba...
The importance of a mesoscopic description level of the brain has now been well established. Rate ba...
MIIND is a software platform for easily and efficiently simulating the behaviour of interacting popu...
Population density methods provide promising time-saving alternatives to direct Monte Carlo simulati...
Population density techniques are efficient simulation techniques for modeling large homogeneous pop...
A: Gain curve for quadratic-integrate-and-fire neurons. Population density techniques handle deviati...
MIIND is a neural simulator which uses an innovative numerical population density technique to simul...
The use of a population dynamics approach promises efficient simulation of large assemblages of neur...
MIIND [1] is the first publicly available implementation of population density algorithms. Like neur...
We present a method for solving population density equations (PDEs)–-a mean-field technique describi...
We propose a macroscopic approach towards realistic simulations of population activity of cortical n...
Modern experimental technologies enable simultaneous recording of large neural populations. These hi...
MIIND [1] is the first publicly available implementation of population density algorithms. Like neur...
A-D: Evolution of the density at t = 5, 10, 50 s an steady state for a diffusive input (J = ±0.02, ν...