Detecting change points
The function detect_cp provide a method for detecting
change points, it is based on the work Martínez
and Mena (2014) and on Corradin et al.
(2025).
Depending on the structure of the data, detect_cp might
perform change points detection on univariate time series or
multivariate time series. For example we can create a vector of 100
observations where the first 50 observations are sampled from a normal
distribution with mean 0 and variance 0.1 and the other 50 observations
still from a normal distribution with mean 0 but variance 0.25.
data_uni <- as.numeric(c(rnorm(50,0,0.1), rnorm(50,1,0.25)))
Now we can run the function detect_cp, as arguments of
the function we need to specify the number of iterations, the number of
burn-in steps and a list with the the autoregressive coefficient
phi for the likelihood of the data, the parameters
a, b, c for the priors and the
probability q of performing a split at each step. Since we
deal with time series we need also to specify
kernel = "ts".
out <- detect_cp(data = data_uni,
n_iterations = 1000, n_burnin = 100,
params = list(q = 0.25, phi = 0.1, a = 1, b = 1, c = 0.1), kernel = "ts")
#> Completed: 100/1000 - in 0.009 sec
#> Completed: 200/1000 - in 0.018 sec
#> Completed: 300/1000 - in 0.027 sec
#> Completed: 400/1000 - in 0.036 sec
#> Completed: 500/1000 - in 0.045 sec
#> Completed: 600/1000 - in 0.053 sec
#> Completed: 700/1000 - in 0.061 sec
#> Completed: 800/1000 - in 0.07 sec
#> Completed: 900/1000 - in 0.078 sec
#> Completed: 1000/1000 - in 0.087 sec
With the methods print and summary we can
get information about the algorithm.
print(out)
#> DetectCpObj object
#> Type: change points detection on univariate time series
summary(out)
#> DetectCpObj object
#> Detecting change points on an univariate time series:
#> Number of burn-in iterations: 100
#> Number of MCMC iterations: 900
#> Computational time: 0.09 seconds
In order to get a point estimate of the change points we can use the
method posterior_estimate that uses the method
salso by David B. Dahl and Müller
(2022) to get the final latent order and then detect the change
points.
table(posterior_estimate(out, loss = "binder"))
#>
#> 1 2
#> 50 50
The package also provides a method for plotting the change
points.
plot(out, loss = "binder")
If we define instead a matrix of data, detect_cp
automatically performs a multivariate change points detection
method.
data_multi <- matrix(NA, nrow = 3, ncol = 100)
data_multi[1,] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_multi[2,] <- as.numeric(c(rnorm(50,0,0.125), rnorm(50,1,0.225)))
data_multi[3,] <- as.numeric(c(rnorm(50,0,0.175), rnorm(50,1,0.280)))
Arguments k_0, nu_0, phi_0,
m_0, par_theta_c, par_theta_d and
prior_var_gamma correspond to the parameters of the prior
distributions for the multivariate likelihood.
out <- detect_cp(data = data_multi, n_iterations = 1000, n_burnin = 100,
q = 0.25, params = list(k_0 = 0.25, nu_0 = 4, phi_0 = diag(1,3,3),
m_0 = rep(0,3), par_theta_c = 2, par_theta_d = 0.2,
prior_var_gamma = 0.1), kernel = "ts")
#> Completed: 100/1000 - in 0.013 sec
#> Completed: 200/1000 - in 0.025 sec
#> Completed: 300/1000 - in 0.038 sec
#> Completed: 400/1000 - in 0.05 sec
#> Completed: 500/1000 - in 0.061 sec
#> Completed: 600/1000 - in 0.073 sec
#> Completed: 700/1000 - in 0.084 sec
#> Completed: 800/1000 - in 0.096 sec
#> Completed: 900/1000 - in 0.107 sec
#> Completed: 1000/1000 - in 0.119 sec
table(posterior_estimate(out, loss = "binder"))
#>
#> 1 2
#> 50 50
plot(out, loss = "binder", plot_freq = TRUE)
Function detect_cp can also be used to detect change
points on survival functions. We define a matrix of one row and a vector
with the infection rates.
data_mat <- matrix(NA, nrow = 100, ncol = 1)
betas <- c(rep(0.45, 25),rep(0.14,75))
With function sim_epi_data we simulate a set of
infection times.
inf_times <- sim_epi_data(10000, 10, 100, betas, 1/8)
inf_times_vec <- rep(0,100)
names(inf_times_vec) <- as.character(1:100)
for(j in 1:100){
if(as.character(j) %in% names(table(floor(inf_times)))){
inf_times_vec[j] = table(floor(inf_times))[which(names(table(floor(inf_times))) == j)]
}
}
data_mat[,1] <- inf_times_vec
To run detect_cp on epidemiological data we need to set
kernel = "epi". Moreover, besides the usual parameters, we
need to set the number of Monte Carlo replications M for
the approximation of the integrated likelihood and the recovery rate
xi. a0 and b0 are optional and
correspond to the parameters of the gamma distribution for the
integration of the likelihood.
out <- detect_cp(data = data_mat, n_iterations = 200, n_burnin = 50,
params = list(xi = 1/8, a0 = 40, b0 = 10, M = 1000), kernel = "epi")
#> Completed: 20/200 - in 1.229 sec
#> Completed: 40/200 - in 2.305 sec
#> Completed: 60/200 - in 3.518 sec
#> Completed: 80/200 - in 4.731 sec
#> Completed: 100/200 - in 5.945 sec
#> Completed: 120/200 - in 7.153 sec
#> Completed: 140/200 - in 8.477 sec
#> Completed: 160/200 - in 9.86 sec
#> Completed: 180/200 - in 11.237 sec
#> Completed: 200/200 - in 12.611 sec
print(out)
#> DetectCpObj object
#> Type: change points detection on an epidemic diffusion
table(posterior_estimate(out, loss = "binder"))
#>
#> 1 2
#> 26 74
Also here, with function plot we can plot the survival
function and the position of the change points.
plot(out)
#> Warning in salso::salso(mcmc_chain, loss = "VI", maxNClusters = maxNClusters, :
#> The number of clusters equals the default maximum possible number of clusters.
Clustering time dependent data with common change points
BayesChange contains another function,
clust_cp, that cluster respectively univariate and
multivariate time series and survival functions with common change
points. Details about this methods can be found in Corradin et al. (2024).
In clust_cp the argument kernel must be
specified, if data are time series then kernel = "ts" must
be set. Then the algorithm automatically detects if data are univariate
or multivariate.
If time series are univariate we need to set a matrix where each row
is a time series.
data_mat <- matrix(NA, nrow = 5, ncol = 100)
data_mat[1,] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_mat[2,] <- as.numeric(c(rnorm(50,0,0.125), rnorm(50,1,0.225)))
data_mat[3,] <- as.numeric(c(rnorm(50,0,0.175), rnorm(50,1,0.280)))
data_mat[4,] <- as.numeric(c(rnorm(25,0,0.135), rnorm(75,1,0.225)))
data_mat[5,] <- as.numeric(c(rnorm(25,0,0.155), rnorm(75,1,0.280)))
Arguments that need to be specified in clust_cp are the
number of iterations n_iterations, the number of elements
in the normalisation constant B, the split-and-merge step
L performed when a new partition is proposed and a list
with the parameters of the algorithm, the likelihood and the
priors..
out <- clust_cp(data = data_mat, n_iterations = 1000, n_burnin = 100,
kernel = "ts",
params = list(B = 1000, L = 1, gamma = 0.5))
#> Normalization constant - completed: 100/1000 - in 0.004 sec
#> Normalization constant - completed: 200/1000 - in 0.008 sec
#> Normalization constant - completed: 300/1000 - in 0.012 sec
#> Normalization constant - completed: 400/1000 - in 0.016 sec
#> Normalization constant - completed: 500/1000 - in 0.02 sec
#> Normalization constant - completed: 600/1000 - in 0.024 sec
#> Normalization constant - completed: 700/1000 - in 0.028 sec
#> Normalization constant - completed: 800/1000 - in 0.032 sec
#> Normalization constant - completed: 900/1000 - in 0.036 sec
#> Normalization constant - completed: 1000/1000 - in 0.04 sec
#>
#> ------ MAIN LOOP ------
#>
#> Completed: 100/1000 - in 0.049 sec
#> Completed: 200/1000 - in 0.098 sec
#> Completed: 300/1000 - in 0.149 sec
#> Completed: 400/1000 - in 0.2 sec
#> Completed: 500/1000 - in 0.248 sec
#> Completed: 600/1000 - in 0.299 sec
#> Completed: 700/1000 - in 0.356 sec
#> Completed: 800/1000 - in 0.405 sec
#> Completed: 900/1000 - in 0.455 sec
#> Completed: 1000/1000 - in 0.505 sec
posterior_estimate(out, loss = "binder")
#> [1] 1 2 3 4 4
Method plot for clustering univariate time series
represents the data colored according to the assigned cluster.
plot(out, loss = "binder")
If time series are multivariate, data must be an array, where each
element is a multivariate time series represented by a matrix. Each row
of the matrix is a component of the time series.
data_array <- array(data = NA, dim = c(3,100,5))
data_array[1,,1] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_array[2,,1] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_array[3,,1] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_array[1,,2] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_array[2,,2] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_array[3,,2] <- as.numeric(c(rnorm(50,0,0.100), rnorm(50,1,0.250)))
data_array[1,,3] <- as.numeric(c(rnorm(50,0,0.175), rnorm(50,1,0.280)))
data_array[2,,3] <- as.numeric(c(rnorm(50,0,0.175), rnorm(50,1,0.280)))
data_array[3,,3] <- as.numeric(c(rnorm(50,0,0.175), rnorm(50,1,0.280)))
data_array[1,,4] <- as.numeric(c(rnorm(25,0,0.135), rnorm(75,1,0.225)))
data_array[2,,4] <- as.numeric(c(rnorm(25,0,0.135), rnorm(75,1,0.225)))
data_array[3,,4] <- as.numeric(c(rnorm(25,0,0.135), rnorm(75,1,0.225)))
data_array[1,,5] <- as.numeric(c(rnorm(25,0,0.155), rnorm(75,1,0.280)))
data_array[2,,5] <- as.numeric(c(rnorm(25,0,0.155), rnorm(75,1,0.280)))
data_array[3,,5] <- as.numeric(c(rnorm(25,0,0.155), rnorm(75,1,0.280)))
out <- clust_cp(data = data_array, n_iterations = 1000, n_burnin = 100,
kernel = "ts", params = list(gamma = 0.1, k_0 = 0.25, nu_0 = 5, phi_0 = diag(0.1,3,3), m_0 = rep(0,3)))
#> Normalization constant - completed: 100/1000 - in 0.008 sec
#> Normalization constant - completed: 200/1000 - in 0.017 sec
#> Normalization constant - completed: 300/1000 - in 0.026 sec
#> Normalization constant - completed: 400/1000 - in 0.035 sec
#> Normalization constant - completed: 500/1000 - in 0.044 sec
#> Normalization constant - completed: 600/1000 - in 0.052 sec
#> Normalization constant - completed: 700/1000 - in 0.061 sec
#> Normalization constant - completed: 800/1000 - in 0.07 sec
#> Normalization constant - completed: 900/1000 - in 0.079 sec
#> Normalization constant - completed: 1000/1000 - in 0.087 sec
#>
#> ------ MAIN LOOP ------
#>
#> Completed: 100/1000 - in 0.079 sec
#> Completed: 200/1000 - in 0.158 sec
#> Completed: 300/1000 - in 0.232 sec
#> Completed: 400/1000 - in 0.307 sec
#> Completed: 500/1000 - in 0.38 sec
#> Completed: 600/1000 - in 0.463 sec
#> Completed: 700/1000 - in 0.539 sec
#> Completed: 800/1000 - in 0.623 sec
#> Completed: 900/1000 - in 0.7 sec
#> Completed: 1000/1000 - in 0.775 sec
posterior_estimate(out, loss = "binder")
#> [1] 1 2 3 4 4
plot(out, loss = "binder")
Finally, if we set kernel = "epi", clust_cp
cluster survival functions with common change points. Also here details
can be found in Corradin et al.
(2024).
Data are a matrix where each row is the number of infected at each
time. Inside this package is included the function
sim_epi_data that simulates infection times.
data_mat <- matrix(NA, nrow = 5, ncol = 50)
betas <- list(c(rep(0.45, 25),rep(0.14,25)),
c(rep(0.55, 25),rep(0.11,25)),
c(rep(0.50, 25),rep(0.12,25)),
c(rep(0.52, 10),rep(0.15,40)),
c(rep(0.53, 10),rep(0.13,40)))
inf_times <- list()
for(i in 1:5){
inf_times[[i]] <- sim_epi_data(S0 = 10000, I0 = 10, max_time = 50, beta_vec = betas[[i]], xi_0 = 1/8)
vec <- rep(0,50)
names(vec) <- as.character(1:50)
for(j in 1:50){
if(as.character(j) %in% names(table(floor(inf_times[[i]])))){
vec[j] = table(floor(inf_times[[i]]))[which(names(table(floor(inf_times[[i]]))) == j)]
}
}
data_mat[i,] <- vec
}
out <- clust_cp(data = data_mat, n_iterations = 100, n_burnin = 10,
kernel = "epi",
list(M = 100, B = 1000, L = 1, q = 0.1, gamma = 1/8))
#> Normalization constant - completed: 100/1000 - in 0.521 sec
#> Normalization constant - completed: 200/1000 - in 1.045 sec
#> Normalization constant - completed: 300/1000 - in 1.573 sec
#> Normalization constant - completed: 400/1000 - in 2.097 sec
#> Normalization constant - completed: 500/1000 - in 2.606 sec
#> Normalization constant - completed: 600/1000 - in 3.133 sec
#> Normalization constant - completed: 700/1000 - in 3.641 sec
#> Normalization constant - completed: 800/1000 - in 4.15 sec
#> Normalization constant - completed: 900/1000 - in 4.682 sec
#> Normalization constant - completed: 1000/1000 - in 5.195 sec
#>
#> ------ MAIN LOOP ------
#>
#> Completed: 10/100 - in 0.483 sec
#> Completed: 20/100 - in 0.988 sec
#> Completed: 30/100 - in 1.487 sec
#> Completed: 40/100 - in 1.989 sec
#> Completed: 50/100 - in 2.54 sec
#> Completed: 60/100 - in 3.076 sec
#> Completed: 70/100 - in 3.612 sec
#> Completed: 80/100 - in 4.249 sec
#> Completed: 90/100 - in 5.172 sec
#> Completed: 100/100 - in 5.997 sec
posterior_estimate(out, loss = "binder")
#> [1] 1 2 1 3 4
plot(out, loss = "binder")
Corradin, Riccardo, Luca Danese, Wasiur R. KhudaBukhsh, and Andrea
Ongaro. 2024.
“Model-Based Clustering of Time-Dependent
Observations with Common Structural Changes.” https://arxiv.org/abs/2410.09552.
———. 2025.
“Model-Based Clustering of Time-Dependent Observations
with Common Structural Changes.” Statistics and
Computing 36 (1): 7.
https://doi.org/10.1007/s11222-025-10756-x.
David B. Dahl, Devin J. Johnson, and Peter Müller. 2022.
“Search
Algorithms and Loss Functions for Bayesian Clustering.”
Journal of Computational and Graphical Statistics 31 (4):
1189–1201.
https://doi.org/10.1080/10618600.2022.2069779.
Martínez, Asael Fabian, and Ramsés H. Mena. 2014.
“On a Nonparametric Change Point Detection Model in
Markovian Regimes.” Bayesian Analysis 9 (4):
823–58.
https://doi.org/10.1214/14-BA878.