Getting started with functional statistical testing

simu_vec <- simul_traj(100)
plot(simu_vec, xlab = "point", ylab = "value")

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)
str(simu_data)
#> List of 5
#>  $ mat_sample1: num [1:100, 1:50] 10 10.1 10.2 10.3 10.4 ...
#>  $ mat_sample2: num [1:100, 1:75] 0 0.00241 0.00497 0.00775 0.01071 ...
#>  $ c_val      : num 10
#>  $ distrib    : chr "normal"
#>  $ delta_shape: chr "constant"

# constant delta
simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 5, 
    delta_shape = "constant", distrib = "normal"
)
plot_simu(simu_data)

# linear delta
simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 5, 
    delta_shape = "linear", distrib = "normal"
)
plot_simu(simu_data)

# quadratic delta
simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 5, 
    delta_shape = "quadratic", distrib = "normal"
)
plot_simu(simu_data)

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)

MatX <- simu_data$mat_sample1
MatY <- simu_data$mat_sample2

stat_mo(MatX, MatY)
#> [1] 0.9988008

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)

MatX <- simu_data$mat_sample1
MatY <- simu_data$mat_sample2

stat_med(MatX, MatY)
#> [1] 0.9993601

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)

MatX <- simu_data$mat_sample1
MatY <- simu_data$mat_sample2

stat_wmw(MatX, MatY)
#> [1] 0.9984562

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)

MatX <- simu_data$mat_sample1
MatY <- simu_data$mat_sample2

stat_hkr(MatX, MatY)
#> $T1
#> [1] 56962058560
#> 
#> $T2
#> [1] 297023.2
#> 
#> $eigenval
#>  [1] 3.664005e+01 5.308985e+00 1.522118e+00 6.759658e-01 2.275435e-01
#>  [6] 1.705847e-01 9.892918e-02 6.026029e-02 3.071646e-02 1.788522e-02
#> [11] 1.102164e-02 9.424057e-03 6.172824e-03 5.108395e-03 2.334137e-03
#> [16] 1.450027e-03 3.118851e-04 6.975138e-05 1.716764e-09

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)

MatX <- simu_data$mat_sample1
MatY <- simu_data$mat_sample2

stat_cff(MatX, MatY)
#> [1] 511045.7

simu_data <- simul_data(
    n_point = 100, n_obs1 = 50, n_obs2 = 75, c_val = 10, 
    delta_shape = "constant", distrib = "normal"
)

MatX <- simu_data$mat_sample1
MatY <- simu_data$mat_sample2

res <- comp_stat(MatX, MatY, stat = c("mo", "med", "wmw", "hkr", "cff"))
res
#> $mo
#> [1] 0.9989056
#> 
#> $med
#> [1] 0.9992861
#> 
#> $wmw
#> [1] 0.9985099
#> 
#> $hkr
#>            [,1]
#> T1 5.132184e+10
#> T2 3.018523e+05
#> 
#> $cff
#> [1] 511580.1