**Short answer**

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.

**Long Answer**

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:

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...

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)
extraday = np.r_[month>2].astype(int)*leapyr
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()
extraday = np.r_[month>2].astype(int)*leapyr
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.

: constructing a continuous numeric (float) variable to express time as a float. (Don't confuse statistical"time index""time index"with a Python datetime being (say) the index of a DataFrame; those are two separate things.)1more comment