This vignette serves as an example on data wrangling & visualization with
opensensmapr
,dplyr
andggplot2
.
# required packages: library(opensensmapr) # data download library(dplyr) # data wrangling library(ggplot2) # plotting library(lubridate) # date arithmetic library(zoo) # rollmean()
openSenseMap.org has grown quite a bit in the last years; it would be interesting
to see how we got to the current r osem_counts()$boxes
sensor stations,
split up by various attributes of the boxes.
While opensensmapr
provides extensive methods of filtering boxes by attributes
on the server, we do the filtering within R to save time and gain flexibility.
So the first step is to retrieve all the boxes.
# if you want to see results for a specific subset of boxes, # just specify a filter such as grouptag='ifgi' here # boxes = osem_boxes(cache = '.') boxes = readRDS('boxes_precomputed.rds') # read precomputed file to save resources
In the following we just want to have a look at the boxes created in 2022, so we filter for them.
boxes = filter(boxes, locationtimestamp >= "2022-01-01" & locationtimestamp <="2022-12-31") summary(boxes) -> summary.data.frame
Another feature of interest is the spatial distribution of the boxes: plot()
can help us out here. This function requires a bunch of optional dependencies though.
plot(boxes)
But what do these sensor stations actually measure? Lets find out.
osem_phenomena()
gives us a named list of of the counts of each observed
phenomenon for the given set of sensor stations:
phenoms = osem_phenomena(boxes) str(phenoms)
Thats quite some noise there, with many phenomena being measured by a single sensor only, or many duplicated phenomena due to slightly different spellings. We should clean that up, but for now let's just filter out the noise and find those phenomena with high sensor numbers:
phenoms[phenoms > 50]
By looking at the createdAt
attribute of each box we know the exact time a box
was registered. Because of some database migration issues the createdAt
values are mostly wrong (~80% of boxes created 2022-03-30), so we are using the timestamp
attribute of the currentlocation
which should in most cases correspond to the creation date.
With this approach we have no information about boxes that were deleted in the meantime, but that's okay for now.
exposure_counts = boxes %>% group_by(exposure) %>% mutate(count = row_number(locationtimestamp)) exposure_colors = c(indoor = 'red', outdoor = 'lightgreen', mobile = 'blue', unknown = 'darkgrey') ggplot(exposure_counts, aes(x = locationtimestamp, y = count, colour = exposure)) + geom_line() + scale_colour_manual(values = exposure_colors) + xlab('Registration Date') + ylab('senseBox count')
Outdoor boxes are growing fast!
We can also see the introduction of mobile
sensor "stations" in 2017.
Let's have a quick summary:
exposure_counts %>% summarise( oldest = min(locationtimestamp), newest = max(locationtimestamp), count = max(count) ) %>% arrange(desc(count))
We can try to find out where the increases in growth came from, by analysing the box count by grouptag.
Caveats: Only a small subset of boxes has a grouptag, and we should assume
that these groups are actually bigger. Also, we can see that grouptag naming is
inconsistent (Luftdaten
, luftdaten.info
, ...)
grouptag_counts = boxes %>% group_by(grouptag) %>% # only include grouptags with 15 or more members filter(length(grouptag) >= 15 & !is.na(grouptag) & grouptag != '') %>% mutate(count = row_number(locationtimestamp)) # helper for sorting the grouptags by boxcount sortLvls = function(oldFactor, ascending = TRUE) { lvls = table(oldFactor) %>% sort(., decreasing = !ascending) %>% names() factor(oldFactor, levels = lvls) } grouptag_counts$grouptag = sortLvls(grouptag_counts$grouptag, ascending = FALSE) ggplot(grouptag_counts, aes(x = locationtimestamp, y = count, colour = grouptag)) + geom_line(aes(group = grouptag)) + xlab('Registration Date') + ylab('senseBox count')
grouptag_counts %>% summarise( oldest = min(locationtimestamp), newest = max(locationtimestamp), count = max(count) ) %>% arrange(desc(count))
First we group the boxes by locationtimestamp
into bins of one week:
bins = 'week' mvavg_bins = 6 growth = boxes %>% mutate(week = cut(as.Date(locationtimestamp), breaks = bins)) %>% group_by(week) %>% summarize(count = length(week)) %>% mutate(event = 'registered')
We can do the same for updatedAt
, which informs us about the last change to
a box, including uploaded measurements. As a lot of boxes were "updated" by the database
migration, many of them are updated at 2022-03-30, so we try to use the lastMeasurement
attribute instead of updatedAt
. This leads to fewer boxes but also automatically excludes
boxes which were created but never made a measurement.
This method of determining inactive boxes is fairly inaccurate and should be considered an approximation, because we have no information about intermediate inactive phases. Also deleted boxes would probably have a big impact here.
inactive = boxes %>% # remove boxes that were updated in the last two days, # b/c any box becomes inactive at some point by definition of updatedAt filter(lastMeasurement < now() - days(2)) %>% mutate(week = cut(as.Date(lastMeasurement), breaks = bins)) %>% filter(as.Date(week) > as.Date("2021-12-31")) %>% group_by(week) %>% summarize(count = length(week)) %>% mutate(event = 'inactive')
Now we can combine both datasets for plotting:
boxes_by_date = bind_rows(growth, inactive) %>% group_by(event) ggplot(boxes_by_date, aes(x = as.Date(week), colour = event)) + xlab('Time') + ylab(paste('rate per ', bins)) + scale_x_date(date_breaks="years", date_labels="%Y") + scale_colour_manual(values = c(registered = 'lightgreen', inactive = 'grey')) + geom_point(aes(y = count), size = 0.5) + # moving average, make first and last value NA (to ensure identical length of vectors) geom_line(aes(y = rollmean(count, mvavg_bins, fill = list(NA, NULL, NA))))
And see in which weeks the most boxes become (in)active:
boxes_by_date %>% filter(count > 50) %>% arrange(desc(count))
While we are looking at locationtimestamp
and lastMeasurement
, we can also extract the duration of activity
of each box, and look at metrics by exposure and grouptag once more:
durations = boxes %>% group_by(exposure) %>% filter(!is.na(lastMeasurement)) %>% mutate(duration = difftime(lastMeasurement, locationtimestamp, units='days')) %>% filter(duration >= 0) ggplot(durations, aes(x = exposure, y = duration)) + geom_boxplot() + coord_flip() + ylab('Duration active in Days')
The time of activity averages at only r round(mean(durations$duration))
days,
though there are boxes with r round(max(durations$duration))
days of activity,
spanning a large chunk of openSenseMap's existence.
durations = boxes %>% filter(!is.na(lastMeasurement)) %>% group_by(grouptag) %>% # only include grouptags with 20 or more members filter(length(grouptag) >= 15 & !is.na(grouptag) & !is.na(lastMeasurement)) %>% mutate(duration = difftime(lastMeasurement, locationtimestamp, units='days')) %>% filter(duration >= 0) ggplot(durations, aes(x = grouptag, y = duration)) + geom_boxplot() + coord_flip() + ylab('Duration active in Days') durations %>% summarize( duration_avg = round(mean(duration)), duration_min = round(min(duration)), duration_max = round(max(duration)), oldest_box = round(max(difftime(now(), locationtimestamp, units='days'))) ) %>% arrange(desc(duration_avg))
The time of activity averages at only r round(mean(durations$duration))
days,
though there are boxes with r round(max(durations$duration))
days of activity,
spanning a large chunk of openSenseMap's existence.
This is less useful, as older boxes are active for a longer time by definition. If you have an idea how to compensate for that, please send a Pull Request!
# NOTE: boxes older than 2016 missing due to missing updatedAt in database duration = boxes %>% mutate(year = cut(as.Date(locationtimestamp), breaks = 'year')) %>% group_by(year) %>% filter(!is.na(lastMeasurement)) %>% mutate(duration = difftime(lastMeasurement, locationtimestamp, units='days')) %>% filter(duration >= 0) ggplot(duration, aes(x = substr(as.character(year), 0, 4), y = duration)) + geom_boxplot() + coord_flip() + ylab('Duration active in Days') + xlab('Year of Registration')
Other visualisations come to mind, and are left as an exercise to the reader. If you implemented some, feel free to add them to this vignette via a Pull Request.
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