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Software package for Gaussian Process (GP) modelling written in R language. The core functions are coded in C++ and based on the EIGEN library (through RcppEigen).

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GauProMod

Emanuel Huber
2021-07-13

R functions for Gaussian process (GP) modelling. The core functions are coded in C++ and based on the EIGEN library (through RcppEigen)

Notes

Companion website (in construction): http://emanuelhuber.github.io/GauProMod/

Currently implemented/to do:

  • Posterior Gaussian Process with Gaussian likelihood (Gaussian process conditioned to noise-free and noisy observations)
  • Space-time Gaussian process
  • Gaussian Process with monomial mean functions with vague Gaussian prior on the coefficient parameters.
  • Gaussian Process conditioned to derivative observations
  • Anisotropic covariance functions (scale and rotation)
  • Log marginal likelihood of the Gaussian process
  • Cross-matrix distance (distance between every rows of each matrix): crossdist(x,y,M) (with M a positive semidefinite matrix for anisotropic distances)
  • Covariance function: Matern, Gaussian, linear
  • maximum likelihood hyper-parameter estimation
  • McMC hyper-parameter sampling
  • spatially varying covariance function
  • Gaussian Process approximations (to deal with larger data set)
  • add other covariance models

This is an ongoing project. If you have any questions, don't hesitate to contact me:

[email protected]

Thank you!

How to install/load

if(!require("devtools")) install.packages("devtools")
devtools::install_github("emanuelhuber/GauProMod")

Short tutorial

Load libraries

library(GauProMod)
library(plot3D)
library(RColorBrewer)

1D Gaussian Process Modelling

Observations and target

The observations are defined by a list with x the positions of the observations and y the observed values. The targets are the positions x where to simulate the Gaussian Process.

#observations
obs <- list(x=c(-4, -3, -1, 0, 4),
            y=c(-2,  0,  1, 2, 0))
# targets
targ <- list("x"=seq(-10,10,len=200))

Covariance function, mean function and likelihood

To build the covariance functions, the following kernels are available

# linear kernel
covModel <- list(kernel="linear",
                 b = 1,         # slope
                 h = 1.5,       # std. deviation
                 c = 0)         # constant
                 
# Matern kernel
covModel <- list(kernel="matern",
                 l = 1,       # correlation length
                 v = 2.5,     # smoothness
                 h = 2.45)    # std. deviation

# squared exponential kernel (Gaussian)
covModel <- list(kernel="gaussian",
                 l = 0.5,   # correlation length
                 h = 0.25)  # std. deviation
Covariance as a function of distance
covModel <- list(kernel="matern",
                 l = 5,     # correlation length
                 v = 1,     # smoothness
                 h = 2.45   # std. deviation
                )
r <- seq(0, 20, by = 0.1)
myCov <- covfx(r = r, covModel = covModel)
plot(r, myCov, type = "l", ylim = c(0, max(myCov)),
     ylab = "covariance", xlab = "distance", xaxs = "i", yaxs = "i")

The following mean function (or basis functions) are available (see Rasmussen and Williams (2006), Section 2.7):

# quadratic mean function
op <- 2
# linear mean function
op <- 1
# zero-mean function (no trend)
op <- 0 

Because nothing is perfectly observed, it makes sense to account for uncertainty in the observation. Gaussian likelihood, defined by the standard deviation sigma (erreur uncertainty) is the only form of likelihood currently implemented in GauProMod. Sigma must be either a length-one vector or has exactly the same length as the observations values

# standard deviation measurement error
# Gaussian likelihood
sigma <- 0.2
# or
sigma <- abs(rnorm(length(obs$y)))

Conditional Gaussian Process modelling

GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
               sigma = sigma, op = op)
names(GP)
# GP$mean   = mean value at location xstar
# GP$cov    = covariance matrix of the conditioned GP
# GP$logLik = log-likelihood of the conditioned GP
# GP$xstar  = x-coordinates at which the GP is simulated

Plot the mean function plus/minus the standard deviation

#--- plot mean +/- sd
xp <-(GP$mean + sqrt(diag(GP$cov)))  # mean + sd
xm <-(GP$mean - sqrt(diag(GP$cov)))  # mean - sd

# initialise the plot
plot(cbind(obs$x, obs$y), type="p", xlab="x", ylab="y", 
     xlim = range(c(obs$x, targ$x)), ylim = range(c(xp, xm, obs$y)),
     pch = 20, col = "black") 
lines(GP$xstar, GP$mean,col="red")  # mean
lines(GP$xstar, xm,lty=3)            # + sd
lines(GP$xstar, xp,lty=3)            # - sd
legend("topleft", legend = c("obs", "mean", "sd"), lty = c(NA, 1, 3),
       pch = c(20, NA, NA), col=c("black", "red", "black"), bty="n")

Random conditional simulation

# cholesky factorisation
L <- cholfac(GP$cov)
# random simulation
ystar <- gpSim(GP , L = L)

You can also directly use ystar <- gpSim(GP) without the argument L (the Cholesky factor) but each time you will call gpSim(GP), gpSim will compute again internally the Cholesky factor. So, if you plan to run many unconditional simulations, it is faster to first compute the Cholesky factor and then run several time gpSim with the argument L.

Plot the random simulation:

plot(rbind(cbind(obs$x, obs$y), ystar), type="n", xlab="x", ylab="y") 
lines(ystar, col = "blue")
points(cbind(obs$x, obs$y), col = "black", pch = 20)
legend("topleft", legend = c("obs", "GP sim"), lty = c(NA, 1),
       pch = c(20, NA), col=c("black", "blue"), bty="n")

Conditional Gaussian Process modelling with derivatives

We define a new object bc (a list) defining the derivatives, with elements:

  • x the location of the derivative
  • y the value of the derivative
  • sigma the uncertainty (standard deviation) on the derivative value (y)
covModel <- list(kernel = "matern",
                 l = 0.25,
                 v = 3.5,
                 h = 0.55)

bc <- list(x = c(-4.5, -2, 0,  3, 4.5),
           y = c(   0,  1, 0, -1,   0),
           sigma = 0)

sigma <- 0.1

GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
               sigma = sigma, op = 0)
GP2 <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
               sigma = sigma, op = 0, bc = bc)


#--- plot mean +/- sd
xp <-(GP$mean + sqrt(diag(GP$cov)))  # mean + sd
xm <-(GP$mean - sqrt(diag(GP$cov)))  # mean - sd
xp2 <-(GP2$mean + sqrt(diag(GP2$cov)))  # mean + sd
xm2 <-(GP2$mean - sqrt(diag(GP2$cov)))  # mean - sd


plot(cbind(obs$x, obs$y), type="p", xlab="x", ylab="y", 
     xlim = range(c(obs$x, targ$x)), ylim = range(c(xp, xm, obs$y)),
     pch = 20, col = "black", main = "without derivatives") 
lines(GP$xstar, GP$mean,col="red")  # mean
lines(GP$xstar, xm,lty=3)            # + sd
lines(GP$xstar, xp,lty=3)            # - sd
legend("topleft", legend = c("obs", "mean", "sd"), lty = c(NA, 1, 3),
       pch = c(20, NA, NA), col=c("black", "red", "black"), bty="n")

plot(cbind(obs$x, obs$y), type="p", xlab="x", ylab="y", 
     xlim = range(c(obs$x, targ$x)), ylim = range(c(xp, xm, obs$y)),
     pch = 20, col = "black", main = "with derivatives") 
lines(GP2$xstar, GP2$mean, col = "red")  # mean
lines(GP2$xstar, xm2,lty=3)            # + sd
lines(GP2$xstar, xp2,lty=3)            # - sd
legend("topleft", legend = c("obs", "mean", "sd"), lty = c(NA, 1, 3),
       pch = c(20, NA, NA), col=c("black", "red", "black"), bty="n")
y0 <- GP2$mean[sapply(bc$x, function(x, a) which.min(abs(x - a)), GP2$xstar)]
arrows(x0 = bc$x - 1/2, y0 = y0 - bc$y/2, 
       x1 = bc$x + 1/2, y1 = y0 + bc$y/2,
       length = 0.15, col = "dodgerblue2", lwd = 2)

Gaussian Process Modelling with two dimensional "positions"

To understand everything, please read the previous section ("1D Gaussian Process Modelling").

I you want to simulate a Gaussian process on a two-dimensional mesh, go to the section "2D Gaussian Process Modelling (simulation on a 2D mesh)".

Observations and target

The observations are defined by a list with x the positions of the observations and y the observed values. Here, the element x of the observation list is a matrix corresponding to the coordinates of the observations points (East/North coordinates or x/y coordinates).

#observations
obs <- list(x = cbind(c(2.17, 7.92, 8.98, 7.77, 2.79, 5.36, 4.27, 3.07, 6.31),
                     c(1.33, 7.24, 4.26, 2.67, 6.17, 8.04, 3.18, 5.63, 8.33)),
            y = c(2.60, 1.48, 1.36, 8.61, 1.00, 1.58, 8.42, 8.39, 1.50))

The target is defined by a two-columns matrix corresponding to the coordinates of the target points.

# targets (=2D mesh)
targ <- list(x = cbind(c(2.17, 7.92, 8.98, 7.77, 2.79, 5.36, 4.27, 3.07, 6.31, 
                       3.74, 5.93, 7.19, 6.61, 5.54, 2.27, 1.61, 4.02, 1.06),
                     c(1.33, 7.24, 4.26, 2.67, 6.17, 8.04, 3.18, 5.63, 8.33,
                       6.34, 3.68, 6.82, 1.79, 8.60, 7.73, 5.35, 2.45, 4.92))
                      )

Covariance function, mean function and likelihood

To build the covariance functions, the same kernels as in the previously defined are available:

# Matern kernel
covModel <- list(kernel="matern",
                 l = 5,     # correlation length
                 v = 1,     # smoothness
                 h = 2.45   # std. deviation
                )

Note that the 2D mean functions (or basis functions) are differently defined:

# 2D quadratic mean function
op <- 5
# zero-mean function (no trend)
op <- 0 
# 2D linear mean function
op <- 2

Standard deviation (measurement error):

# Gaussian likelihood
sigma <- 0.2

Conditional Gaussian Process modelling

GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
               sigma = sigma, op = op)
names(GP)
# GP$mean   = mean value at location xstar
# GP$cov    = covariance matrix of the conditioned GP
# GP$logLik = log-likelihood of the conditioned GP
# GP$xstar  = x-coordinates at which the GP is simulated
# mean
Ymean <- GP$mean
# standard deviation
YSD <- sqrt(diag(GP$cov))
ysdplus <- Ymean - 1.95* YSD
ysdminus <- Ymean + 1.95* YSD

Results

Plot the mean and standard deviation functions

Three-dimensional plot

par(mfrow = c(1,1))
ylim <- range(Ymean, obs$y)
plot3D::scatter3D(x = targ$x[,1], y = targ$x[,2], z = Ymean, clim = ylim, 
                  pch = 20)
plot3D::arrows3D(x0 = targ$x[,1], y0 = targ$x[,2], z0 = ysdminus, 
                 x1 = targ$x[,1], y1 = targ$x[,2], z1 = ysdplus,
                 length=0.05, angle=90, code=3, add = TRUE, col = "black")
# large dots = observations
plot3D::scatter3D(x = obs$x[,1], y = obs$x[,2], z = obs$y, add = TRUE, 
                  pch = 20, cex = 3, clim = ylim)

Pair of two-dimensional plots

par(mfrow = c(1, 2))
ylim <- range(ysdplus, ysdminus, obs$y)

plot(targ$x[,1], Ymean, type = "p", ylim = ylim, pch = 3, cex = 0.5)
arrows(targ$x[,1], ysdminus, targ$x[,1], ysdplus, length=0.05, angle=90, code=3)
points(obs$x[,1], obs$y, col = "dodgerblue", pch = 20)

plot(targ$x[,2], Ymean, type = "p", ylim = ylim, pch = 3, cex = 0.5)
arrows(targ$x[,2], ysdminus, targ$x[,2], ysdplus, length=0.05, angle=90, code=3)
points(obs$x[,2], obs$y, col = "dodgerblue", pch = 20)

Random conditional simulation

L <- cholfac(GP$cov)
ystar <- gpSim(GP , L = L)

par(mfrow = c(1,1))
ylim <- range(ystar[,3], obs$y)
plot3D::scatter3D(x = targ$x[,1], y = targ$x[,2], z = ystar[,3], clim = ylim, 
                  pch = 18)
# dots = observations
plot3D::scatter3D(x = obs$x[,1], y = obs$x[,2], z = obs$y, add = TRUE, 
                  pch = 20, cex = 3, clim = ylim)

2D Gaussian Process Modelling (simulation on a 2D mesh)

To understand everything, please read the previous section ("1D Gaussian Process Modelling").

Observations and target

The observations are defined by a list with x the positions of the observations and y the observed values. Here, the element x of the observation list is a matrix corresponding to the coordinates of the observations points (East/North coordinates or x/y coordinates).

#observations
obs <- list(x = cbind(c(2.17, 7.92, 8.98, 7.77, 2.79, 5.36, 4.27, 3.07, 6.31, 
                       3.74, 5.93, 7.19, 6.61, 5.54, 2.27, 1.61, 4.02, 1.06),
                     c(1.33, 7.24, 4.26, 2.67, 6.17, 8.04, 3.18, 5.63, 8.33,
                       6.34, 3.68, 6.82, 1.79, 8.60, 7.73, 5.35, 2.45, 4.92)),
            y = c(2.60, 1.48, 1.36, 8.61, 1.00, 1.58, 8.42, 8.39, 1.50, 
                  9.05, 1.14, 1.49, 9.19, 1.32, 1.03, 6.41, 6.16, 5.42))

The target is defined by a regular grid defined by two orthogonal vectors. The function vecGridreturns a two-columns matrix corresponding to the coordinates of each element of the grid.

# targets (=2D mesh)
vx <- seq(0, 10, by = 0.5)
vy <- seq(0, 10, by = 0.5)
targ <- list(x = vecGrid(vx, vy))

Covariance function, mean function and likelihood

To build the covariance functions, the same kernels as in the previously defined are available:

# linear kernel
covModel <- list(kernel="linear",
                 b = 1,         # slope
                 h = 0.5,       # std. deviation
                 c = 1)         # constant
                 
# Matern kernel
covModel <- list(kernel="matern",
                 l = 1,       # correlation length
                 v = 2.5,     # smoothness
                 h = 2.45)    # std. deviation

# squared exponential kernel (Gaussian)
covModel <- list(kernel="gaussian",
                 l = 0.5,   # correlation length
                 h = 0.25)  # std. deviation

Note that the 2D mean functions (or basis functions) are differently defined:

# 2D quadratic mean function
op <- 5
# zero-mean function (no trend)
op <- 0 
# 2D linear mean function
op <- 2

Standard deviation (measurement error):

# Gaussian likelihood
sigma <- 0.2

Conditional Gaussian Process modelling

GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
               sigma = sigma, op = op)
names(GP)
# GP$mean   = mean value at location xstar
# GP$cov    = covariance matrix of the conditioned GP
# GP$logLik = log-likelihood of the conditioned GP
# GP$xstar  = x-coordinates at which the GP is simulated

Plot the mean and standard deviation functions

# mean
Ymean <- matrix(GP$mean, nrow = length(vx), ncol = length(vy), byrow = TRUE)
# standard deviation
YSD <- matrix(sqrt(diag(GP$cov)), nrow = length(vx), ncol = length(vy), 
              byrow = TRUE)
              
par(mfrow = c(2,2))
plot3D::image2D(x = vx, y = vy, z = Ymean, asp=1)
points(obs$x, col="white",pch=3)
title(main = "mean")

plot3D::contour2D(x = vx, y = vy, Ymean, asp=1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "mean")

plot3D::image2D(x = vx, y = vy, z = YSD, asp=1)
points(obs$x, col="white",pch=3)
title(main = "standard deviation")

plot3D::contour2D(x = vx, y = vy, YSD, asp=1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "standard deviation")

Random conditional simulation

L <- cholfac(GP$cov)
ystar <- gpSim(GP , L = L)

Ysim <- matrix(ystar[,3], nrow = length(vx), ncol = length(vy), byrow = TRUE)

par(mfrow=c(1,2))
plot3D::image2D(x = vx, y = vy, z = Ysim, asp=1)
points(obs$x, col="white",pch=3)


plot3D::contour2D(x = vx, y = vy, Ysim, asp=1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])

Anisotropy (scaling only along the coordinates axes)

covModelAni <- list(kernel="matern",
                 l = 1,       # correlation length
                 v = 2.5,     # smoothness
                 h = 2.45,
                 scale = c(1, 0.25))    # std. deviation
# 2D linear mean function
op <- 2

GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModelAni), 
               sigma = sigma, op = op)
names(GP)
# GP$mean   = mean value at location xstar
# GP$cov    = covariance matrix of the conditioned GP
# GP$logLik = log-likelihood of the conditioned GP
# GP$xstar  = x-coordinates at which the GP is simulated

Plot the mean and standard deviation functions

# mean
YmeanAni <- matrix(GP$mean, nrow = length(vx), ncol = length(vy), byrow = TRUE)
# standard deviation
YSDAni <- matrix(sqrt(diag(GP$cov)), nrow = length(vx), ncol = length(vy), 
              byrow = TRUE)
              
par(mfrow = c(2,2))
plot3D::image2D(x = vx, y = vy, z = Ymean, asp = 1)
points(obs$x, col="white",pch=3)
title(main = "isotropic GP: mean ")

plot3D::contour2D(x = vx, y = vy, Ymean, asp = 1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "isotropic GP: mean")

plot3D::image2D(x = vx, y = vy, z = YmeanAni, asp = 1)
points(obs$x, col="white",pch=3)
title(main = "anisotropic GP: mean ")

plot3D::contour2D(x = vx, y = vy, YmeanAni, asp = 1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "anisotropic GP: mean")

Anisotropy (scaling and rotation along the coordinates axes)

covModelAni2 <- list(kernel="matern",
                 l = 1,       # correlation length
                 v = 2.5,     # smoothness
                 h = 2.45,
                 scale = c(1, 0.25),
                 rot = c(1.0))    # std. deviation
# 2D linear mean function
op <- 2

GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModelAni2), 
               sigma = sigma, op = op)
names(GP)
# GP$mean   = mean value at location xstar
# GP$cov    = covariance matrix of the conditioned GP
# GP$logLik = log-likelihood of the conditioned GP
# GP$xstar  = x-coordinates at which the GP is simulated

Plot the mean and standard deviation functions

# mean
YmeanAni2 <- matrix(GP$mean, nrow = length(vx), ncol = length(vy), byrow = TRUE)
# standard deviation
YSDAni2 <- matrix(sqrt(diag(GP$cov)), nrow = length(vx), ncol = length(vy), 
              byrow = TRUE)
              
par(mfrow = c(2,2))
plot3D::image2D(x = vx, y = vy, z = YmeanAni, asp = 1)
points(obs$x, col="white",pch=3)
title(main = "anisotropic GP (scale): mean ")

plot3D::contour2D(x = vx, y = vy, YmeanAni, asp = 1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "anisotropic GP (scale): mean")

plot3D::image2D(x = vx, y = vy, z = YmeanAni2, asp = 1)
points(obs$x, col="white",pch=3)
title(main = "anisotropic GP (scale + rotation): mean ")

plot3D::contour2D(x = vx, y = vy, YmeanAni2, asp = 1)
points(obs$x, col="black",pch=3)
rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "anisotropic GP (scale + rotation): mean")

Gaussian process with derivative constraints

Interpolation of hydraulic heads that accounts for no-flow boundary conditions at the top and bottom model boundary (adapted from Kuhlman and IgĂşzquiz, 2010, doi:10.1016/j.jhydrol.2010.01.002).

We create a new object bc (a list) with elements

  • x is the locations where we set the derivative of the Gaussian field,
  • v the gradient derivative, i.e., a unit vector normal to the no-flow boundary (or tangent to a constant-head boundary)
  • y is the value of the gradient (in this case 0 meaning that the gradient is flat)
  • sigma the standard deviation reprensenting the uncertainty on the value of the gradient (i.e., y).
obs <- list(x = cbind(c(2.17, 7.92, 8.98, 7.77, 2.79, 5.36, 4.27, 3.07, 6.31),
                      c(1.33, 7.24, 4.26, 2.67, 6.17, 8.04, 3.18, 5.63, 8.33)),
            y = c(2.60, 1.48, 1.36, 8.61, 1.00, 1.58, 8.42, 8.39, 1.50))



# Matern kernel

vx <- seq(0, 10, by = 0.25)
vy <- seq(0, 10, by = 0.25)
targ <- list(x = vecGrid(vx, vy))


covModel <- list(kernel="matern",
                 l = 1,
                 v = 2.5,
                 h = 3)

op <- 5    
sigma <- 0.05


GP <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
             sigma = sigma, op = op)
# mean
Ymean <- matrix(GP$mean, nrow = length(vx), ncol = length(vy), byrow = TRUE)

#  no-flow boundary top and bottom
bc <- list(x = cbind(c( rep(seq(0.5, 9.5, by = 2), 2)),
                     c(rep(0, 5), rep(10, 5))),
           v = cbind( rep(0, 10),
                      rep(1, 10) ),
           y =  rep(0, 10),
           sigma = 0) 



GPbc <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
             sigma = sigma, op = op, bc = bc)
# mean
Ymeanbc <- matrix(GPbc$mean, nrow = length(vx), ncol = length(vy), byrow = TRUE)

par(mfrow = c(1,2))


plot3D::contour2D(x = vx, y = vy, Ymean, asp=1, nlevels = 20, col = "black", lwd = 2, 
                  xaxs = "i", yaxs = "i", labcex = 1)
points(obs$x, pch=20, col = "red", cex = 2)
#rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "mean GP")



plot3D::contour2D(x = vx, y = vy, Ymeanbc, asp=1, nlevels = 20, col = "black", lwd = 2, 
                  xaxs = "i", yaxs = "i", labcex = 1)
points(obs$x, pch=20, col = "red", cex = 2)
#rect(vx[1], vy[1], vx[length(vx)], vy[length(vy)])
title(main = "mean GP with no-flow\n boundaries")

points(bc$x, pch = 4)
arrows(bc$x[,1] - bc$v[,2]/2, bc$x[,2] - bc$v[,1]/2, 
       bc$x[,1] + bc$v[,2]/2, bc$x[,2] + bc$v[,1]/2,
       length = 0.15, col = "dodgerblue2", lwd = 2)

The same with:

  • no-flow condition at top and bottom model boundaries
  • constant-head boundary at left and right model boundaries
#  no-flow boundary top and bottom
bc2 <- list(x = cbind(c( rep(seq(0.5, 9.5, by = 2), 2),
                        rep(0, 5), rep(10, 5)),
                     c( rep(0, 5), rep(10, 5),
                        rep(seq(0.5, 9.5, by = 2), 2))),
           v = cbind( rep(0, 20),
                      rep(1, 20) ),
           y =  rep(0, 20),
           sigma = 0) 

GPbc2 <- gpCond(obs = obs, targ = targ, covModels=list(pos=covModel), 
             sigma = sigma, op = op, bc = bc2)
# mean
Ymeanbc2 <- matrix(GPbc2$mean, nrow = length(vx), ncol = length(vy), byrow = TRUE)

par(mfrow = c(1,2))


plot3D::contour2D(x = vx, y = vy, Ymeanbc, asp=1, nlevels = 20, col = "black", lwd = 2, 
                  xaxs = "i", yaxs = "i", labcex = 1, xlim = c(-0.5, 10.5))
points(obs$x, pch=20, col = "red", cex = 2)
title(main = "mean GP with no-flow\n boundaries")

points(bc$x, pch = 4)
arrows(bc$x[,1] - bc$v[,2]/2, bc$x[,2] - bc$v[,1]/2, 
       bc$x[,1] + bc$v[,2]/2, bc$x[,2] + bc$v[,1]/2,
       length = 0.15, col = "dodgerblue2", lwd = 2)

plot3D::contour2D(x = vx, y = vy, Ymeanbc2, asp=1, nlevels = 20, col = "black", lwd = 2, 
                  xaxs = "i", yaxs = "i", labcex = 1, xlim = c(-0.5, 10.5))
points(obs$x, pch=20, col = "red", cex = 2)
title(main = "mean GP with no-flow \n and cst head boundaries")

points(bc2$x, pch = 4)
arrows(bc2$x[,1] - bc2$v[,2]/2, bc2$x[,2] - bc2$v[,1]/2, 
       bc2$x[,1] + bc2$v[,2]/2, bc2$x[,2] + bc2$v[,1]/2,
       length = 0.15, col = "dodgerblue2", lwd = 2)

Space-time Gaussian Process Modelling

To understand everything, please read the previous sections.

Observations and target

The observations are defined by a list with x the positions of the observations, y the observed time-series and t the time scale. Note that all the time-series must have the same time scale. Here, the element x of the observation list is a matrix corresponding to the coordinates of the observations points (East/North coordinates or x/y coordinates).

The element y is a big vector constiting of all the time-series recorded at the positions defined by element x put one after another. For example, consider 5 monitoring stations with positions x1, x2, x3, x4 and x5. At each station, a time-series was recorded:

  • at station 1: y1 = y1,1, y1,2, ..., y1,t
  • at station 2: y2 = y2,1, y2,2, ..., y2,t
  • ...
  • at station 5: y5 = y5,1, y5,2, ..., y5,t

Then, the element y is set to c(y1, y2, y3, y4, y5).

Assuming that the data were recorded every hour, the time scale t is simply 1, 2, 3, ..., t.

#observations
obs <- list(x = cbind(c(2, 8, 1, 3, 5),
                      c(9, 2, 3, 4, 6)),
            y = c(1:10 + rnorm(10, 0, 0.1),
                  1:10 + rnorm(10, -0.5, 0.1),
                  1:10 + rnorm(10, 1, 0.4),
                  1:10 + rnorm(10, -0.5, 0.2),
                  1:10 + rnorm(10, 0, 0.1)),
            t = seq_len(10))

The target is defined by a regular grid defined by two orthogonal vectors. The function vecGridreturns a two-columns matrix corresponding to the coordinates of each element of the grid. For each element of the grid, the Gaussian process simulate a time-series whose time scale is identical to that of the observations.

# targets
vx <- seq(0, 10, by = 0.5)
vy <- seq(0, 10, by = 0.5)
targ <- list(x = vecGrid(vx, vy))

Covariance function, mean function and likelihood

Two covariance are defined, one for the space domain (element pos) and one for the time domain (element time). For the moment, the covariance function of the space-time Gaussian process is defined by the product of the spatial and temporal kernel.

covModels <- list(pos =  list(kernel="matern",
                              l = 4,       # correlation length
                              v = 2.5,     # smoothness
                              h = 2.45),    # std. deviation
                  time = list(kernel="gaussian",
                              l = 0.15,   # correlation length
                              h = 1.25))
                              
# 2D mean linear mean function 
op <- 2

# Gaussian likelihood
sigma <- 0.2

Conditional Gaussian Process modelling

GP <- gpCond(obs = obs, targ = targ, covModels = covModels, 
               sigma = sigma, op = op)
names(GP)
# GP$mean   = mean value at location xstar
# GP$cov    = covariance matrix of the conditioned GP
# GP$logLik = log-likelihood of the conditioned GP
# GP$xstar  = x-coordinates at which the GP is simulated

The mean values are re-organised into a three-dimensional array of dimension $n_t \times n_x \times n_y, with $n_t$ the number of time-step, and $n_x \times n_y$ the dimension of the (spatial) target grid.

Ymean <-  array(GP$mean, dim=c(length(obs$t), length(vx), length(vy)))
Ysd <-  array(sqrt(diag(GP$cov)), dim=c(length(obs$t), length(vx), length(vy)))

par(mfrow = c(2,5))
for(i in seq_along(obs$t)){
  plot3D::image2D(z = Ymean[i,,], x = vx, y = vy, zlim = range(Ymean), 
                  main = paste("mean at t =",obs$t[i]))
  points(obs$x, col="white",pch=20, cex=2)
  points(obs$x, col="black",pch=3)
}

par(mfrow = c(2,5))
for(i in seq_along(obs$t)){
  plot3D::image2D(z = Ysd[i,,], x = vx, y = vy, zlim = range(Ysd), 
                  main =  paste("std. dev. at t =",obs$t[i]))
  points(obs$x, col="white",pch=20, cex=2)
  points(obs$x, col="black",pch=3)
}

Random conditional simulation. La function gpSim returns a matrix whose two first column correspond to the position coordinate, the third columns corresponds to the time scale and the fourth column to the simulated Gaussian process.

L <- cholfac(GP$cov)
ystar <- gpSim(GP , L = L)

colnames(ystar) <- c("x1", "x2", "t", "y")

Ysim <- array(ystar[,"y"], dim=c(length(obs$t), length(vx), length(vy)))

par(mfrow = c(2,5))
for(i in seq_along(obs$t)){
  plot3D::image2D(z = Ysim[i,,], x = vx, y = vy,
                  zlim = range(ystar[,"y"]), 
                  main = paste("simulation at t =",obs$t[i]))
  points(obs$x, col="white",pch=20, cex=2)
  points(obs$x, col="black",pch=3)
}

Time-series at location (4,1):

par(mfrow = c(1,1))
plot(Ysim[,vx == 4, vy == 1], type = "l", xlab = "time", ylab = "value")

References

Rasmussen C.E. and Williams C.K.I. (2006), Gaussian Processes for Machine Learning, the MIT Press, ISBN 026218253X. www.GaussianProcess.org/gpml

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Software package for Gaussian Process (GP) modelling written in R language. The core functions are coded in C++ and based on the EIGEN library (through RcppEigen).

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