## ----setup, include=FALSE----------------------------------------------------- knitr::opts_chunk$set( collapse = TRUE, comment = "#>", fig.width=6, fig.height=4 ) # Legge denne i YAML på toppen for å skrive ut til tex #output: # pdf_document: # keep_tex: true # Original: # rmarkdown::html_vignette: # toc: true ## ----------------------------------------------------------------------------- # Start the multiblock R package library(multiblock) ## ----------------------------------------------------------------------------- set.seed(42) # Simulate data set sim <- lplsData(I = 30, N = 20, J = 5, K = 6, ncomp = 2) # Split into separate blocks X1 <- sim$X1; X2 <- sim$X2; X3 <- sim$X3 ## ----fig.width=5, fig.height=5------------------------------------------------ # exo-L-PLS: lp.exo <- lpls(X1,X2,X3, ncomp = 2) # type = "exo" is default # Predict X1 pred.exo.X2 <- predict(lp.exo, X1new = X1, exo.direction = "X2") # Predict X3 pred.exo.X2 <- predict(lp.exo, X1new = X1, exo.direction = "X3") # Correlation loading plot plot(lp.exo) ## ----------------------------------------------------------------------------- # endo-L-PLS: lp.endo <- lpls(X1,X2,X3, ncomp = 2, type = "endo") # Predict X1 from X2 and X3 (in this case fitted values): pred.endo.X1 <- predict(lp.endo, X2new = X2, X3new = X3) ## ----------------------------------------------------------------------------- # LOO cross-validation horizontally lp.cv1 <- lplsCV(lp.exo, segments1 = as.list(1:dim(X1)[1]), trace = FALSE) # LOO cross-validation vertically lp.cv2 <- lplsCV(lp.exo, segments2 = as.list(1:dim(X1)[2]), trace = FALSE) # Three-fold CV, horizontal lp.cv3 <- lplsCV(lp.exo, segments1 = as.list(1:10, 11:20, 21:30), trace = FALSE) # Three-fold CV, horizontal, inwards model lp.cv4 <- lplsCV(lp.endo, segments1 = as.list(1:10, 11:20, 21:30), trace = FALSE) ## ----------------------------------------------------------------------------- # Load potato data data(potato) # Single path pot.pm <- sopls_pm(potato[1:3], potato[['Sensory']], c(5,5,5), computeAdditional=TRUE) # Report of explained variances and optimal number of components . # Bootstrapping can be enabled to assess stability. # (LOO cross-validation is default) pot.pm ## ----------------------------------------------------------------------------- # Load wine data data(wine) # All path in the forward direction pot.pm.multiple <- sopls_pm_multiple(wine, ncomp = c(4,2,9,8)) # Report of direct, indirect and total explained variance per sub-path. # Bootstrapping can be enabled to assess stability. pot.pm.multiple