Granger causality detection in high-dimensional systems using feedforward neural networks.
H.-F. Calvo-Pardo, T. Mancini and J. Olmo (2021). Granger causality detection in high-dimensional systems using feedforward neural networks. International Journal of Forecasting 37, 920-940.
This paper proposes a novel methodology to detect Granger causality in mean in vector autoregressive settings using feedforward neural networks. The approach accommodates unknown dependence structures between the elements of high-dimensional multivariate time series with weak and strong persistence. To do this, we propose a two-stage procedure. First, we maximize the transfer of information between input and output variables in the network to obtain an optimal number of nodes in the intermediate hidden layers. Second, we apply a novel sparse double group lasso penalty function to identify the variables that have predictive ability and, hence, Granger cause the others. The penalty function inducing sparsity is applied to the weights characterizing the nodes of the neural network. We show the correct identification of these weights for increasing sample sizes. We apply this method to the recently created Tobalaba network of renewable energy companies and show the increase in connectivity between companies after the creation of the network using Granger causality measures to map the connections.
This paper proposes a novel methodology to detect Granger causality in mean in vector autoregressive settings using feedforward neural networks. The approach accommodates unknown dependence structures between the elements of high-dimensional multivariate time series with weak and strong persistence. To do this, we propose a two-stage procedure. First, we maximize the transfer of information between input and output variables in the network to obtain an optimal number of nodes in the intermediate hidden layers. Second, we apply a novel sparse double group lasso penalty function to identify the variables that have predictive ability and, hence, Granger cause the others. The penalty function inducing sparsity is applied to the weights characterizing the nodes of the neural network. We show the correct identification of these weights for increasing sample sizes. We apply this method to the recently created Tobalaba network of renewable energy companies and show the increase in connectivity between companies after the creation of the network using Granger causality measures to map the connections.