# How to convert Python datetime dates to decimal/float years

I am looking for a way to convert datetime objects to decimal(/float) year, including fractional part. Example:

``````>>> obj = SomeObjet()
>>> obj.DATE_OBS
datetime.datetime(2007, 4, 14, 11, 42, 50)
``````

How do I convert `datetime.datetime(2007, 4, 14, 11, 42, 50)` to decimal years. By decimal format I mean the float value `2007.4523`, where the fractional part is the number of seconds from the beginning of the year (2007-01-01 till 2007-04-14), divided by the total number of seconds in that year (2007-01-01 till 2008-01-01).

(NOTE: in statistical modeling (e.g. for linear regression), this is called "time index")

• Can you give some example? What do you mean by "decimal years"? Jun 23 '11 at 9:05
• From this format dd/mm/yyyy to this kind of format yyyy.yyyy Jun 23 '11 at 9:07
• Something like - month is 1/12 years; day is 1/365(366, depending on the year - leap or not), etc. Jun 23 '11 at 9:12
• Give us a real example - with numbers Jun 23 '11 at 9:13
• In statistical modeling (e.g. for linear regression), this is called "time index": constructing a continuous numeric (float) variable to express time as a float. (Don't confuse statistical "time index" with a Python datetime being (say) the index of a DataFrame; those are two separate things.)
– smci
Nov 15 '19 at 22:03

``````from datetime import datetime as dt
import time

def toYearFraction(date):
def sinceEpoch(date): # returns seconds since epoch
return time.mktime(date.timetuple())
s = sinceEpoch

year = date.year
startOfThisYear = dt(year=year, month=1, day=1)
startOfNextYear = dt(year=year+1, month=1, day=1)

yearElapsed = s(date) - s(startOfThisYear)
yearDuration = s(startOfNextYear) - s(startOfThisYear)
fraction = yearElapsed/yearDuration

return date.year + fraction
``````

Demo:

``````>>> toYearFraction(dt.today())
2011.47447514
``````

This method is probably accurate to within the second (or the hour if daylight savings or other strange regional things are in effect). It also works correctly during leapyears. If you need drastic resolution (such as due to changes in the Earth's rotation) you are better off querying a net service.

• My answer is much more simple and gives an equally comparable float. Neither of our solutions are exact, but there is no generally acceptable standard way of converting a certain moment in time in to a decimal representation of a year, is there? Jun 23 '11 at 9:27
• @Kimvais yes, there is; it is a well-defined quantity. This accurate to within an hour, more if the libraries take care of daylight savings (which I don't think they do). Jun 23 '11 at 9:31
• @Kimvais: yes, the following is well defined and accepted by every mathematician in existance (but not the physicists, who may say relativity means this question is not well-defined). The start of the year is at time t0. The end of the year is at time t1. If you take any time between those two, you have a fraction. Jun 23 '11 at 9:36
• if your solution is expected to be correct within an hour then you should not use more than 4 digits after the decimal point here. 8 digits in your answer misleadingly suggest that you are taking into account even leap seconds that you don't. Though if the input `date` is known only within a day then you don't need more than 3 digits anyway (and `time.mktime()` is an overkill in this case). btw, there are different definitions of the year that are not connected with relativity in any way e.g., sidereal year.
– jfs
Apr 24 '15 at 19:41
• Note that Matplotlib also has a built-in date2num() function. Jul 20 '16 at 8:43

This is a little simpler way than the other solutions:

``````import datetime
def year_fraction(date):
start = datetime.date(date.year, 1, 1).toordinal()
year_length = datetime.date(date.year+1, 1, 1).toordinal() - start
return date.year + float(date.toordinal() - start) / year_length

>>> print year_fraction(datetime.datetime.today())
2016.32513661
``````

Note that this calculates the fraction based on the start of the day, so December 31 will be 0.997, not 1.0.

• That's quite neat. In particular you calculate `year_length` in a leap-year-aware way, which other answer don't, hence are slightly off.
– smci
Nov 16 '19 at 0:51

After implementing the accepted solution, I had the revelation that this modern pandas version is identical, and much simpler:

``````dat['decimal_date']=dat.index.year+ (dat.index.dayofyear -1)/365
``````

Must be used on a date-time index Pandas dataframe. Adding as this solution post comes up in the top of my google search for this issue.

• You need a . after 365 or else everything (including your returned years) are integers.
– Rob
Jun 5 '19 at 1:20
• This is the best answer. But a) the denominator needs to be 366 for leap-years b) if you want a datetime-index you can use `(df.index.dayofyear-1 + df.index.hour/24) /365`. You could even throw in minutes or seconds terms too.
– smci
Nov 16 '19 at 0:06

The date to decimal year conversion is ambiguously defined beyond .002 years (~1 day) precision. For cases where high decimal accuracy isn't important, this will work:

``````# No library needed, one-liner that's probably good enough
def decyear4(year, month, day, h=0, m=0, s=0) :
return year + ((30.4375*(month-1) + day-1)*24+h)*3600/31557600.0
``````

If you need accuracy better than .005 years (~2 days), you should be using something else (e.g. seconds since epoch, or some such). If you are forced to (or just really, really want to do it this way) use decimal years, read on.

Contrary to some of the answers and comments previously posted, a 'decimal year' date/timestamp is not an unambiguously defined quantity. When you consider the idea of a decimal year, there are two properties that you probably expect to be true:

1. Perfect interpolation between beginning of year and end of year:
2020, Jan 1, 12:00:00am would correspond 2020.000
2020, Dec 31 11:59:59.999... pm would correspond to 2020.999...

2. Constant units (i.e. linear mapping):
2020.03-2020.02 == 2021.03-2021.02

Unfortunately you can't satisfy both of these simultaneously, because the length of time of 1 year is different on leap years then non-leap years. The first requirement is what most previous answers are trying to fulfill. But in many (most?) cases where a decimal year might actually be used (e.g. where it will be used in a regression or model of some sort) then the second property is just as (if not more) important.

Here are some options. I did these in vectorized form for numpy, so some of them can be simplified a bit if numpy is not needed.

``````import numpy as np
# Datetime based
# Non-linear time mapping! (Bad for regressions, models, etc.
# e.g. 2020.2-2020.1 != 2021.2-2021.1)
def decyear1(year, month, day, h=0, m=0, s=0) :
import datetime
year_seconds = (datetime.datetime(year,12,31,23,59,59,999999)-datetime.datetime(year,1,1,0,0,0)).total_seconds()
second_of_year = (datetime.datetime(year,month,day,h,m,s) - datetime.datetime(year,1,1,0,0,0)).total_seconds()
return year + second_of_year / year_seconds

# Basically the same as decyear1 but without datetime library
def decyear2(year, month, day, h=0, m=0, s=0) :
leapyr = ((np.r_[year]%4==0) * (np.r_[year]%100!=0) + (np.r_[year]%400==0)).astype(int)
day_of_year = np.r_[0,31,28,31,30,31,30,31,31,30,31,30,31].cumsum()
year_seconds = ( (day_of_year[-1]+leapyr )*24*3600)
second_of_year = (((( day_of_year[month-1]+extraday + day-1)*24 + h)*60+m)*60+s)
return year + second_of_year / year_seconds

# No library needed
# Linear mapping, some deviation from some conceptual expectations
# e.g. 2019.0000 != exactly midnight, January 1, 2019
def decyear3(year, month, day, h=0, m=0, s=0) :
refyear = 2015
leapyr = ((np.r_[year]%4==0) * (np.r_[year]%100!=0) + (np.r_[year]%400==0)).astype(int)
day_of_year = np.r_[0,31,28,31,30,31,30,31,31,30,31,30,31].cumsum()
year_seconds = 31557600.0 # Weighted average of leap and non-leap years
seconds_from_ref = ((year-refyear)*year_seconds + (((( day_of_year[month-1]+extraday + day-1)*24+h)*60 + m)*60 +s))
return refyear + seconds_from_ref/year_seconds

# No library needed, one-liner that's probably good enough
def decyear4(year, month, day, h=0, m=0, s=0) :
return year + ((30.4375*(month-1) + day-1)*24+h)*3600/31557600.0

# Just for fun - empirically determined one-liner (e.g. with a linear fit)
def decyear5(year, month, day, h=0, m=0, s=0) :
return -8.789580e-02 + year + 8.331180e-02*month + 2.737750e-03*day + 1.142047e-04*hr + 2.079919e-06*mn + -1.731524e-07*sec

#
# Code to compare conversions
#
N = 500000
year = np.random.randint(1600,2050,(N))
month = np.random.randint(1,12,(N))
day = np.random.randint(1,28,(N))
hr = np.random.randint(0,23,(N))
mn = np.random.randint(0,59,(N))
sec = np.random.randint(0,59,(N))
s = ('decyear1','decyear2','decyear3','decyear4','decyear5')
decyears = np.zeros((N,len(s)))
for f, i in zip( (np.vectorize(decyear1), decyear2, decyear3, decyear4, decyear5), range(len(s)) ) :
decyears[:,i] = f(year,month,day,hr,mn,sec)

avg, std, mx = np.zeros((len(s),len(s)), 'float64'),np.zeros((len(s),len(s)), 'float64'),np.zeros((len(s),len(s)), 'float64')
for i in range(len(s)) :
for j in range(len(s)) :
avg[i,j] = np.abs(decyears[:,i]-decyears[:,j]).mean()*365*24
std[i,j] = (decyears[:,i]-decyears[:,j]).std()*365*24
mx[i,j] = np.abs(decyears[:,i]-decyears[:,j]).max()*365*24

import pandas as pd
unit = " (hours, 1 hour ~= .0001 year)"
for a,b in zip((avg, std, mx),("Average difference"+unit, "Standard dev.", "Max difference")) :
print(b+unit)
print(pd.DataFrame(a, columns=s, index=s).round(3))
print()
``````

And hear is how they all compare on a pseudo-random collection of dates:

``````Average magnitude of difference (hours, 1 hour ~= .0001 year)
decyear1  decyear2  decyear3  decyear4  decyear5
decyear1     0.000     0.000     4.035    19.258    14.051
decyear2     0.000     0.000     4.035    19.258    14.051
decyear3     4.035     4.035     0.000    20.609    15.872
decyear4    19.258    19.258    20.609     0.000    16.631
decyear5    14.051    14.051    15.872    16.631     0.000

Standard dev of difference (hours, 1 hour ~= .0001 year)
decyear1  decyear2  decyear3  decyear4  decyear5
decyear1     0.000     0.000     5.402    16.550    16.537
decyear2     0.000     0.000     5.402    16.550    16.537
decyear3     5.402     5.402     0.000    18.382    18.369
decyear4    16.550    16.550    18.382     0.000     0.673
decyear5    16.537    16.537    18.369     0.673     0.000

Max difference (hours, 1 hour ~= .0001 year)
decyear1  decyear2  decyear3  decyear4  decyear5
decyear1     0.000     0.000    16.315    43.998    30.911
decyear2     0.000     0.000    16.315    43.998    30.911
decyear3    16.315    16.315     0.000    44.969    33.171
decyear4    43.998    43.998    44.969     0.000    18.166
decyear5    30.911    30.911    33.171    18.166     0.000
``````

Note, that none of these is necessarily more 'correct' then the others. It depends on your definition and your use case. But `decyear1` and `decyear2` are probably what most people are thinking of, even though (as noted above) they are probably not the best version to use in cases where decimal years are likely to be used, because of the non-linearity problem. Although all versions are consistent with each other to within a hundredth of a year, so any one will do in many situations (such as my case, where I needed it as input to the World Magnetic Model 2020).

Gotchas:

Hopefully it's apparent now that precision to better than an hour is probably not really necessary, but if it is, then might need to compensate your data for timezones and daylight savings time. Edit: And don't forget about leap seconds if you need another 3 digits of precision after sorting out the hours.

Note on precision:

All of the variants given above are well behaved and reversible - meaning the mappings themselves have unlimited precision. Accuracy, on the other hand, assumes a particular standard. If, for example, you are given decimal years without explanation then the accuracy of the reverse mapping you do would only be guaranteed to within half a day or so.

• Great point about leap years! Like you said, precision to better than an hour is probably not really necessary, but another point if it is: Leap Seconds. Positive leap seconds cause the affected UTC days to be 86,401 seconds long instead of 86,400 seconds. And there have been 37 total leap seconds (as of March 2021).
– rmc
Mar 11 '21 at 17:59
• Also, if leap seconds are important to your calculation, then you must be extra careful about your library and system behavior. For example, Unix/POSIX time explicitly ignores leap seconds. Likewise, python's datetime module does not account for leap seconds. For example, there are 18,628 days between Unix epoch and 01 Jan 2021. However, there were 31,622,437 seconds between those dates (days*86400+37), not 31,622,400 seconds (days*86400)
– rmc
Mar 11 '21 at 18:09

I'm assuming that you are using this to compare datetime values. To do that, please use the the timedelta objects instead of reiniventing the wheel.

Example:

``````>>> from datetime import timedelta
>>> from datetime import datetime as dt
>>> d = dt.now()
>>> year = timedelta(days=365)
>>> tomorrow = d + timedelta(days=1)
>>> tomorrow + year > d + year
True
``````

If for some reason you truly need decimal years, `datetime` objects method `strftime()` can give you an integer representation of day of the year if asked for `%j` - if this is what you are looking for, see below for a simple sample (only on 1 day resolution):

``````>>> from datetime import datetime
>>> d = datetime(2007, 4, 14, 11, 42, 50)
>>> (float(d.strftime("%j"))-1) / 366 + float(d.strftime("%Y"))
2007.2814207650274
``````
• This method is inaccurate by approximately 1-2 days depending on the year and doesn't work for leap years. I am also confused why you are assuming 367 days per year. Jun 23 '11 at 9:29
• 367 so that the leap year's last day does not become exactly the next year. Jun 23 '11 at 9:35
• that is not the right thing to do. Furthermore you have another bug: you always skip `2010.0` and `2011.0` and all those other numbers, because datetime(year=2011,month=1,day=1).strftime("%j") is 1 not 0. The fix is to subtract 1, but that still is inaccurate by a day during leapyears. Jun 23 '11 at 9:39

Surprised no one has mentioned this... but the `datetime.timedelta` objects that result from subtracting `datetime.datetime` objects have a division method. So, you could use the simple function

``````from datetime import datetime
def datetime2year(dt):
year_part = dt - datetime(year=dt.year, month=1, day=1)
year_length = (
datetime(year=dt.year + 1, month=1, day=1)
- datetime(year=dt.year, month=1, day=1)
)
return dt.year + year_part / year_length
``````

where the division is between `datetime.timedelta` objects.

It's possible to calculate decimal date by using Pandas's julian date and the following formulas.

In the case where your pandas dataframe has an index that is date-time:

``````JD=dat.index.to_julian_date() #create julian date
L= JD+68569
N= 4*L/146097
L= L-(146097*N+3)/4
I= 4000*(L+1)/1461001
L= L-1461*I/4+31
J= 80*L/2447
K= L-2447*J/80
L= J/11
J= J+2-12*L
decimal_date= 100*(N-49)+I+L
``````

decimal_date is a series of your date (in the same TZ as the dataframe index) in form of something like 2007.123452.

• Some sensible variable naming would really help this example. Sep 22 '20 at 3:19

Ten years down the line, let me add my two cents, using the astropy library.

``````    import datetime
from astropy.time import Time

input_date =  datetime.datetime(2007, 4, 14, 11, 42, 50)
astropy_time_object = Time(input_date,format='datetime')

decimal_year = astropy_time_object.decimalyear

print(decimal_year)
#2007.2835289827499
``````

If you want to include the minutes and seconds use this:

``````YearF=[(x.timetuple().tm_yday-1+x.timetuple().tm_hour/24+x.timetuple().tm_min/(60*24)+x.timetuple().tm_sec/(24*3600))/(365+((x.timetuple().tm_year//4)==(x.timetuple().tm_year/4)))+x.timetuple().tm_year for x in DateArray]
``````