healthyverse_tsa

Time Series Analysis and Nested Modeling of the Healthyverse Packages

Steven P. Sanderson II, MPH - Date: 04 February, 2024

This analysis follows a Nested Modeltime Workflow.

Get Data

glimpse(downloads_tbl)

## Rows: 91,438
## Columns: 11
## $ date      <date> 2020-11-23, 2020-11-23, 2020-11-23, 2020-11-23, 2020-11-23,…
## $ time      <Period> 15H 36M 55S, 11H 26M 39S, 23H 34M 44S, 18H 39M 32S, 9H 0M…
## $ date_time <dttm> 2020-11-23 15:36:55, 2020-11-23 11:26:39, 2020-11-23 23:34:…
## $ size      <int> 4858294, 4858294, 4858301, 4858295, 361, 4863722, 4864794, 4…
## $ r_version <chr> NA, "4.0.3", "3.5.3", "3.5.2", NA, NA, NA, NA, NA, NA, NA, N…
## $ r_arch    <chr> NA, "x86_64", "x86_64", "x86_64", NA, NA, NA, NA, NA, NA, NA…
## $ r_os      <chr> NA, "mingw32", "mingw32", "linux-gnu", NA, NA, NA, NA, NA, N…
## $ package   <chr> "healthyR.data", "healthyR.data", "healthyR.data", "healthyR…
## $ version   <chr> "1.0.0", "1.0.0", "1.0.0", "1.0.0", "1.0.0", "1.0.0", "1.0.0…
## $ country   <chr> "US", "US", "US", "GB", "US", "US", "DE", "HK", "JP", "US", …
## $ ip_id     <int> 2069, 2804, 78827, 27595, 90474, 90474, 42435, 74, 7655, 638…

The last day in the data set is 2024-02-02 23:18:29, the file was birthed on: 2022-07-02 23:58:17.511888, and at report knit time is -1.391534^{4} hours old. Happy analyzing!

Now that we have our data lets take a look at it using the skimr package.

skim(downloads_tbl)
   
Name downloads_tbl
Number of rows 91438
Number of columns 11
_______________________  
Column type frequency:  
character 6
Date 1
numeric 2
POSIXct 1
Timespan 1
________________________  
Group variables None

Data summary

Variable type: character

skim_variable n_missing complete_rate min max empty n_unique whitespace
r_version 63433 0.31 5 5 0 40 0
r_arch 63433 0.31 3 7 0 5 0
r_os 63433 0.31 7 15 0 17 0
package 0 1.00 7 13 0 7 0
version 0 1.00 5 6 0 50 0
country 7495 0.92 2 2 0 151 0

Variable type: Date

skim_variable n_missing complete_rate min max median n_unique
date 0 1 2020-11-23 2024-02-02 2022-09-01 1167

Variable type: numeric

skim_variable n_missing complete_rate mean sd p0 p25 p50 p75 p100 hist
size 0 1 1214498.63 1594543.03 355 14701 289681 2384924 5677952 ▇▁▂▁▁
ip_id 0 1 10224.37 18082.54 1 258 2973 11342 143633 ▇▁▁▁▁

Variable type: POSIXct

skim_variable n_missing complete_rate min max median n_unique
date_time 0 1 2020-11-23 09:00:41 2024-02-02 23:18:29 2022-09-01 08:09:39 54913

Variable type: Timespan

skim_variable n_missing complete_rate min max median n_unique
time 0 1 0 59 32.5 60

We can see that the following columns are missing a lot of data and for us are most likely not useful anyways, so we will drop them c(r_version, r_arch, r_os)

Plots

Now lets take a look at a time-series plot of the total daily downloads by package. We will use a log scale and place a vertical line at each version release for each package.

Now lets take a look at some time series decomposition graphs.

Feature Engineering

Now that we have our basic data and a shot of what it looks like, let’s add some features to our data which can be very helpful in modeling. Lets start by making a tibble that is aggregated by the day and package, as we are going to be interested in forecasting the next 4 weeks or 28 days for each package. First lets get our base data.

Now we are going to do some basic pre-processing.

data_padded_tbl <- base_data %>%
  pad_by_time(
    .date_var  = date,
    .pad_value = 0
  )

# Get log interval and standardization parameters
log_params  <- liv(data_padded_tbl$value, limit_lower = 0, offset = 1, silent = TRUE)
limit_lower <- log_params$limit_lower
limit_upper <- log_params$limit_upper
offset      <- log_params$offset

data_liv_tbl <- data_padded_tbl %>%
  # Get log interval transform
  mutate(value_trans = liv(value, limit_lower = 0, offset = 1, silent = TRUE)$log_scaled)

# Get Standardization Params
std_params <- standard_vec(data_liv_tbl$value_trans, silent = TRUE)
std_mean   <- std_params$mean
std_sd     <- std_params$sd

data_transformed_tbl <- data_liv_tbl %>%
  # get standardization
  mutate(value_trans = standard_vec(value_trans, silent = TRUE)$standard_scaled) %>%
  select(-value)

Since this is panel data we can follow one of two different modeling strategies. We can search for a global model in the panel data or we can use nested forecasting finding the best model for each of the time series. Since we only have 5 panels, we will use nested forecasting.

To do this we will use the nest_timeseries and split_nested_timeseries functions to create a nested tibble.

horizon <- 4*7

nested_data_tbl <- data_transformed_tbl %>%
    
    # 1. Extending: We'll predict n days into the future.
    extend_timeseries(
        .id_var        = package,
        .date_var      = date,
        .length_future = horizon
    ) %>%
    
    # 2. Nesting: We'll group by id, and create a future dataset
    #    that forecasts n days of extended data and
    #    an actual dataset that contains n*2 days
    nest_timeseries(
        .id_var        = package,
        .length_future = horizon
        #.length_actual = horizon*2
    ) %>%
    
   # 3. Splitting: We'll take the actual data and create splits
   #    for accuracy and confidence interval estimation of n das (test)
   #    and the rest is training data
    split_nested_timeseries(
        .length_test = horizon
    )

nested_data_tbl

## # A tibble: 7 × 4
##   package       .actual_data       .future_data      .splits         
##   <fct>         <list>             <list>            <list>          
## 1 TidyDensity   <tibble [550 × 2]> <tibble [28 × 2]> <split [522|28]>
## 2 healthyR      <tibble [547 × 2]> <tibble [28 × 2]> <split [519|28]>
## 3 healthyR.ai   <tibble [547 × 2]> <tibble [28 × 2]> <split [519|28]>
## 4 healthyR.data <tibble [548 × 2]> <tibble [28 × 2]> <split [520|28]>
## 5 healthyR.ts   <tibble [543 × 2]> <tibble [28 × 2]> <split [515|28]>
## 6 healthyverse  <tibble [538 × 2]> <tibble [28 × 2]> <split [510|28]>
## 7 tidyAML       <tibble [352 × 2]> <tibble [28 × 2]> <split [324|28]>

Now it is time to make some recipes and models using the modeltime workflow.

Modeltime Workflow

Recipe Object

recipe_base <- recipe(
  value_trans ~ date
  , data = extract_nested_test_split(nested_data_tbl)
  )

recipe_base

recipe_date <- recipe_base %>%
    step_mutate(date = as.numeric(date))

Models

# Models ------------------------------------------------------------------

# Auto ARIMA --------------------------------------------------------------

model_spec_arima_no_boost <- arima_reg() %>%
  set_engine(engine = "auto_arima")

wflw_auto_arima <- workflow() %>%
  add_recipe(recipe = recipe_base) %>%
  add_model(model_spec_arima_no_boost)

# NNETAR ------------------------------------------------------------------

model_spec_nnetar <- nnetar_reg(
  mode              = "regression"
  , seasonal_period = "auto"
) %>%
  set_engine("nnetar")

wflw_nnetar <- workflow() %>%
  add_recipe(recipe = recipe_base) %>%
  add_model(model_spec_nnetar)

# TSLM --------------------------------------------------------------------

model_spec_lm <- linear_reg() %>%
  set_engine("lm")

wflw_lm <- workflow() %>%
  add_recipe(recipe = recipe_base) %>%
  add_model(model_spec_lm)

# MARS --------------------------------------------------------------------

model_spec_mars <- mars(mode = "regression") %>%
  set_engine("earth")

wflw_mars <- workflow() %>%
  add_recipe(recipe = recipe_base) %>%
  add_model(model_spec_mars)

Nested Modeltime Tables

nested_modeltime_tbl <- modeltime_nested_fit(
  # Nested Data
  nested_data = nested_data_tbl,
   control = control_nested_fit(
     verbose = TRUE,
     allow_par = FALSE
   ),
  # Add workflows
  wflw_auto_arima,
  wflw_lm,
  wflw_mars,
  wflw_nnetar
)

nested_modeltime_tbl

## # Nested Modeltime Table
##   # A tibble: 7 × 5
##   package       .actual_data .future_data .splits          .modeltime_tables 
##   <fct>         <list>       <list>       <list>           <list>            
## 1 TidyDensity   <tibble>     <tibble>     <split [522|28]> <mdl_tm_t [4 × 5]>
## 2 healthyR      <tibble>     <tibble>     <split [519|28]> <mdl_tm_t [4 × 5]>
## 3 healthyR.ai   <tibble>     <tibble>     <split [519|28]> <mdl_tm_t [4 × 5]>
## 4 healthyR.data <tibble>     <tibble>     <split [520|28]> <mdl_tm_t [4 × 5]>
## 5 healthyR.ts   <tibble>     <tibble>     <split [515|28]> <mdl_tm_t [4 × 5]>
## 6 healthyverse  <tibble>     <tibble>     <split [510|28]> <mdl_tm_t [4 × 5]>
## 7 tidyAML       <tibble>     <tibble>     <split [324|28]> <mdl_tm_t [4 × 5]>

Model Accuracy

nested_modeltime_tbl %>%
  extract_nested_test_accuracy() %>%
  knitr::kable()
package .model_id .model_desc .type mae mape mase smape rmse rsq
TidyDensity 1 ARIMA Test 1.2153263 435.45871 1.1881718 118.07241 1.591050 0.0635024
TidyDensity 2 LM Test 1.1391229 570.32060 1.1136711 103.47850 1.524013 0.0014013
TidyDensity 3 EARTH Test 1.2472114 391.10198 1.2193445 124.02813 1.635263 0.0014013
TidyDensity 4 NNAR Test 1.3316005 258.96350 1.3018481 144.62278 1.717588 0.0486765
healthyR 1 ARIMA Test 1.0915986 192.22486 0.8214286 164.57444 1.524395 0.1222031
healthyR 2 LM Test 1.0992646 106.62390 0.8271974 187.93009 1.556732 0.0345419
healthyR 3 EARTH Test 1.1071872 127.91147 0.8331591 162.44796 1.586700 0.0345419
healthyR 4 NNAR Test 1.1429687 237.27968 0.8600847 154.40828 1.610972 0.0062545
healthyR.ai 1 ARIMA Test 0.9742751 432.86803 0.7784529 130.95852 1.488717 0.1169042
healthyR.ai 2 LM Test 1.0199415 390.45809 0.8149408 143.51495 1.507630 0.0412232
healthyR.ai 3 EARTH Test 1.0552663 701.59273 0.8431655 126.27116 1.588763 0.0412232
healthyR.ai 4 NNAR Test 0.9312032 386.06346 0.7440382 132.94240 1.410092 0.1225176
healthyR.data 1 ARIMA Test 1.2311047 137.76268 0.9202646 153.34970 1.574162 0.0008147
healthyR.data 2 LM Test 1.1262078 100.79592 0.8418530 191.73871 1.444417 0.0293513
healthyR.data 3 EARTH Test 1.2214285 130.66860 0.9130316 147.45466 1.588167 0.0293513
healthyR.data 4 NNAR Test 1.1308394 101.90841 0.8453151 169.67921 1.460348 0.0064248
healthyR.ts 1 ARIMA Test 1.1886555 101.27735 0.6850736 139.22584 1.721917 0.0850089
healthyR.ts 2 LM Test 1.1555052 109.12229 0.6659676 113.03027 1.703578 0.0192034
healthyR.ts 3 EARTH Test 2.8094365 343.25210 1.6191998 165.08835 3.403923 0.0192034
healthyR.ts 4 NNAR Test 1.2355042 92.98315 0.7120745 166.97903 1.821657 0.0278023
healthyverse 1 ARIMA Test 0.8826828 349.10046 0.8002295 97.29576 1.404193 0.2517005
healthyverse 2 LM Test 0.9620751 337.49682 0.8722055 100.79753 1.483884 0.0680391
healthyverse 3 EARTH Test 0.9739670 366.27067 0.8829866 100.17827 1.498780 0.0680391
healthyverse 4 NNAR Test 1.0614652 414.12135 0.9623114 100.41332 1.630465 0.1161201
tidyAML 1 ARIMA Test 1.2119226 104.93059 1.3641290 140.84909 1.619921 0.0927306
tidyAML 2 LM Test 1.2997261 114.12242 1.4629598 136.29112 1.745890 0.0047468
tidyAML 3 EARTH Test 1.4076875 131.36954 1.5844802 137.14234 1.860826 0.0047468
tidyAML 4 NNAR Test 1.2441003 108.86130 1.4003478 138.65775 1.666650 0.0362042

Plot Models

nested_modeltime_tbl %>%
  extract_nested_test_forecast() %>%
  group_by(package) %>%
  plot_modeltime_forecast(
    .interactive = FALSE,
    .conf_interval_show  = FALSE,
    .facet_scales = "free"
  ) +
  theme_minimal() +
  theme(legend.position = "bottom")

Best Model

best_nested_modeltime_tbl <- nested_modeltime_tbl %>%
  modeltime_nested_select_best(
    metric = "rmse",
    minimize = TRUE,
    filter_test_forecasts = TRUE
  )

best_nested_modeltime_tbl %>%
  extract_nested_best_model_report()

## # Nested Modeltime Table
##   # A tibble: 7 × 10
##   package      .model_id .model_desc .type   mae  mape  mase smape  rmse     rsq
##   <fct>            <int> <chr>       <chr> <dbl> <dbl> <dbl> <dbl> <dbl>   <dbl>
## 1 TidyDensity          2 LM          Test  1.14   570. 1.11  103.   1.52 0.00140
## 2 healthyR             1 ARIMA       Test  1.09   192. 0.821 165.   1.52 0.122  
## 3 healthyR.ai          4 NNAR        Test  0.931  386. 0.744 133.   1.41 0.123  
## 4 healthyR.da…         2 LM          Test  1.13   101. 0.842 192.   1.44 0.0294 
## 5 healthyR.ts          2 LM          Test  1.16   109. 0.666 113.   1.70 0.0192 
## 6 healthyverse         1 ARIMA       Test  0.883  349. 0.800  97.3  1.40 0.252  
## 7 tidyAML              1 ARIMA       Test  1.21   105. 1.36  141.   1.62 0.0927

best_nested_modeltime_tbl %>%
  extract_nested_test_forecast() %>%
  #filter(!is.na(.model_id)) %>%
  group_by(package) %>%
  plot_modeltime_forecast(
    .interactive = FALSE,
    .conf_interval_alpha = 0.2,
    .facet_scales = "free"
  ) +
  theme_minimal() +
  theme(legend.position = "bottom")

Refitting and Future Forecast

Now that we have the best models, we can make our future forecasts.

nested_modeltime_refit_tbl <- best_nested_modeltime_tbl %>%
    modeltime_nested_refit(
        control = control_nested_refit(verbose = TRUE)
    )

nested_modeltime_refit_tbl

## # Nested Modeltime Table
##   # A tibble: 7 × 5
##   package       .actual_data .future_data .splits          .modeltime_tables 
##   <fct>         <list>       <list>       <list>           <list>            
## 1 TidyDensity   <tibble>     <tibble>     <split [522|28]> <mdl_tm_t [1 × 5]>
## 2 healthyR      <tibble>     <tibble>     <split [519|28]> <mdl_tm_t [1 × 5]>
## 3 healthyR.ai   <tibble>     <tibble>     <split [519|28]> <mdl_tm_t [1 × 5]>
## 4 healthyR.data <tibble>     <tibble>     <split [520|28]> <mdl_tm_t [1 × 5]>
## 5 healthyR.ts   <tibble>     <tibble>     <split [515|28]> <mdl_tm_t [1 × 5]>
## 6 healthyverse  <tibble>     <tibble>     <split [510|28]> <mdl_tm_t [1 × 5]>
## 7 tidyAML       <tibble>     <tibble>     <split [324|28]> <mdl_tm_t [1 × 5]>

nested_modeltime_refit_tbl %>%
  extract_nested_future_forecast() %>%
  mutate(across(.value:.conf_hi, .fns = ~ standard_inv_vec(
    x    = .,
    mean = std_mean,
    sd   = std_sd
  )$standard_inverse_value)) %>%
  mutate(across(.value:.conf_hi, .fns = ~ liiv(
    x = .,
    limit_lower = limit_lower,
    limit_upper = limit_upper,
    offset      = offset
  )$rescaled_v)) %>%
  group_by(package) %>%
  plot_modeltime_forecast(
    .interactive = FALSE,
    .conf_interval_alpha = 0.2,
    .facet_scales = "free"
  ) +
  theme_minimal() +
  theme(legend.position = "bottom")

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