knitr::opts_chunk$set( collapse = TRUE, comment = "#>" )
library(tidyverse)
forecasts_full <- tribble( ~City, ~Forecast, ~ForecastDate, "New York", 20, "2023-09-28", "Los Angeles", 23, "2023-09-28", "Seattle", 16, "2023-09-28", "Houston", 34, "2023-09-28", "New York", 18, "2023-09-29", "Los Angeles", 25, "2023-09-29", "Seattle", 17, "2023-09-29", "Houston", 34, "2023-09-29" ) %>% mutate(across("ForecastDate", as.Date)) forecasts_scd <- forecasts_full %>% mutate(ForecastFrom = ForecastDate, ForecastUntil = case_when( City == "Houston" ~ NA, ForecastDate == "2023-09-29" ~ NA, TRUE ~ "2023-09-29" )) %>% mutate(across("ForecastUntil", as.Date)) %>% filter(!(City == "Houston" & ForecastFrom == "2023-09-29")) %>% distinct() %>% select(!"ForecastDate") %>% arrange(ForecastFrom) forecasts_dated <- filter(forecasts_full, ForecastDate == "2023-09-28") forecasts <- select(forecasts_dated, !"ForecastDate") forecasts2 <- filter(forecasts_full, ForecastDate == "2023-09-29") %>% select(!"ForecastDate") forecasts2a <- filter(forecasts_full, ForecastDate == "2023-09-29")
A slowly changing dimension is a concept in data warehousing which refers to data which may change over time, but at an irregular schedule.
For example, consider the following table of forecasts for a number of cities:
# Current date: 2023-09-28
forecasts
The following day, the forecasts will have changed, and — barring the occasional data hoarder — the existing data is no longer relevant.
In this example, most (if not all) of the values of the Forecast
column will change with each regular update.
Putting it into other words, the table is a snapshot^[A snapshot is a static view of (part of) a database at a specific point in time] of forecasts at the last time of update.
The following day, the forecasts naturally change:
# Current date: 2023-09-29
forecasts2
We could choose to update the forecasts table so that it would always contain the current data. This is what is referred to as Type 1 methodology [@Kimball2013].
Databases are thankfully a rather efficient way of storing and accessing data, so instead of discarding the values from the previous day, we append the new data to those of the previous day.
Also, in order to keep our data organized, we add a column with the date of the forecast, aptly named ForecastDate
.
The full table of forecasts for the two days now looks like below, and we are slowly building a full history of forecasts:
forecasts_full
Managing historical data by inserting new data in this manner is often referred to as Type 2 methodology or Type 2 history.
Our table now provides much more information for the user through filtering:
# Current forecasts forecasts_full %>% slice_max(ForecastDate, n = 1) %>% select(!"ForecastDate") # Forecasts for a given date forecasts_full %>% filter(ForecastDate == "2023-09-28") # Full history for a given city forecasts_full %>% filter(City == "New York")
Now, we note that the forecast for Houston has not changed between the two days.
In order to keep our data as minimized as possible, we modify the table again, now expanding ForecastDate
into ForecastFrom
and ForecastUntil
.
Our table of forecasts now looks like this:
forecasts_scd
For now, the ForecastUntil
value is set to NA
, as it is not known when these rows will "expire" (if ever).
This also makes it easy to identify currently valid data.
Adding a new column to save a single row of data naturally seems a bit overkill, but as the number of rows in the data set increases indefinitely, this solutions scales much better.
Let's now introduce additional information and see how managing slowly changing dimensions enables us to easily navigate large amounts of data over large periods of time.
addresses <- tibble::tibble( ID = c(1, 2, 1, 1), GivenName = c("Alice", "Robert", "Alice", "Alice"), Surname = c("Doe", "Tables", "Doe", "Doe"), Address = c("Donut Plains 1", "Rainbow Road 8", "Donut Plains 1", "Rainbow Road 8"), MovedIn = c("1989-06-26", "1989-12-13", "1989-06-26", "2021-03-01"), MovedOut = c(NA, NA, "2021-03-01", NA), ValidFrom = c("1989-06-26", "1989-12-13", "2021-03-08", "2021-03-08"), ValidUntil = c("2021-03-08", NA, NA, NA) ) %>% mutate(across(c("MovedIn", "MovedOut", "ValidFrom", "ValidUntil"), as.Date)) name_change_date <- as.Date("2023-08-28") addresses2 <- addresses %>% filter(ID == 1) %>% { .data <- . .data %>% filter(Address == "Rainbow Road 8") %>% mutate(Surname = "Tables", ValidFrom = !!name_change_date) %>% bind_rows(.data) } %>% mutate(ValidUntil = as.Date(c(NA, !!name_change_date, NA, !!name_change_date), origin = "1970-01-01")) %>% bind_rows(filter(addresses, ID == 2)) %>% arrange(ValidFrom) %>% distinct()
Imagine a town of several thousand citizens, with a town hall maintaining a civil registry of names and addresses of every citizen, updated daily with any changes submitted by the citizens, each of whom having an individual identification number.^[If this concept seems very familiar, you may have heard of the Danish central civil registry]
The data is largely static, as a very small fraction of citizens move on any given day, but it is of interest to keep data relatively up-to-date. This is where managing a slowly changing dimension becomes very powerful, compared to full incremental backups.
One day, Alice Doe meets Robert "Bobby" Tables, and they move in together:
addresses
First thing to notice is that the registry is not updated in real-time, as citizens may have been late in registering a change of address.
This can be seen when comparing the values of MovedIn
and ValidFrom
for row 4.
When using Type 2 history, this feature is correctly replicated when reconstructing historical data:
slice_timestamp <- "2021-03-02" addresses %>% filter(ID == 1, ValidFrom < !!slice_timestamp, ValidUntil >= !!slice_timestamp | is.na(ValidUntil)) %>% select(!c("ValidFrom", "ValidUntil"))
In other words, even though Alice's address was subsequently updated in the registry, we can still see that she was registered as living in Donut Plains at this time. This modeling of "timelines of timelines" is also called bitemporal modeling.
By now, things are going well between Alice and Robert; they get married, with Alice taking Robert's surname. It is the same person that has lived with Robert, but as of the day of marriage, she has a different name:
filter(addresses2, ID == 1, Address == "Rainbow Road 8") %>% select(ID, GivenName, Surname, MovedIn, MovedOut, ValidFrom, ValidUntil)
This is now also reflected in the data; the MovedIn
date is persistent across the date of the name change, only the Surname
changes:
slice_timestamp <- "2022-03-04" addresses2 %>% filter(Address == "Rainbow Road 8", is.na(MovedOut), ValidFrom < !!slice_timestamp, ValidUntil >= !!slice_timestamp | is.na(ValidUntil)) %>% select(ID, GivenName, Surname, MovedIn, MovedOut) slice_timestamp <- "2023-09-29" addresses2 %>% filter(Address == "Rainbow Road 8", is.na(MovedOut), ValidFrom < !!slice_timestamp, ValidUntil >= !!slice_timestamp | is.na(ValidUntil)) %>% select(ID, GivenName, Surname, MovedIn, MovedOut)
By now, it is hopefully clear how managing a slowly changing dimension allows you to access data at any point in (tracked) time while potentially avoiding a lot of data redundancy.
You are now ready to get started with the SCDB
package!
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