A framework to infer causality on a pair of time series of real numbers based on Variable-lag Granger causality (VL-Granger) and transfer entropy (VL-Transfer Entropy).
Typically, Granger causality and transfer entropy have an assumption of a fixed and constant time delay between the cause and effect. However, for a non-stationary time series, this assumption is not true. For example, considering two time series of velocity of person A and person B where B follows A. At some time, B stops tying his shoes, then running to catch up A. The fixed-lag assumption is not true in this case.
We propose a framework that allows variable-lags between cause and effect in Granger causality and transfer entropy to allow them to deal with variable-lag non-stationary time series.
You can install our package from CRAN
install.packages("VLTimeCausality")For the newest version on github, please call the following command in R terminal.
remotes::install_github("DarkEyes/VLTimeSeriesCausality")This requires a user to install the "remotes" package before installing VLTimeSeriesCausality.
In the first step, we generate time series TS$X and TS$Y where TS$X causes TS$Y with variable-lags.
library(VLTimeCausality)
# Generate simulation data
TS <- VLTimeCausality::SimpleSimulationVLtimeseries()We can plot time series using the following function.
VLTimeCausality::plotTimeSeries(TS$X,TS$Y)A sample of generated time series pair that has a causal relation is plotted below:
We use the following function to infer whether X causes Y.
# Run the function
out<-VLTimeCausality::VLGrangerFunc(Y=TS$Y,X=TS$X)The result of VL-Granger causality is below:
out$BICDiffRatio
[1] 0.8882051
out$XgCsY
[1] TRUEIf out$XgCsY is true, then it means that X VL-Granger-causes Y. The value out$BICDiffRatio is a BIC difference ratio. If out$BICDiffRatio>0, it means that X is a good predictor of Y behaviors. The closer out$BICDiffRatio to 1, the stronger we can claim that X VL-Granger-causes Y.
For the comparison between normal Granger test with our VL-Granger test, we recommend to use the F-test decision criterion the same as typical Granger test criterion.
Below are the results of VL-Granger Causality using F-test.
library(lmtest)
data(ChickEgg)
ChickEgg <- as.data.frame(ChickEgg)
#============ The the egg causes chicken.
out_test1 <- VLTimeCausality::VLGrangerFunc(X=ChickEgg$egg,Y=ChickEgg$chicken)
out_test1$p.val
[1] 0.004980847
out_test1$XgCsY_ftest
[1] TRUE
#============ The reverse direction has no causal relation
out_test2 <- VLTimeCausality::VLGrangerFunc(Y=ChickEgg$egg,X=ChickEgg$chicken)
out_test2$p.val
[1] 1
out_test2$XgCsY_ftest
[1] FALSEChainarong Amornbunchornvej, Elena Zheleva, and Tanya Berger-Wolf (2021). Variable-lag Granger Causality and Transfer Entropy for Time Series Analysis. ACM Transactions on Knowledge Discovery from Data (TKDD), 15(4), 1-30. https://doi.org/10.1145/3441452
- Developer: C. Amornbunchornvej
- Strategic Analytics Networks with Machine Learning and AI (SAI), NECTEC, Thailand
- Homepage: Link
