Using the FoReco package for cross-sectional, temporal and cross-temporal point forecast reconciliation

Daniele Girolimetto

2022-07-04

The FoReco (Forecast Reconciliation) package is designed for point forecast reconciliation, a post-forecasting process aimed to improve the quality of the base forecasts for a system of linearly constrained (e.g. hierarchical/grouped) time series.

It offers classical (bottom-up and top-down), and modern (optimal and heuristic combination) forecast reconciliation procedures for cross-sectional, temporal, and cross-temporal linearly constrained time series.

What are the most important functions?

The main functions are:

Installation

You can install the stable version on R CRAN.

install.packages('FoReco', dependencies = TRUE)

You can also install the development version from Github

# install.packages("devtools")
devtools::install_github("daniGiro/FoReco")

Example: cross-temporal data

A two-level hierarchy with \(n = 8\) monthly time series. In the cross-sectional framework, at any time it is \(Tot = A + B + C\), \(A = AA + AB\) and \(B = BA + BB\) (\(nb = 5\) at the bottom level). For monthly data, the observations are aggregated to annual \((k = 12)\), semi-annual \((k = 6)\), four-monthly \((k = 4)\), quarterly \((k = 3)\), and bi-monthly \((k = 2)\) observations. The monthly bottom time series are simulated from five different SARIMA models. There are 180 monthly observations (15 years): the first 168 values (14 years) are used as training set, and the last 12 form the test set.

Cross-sectional hierarchy

Cross-sectional hierarchy

Simulation

In the following script we simulate five independent monthly bottom time series, each of length 180 (15 complete years of monthly data).

library(FoReco)
library(forecast)
library(sarima)
values <- NULL
base <- NULL
residuals <- NULL
test <- NULL

bottom <- matrix(NA, nrow = 180, ncol = 5)
# Model definition
bts <- list()
#ARIMA(1,0,0)(0,0,0)[12]
bts[[1]] <- list(ar=0.31,
                 nseasons=12)
#ARIMA(0,0,1)(0,0,0)[12]
bts[[2]] <- list(ma=0.61,
                 nseasons=12)
#ARIMA(0,1,1)(0,1,1)[12]
bts[[3]] <- list(ma=-0.1,
                 sma=-0.12,
                 iorder=1,
                 siorder=1,
                 nseasons=12)
#ARIMA(2,1,0)(0,0,0)[12]
bts[[4]] <- list(ar=c(0.38,0.25),
                 iorder=1,
                 nseasons=12)
#ARIMA(2,0,0)(0,1,1)[12]
bts[[5]] <- list(ar=c(0.30,0.12),
                 sma=0.23,
                 siorder=1,
                 nseasons=12)
mm <- c(58.85, 60.68, 59.26, 35.47, 58.61)
set.seed(525)
for(i in 1:5){
  bottom[,i] <- mm[i] + sim_sarima(n=180, model = bts[[i]],
                           n.start = 200)
}
colnames(bottom) <- c("AA", "AB", "BA", "BB", "C")
C <- matrix(c(rep(1,5),
              rep(1,2), rep(0,3),
              rep(0,2), rep(1,2), 0), byrow = TRUE, nrow = 3)

upper <- bottom%*%t(C)
colnames(upper) <- c("T", "A", "B")
values$k1 <- ts(cbind(upper, bottom), frequency = 12)
colnames(values$k1) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")

More precisely, AA is simulated from an AR(1) process, AB from an MA(1), BA from an ARIMA(0,1,1)(0,1,1), BB from an ARIMA(2,1,0), and C from an ARIMA(2,0,0)(0,1,1). The higher levels series in the hierarchy (T,A,B) are obtained by simple summation of the five bottom time series.

Then we compute the temporally aggregated series at annual \((k = 12)\), semi-annual \((k = 6)\), four-monthly \((k = 4)\), quarterly \((k = 3)\), and bi-monthly \((k = 2)\) frequencies.

# BI-MONTHLY SERIES
values$k2 <- ts(apply(values$k1, 2,
                      function(x) colSums(matrix(x, nrow = 2))),
                frequency = 6)

# QUARTERLY SERIES
values$k3 <- ts(apply(values$k1, 2,
                      function(x) colSums(matrix(x, nrow = 3))),
                frequency = 4)

# FOUR-MONTHLY SERIES
values$k4 <- ts(apply(values$k1, 2,
                      function(x) colSums(matrix(x, nrow = 4))),
                frequency = 3)

# SEMI-ANNUAL SERIES
values$k6 <- ts(apply(values$k1, 2,
                      function(x) colSums(matrix(x, nrow = 6))),
                frequency = 2)

# ANNUAL SERIES
values$k12 <- ts(apply(values$k1, 2,
                       function(x) colSums(matrix(x, nrow = 12))),
                 frequency = 1)

The first 14 years of each simulated series are used as training set, and the last year as test set. The forecasts are obtained using the auto.arima function of the forecast package (Hyndman et al., 2020).

# MONTHLY FORECASTS
base$k1 <- matrix(NA, nrow = 12, ncol = ncol(values$k1))
residuals$k1 <- matrix(NA, nrow = 168, ncol = ncol(values$k1))
for (i in 1:ncol(values$k1)) {
  train <- values$k1[1:168, i]
  forecast_arima <- forecast(auto.arima(train), h = 12)
  base$k1[, i] <- forecast_arima$mean
  residuals$k1[, i] <- forecast_arima$residuals
}
base$k1 <- ts(base$k1, frequency = 12, start = c(15, 1))
colnames(base$k1) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
residuals$k1 <- ts(residuals$k1, frequency = 12)
colnames(residuals$k1) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
test$k1 <- values$k1[-c(1:168), ]

The following plots show the actual values and the forecasts for the test year at any temporal aggregation level.

# BI-MONTHLY FORECASTS
base$k2 <- matrix(NA, nrow = 6, ncol = ncol(values$k2))
residuals$k2 <- matrix(NA, nrow = 84, ncol = ncol(values$k2))
for (i in 1:ncol(values$k2)) {
  train <- values$k2[1:84, i]
  forecast_arima <- forecast(auto.arima(train), h = 6)
  base$k2[, i] <- forecast_arima$mean
  residuals$k2[, i] <- forecast_arima$residuals
}
base$k2 <- ts(base$k2, frequency = 6, start = c(15, 1))
colnames(base$k2) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
residuals$k2 <- ts(residuals$k2, frequency = 6)
colnames(residuals$k2) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
test$k2 <- values$k2[-c(1:84), ]

# QUARTERLY FORECASTS
base$k3 <- matrix(NA, nrow = 4, ncol = ncol(values$k3))
residuals$k3 <- matrix(NA, nrow = 56, ncol = ncol(values$k3))
for (i in 1:ncol(values$k3)) {
  train <- values$k3[1:56, i]
  forecast_arima <- forecast(auto.arima(train), h = 4)
  base$k3[, i] <- forecast_arima$mean
  residuals$k3[, i] <- forecast_arima$residuals
}
base$k3 <- ts(base$k3, frequency = 4, start = c(15, 1))
colnames(base$k3) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
residuals$k3 <- ts(residuals$k3, frequency = 4)
colnames(residuals$k3) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
test$k3 <- values$k3[-c(1:56), ]

# FOUR-MONTHLY FORECASTS
base$k4 <- matrix(NA, nrow = 3, ncol = ncol(values$k4))
residuals$k4 <- matrix(NA, nrow = 42, ncol = ncol(values$k4))
for (i in 1:ncol(values$k4)) {
  train <- values$k4[1:42, i]
  forecast_arima <- forecast(auto.arima(train), h = 3)
  base$k4[, i] <- forecast_arima$mean
  residuals$k4[, i] <- forecast_arima$residuals
}
base$k4 <- ts(base$k4, frequency = 3, start = c(15, 1))
colnames(base$k4) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
residuals$k4 <- ts(residuals$k4, frequency = 3)
colnames(residuals$k4) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
test$k4 <- values$k4[-c(1:42), ]

# SEMI-ANNUAL FORECASTS
base$k6 <- matrix(NA, nrow = 2, ncol = ncol(values$k6))
residuals$k6 <- matrix(NA, nrow = 28, ncol = ncol(values$k6))
for (i in 1:ncol(values$k6)) {
  train <- values$k6[1:28, i]
  forecast_arima <- forecast(auto.arima(train), h = 2)
  base$k6[, i] <- forecast_arima$mean
  residuals$k6[, i] <- forecast_arima$residuals
}
base$k6 <- ts(base$k6, frequency = 2, start = c(15, 1))
colnames(base$k6) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
residuals$k6 <- ts(residuals$k6, frequency = 2)
colnames(residuals$k6) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
test$k6 <- values$k6[-c(1:28), ]

# ANNUAL FORECASTS
base$k12 <- matrix(NA, nrow = 1, ncol = ncol(values$k12))
residuals$k12 <- matrix(NA, nrow = 14, ncol = ncol(values$k12))
for (i in 1:ncol(values$k12)) {
  train <- values$k12[1:14, i]
  forecast_arima <- forecast(auto.arima(train), h = 1)
  base$k12[, i] <- forecast_arima$mean
  residuals$k12[, i] <- forecast_arima$residuals
}
base$k12 <- ts(base$k12, frequency = 1, start = c(15, 1))
colnames(base$k12) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
residuals$k12 <- ts(residuals$k12, frequency = 1)
colnames(residuals$k12) <- c("T", "A", "B", "AA", "AB", "BA", "BB", "C")
test$k12 <- values$k12[-c(1:14), ]

base <- t(do.call(rbind, rev(base)))
res <- t(do.call(rbind, rev(residuals)))
test <- t(do.call(rbind, rev(test)))

kset <- c(12, 6, 4, 3, 2, 1)
h <- 1
colnames(base) <- paste("k", rep(kset, h * rev(kset)), "_h",
                        do.call("c", as.list(sapply(
                          rev(kset) * h,
                          function(x) seq(1:x)))),
                        sep = "")


colnames(test) <- paste("k", rep(kset, h * rev(kset)), "_h",
                        do.call("c", as.list(sapply(
                          rev(kset) * h,
                          function(x) seq(1:x)))),
                        sep = "")

h <- 14
colnames(res) <- paste("k", rep(kset, h * rev(kset)), "_h",
                       do.call("c", as.list(sapply(
                         rev(kset) * h,
                         function(x) seq(1:x)))),
                       sep = "")

colnames(C) <- c("AA", "AB", "BA", "BB", "C")
rownames(C) <- c("Tot", "A", "B")
obs <- values
FoReco_data <- list(base = base,
                           test = test,
                           res = res,
                           C = C,
                           obs = obs)

Reconciliation

K <- c(1,2,3,4,6,12)
hts_recf_list <- NULL
for(i in 1:length(K)){
  # base forecasts
  id <- which(simplify2array(strsplit(colnames(FoReco_data$base),
                                      split = "_"))[1, ] == paste("k", K[i], sep=""))
  mbase <- t(FoReco_data$base[, id])
  # residuals
  id <- which(simplify2array(strsplit(colnames(FoReco_data$res),
                                      split = "_"))[1, ] == "k1")
  mres <- t(FoReco_data$res[, id])
  hts_recf_list[[i]] <- htsrec(mbase, C = FoReco_data$C, comb = "shr",
                          res = mres, keep = "recf")
}
names(hts_recf_list) <- paste("k", K, sep="")
hts_recf <- t(do.call(rbind, hts_recf_list[rev(names(hts_recf_list))]))
colnames(hts_recf) <- paste("k", 
                            rep(K, sapply(hts_recf_list[rev(names(hts_recf_list))], NROW)),
                            colnames(hts_recf), sep="")
n <- NROW(FoReco_data$base)
thf_recf <- matrix(NA, n, NCOL(FoReco_data$base))
dimnames(thf_recf) <- dimnames(FoReco_data$base)
for(i in 1:n){
  # ts base forecasts ([lowest_freq' ...  highest_freq']')
  tsbase <- FoReco_data$base[i, ]
  # ts residuals ([lowest_freq' ...  highest_freq']')
  tsres <- FoReco_data$res[i, ]
  thf_recf[i,] <- thfrec(tsbase, m = 12, comb = "acov",
                         res = tsres, keep = "recf")
}
tcs_recf <- tcsrec(FoReco_data$base, m = 12, C = FoReco_data$C,
                   thf_comb = "wlsv", hts_comb = "shr",
                   res = FoReco_data$res)$recf
cst_recf <- cstrec(FoReco_data$base, m = 12, C = FoReco_data$C,
                   thf_comb = "acov", hts_comb = "shr",
                   res = FoReco_data$res)$recf
ite_recf <- iterec(FoReco_data$base,
                   m = 12, C = FoReco_data$C,
                   thf_comb = "acov", hts_comb = "shr",
                   res = FoReco_data$res, start_rec = "thf")$recf
#> --------------------------------------------------------------------------------
#> Iter       # |     Cross-sec. incoherence     |      Temporal incoherence      |
#> thf:       0 |                         159.89 |                         187.63 |
#> thf:       1 |                          60.11 |                          38.77 |
#> thf:       2 |                          18.60 |                           7.73 |
#> thf:       3 |                           1.61 |                       9.91e-01 |
#> thf:       4 |                       4.16e-01 |                       2.07e-01 |
#> thf:       5 |                       3.03e-02 |                       2.00e-02 |
#> thf:       6 |                       9.18e-03 |                       5.31e-03 |
#> thf:       7 |                       5.18e-04 |                       1.98e-04 |
#> thf:       8 |                       1.30e-04 |                       6.45e-05 |
#> thf: Convergence (starting from thf) achieved at iteration number 9! 
#> thf: Temporal incoherence 4.94e-06 < 1e-05 tolerance
#> --------------------------------------------------------------------------------

The above plot shows the convergence path of both cross-sectional and temporal discrepancies.

oct_recf <- octrec(FoReco_data$base, m = 12, C = FoReco_data$C,
                   comb = "bdshr", res = FoReco_data$res, keep = "recf")

Monthly actual and forecasted values are shown in the following figure.

An evaluation of the quality of the reconciled forecasts can be obtained by using appropriate accuracy indices (see score_index()).

References

Di Fonzo, T., Girolimetto, D. (2021), Cross-temporal forecast reconciliation: Optimal combination method and heuristic alternatives, International Journal of Forecasting, in press.

Hyndman R, Athanasopoulos G, Bergmeir C, Caceres G, Chhay L, O’Hara-Wild M, Petropoulos F, Razbash S, Wang E, Yasmeen F (2020). forecast: Forecasting functions for time series and linear models . R package version 8.13, https://pkg.robjhyndman.com/forecast/.

Kourentzes, N., Athanasopoulos, G. (2019), Cross-temporal coherent forecasts for Australian tourism, Annals of Tourism Research, 75, 393-409.

Nystrup, P., Lindström, E., Pinson, P., Madsen, H. (2020), Temporal hierarchies with autocorrelation for load forecasting, European Journal of Operational Research, 280, 3, 876–888.

Wickramasuriya, S.L., Athanasopoulos, G., Hyndman, R.J. (2019), Optimal forecast reconciliation for hierarchical and grouped time series through trace minimization, Journal of the American Statistical Association, 114, 526, 804-819.