# Get date difference in years (floating point)

I want to correct source activity based on the difference between reference and measurement date and source half life (measured in years). Say I have

``````ref_date <- as.Date('06/01/08',format='%d/%m/%y')
``````

and a column in my `data.frame` with the same date format, e.g.,

``````today <- as.Date(Sys.Date(), format='%d/%m/%y')
``````

I can find the number of years between these dates using the `lubridate` package

``````year(today)-year(ref_date)
 5
``````

Is there a function I can use to get a floating point answer `today - ref_date` = 5.2y, for example?

Answer recommended by R Language Collective

Yes, of course, use `difftime()` with an as numeric:

``````R> as.numeric(difftime(as.Date("2003-04-05"), as.Date("2001-01-01"),
+                      unit="weeks"))/52.25
 2.2529
R>
``````

Note that we do have to switch to weeks scaled by 52.25 as there is a bit of ambiguity there in terms of counting years---a February 29 comes around every 4 years but not every 100th etc.

So you have to define that. `difftime()` handles all time units up to weeks. Months cannot be done for the same reason of the non-constant 'numerator'.

• Thanks. I assume I can divide by 365.25 and omit `unit=weeks" Mar 22, 2013 at 11:46
• No, you need to -- just play with it to see. The unit auto-adjusts, try it with deltas of less than one, or even `POSIXct` objects (eg from `Sys.time()`). Mar 22, 2013 at 12:18
• And the weeks are always the same number in an year?
– sop
Jun 23, 2015 at 14:04
• 52.25*7=365.75, is this OK? Wiki says that the gregorian calender has 365.2425 days... 365.2425/7=52.1775, How to do it right?
– sop
Jun 23, 2015 at 14:16

The lubridate package contains a built-in function, time_length, which can help perform this task.

``````time_length(difftime(as.Date("2003-04-05"), as.Date("2001-01-01")), "years")
 2.257534

time_length(difftime(as.Date("2017-03-01"), as.Date("2012-03-01")),"years")
 5.00274
``````

Documentation for the lubridate package can be found here.

• Do note @RenMa's answer below, as using difftime() can indeed give incorrect results. I happened to notice this when looking at the difference between 1948-12-07 and today (2018-11-29), which is 70.02466 via difftime() and 69.97808 via interval(). start <- as.Date("1948-12-07"); end <- as.Date("2018-11-29"); difftime(end, start) %>% time_length(unit = "years"); interval(start, end) %>% time_length(unit = "years") Nov 29, 2018 at 10:34

Inspired by Bryan F, `time_length()` would work better if using interval object

``````time_length(interval(as.Date("2003-04-05"), as.Date("2001-01-01")), "years")
 -2.257534
time_length(difftime(as.Date("2017-03-01"), as.Date("2012-03-01")),"years")
 5.00274
time_length(interval(as.Date("2017-03-01"), as.Date("2012-03-01")),"years")
 -5
``````

You can see if you use `interval()` to get the time difference and then pass it to `time_length()`, `time_length()` would take into account the fact that not all months and years have the same number of days, e.g., the leap year.

• Why do we get a negative sign after the time length calculation?
– Ray
Apr 23, 2021 at 14:35
• `interval(start_date, end_date)` basically uses end_date minus start_date. So if your start_date occurs after the end_date, the interval will be negative. Apr 25, 2021 at 13:35

Not an exact answer to your question, but the answer from Dirk Eddelbuettel in some situations can produce small errors.

``````as.numeric(difftime(as.Date("2012-03-01"), as.Date("2017-03-01"), unit="weeks"))/52.25
 -4.992481
``````

The correct answer here should be at least 5 years.

The following function (using lubridate package) will calculate a number of full years between two dates:

``````# Function to calculate an exact full number of years between two dates
year.diff <- function(firstDate, secondDate) {
yearsdiff <- year(secondDate) - year(firstDate)
monthsdiff <- month(secondDate) - month(firstDate)
daysdiff <- day(secondDate) - day(firstDate)

if ((monthsdiff < 0) | (monthsdiff == 0 & daysdiff < 0)) {
yearsdiff <- yearsdiff - 1
}

yearsdiff
}
``````

You can modify it to calculate a fractional part depending on how you define the number of days in the last (not finished) year.

You can use the function `AnnivDates()` of the package BondValuation:

``````R> library('BondValuation')
R> DateIndexes <- unlist(
+   suppressWarnings(
+     AnnivDates("2001-01-01", "2003-04-05", CpY=1)\$DateVectors
+     )
+   )
R> names(DateIndexes) <- NULL
R> DateIndexes[length(DateIndexes)] - DateIndexes
 2.257534
``````

To get the date difference in years (floating point) you can convert the dates to decimal numbers of Year and calculate then their difference.

``````#Example Dates
x <- as.Date(c("2001-01-01", "2003-04-05"))

#Convert Date to decimal year:
date2DYear <- function(x) {
as.numeric(format(x,"%Y")) + #Get Year an add
(as.numeric(format(x,"%j")) - 0.5) / #Day of the year divided by
as.numeric(format(as.Date(paste0(format(x,"%Y"), "-12-31")),"%j")) #days of the year
}
diff(date2DYear(x)) #Get the difference in years
# 2.257534
``````

I subtract `0.5` from the day of the year as it is not known if you are at the beginning or the end of the day and `%j` starts with `1`.

I think the difference between `2012-03-01` and `2017-03-01` need not to be 5 Years, as 2012 has 366 days and 2017 365 and `2012-03-01` is on the 61 day of the year and `2017-03-01` on the 60.

``````x <- as.Date(c("2012-03-01", "2017-03-01"))
diff(date2DYear(x))
# 4.997713
``````

Note that using `time_length` and `interval` from `lubridate` need not come to the same result when you make a cumulative time difference.

``````library(lubridate)

x <- as.Date(c("2012-01-01", "2012-03-01", "2012-12-31"))
time_length(interval(x, x), "years")
# 0.9972678
time_length(interval(x, x), "years") +
time_length(interval(x, x), "years")
# 0.9995509 #!
diff(date2DYear(x[c(1,3)]))
# 0.9972678
diff(date2DYear(x[c(1,2)])) + diff(date2DYear(x[c(2,3)]))
# 0.9972678

x <- as.Date(c("2013-01-01", "2013-03-01", "2013-12-31"))
time_length(interval(x, x), "years")
# 0.9972603
time_length(interval(x, x), "years") +
time_length(interval(x, x), "years")
# 0.9972603
diff(date2DYear(x[c(1,3)]))
# 0.9972603
diff(date2DYear(x[c(1,2)])) + diff(date2DYear(x[c(2,3)]))
# 0.9972603
``````

Since you are already using lubridate package, you can obtain number of years in floating point using a simple trick:

find number of seconds in one year:

``````seconds_in_a_year <- as.integer((seconds(ymd("2010-01-01")) - seconds(ymd("2009-01-01"))))
``````

now obtain number of seconds between the 2 dates you desire

``````seconds_between_dates <- as.integer(seconds(date1) - seconds(date2))
``````

your final answer for number of years in floating points will be

``````years_between_dates <- seconds_between_dates / seconds_in_a_year
``````