1

The dataframe df1 summarizes different datetimes in which people has gone to a public toilet for a specific period of time (let's say between "2017-06-01" and "2017-06-30"). The column Zone specifies the area where the toilet was placed, being a factor with two levels: A (a party area) orB (a residence area).

I show below a reproducible example of what I have. This example contains only two days to reduce the size of the example dataset. In order to create df1 I had first to create 4 separate dataframes and then bind them to create the dataframe df1 (I had error when a tried to create df1 at once). df1 has 193 rows.

options(digits.secs=3)
day_1_A<- data.frame(Datetime= ymd_hms(c("2017-06-01 00:04:17.986","2017-06-01 00:17:43.456","2017-06-01 00:22:43.456","2017-06-01 00:34:43.456","2017-06-01 00:45:43.456","2017-06-01 01:15:23.275","2017-06-01 01:41:32.609","2017-06-01 02:04:17.986","2017-06-01 02:17:43.456","2017-06-01 03:15:23.275","2017-06-01 03:41:32.609","2017-06-01 04:04:17.986","2017-06-01 04:17:43.456","2017-06-01 05:15:23.275","2017-06-01 05:41:32.609","2017-06-01 06:04:17.986","2017-06-01 06:17:43.456","2017-06-01 07:15:23.275","2017-06-01 07:41:32.609","2017-06-01 08:04:17.986","2017-06-01 08:17:43.456","2017-06-01 09:15:23.275","2017-06-01 09:41:32.609","2017-06-01 10:04:17.986","2017-06-01 10:17:43.456","2017-06-01 11:15:23.275","2017-06-01 11:41:32.609","2017-06-01 12:04:17.986","2017-06-01 12:17:43.456","2017-06-01 13:15:23.275","2017-06-01 13:41:32.609","2017-06-01 14:04:17.986","2017-06-01 14:17:43.456","2017-06-01 15:17:23.275","2017-06-01 15:41:32.609","2017-06-01 16:04:17.986","2017-06-01 16:17:43.456","2017-06-01 17:15:23.275","2017-06-01 17:41:32.609","2017-06-01 18:04:17.986","2017-06-01 18:17:43.456","2017-06-01 19:15:23.275","2017-06-01 19:41:32.609","2017-06-01 20:04:17.986","2017-06-01 20:17:43.456","2017-06-01 21:15:23.275","2017-06-01 21:41:32.609","2017-06-01 22:04:17.986","2017-06-01 22:17:43.456","2017-06-01 23:15:23.275","2017-06-01 23:41:32.609")),
                 ToiletZone = c("A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A"))

day_1_B<- data.frame(Datetime= ymd_hms(c("2017-06-01 00:04:17.986","2017-06-01 00:17:43.456","2017-06-01 01:15:23.275","2017-06-01 01:41:32.609","2017-06-01 02:04:17.986","2017-06-01 02:17:43.456","2017-06-01 03:15:23.275","2017-06-01 03:41:32.609","2017-06-01 04:04:17.986","2017-06-01 04:17:43.456","2017-06-01 05:15:23.275","2017-06-01 05:41:32.609","2017-06-01 06:04:17.986","2017-06-01 06:17:43.456","2017-06-01 07:15:23.275","2017-06-01 07:41:32.609","2017-06-01 08:04:17.986","2017-06-01 08:17:43.456","2017-06-01 09:15:23.275","2017-06-01 09:41:32.609","2017-06-01 10:04:17.986","2017-06-01 10:17:43.456","2017-06-01 11:15:23.275","2017-06-01 11:41:32.609","2017-06-01 12:04:17.986","2017-06-01 12:17:43.456","2017-06-01 13:15:23.275","2017-06-01 13:41:32.609","2017-06-01 14:04:17.986","2017-06-01 14:17:43.456","2017-06-01 15:15:23.275","2017-06-01 15:41:32.609","2017-06-01 16:04:17.986","2017-06-01 16:17:43.456","2017-06-01 17:15:23.275","2017-06-01 17:41:32.609","2017-06-01 18:04:17.986","2017-06-01 18:17:43.456","2017-06-01 19:15:23.275","2017-06-01 19:41:32.609","2017-06-01 20:04:17.986","2017-06-01 20:17:43.456","2017-06-01 21:15:23.275","2017-06-01 21:41:32.609","2017-06-01 22:04:17.986","2017-06-01 22:17:43.456","2017-06-01 23:15:23.275","2017-06-01 23:41:32.609")),
                 ToiletZone = c("B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B"))

day_2_A<- data.frame(Datetime= ymd_hms(c("2017-06-02 00:17:43.456","2017-06-02 00:48:43.456","2017-06-02 01:15:23.275","2017-06-02 01:52:23.275","2017-06-02 02:04:17.986","2017-06-02 02:17:43.456","2017-06-02 03:15:23.275","2017-06-02 03:41:32.609","2017-06-02 04:04:17.986","2017-06-02 04:17:43.456","2017-06-02 05:15:23.275","2017-06-02 05:41:32.609","2017-06-02 06:04:17.986","2017-06-02 06:17:43.456","2017-06-02 07:15:23.275","2017-06-02 07:41:32.609","2017-06-02 08:04:17.986","2017-06-02 08:17:43.456","2017-06-02 09:15:23.275","2017-06-02 09:41:32.609","2017-06-02 10:04:17.986","2017-06-02 10:17:43.456","2017-06-02 11:15:23.275","2017-06-02 11:41:32.609","2017-06-02 12:04:17.986","2017-06-02 12:17:43.456","2017-06-02 13:15:23.275","2017-06-02 13:41:32.609","2017-06-02 14:04:17.986","2017-06-02 14:17:43.456","2017-06-02 15:15:23.275","2017-06-02 15:41:32.609","2017-06-02 16:04:17.986","2017-06-02 16:17:43.456","2017-06-02 17:15:23.275","2017-06-02 17:41:32.609","2017-06-02 18:04:17.986","2017-06-02 18:17:43.456","2017-06-02 19:15:23.275","2017-06-02 19:41:32.609","2017-06-02 20:04:17.986","2017-06-02 20:17:43.456","2017-06-02 21:15:23.275","2017-06-02 21:41:32.609","2017-06-02 22:04:17.986","2017-06-02 22:17:43.456","2017-06-02 23:15:23.275","2017-06-02 23:41:32.609")),
                 ToiletZone = c("A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A","A"))

day_2_B<- data.frame(Datetime= ymd_hms(c("2017-06-02 00:04:17.986","2017-06-02 01:15:23.275","2017-06-02 02:04:17.986","2017-06-02 02:17:43.456","2017-06-02 03:15:23.275","2017-06-02 03:41:32.609","2017-06-02 04:04:17.986","2017-06-02 04:17:43.456","2017-06-02 05:15:23.275","2017-06-02 05:41:32.609","2017-06-02 06:04:17.986","2017-06-02 06:17:43.456","2017-06-02 07:15:23.275","2017-06-02 07:41:32.609","2017-06-02 08:04:17.986","2017-06-02 08:17:43.456","2017-06-02 09:15:23.275","2017-06-02 09:41:32.609","2017-06-02 10:04:17.986","2017-06-02 10:17:43.456","2017-06-02 11:15:23.275","2017-06-02 11:41:32.609","2017-06-02 12:04:17.986","2017-06-02 12:17:43.456","2017-06-02 13:15:23.275","2017-06-02 13:41:32.609","2017-06-02 14:04:17.986","2017-06-02 14:17:43.456","2017-06-02 15:15:23.275","2017-06-02 15:41:32.609","2017-06-02 16:04:17.986","2017-06-02 16:17:43.456","2017-06-02 17:15:23.275","2017-06-02 17:41:32.609","2017-06-02 18:04:17.986","2017-06-02 18:17:43.456","2017-06-02 19:15:23.275","2017-06-02 19:41:32.609","2017-06-02 20:04:17.986","2017-06-02 20:17:43.456","2017-06-02 21:15:23.275","2017-06-02 21:41:32.609","2017-06-02 22:04:17.986","2017-06-02 22:17:43.456","2017-06-02 23:15:23.275","2017-06-02 23:41:32.609")),
                 ToiletZone = c("B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B","B"))


df1<- rbind(day_1_A,day_1_B,day_2_A,day_2_B)
df1

> df1
                   Datetime ToiletZone
1   2017-06-01 00:04:17.986          A
2   2017-06-01 00:17:43.455          A
3   2017-06-01 00:22:43.455          A
4   2017-06-01 00:34:43.455          A
5   2017-06-01 00:45:43.455          A
6   2017-06-01 01:15:23.275          A
.               .                    .
.               .                    .
.               .                    .
193 2017-06-02 23:41:32.608          B

For some reasons I won't explain here, I need to calculate for EACH DAY and for EACH ZONE a statistic called θ, that could be defined as the coefficient of the division of the "average hourly number of visits to the toilet during the day" (Hourly_daily_μ) by the "average hourly number of visits for the entire period of interest" (Overall_hourly_μ).

I show in a picture what I would expect from the previous example (the columns Hourly_daily_μ_A, Hourly_daily_μ_B, Overall_hourly_μ_A and Overall_hourly_μ_A are incorporated to clarify the calculations. The columns that I really need are θ_A and θ_B): enter image description here

Why Hourly_daily_μ_A is 51/24 on 2017-06-01? Because this day there were 51 persons that went to the toilet. Hence, if we divide between 24 we get the hourly mean of people that went to the toilet this day.

Why Overall_hourly_μ_A is the same for each zone for the different days? Because it is an overall mean for each zone. Here we want to know what is the general average of people that go to the toilet per hour. In this example, we know that 99 persons went to the toilet between the 1st June and the 2nd June in the Zone A. So we divide this between the total number of hours (48 hours in the example) and we get the overall hourly mean of people that go to the toilet in the zone A. It is a unique value for each Zone.

Why θ_A is (51*48)/(24*99) on the 2017-06-01? Because is the result of dividing Hourly_daily_μ_A (51/24) by Overall_hourly_μ_A (99/48).

Does anyone know how to do it? My dataframe is quite large so I guess that the package data.table could be a good option.

| |
  • Sorry, I get some different numbers - – akrun Jul 10 '19 at 16:46
  • If I'm not wrong, in the example there are 51 people that go to the toilet in the Zone A and 48 in the Zone B on the 1st June. On the 2nd June, there are 48 people that go to the toilet in the Zone A and 46 that go to the toilet B. If you sum all, it is 193 people (the number of rows of the example dataset). – Dekike Jul 10 '19 at 16:50
  • I tried couple of ways, df1 %>% group_by(ToiletZone) %>% summarise(n = n()) gives 99 and 94 as yours. Next I converted the 'Datetime' to hourly with ceiling and checked the frequency – akrun Jul 10 '19 at 16:52
  • The calculations are "easy", but I don't know how to do it. I want to get for each day and zone a statistic that is the result of dividing the hourly average number of people that goes to the toilet this day (Hourly_daily_μ) by the overall hourly average number of people that go to the toilet using all the days from the dataset (Overall_hourly_μ). – Dekike Jul 10 '19 at 16:53
  • May be I missed the year part df1 %>% group_by(ToiletZone, date = as.Date(Datetime)) %>% summarise(v1 = n_distinct(ceiling_date(Datetime, 'hour'))) – akrun Jul 10 '19 at 16:58
1

I think you only need to floor your dates to a day unit and then you can use it for grouping. With data.table:

setDT(df1)

df1[, Date := floor_date(Datetime, "day")]

daily <- df1[, .(DailyCount = .N, DailyAvg = .N / 24), by = .(ToiletZone, Date)]
overall <- daily[, .(Total = sum(DailyCount) / (.N * 24)), by = .(ToiletZone)]

overall[daily, .(ToiletZone, Date, Theta = DailyAvg / Total), on = "ToiletZone"]
   ToiletZone       Date     Theta
1:          A 2017-06-01 1.0303030
2:          B 2017-06-01 1.0212766
3:          A 2017-06-02 0.9696970
4:          B 2017-06-02 0.9787234

And hourly would be similar, just change floor_date and adjust some denominators:

df1[, Date := floor_date(Datetime, "hour")]

hourly <- df1[, .(HourlyCount = .N), by = .(ToiletZone, Date)]
overall <- hourly[, .(Total = sum(HourlyCount) / .N), by = "ToiletZone"]

ans <- overall[hourly, .(ToiletZone, Date, Theta = HourlyCount / Total), on = "ToiletZone"]

BTW, the last lines are a join, you can think of them as a left join with, respectively, daily and hourly as the left-hand table.

| |
  • Thanks Alexis. One doubt, can I use the same script if I increase the period with data? I will desire the same: a 'zheta' per zone and per day which divide the hourly mean of people that go to the toilet in this day in this zone (numerator) between the 'Overall hourly mean of people' that go to the toilet in this zone for the whole period. I guess I can change the number of row and it still work, but just in case I ask you... – Dekike Jul 10 '19 at 18:25
  • @Dekike yes, I think it should work, it makes no assumptions regarding the amount of days in your data. – Alexis Jul 10 '19 at 20:34
  • Hi @Alexis, I am sorry for disturbing you again. How could I do if I want to calculate a "Theta" by hour instead than by day? That is, on each hour I divide the number of visits in this hour to the toilet by the overall hourly mean of visits to the toilet for the whole period. I think I might use this instead of a "Theta" by day... – Dekike Jul 10 '19 at 21:41
  • @Dekike I've updated the answer, doesn't fit in a comment. BTW, the code in your question has a typo, you used day_2_A two times. – Alexis Jul 10 '19 at 21:59
1

An option would be do group by frequency count, do some calculations to get the expected output

library(dplyr)
library(tidyr)
library(lubridate)
df1 %>% 
  mutate(Date = floor_date(Datetime, "hour")) %>% 
  group_by(ToiletZone, Date) %>% 
  mutate(hourlyCount = n(), HourlyAvg = hourlyCount/24) %>% 
  group_by(ToiletZone) %>% 
  mutate(Total = sum(hourlyCount)/ n() * 24) %>% 
  group_by(Date = as.Date(Date), add = TRUE) %>% 
  summarise(Theta = hourlyCount[1]/Total[1]) %>%
  spread(ToiletZone, Theta)
| |
  • Hi akrun, I added an example to try both clarify what I need and to know if your code does what I need... – Dekike Jul 10 '19 at 16:21
  • I need to calculate for each zone and day the average hourly number of people that go to the toilet. On the other hand, I calculate the average hourly number of people that go to the toilet BUT FOR THE WHOLE PERIOD (in this case the days 2017-06-01 and 2017-06-02). And finally, I get the statistic that I need that is the division between the first and the second parameter. – Dekike Jul 10 '19 at 16:30
  • @Dekike I got 99 part, but what is the 48 – akrun Jul 10 '19 at 16:30
  • The number of hours. For the daily mean you divide by 24 (1 day = 24 hours), but for the "overall mean", you have to divide by the total number of hours of the period, in this case since the period are two days, 48 hours. 99 is the amount of people that go to the toilet in two days, and dividing it by 48 hours you get the hourly mean for the whole period. – Dekike Jul 10 '19 at 16:36
  • @Dekike I usedd ceiling_date earlier, but ddue to the confusion in the days, have to change it. – akrun Jul 10 '19 at 20:45

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.