# Get average time of day in SQLite from datetimes

I have times in SQLite in the form of '2012-02-21 00:00:00.000000' and would like to average times of day together. Dates don't matter--just times. So, e.g., if the data is:

``````'2012-02-18 20:00:00.000000'
'2012-02-19 21:00:00.000000'
'2012-02-20 22:00:00.000000'
'2012-02-21 23:00:00.000000'
``````

The average of 20, 21, 22, an 23, should be 21.5, or 21:30 (or 9:30pm in the U.S.).

Q1) Is there a best way to do this in a SELECT query in SQLite?

But more difficult: what if one or more of the datetimes crosses midnight? They definitely will in my data set. Example:

``````'2012-02-18 22:00:00.000000'
'2012-02-19 23:00:00.000000'
'2012-02-21 01:00:00.000000'
``````

Now the average seems like it should be (22 + 23 + 1)/3 = 15.33 or 15:20 (3:20pm). But that would misrepresent the data, as these events are all happening at night, from 22:00 to 01:00 (10pm to 1am). Really, the better approach would be to average them like (22 + 23 + 25)/3 = 23.33 or 23:20 (11:20pm).

Q2) Is there anything I should do to my SELECT query to take this into account, or is this something I have to code in Python?

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You need to define your "average" better. Seems like sometimes you want the date to matter but sometimes you don't. –  mu is too short Feb 24 '12 at 4:18
@muistooshort Can you explain what makes you say that? Unless I am misunderstanding my needs (and perhaps I am), I don't want the date to ever matter. In fact, these fields might as well not have the date portion, so they could be like "22:00:00", "23:00:00", and "01:00:00" and I'd like the average of those to come out to 23:20. –  Chelonian Feb 24 '12 at 4:50
You give two possible values for the "average": 15:20 and 23:20. The first only looks at the time-of-day, the second uses knowledge of the date transition to avoid a mod-24 adjustment to the hour handling. –  mu is too short Feb 24 '12 at 5:21
@muistooshort Well, what I'm after is only the 23:20. The problem is, I will not have all data for every date (there will be gaps). Because of that, if I use your original code, the date information will matter but in a way that will not give me (in this example) 23:20 if I have a gap of a few days between values. I would rather have a mod-24 adjustment, just not sure how best to go about that in SQLITE or Python. Does this make more sense? Thanks for your patience. –  Chelonian Feb 24 '12 at 18:03
Have you considered the possibility that you're just drawing bad conclusions from a limited sample? The outlier problem might go away if you look at the whole dataset. –  mu is too short Feb 25 '12 at 2:45
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Site Rosetta Code has a task and code on this subject, and in researching that I came across this wikipedia link. Check out the talk/discussion pages too for discussions on applicability etc.

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what do you really want to compute?

• datetimes (or times within 1 day) are usually represented as real numbers
• time coordinates on a 24-hour clock are complex numbers, however
• average of real-number representations of the times will give you dubious results...

i don't know what you want to do with edge cases like [`1:00`, `13:00`], but let's consider following example: [`01:30`, `06:30`, `13:20`, `15:30`, `16:15`, `16:45`, `17:10`]

I suggest implementing this algorithm - in Python:

1. convert times to complex numbers - e.g. compute their coordinates on a circle of radius = 1
2. compute the average using vector addition
3. convert the result vector angle to minutes + compute the relevance of this result (e.g. relevance of average of [`1:00`, `13:00`] should be 0 whatever the angle is computed because of rounding errors)
``````import math
def complex_average(minutes):
# first convert the times from minutes (0:00 - 23:59) to radians
# so we get list for quasi polar coordinates (1, radians)
# (no point in rotating/flipping to get real polar coordinates)
# 180° = 1/2 day = 24*60/2 minutes
radians = [t*math.pi/(24*60/2) for t in minutes]
xs = []
ys = []
# convert polar coordinates (1, r) to cartesian (x, y)
# the vectors start at (0, 0) and end in (x, y)
x, y = (math.cos(r), math.sin(r))
xs.append(x)
ys.append(y)

# result vector = vector addition
sum_x, sum_y = (sum(ys), sum(xs))

# convert result vector coordinates to radians, then to minutes
# note the cumulative ROUNDING ERRORS, however
result_minutes = int(result_radians / math.pi * (24*60/2))
if result_minutes < 0:
result_minutes += 24*60

# relevance = magnitude of the result vector / number of data points
# (<0.0001 means that all vectors cancel each other, e.g. [1:00, 13:00]
#  => result_minutes would be random due to rounding error)
# FYI: standart_deviation = 6*60 - 6*60*relevance
relevance = round(math.sqrt(sum_x**2 + sum_y**2) / len(minutes), 4)

return result_minutes, relevance
``````

And test it like this:

``````# let's say the select returned a bunch of integers in minutes representing times
selected_times = [90, 390, 800, 930, 975, 1005, 1030]
# or create other test data:
#selected_times = [hour*60 for hour in [23,22,1]]

complex_avg_minutes, relevance = complex_average(selected_times)
print("complex_avg_minutes = {:02}:{:02}".format(complex_avg_minutes//60,
complex_avg_minutes%60),
"(relevance = {}%)".format(int(round(relevance*100))))

simple_avg = int(sum(selected_times) / len(selected_times))
print("simple_avg = {:02}:{:02}".format(simple_avg//60,
simple_avg%60))

hh_mm = ["{:02}:{:02}".format(t//60, t%60) for t in selected_times]
print("\ntimes = {}".format(hh_mm))
``````

Output for my example:

``````complex_avg_minutes = 15:45 (relevance = 44%)
simple_avg = 12:25
``````
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or maybe 1-dimensional finite space would be better representation than complex numbers - becase only points on the circle represent time points, but the vector results are within the circle :( –  deathApril Jul 12 '12 at 14:55

If I understand correctly, you want to get the average distance of the times from midnight?

``````SELECT SUM(mins) / COUNT(*) from
( SELECT
CASE
WHEN strftime('%H', t) * 1 BETWEEN 0 AND 11
THEN (strftime('%H', t)) * 60 + strftime('%M', t)
ELSE strftime('%H', t) * 60 + strftime('%M', t) - 24 * 60
END mins
FROM timestamps
);
``````

So we calculate the minutes offset from midnight: after noon we get a negative value, before noon is positive. The first line averages them and gives us a result in minutes. Converting that back to a `hh:mm` time is left as an "exercise for the student" ;-)

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what about average of (`11:00`, `12:00`, `13:00`)?? surelly 00:00 is not exactly the expected result ;)) –  deathApril Mar 2 '12 at 11:44
@deathApril - As I specified, I guessed that the requirement is context-dependent and assumes that the times are clustered around midnight. If that's the case, this is a reasonable solution. If not, then as you point out, it's not very appropriate ;-) –  Mike Woodhouse Mar 5 '12 at 10:26
``````select dateadd(hh,avg(datediff(hh,getdate(),myrow)),getdate())