581 lines
28 KiB
Markdown
581 lines
28 KiB
Markdown
Log data from the Multi-Touch Table at the HAUM
|
||
================
|
||
|
||
The Multi Touch Table at the Herzog-Anton-Ulrich-Museum (HAUM) in
|
||
Braunschweig gives visitors of the Museum the opportunity to interact
|
||
with about 70 artworks and 3 virtual cards containing information about
|
||
the museum and its layout. The table was installed at the museum in
|
||
October 2016 and since November 2016 log files from interactions of
|
||
visitors of the museum have been collected. These log files are in an
|
||
unstructured format and cannot be easily analyzed. The purpose of the
|
||
following document is to describe how the data haven been transformed
|
||
and which decisions have been made along the way.
|
||
|
||
The implementation of the steps described here can be found at:
|
||
<https://gitea.iwm-tuebingen.de/R/mtt>.
|
||
|
||
# Data structure
|
||
|
||
The log files contain lines that indicate the beginning and end of
|
||
possible activities that can be performed when interacting with the
|
||
artworks on the table. The layout of the table looks like pictures have
|
||
been tossed on a large table. Every artwork is visible at the start
|
||
configuration. People can move the pictures on the table, they can be
|
||
scaled and rotated. Additionally, the virtual picture cards can be
|
||
flipped in order to find more information of the artwork on the “back”
|
||
of the card. One has to press a little `i` for more information in one
|
||
of the bottom corners of the card. On the back of the card two to six
|
||
information cards can be found with a teaser text about a certain topic.
|
||
These topic cards can be opened and a hypertext with detailed
|
||
information opens. Within these hypertexts certain technical terms can
|
||
be clicked for lay people to get more information. This also opens up a
|
||
pop-up. The events encoded in the raw log files therefore have the
|
||
following structure.
|
||
|
||
"Start Application" --> Start Application
|
||
"Show Application"
|
||
"Transform start" --> Move
|
||
"Transform stop"
|
||
"Show Info" --> Flip Card
|
||
"Show Front"
|
||
"Artwork/OpenCard" --> Open Topic
|
||
"Artwork/CloseCard"
|
||
"ShowPopup" --> Open Popup
|
||
"HidePopup"
|
||
|
||
The right side shows what events can be extracted from these raw lines.
|
||
The “Start Application” is not an event in the original sense since it
|
||
only indicates if the table was started or maybe reset itself. This is
|
||
not an interaction with the table and therefore not interesting in
|
||
itself. All “Start Application” and “Show Application” are therefore
|
||
excluded from the data when further processed and are only in the raw
|
||
log files.
|
||
|
||
# Parsing the raw log files
|
||
|
||
The first step is to parse the raw log files that are stored by the
|
||
application as text files in a rather unstructured format to a format
|
||
that can be read by common statistics software packages. The data are
|
||
therefore transferred to a spread sheet format. The following section
|
||
describes what problems were encountered while doing this.
|
||
|
||
## Corrupt lines
|
||
|
||
When reading the files containing the raw logs into R, a warning appears
|
||
that says
|
||
|
||
Warning messages:
|
||
incomplete final line found on '2016/2016_11_18-11_31_0.log'
|
||
incomplete final line found on '2016/2016_11_18-11_38_30.log'
|
||
incomplete final line found on '2016/2016_11_18-11_40_36.log'
|
||
...
|
||
|
||
When you open these files, it looks like the last line contains some
|
||
binary content. It is unclear why and how this happens. So when reading
|
||
the data, these lines were removed. A warning will be given that
|
||
indicates how many files have been affected.
|
||
|
||
## Extracted variables from raw log files
|
||
|
||
The following variables (columns in the data frame) are extracted from
|
||
the raw log file:
|
||
|
||
- `fileId`: Containing the zero-left-padded file name of the raw log
|
||
file the data line has been extracted from
|
||
|
||
- `folder`: The folder names in which the raw log files haven been
|
||
organized in. For the HAUM data set, the data are sorted by year
|
||
(folders 2016, 2017, 2018, 2019, 2020, 2021, 2022, and 2023).
|
||
|
||
- `date`: Extracted timestamp from the raw log file in the format
|
||
`yyyy-mm-dd hh:mm:ss`.
|
||
|
||
- `timeMs`: Containing a timestamp in Milliseconds that restarts with
|
||
every new raw log files.
|
||
|
||
- `event`: Start and stop event tags. See above for possible values.
|
||
|
||
- `item`: Identifier of the different items. This is a three-digit
|
||
(left-padded) number. The numbers of the items correspond to the
|
||
folder names in `/ContentEyevisit/eyevisit_cards_light/` and were
|
||
orginally taken from the museums catalogue.
|
||
|
||
- `popup`: Name of the pop-up opened. This is only interesting for
|
||
“openPopup” events.
|
||
|
||
- `topic`: The number of the topic card that has been opened at the back
|
||
of the item card. See below for a more detailed description what these
|
||
numbers mean.
|
||
|
||
- `x`: Value of x-coordinate in pixel on the 4K-Display
|
||
($3840 \times 2160$).
|
||
|
||
- `y`: Value of y-coordinate in pixel.
|
||
|
||
- `scale`: Number in 128 bit that indicates how much the card has been
|
||
scaled.
|
||
|
||
- `rotation`: Degree of rotation from start configuration.
|
||
|
||
<!-- TODO: Nach welchem Zeitintervall resettet sich der Tisch wieder in die
|
||
Ausgangskonfiguration? -> PM needs to look it up -->
|
||
|
||
## Variables after “closing of events”
|
||
|
||
The raw log data consist of start and stop events for each event type.
|
||
After preprocessing four event types are extracted: `move`, `flipCard`,
|
||
`openTopic`, and `openPopup`. Except for the `move` events, which can
|
||
occur at any time when interacting with an item card on the table, the
|
||
events have a hierarchical order: An item card first needs to be flipped
|
||
(`flipCard`), then the topic cards on the back of the card can be opened
|
||
(`openTopic`), and finally pop-ups on these topic cards can be opened
|
||
(`openPopup`). This implies that the event `openPopup` can only be
|
||
present for a certain item, if the card has already been flipped (i.e.,
|
||
an event `flipCard` for the same item has already occured).
|
||
|
||
After preprocessing, the data frame is now in a wide format with columns
|
||
for the start and the stop of each event and contains the following
|
||
variables:
|
||
|
||
- `fileId.start` / `fileId.stop`: See above.
|
||
|
||
- `date.start` / `date.stop`: See above.
|
||
|
||
- `folder`: Containing the folder name (see above).
|
||
|
||
- `case`: A numerical variable indicating cases in the data. A “case”
|
||
indicates an interaction interval and could be defined in different
|
||
ways. Right now a new case begins, when no event occurred when no new
|
||
path started for 20 seconds or longer.
|
||
|
||
- `path`: A path is defined as one interaction with one item A path can
|
||
either start with a `flipCard` event or when an item has been touched
|
||
for the first time within this case. A path ends with the item card
|
||
being flipped close again or with the last movement of the card within
|
||
this case. One case can contain several paths with the same item when
|
||
the item is flipped open and flipped close again several times within
|
||
a short time.
|
||
|
||
- `glossar`: An indicator variable with values 0/1 that tracks if a
|
||
pop-up has been opened from the glossar folder. These pop-ups can be
|
||
assigned to the wrong item since it is not possible to do this
|
||
algorithmically. It is possible that two items are flipped open that
|
||
could both link to the same pop-up from a glossar. The indicator
|
||
variable is left as a variable, so that these pop-ups can be easily
|
||
deleted from the data. Right now, glossar entries can be ignored
|
||
completely by setting an argument and this is done by default. Using
|
||
the pop-ups from the glossar will need a lot more love, before it
|
||
behaves satisfactorily.
|
||
|
||
- `event`: Indicating the event. Can take tha values `move`, `flipCard`,
|
||
`openTopic`, and `openPopup`.
|
||
|
||
- `item`: Identifier of the different artworks and information cards.
|
||
This is a three-digit (left-padded) number. See above.
|
||
|
||
- `timeMs.start` / `timeMs.stop`: See above.
|
||
|
||
- `duration`: Calculated by $timeMs.stop - timeMs.start$ in
|
||
Milliseconds. Needs to be adjusted for events spanning more than one
|
||
log file by a factor of $60,000 \times \text{number of logfiles}$. See
|
||
below for details.
|
||
|
||
- `topic`: See above.
|
||
|
||
- `popup`: See above.
|
||
|
||
- `x.start` / `x.stop`: See above.
|
||
|
||
- `y.start` / `y.stop`: See above.
|
||
|
||
- `distance`: Euclidean distande calculated from $(x.start, y.start)$
|
||
and $(x.stop, y.stop)$.
|
||
|
||
- `scale.start` / `scale.stop`: See above.
|
||
|
||
- `scaleSize`: Relative scaling of item card, calculated by
|
||
$\frac{scale.stop}{scale.start}$.
|
||
|
||
- `rotation.start` / `rotation.stop`: See above.
|
||
|
||
- `rotationDegree`: Difference of rotation from $rotation.stop$ to
|
||
$rotation.start$.
|
||
|
||
## How unclosed events are handled
|
||
|
||
Events do not necessarily need to be completed. A person can, e.g.,
|
||
leave the table and not flip the item card close again. For `flipCard`,
|
||
`openTopic`, and `openPopup` the data frame contains `NA` when the event
|
||
does not complete. For `move` events it happens quite often that a start
|
||
event follows a start event and a stop event follows a stop event.
|
||
Technically a move event cannot *not* be finished and the number of
|
||
events without a start or stop indicate that the time resolution was not
|
||
sufficient to catch all these events accurately. Double start and stop
|
||
`move` events have therefore been deleted from the data set.
|
||
|
||
## Additional meta data
|
||
|
||
For the HAUM data, I added meta data on state holidays and school
|
||
vacations.
|
||
|
||
This led to the following additional variables:
|
||
|
||
- `holiday`
|
||
|
||
- `vacations`
|
||
|
||
# Problems and how I handled them
|
||
|
||
This lists some problems with the log data that required decisions.
|
||
These decisions influence the outcome and maybe even the data quality.
|
||
Hence, I tried to document how I handled these problems and explain the
|
||
decisions I made.
|
||
|
||
## Weird behavior of `timeMs` and neg. `duration` values
|
||
|
||
`timeMs` resets itself every time a new log file starts. This means that
|
||
the durations of events spanning more than one log file must be
|
||
adjusted. Instead of just calculating $timeMs.stop - timeMs.start$,
|
||
`timeMs.start` must be subtracted from the maximum duration of the log
|
||
file where the event started ($600,000 ms$) and the `timeMs.stop` must
|
||
be added. If the event spans more than two log files, a multiple of
|
||
$600,000$ must be taken, e.g. for three log files it must be:
|
||
$2 \times 600,000 - timeMs.start + timeMs.stop$ and so on.
|
||
|
||
![](README_files/figure-gfm/timems-1.png)<!-- -->
|
||
|
||
The boxplot shows that we have a continuous range of values within one
|
||
log file but that `timeMs` does not increase over log files. I kept
|
||
`timeMs.start` and `timeMs.stop` and also `fileId.start` and
|
||
`fileId.stop` in the data frame, so it is clear when events span more
|
||
than one log file.
|
||
|
||
<!--
|
||
Infos from the programmer:
|
||
|
||
"Bin außerdem gerade den Code von damals durchgegangen. Das Logging läuft
|
||
so: Mit Start der Anwendung wird alle 10 Minuten ein neues Logfile
|
||
erstellt. Die Startzeit, von der aus die Duration berechnet wird, wird
|
||
jeweils neu gesetzt. Duration ist also nicht "Dauer seit Start der
|
||
Anwendung" sondern "Dauer seit Restart des Loggers". Deine Vermutung ist
|
||
also richtig - es sollte keine Durations >10 Minuten geben. Der erste
|
||
Eintrag eines Logfiles kann alles zwischen 0 und 10 Minuten sein (je
|
||
nachdem, ob der Tisch zum Zeitpunkt des neuen Logging-Intervalls in
|
||
Benutzung war). Wenn ein Case also über 2+ Logs verteilt ist, musst du auf
|
||
die Duration jeweils 10 Minuten pro Logfile nach dem ersten addieren, damit
|
||
es passt."
|
||
-->
|
||
|
||
## Left padding of file IDs
|
||
|
||
The file names of the raw log files are automatically generated and
|
||
contain a timestamp. This timestamp is not well formed. First, it
|
||
contains an incorrect month. The months go from 0 to 11 which means,
|
||
that the file name `2016_11_15-12_12_57.log` was collected on December
|
||
15, 2016 at 12:12 pm. Another problem is that the file names are not
|
||
zero left padded, e.g., `2016_11_15-12_2_57.log`. This file was
|
||
collected on December 15, 2016 at 12:02 pm and therefore before the file
|
||
above. But most sorting algorithms, will sort these files in the order
|
||
shown below. In order to preprocess the data and close events that
|
||
belong together, the data need to be sorted by events and artworks
|
||
repeatedly. In order to get them back in the correct time order, it is
|
||
necessary to order them based on three variables: `fileId.start`,
|
||
`date.start` and `timeMs.start`. The file IDs therefore need to sort in
|
||
the correct order (again see below for example). I zero left padded the
|
||
log file names within the data frame using it as an identifier. These
|
||
“file names” do not correspond exactly to the original raw log file
|
||
names. This needs to be kept in mind when doing any kind of matching
|
||
etc.
|
||
|
||
## what it looked like before left padding
|
||
# 1422 ../data/haum_logs_2016-2023/_2016b/2016_11_15-12_2_57.log 2016-12-15 12:12:56 599671 Transform start 076 076.xml NA 2092.25 2008.00 0.3000000 13.26874254
|
||
# 1423 ../data/haum_logs_2016-2023/_2016b/2016_11_15-12_12_57.log 2016-12-15 12:12:57 621 Transform start 076 076.xml NA 2092.25 2008.00 0.3000000 13.26523465
|
||
# 1424 ../data/haum_logs_2016-2023/_2016b/2016_11_15-12_12_57.log 2016-12-15 12:12:57 677 Transform stop 076 076.xml NA 2092.25 2008.00 0.2997736 13.26239605
|
||
# 1425 ../data/haum_logs_2016-2023/_2016b/2016_11_15-12_12_57.log 2016-12-15 12:12:57 774 Transform start 076 076.xml NA 2092.25 2008.00 0.2999345 13.26239605
|
||
# 1426 ../data/haum_logs_2016-2023/_2016b/2016_11_15-12_12_57.log 2016-12-15 12:12:57 850 Transform stop 076 076.xml NA 2092.25 2008.00 0.2997107 13.26223362
|
||
# 1427 ../data/haum_logs_2016-2023/_2016b/2016_11_15-12_2_57.log 2016-12-15 12:12:57 599916 Transform stop 076 076.xml NA 2092.25 2008.00 0.2997771 13.26523465
|
||
|
||
## what it looks like now
|
||
# 1422 2016_11_15-12_02_57.log 2016-12-15 12:12:56 599671 Transform start 076 076.xml NA 2092.25 2008.00 0.3000000 13.26874254
|
||
# 1423 2016_11_15-12_02_57.log 2016-12-15 12:12:57 599916 Transform stop 076 076.xml NA 2092.25 2008.00 0.2997771 13.26523465
|
||
# 1424 2016_11_15-12_12_57.log 2016-12-15 12:12:57 621 Transform start 076 076.xml NA 2092.25 2008.00 0.3000000 13.26523465
|
||
# 1425 2016_11_15-12_12_57.log 2016-12-15 12:12:57 677 Transform stop 076 076.xml NA 2092.25 2008.00 0.2997736 13.26239605
|
||
# 1426 2016_11_15-12_12_57.log 2016-12-15 12:12:57 774 Transform start 076 076.xml NA 2092.25 2008.00 0.2999345 13.26239605
|
||
# 1427 2016_11_15-12_12_57.log 2016-12-15 12:12:57 850 Transform stop 076 076.xml NA 2092.25 2008.00 0.2997107 13.26223362
|
||
|
||
## Timestamps repeat
|
||
|
||
The timestamps in the `date` variable record year, month, day, hour,
|
||
minute and seconds. Since one second is not a very short time interval
|
||
for a move on a touch display, this is not fine grained enough to bring
|
||
events into the correct order, meaning there are events from the same
|
||
log file having the same timestamp and even events from different log
|
||
files having the same timestamp. The log files get written about every
|
||
10 minutes (which can easily be seen when looking at the file names of
|
||
the raw log files). So in order to get events in the correct order, it
|
||
is necessary to first order by file ID, within file ID then sort by
|
||
timestamp `date` and then within these more coarse grained timestamps
|
||
sort be `timeMs`. But as explained above, `timeMs` can only be sorted
|
||
within one file ID, since they do not increase consistently over log
|
||
files, but have a new setoff for each raw log file.
|
||
|
||
## x,y-coordinates outside of display range
|
||
|
||
The display of the Multi-Touch-Table is a 4K-display with 3840 x 2160
|
||
pixels. When you plot the start and stop coordinates, the display is
|
||
clearly distinguishable. However, a lot of points are outside of the
|
||
display range. This can happen, when the art objects are scaled and then
|
||
moved to the very edge of the table. Then it will record pixels outside
|
||
of the table. These are actually valid data points and I will leave them
|
||
as is.
|
||
|
||
``` r
|
||
datlogs <- read.table("code/results/event_logfiles_2024-02-21_16-07-33.csv", sep = ";",
|
||
header = TRUE)
|
||
|
||
par(mfrow = c(1, 2))
|
||
plot(y.start ~ x.start, datlogs)
|
||
abline(v = c(0, 3840), h = c(0, 2160), col = "blue", lwd = 2)
|
||
plot(y.stop ~ x.stop, datlogs)
|
||
abline(v = c(0, 3840), h = c(0, 2160), col = "blue", lwd = 2)
|
||
```
|
||
|
||
![](README_files/figure-gfm/xycoord-1.png)<!-- -->
|
||
|
||
``` r
|
||
aggregate(cbind(x.start, x.stop, y.start, y.stop) ~ 1, datlogs, mean)
|
||
```
|
||
|
||
## x.start x.stop y.start y.stop
|
||
## 1 1978.202 1975.876 1137.481 1133.494
|
||
|
||
## Pop-ups from glossar cannot be assigned to a specific item
|
||
|
||
All the information, pictures and texts for the topics and pop-ups are
|
||
stored in
|
||
`/data/haum/ContentEyevisit/eyevisit_cards_light/<item_number>`. Among
|
||
other things, each folder contains XML-files with the information about
|
||
any technical terms that can be opened from the hypertexts on the topic
|
||
cards. Often these information are item dependent and then the
|
||
corresponding XML-file is in the folder for this item. Sometimes,
|
||
however, more general terms can be opened. In order to avoid multiple
|
||
files containing the same information, these were stored in a folder
|
||
called `glossar` and get accessed from there. The raw log files only
|
||
contain the path to this glossar entry and did not record from which
|
||
item it was accessed. I tried to assign these glossar entries to the
|
||
correct items. The (very heuristic) approach was this:
|
||
|
||
1. Create a lookup table with all XML-file names (possible pop-ups)
|
||
from the glossar folder and what items possibly call them. This was
|
||
stored as an `RData` object for easier handling but should maybe be
|
||
stored in a more interoperable format.
|
||
|
||
2. I went through all possible pop-ups in this lookup table and stored
|
||
the items that are associated with it.
|
||
|
||
3. I created a sub data frame without move events (since they can never
|
||
be associated with a pop-up) and went through every line and looked
|
||
up if an item and a topic card had been opened. If this was the case
|
||
and a glossar entry came up before the item was closed again, I
|
||
assigned this item to the glossar entry.
|
||
|
||
This is heuristic since it is possible that several topic cards from
|
||
different items are opened simultaneously and the glossar pop-up could
|
||
be opened from either one (it could even be more than two, of course).
|
||
In these cases the item that was opened closest to the glossar pop-up
|
||
has been assigned, but this can never be completely error free.
|
||
|
||
And this heuristic only assigns a little more than half of the glossar
|
||
entries. Since my heuristic only looks for the last item that has been
|
||
opened and if this item is a possible candidate it misses all glossar
|
||
pop-ups where another item has been opened in between. This is still an
|
||
open TODO to write a more elaborate algorithm.
|
||
|
||
All glossar pop-ups that do not get matched with an item are removed
|
||
from the data set with a warning if the argument `glossar = TRUE` is
|
||
set. Otherwise the glossar entries will be ignored completely.
|
||
|
||
## Assign a `case` variable based on “time heuristic”
|
||
|
||
One thing needed in order to work with the data set and use it for
|
||
machine learning algorithms like process mining, is a variable that
|
||
tries to identify a case. A case variable will structure the data frame
|
||
in a way that navigation behavior can actually be investigated. However,
|
||
we do not know if several people are standing around the table
|
||
interacting with it or just one very active person. The simplest way to
|
||
define a case variable is to just use a time limit between events. This
|
||
means that when the table has not been interacted with for, e.g., 20
|
||
seconds than it is assumed that a person moved on and a new person
|
||
started interacting with the table. This is the easiest heuristic and
|
||
implemented at the moment. Process mining shows that this simple
|
||
approach works in a way that the correct process gets extracted by the
|
||
algorithm.
|
||
|
||
In order to investigate user behavior on a more fine grained level, it
|
||
will be necessary to come up with a more elaborate approach. A better,
|
||
still simple approach, could be to use this kind of time limit and
|
||
additionally look at the distance between items interacted with within
|
||
one time window. When items are far apart it seems plausible that more
|
||
than one person interacted with them. Very short time lapses between
|
||
events on different items could also be an indicator that more than one
|
||
person is interacting with the table.
|
||
|
||
## Assign a `path` variable
|
||
|
||
The `path` variable is supposed to show one interaction trace with one
|
||
artwork. Meaning it starts when an artwork is touched or flipped and
|
||
stops when it is closed again. It is easy to assign a path from flipping
|
||
a card over opening (maybe several) topics and pop-ups for this artwork
|
||
card until closing this card again. But one would like to assign the
|
||
same path to move events surrounding this interaction. Again, this is
|
||
not possible in an algorithmic way but only heuristically.
|
||
|
||
Again, I used a time cutoff for this. First, if a `move` event occurs,
|
||
it is checked, if the same item has been flipped less than 20 seconds
|
||
beforehand. If yes, the same path indicator is assigned to this `move`.
|
||
If not, temporarily a new “move indicator” is assigned. Then, a
|
||
“backward pass” is applied, where it is checked if the same item is
|
||
opened less than 20 seconds *after* the event occurs. If yes, that path
|
||
indicator is assigned. For all the remaining moves, a new path number is
|
||
assigned. This corresponds to items being moved without being flipped.
|
||
|
||
## A `move` event does not record any change
|
||
|
||
Most of the events in the log files are move events. Additionally, many
|
||
of these move events are recorded but they do not indicate any change,
|
||
meaning the only difference is the timestamp. All other variables
|
||
indicating moves like `x.start` and `x.stop`, `rotation.start` and
|
||
`rotation.stop` etc. do not show *any* change. They represent about 2/3
|
||
of all move events. These events are probably short touches of the table
|
||
without an actual interaction. They were therefore removed from the data
|
||
set.
|
||
|
||
## Card indices go from 0 to 7 (instead of 0 to 5 as expected)
|
||
|
||
In the beginning I thought that the number for topics was the index of
|
||
where the card was presented on the back of the item. But this is not
|
||
correct. It is the number of the topic. There are eight topics in total:
|
||
|
||
Indices for topics:
|
||
0 artist
|
||
1 thema
|
||
2 komposition
|
||
3 leben des kunstwerks
|
||
4 details
|
||
5 licht und farbe
|
||
6 extra info
|
||
7 technik
|
||
|
||
On the back of items, there can be between 2 to 6 topic cards. Several
|
||
of these topic cards can be about the same topic, e.g., there can be two
|
||
topic cards assigned to the topic `thema`. It is impossible to find out
|
||
if the same topic card was opened several times or if different topic
|
||
cards with the same topic were opened from the same item. See example
|
||
below for item “001”.
|
||
|
||
## item file_name topic
|
||
## 1 001 001_dargestellte.xml thema
|
||
## 2 001 001_thema1.xml thema
|
||
## 3 001 001_leben.xml leben des kunstwerks
|
||
## 4 001 001_leben3.xml leben des kunstwerks
|
||
## 5 001 001_thema2.xml thema
|
||
## 6 001 001_thema.xml thema
|
||
|
||
## New artworks “504” and “505” starting October 2022
|
||
|
||
When I read in the complete data frame for the first time, all of the
|
||
sudden there were 72 instead of 70 items. It seems like these two
|
||
artworks appear on October 21, 2022.
|
||
|
||
``` r
|
||
summary(as.Date(datraw[datraw$item %in% c("504", "505"), "date"]))
|
||
```
|
||
|
||
## Min. 1st Qu. Median Mean 3rd Qu. Max.
|
||
## "2022-10-21" "2023-01-11" "2023-03-08" "2023-03-09" "2023-05-21" "2023-07-05"
|
||
|
||
The artworks seem to be have updated in general after October 21, 2022.
|
||
The following table shows which items were presented in which years.
|
||
|
||
``` r
|
||
xtabs(~ item + lubridate::year(date.start), datlogs)
|
||
```
|
||
|
||
## lubridate::year(date.start)
|
||
## item 2016 2017 2018 2019 2020 2022 2023
|
||
## 1 277 4082 1912 1434 424 394 1315
|
||
## 3 485 6730 3126 2356 528 457 1124
|
||
## 19 714 8656 4028 2743 660 698 1595
|
||
## 20 595 8461 3996 2983 938 657 1355
|
||
## 24 497 6638 2912 2251 649 439 1028
|
||
## 27 567 5959 3112 2318 651 711 1324
|
||
## 28 601 9329 4394 3056 778 762 1570
|
||
## 29 425 6865 3830 2365 516 615 1174
|
||
## 31 289 4118 2051 1218 291 296 675
|
||
## 32 562 7016 3477 2253 726 766 1647
|
||
## 33 509 4936 2242 1449 555 358 666
|
||
## 36 434 4505 2276 1668 373 387 976
|
||
## 37 242 4478 2182 1554 339 423 1168
|
||
## 38 480 4617 2144 1397 371 381 784
|
||
## 39 395 3227 1313 1003 237 161 622
|
||
## 41 282 3329 1303 1022 225 209 701
|
||
## 42 203 3113 1307 903 242 191 421
|
||
## 43 115 2420 1089 806 176 219 486
|
||
## 45 1491 13561 5924 4474 966 585 1828
|
||
## 46 903 9181 5340 3812 961 944 1648
|
||
## 47 306 4949 2395 1510 750 297 675
|
||
## 48 723 10455 5384 4162 1328 948 2031
|
||
## 49 433 4326 2124 1414 434 431 809
|
||
## 51 564 7837 4577 2991 884 659 1370
|
||
## 52 447 5021 2104 1729 471 349 840
|
||
## 54 424 5068 2816 2008 529 370 918
|
||
## 55 358 4859 2069 1428 341 403 1303
|
||
## 57 860 14264 6625 5092 1410 1221 2714
|
||
## 60 555 6865 3539 2336 639 586 1415
|
||
## 62 547 6736 3803 2210 795 633 1322
|
||
## 63 251 3677 1827 1241 300 282 527
|
||
## 66 552 6004 2774 1977 505 373 932
|
||
## 69 394 3730 1827 1438 272 206 680
|
||
## 70 226 3766 1843 973 293 268 703
|
||
## 71 557 6160 2490 1846 570 323 839
|
||
## 72 426 6194 2857 2129 508 635 1553
|
||
## 73 432 6125 2880 1821 583 395 939
|
||
## 75 258 5885 2418 1562 369 257 645
|
||
## 76 861 12435 6253 4214 1753 1153 2268
|
||
## 77 816 8595 4197 2897 699 674 1452
|
||
## 78 410 5632 2498 1924 394 408 850
|
||
## 80 1650 25687 12429 7782 1975 1712 4433
|
||
## 83 644 8618 4720 3026 987 1027 2294
|
||
## 84 184 2121 1231 759 231 254 465
|
||
## 87 149 1618 722 632 99 0 0
|
||
## 88 513 6996 3493 2272 539 533 1420
|
||
## 89 214 2204 950 723 156 0 0
|
||
## 90 281 3756 1372 1143 403 320 932
|
||
## 93 613 8528 4224 3015 696 1174 2058
|
||
## 98 462 6662 3265 2565 704 670 1453
|
||
## 99 180 4162 1653 1454 363 411 868
|
||
## 101 414 4209 1859 1282 392 411 981
|
||
## 103 677 8758 4366 3165 1045 909 1871
|
||
## 104 423 5256 2381 1865 463 467 933
|
||
## 107 181 2101 1106 788 205 146 339
|
||
## 109 321 4001 1619 1106 292 188 453
|
||
## 110 489 5846 2785 2008 494 387 923
|
||
## 125 640 8435 4519 3334 926 0 0
|
||
## 129 598 11322 5046 3369 910 1131 1682
|
||
## 145 419 7821 3945 2694 706 740 1396
|
||
## 176 507 8465 3968 2787 687 552 1544
|
||
## 180 516 7563 3720 2765 585 550 1272
|
||
## 183 377 4014 1819 1741 346 251 675
|
||
## 187 340 4222 2165 1753 319 312 734
|
||
## 197 426 7710 3603 2510 671 602 1217
|
||
## 229 303 4872 2360 1891 482 389 1005
|
||
## 231 271 3606 1851 1239 318 236 467
|
||
## 501 1915 15968 7849 5060 1157 890 2989
|
||
## 502 1212 14550 7111 4749 1105 883 2752
|
||
## 503 1308 15218 8632 6399 1626 870 2558
|
||
## 504 0 0 0 0 0 363 662
|
||
## 505 0 0 0 0 0 426 1533
|
||
|
||
It shows that the artworks haven been updated after the Corona pandemic.
|
||
I think, the table was also moved to a different location at that point.
|