The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
otpr is an R package that provides a wrapper for the
OpenTripPlanner (OTP)
API. To use otpr you will need a running instance of
OTP. The purpose of the package is to submit a query to the relevant OTP
API resource, parse the OTP response and return useful R objects. The
package is aimed at both new and expert users of OTP. The key parameters
needed to query each supported API resource are provided as (or via)
otpr function arguments. The argument values submitted
by the user are comprehensively checked prior to submission to OTP to
ensure that they are valid and make sense in combination, with feedback
provided as appropriate. This makes the package ideal for new users of
OTP (especially when used with the accompanying
tutorial). Advanced users can provide any additional API parameters
they wish via the extra.params
argument. These parameters
are passed directly to the OTP API without checks.
otpr currently supports the following OTP API resources:
This package will be useful to researchers and transport planners who want to use OTP to generate trip data for accessibility analysis or to derive variables for use in transportation models.
otpr fully supports OTP versions 1 and 2. Please note the following :
maxWalkDistance
parameter is treated as a
hard limit when the mode is either WALK or (strangely) CAR or BICYCLE.
This could result in no itinerary being returned if the parameter is
change from its default (the default is NULL, which means that the OTP
internal default of unlimited takes effect). This is different from the
behaviour of OTPv1 where this parameter is effectively ignored when the
mode is WALK and not applied at all to BICYCLE or CAR trips. See: http://docs.opentripplanner.org/en/latest/OTP2-MigrationGuide/#rest-api
for more information.# Install from CRAN
# install.packages("otpr")
To get a bug fix, or use a feature from the development version, you can install otpr from GitHub. See NEWS for changes since last release.
# install.packages("devtools")
# devtools::install_github("marcusyoung/otpr")
library(otpr)
The first step is to call otp_connect()
, which defines
the parameters needed to connect to a router on a running OTP instance.
The function can also confirm that the router is reachable.
# For a basic instance of OTP running on localhost with standard ports and a 'default' router
# this is all that's needed
<- otp_connect()
otpcon #> http://localhost:8080/otp is running OTPv1
#> Router http://localhost:8080/otp/routers/default exists
If the time zone of an OTP graph differs from the time zone
of the local system running otpr then by default
returned trip start and end times will be expressed in the local
system’s time zone and not the time zone of the graph. This is because
the OTP API returns EPOCH values and the conversion to date and time
format occurs on the local system. A ‘timeZone’ column is included in
returned dataframes that contain start and end times to make this
explicit. If you wish to have start and end times expressed in the time
zone of the graph, the tz
argument can be specified when
calling the otp_connect()
function. This must be a valid
time zone (checked against the vector returned by
OlsonNames()
); for example: “Europe/Berlin”.
The functions that query the OTP API return a list of three or more elements. The first element is an errorId - with the value “OK” or the error code returned by OTP. If errorId is “OK”, the second element will contain the query response; otherwise it will contain the OTP error message. There may be further list elements forming the query response. The last element will be the query URL that was submitted to the OTP API (for information and useful for troubleshooting).
To get the trip distance in metres between an origin and destination
on the street and/or path network use otp_get_distance()
.
You can specify the required mode: CAR (default), BICYCLE or WALK are
valid. The trip information will relate to the first itinerary
that was returned by the OTP server.
# Distance between Manchester city centre and Manchester airport by CAR
otp_get_distance(
otpcon,fromPlace = c(53.48805,-2.24258),
toPlace = c(53.36484,-2.27108)
)#> $errorId
#> [1] "OK"
#>
#> $distance
#> [1] 29050.21
#>
#> $query
#> [1] "http://localhost:8080/otp/routers/default/plan?fromPlace=53.48805,-2.24258&toPlace=53.36484,-2.27108&mode=CAR"
# Now for BICYCLE
otp_get_distance(
otpcon,fromPlace = c(53.48805,-2.24258),
toPlace = c(53.36484,-2.27108),
mode = "BICYCLE"
)#> $errorId
#> [1] "OK"
#>
#> $distance
#> [1] 16028.57
#>
#> $query
#> [1] "http://localhost:8080/otp/routers/default/plan?fromPlace=53.48805,-2.24258&toPlace=53.36484,-2.27108&mode=BICYCLE"
To get the trip duration in minutes between an origin and destination
use otp_get_times()
. You can specify the required mode:
TRANSIT (all available transit modes), BUS, RAIL, SUBWAY, TRAM, CAR,
BICYCLE, and WALK are valid. All the public transit modes automatically
allow WALK. There is also the option to combine TRANSIT with
BICYCLE.
# Time between Manchester city centre and Manchester airport by BICYCLE
otp_get_times(
otpcon,fromPlace = c(53.48805,-2.24258),
toPlace = c(53.36484,-2.27108),
mode = "BICYCLE"
)#> $errorId
#> [1] "OK"
#>
#> $duration
#> [1] 59.75
#>
#> $query
#> [1] "http://localhost:8080/otp/routers/default/plan?fromPlace=53.48805,-2.24258&toPlace=53.36484,-2.27108&mode=BICYCLE&date=01-06-2022&time=19:07:48&walkReluctance=2&waitReluctance=1&arriveBy=FALSE&transferPenalty=0&minTransferTime=0"
# By default the date and time of travel is taken as the current system date and
# time. This can be changed using the 'date' and 'time' arguments
otp_get_times(
otpcon,fromPlace = c(53.48805,-2.24258),
toPlace = c(53.36484,-2.27108),
mode = "TRANSIT",
date = "01-19-2021",
time = "07:15:00"
)#> $errorId
#> [1] "OK"
#>
#> $duration
#> [1] 39.65
#>
#> $query
#> [1] "http://localhost:8080/otp/routers/default/plan?fromPlace=53.48805,-2.24258&toPlace=53.36484,-2.27108&mode=TRANSIT,WALK&date=01-19-2021&time=07:15:00&walkReluctance=2&waitReluctance=1&arriveBy=FALSE&transferPenalty=0&minTransferTime=0"
To get more information about the trip when using transit modes,
otp_get_times()
can be called with the detail
argument set to TRUE. The trip duration (minutes) is then further broken
down by time on transit, walking time (from/to and between stops),
waiting time (when changing transit vehicle or mode), and number of
transfers (when changing transit vehicle or mode). By default the
function returns trip information for the first itinerary suggested by
the OTP server. However, additional itineraries can be requested by
specifying the maxItineraries
argument. The function will
return every available itinerary suggested by the OTP server, in order,
up to the value of maxItineraries
(the default is
1).
# Time between Manchester city centre and Manchester airport by TRANSIT with detail
otp_get_times(
otpcon,fromPlace = c(53.48805,-2.24258),
toPlace = c(53.36484,-2.27108),
mode = "TRANSIT",
date = "01-19-2021",
time = "07:15:00",
detail = TRUE,
maxItineraries = 1
)#> $errorId
#> [1] "OK"
#>
#> $itineraries
#> start end timeZone duration walkTime
#> 1 2021-01-19 07:16:03 2021-01-19 07:55:42 Europe/London 39.65 8
#> transitTime waitingTime transfers
#> 1 31 0.65 1
#>
#> $query
#> [1] "http://localhost:8080/otp/routers/default/plan?fromPlace=53.48805,-2.24258&toPlace=53.36484,-2.27108&mode=TRANSIT,WALK&date=01-19-2021&time=07:15:00&walkReluctance=2&waitReluctance=1&arriveBy=FALSE&transferPenalty=0&minTransferTime=0"
To get information about each leg of transit-based trips,
otp_get_times()
can be called with both the
detail
and includeLegs
arguments set to TRUE.
A column called ‘legs’ will then be included in the itineraries
dataframe. This column contains a nested ‘legs’ dataframe for each
itinerary. The ‘legs’ dataframe contains a row for each leg of the trip.
The information provided for each leg includes start and end times,
duration, distance, mode, route details, agency details, and stop names.
There is also a column called ‘departureWait’ which is the length of
time in minutes required to wait before the start of a leg. The sum of
‘departureWait’ will equal the total waiting time for the itinerary.
# Time between Manchester city centre and Manchester airport by TRANSIT with detail and legs
<- otp_get_times(
trip
otpcon,fromPlace = c(53.48805,-2.24258),
toPlace = c(53.36484,-2.27108),
mode = "TRANSIT",
date = "01-19-2021",
time = "07:15:00",
detail = TRUE,
includeLegs = TRUE,
maxItineraries = 2
)
# Legs for the first itinerary returned by OTP (first 9 columns)
$itineraries$legs[[1]][1:9]
trip#> startTime endTime timeZone mode departureWait
#> 1 2021-01-19 07:16:03 2021-01-19 07:18:59 Europe/London WALK 0.00
#> 2 2021-01-19 07:19:00 2021-01-19 07:28:00 Europe/London TRAM 0.02
#> 3 2021-01-19 07:28:00 2021-01-19 07:29:23 Europe/London WALK 0.00
#> 4 2021-01-19 07:30:00 2021-01-19 07:52:00 Europe/London RAIL 0.62
#> 5 2021-01-19 07:52:01 2021-01-19 07:55:42 Europe/London WALK 0.02
#> duration distance routeType routeId
#> 1 2.93 197.370 NA <NA>
#> 2 9.00 1424.641 0 2:METLYELL:I:2021-01-02
#> 3 1.38 106.629 NA <NA>
#> 4 22.00 14921.306 2 1:7285
#> 5 3.68 246.086 NA <NA>
The otp_get_isochrone()
function can be used to get one
or more travel time isochrones in either GeoJSON or SF format. These are
only available for transit or walking modes (OTP limitation). They can
be generated either from (default) or to the specified
location.
# 900, 1800 and 2700 second isochrones for travel *to* Manchester Airport by any transit mode
<- otp_get_isochrone(
my_isochrone
otpcon,location = c(53.36484, -2.27108),
fromLocation = FALSE,
cutoffs = c(900, 1800, 2700),
mode = "TRANSIT",
date = "01-19-2021",
time = "07:15:00"
)
# function returns a list of two elements
names(my_isochrone)
#> [1] "errorId" "response" "query"
# now write the GeoJSON (in the "response" element) to a file so it can be opened in QGIS (for example)
write(my_isochrone$response, file = "my_isochrone.geojson")
# request format as "SF"
<- otp_get_isochrone(
my_isochrone
otpcon,location = c(53.36484, -2.27108),
format = "SF",
fromLocation = FALSE,
cutoffs = c(900, 1800, 2700, 3600, 4500, 5400),
mode = "TRANSIT",
date = "01-19-2021",
time= "07:15:00",
maxWalkDistance = 1600,
walkReluctance = 5,
minTransferTime = 600
)
# plot using tmap package
library(tmap)
library(tmaptools)
# set bounding box
<- bb(my_isochrone$response)
bbox # get OSM tiles
<- read_osm(bbox, ext = 1.1)
osm_man # plot isochrones
tm_shape(osm_man) +
tm_rgb() +
tm_shape(my_isochrone$response) +
tm_fill(
col = "time",
alpha = 0.8,
palette = "-plasma",
n = 6,
style = "cat",
title = "Time (seconds)"
+ tm_layout(legend.position = c("left", "top"), legend.bg.color = "white",
) main.title = "15-90 minute isochrone to Manchester Airport",
main.title.size = 0.8)
If you wish to calculate the travel time from one or more origins to
many destinations, querying the OTP journey planning API (using
otp_get_times()
) may not be the best option as it requires
multiple requests to the API which can be very inefficient. An
alternative is to use the OTP surface analysis feature, which enables
you to calculate the travel time from an origin to thousands of
destinations in about the same time it takes to perform a single
origin:destination lookup. This is achieved by generating a surface for
an origin which contains the travel time to every geographic coordinate
that can be reached from that origin by the specified transport mode
(though note that there is a hard-coded surface cutoff of 120 minutes
set in OTP).
Once the surface has been generated, it can be evaluated to rapidly retrieve the travel times from the origin to each ‘destination’ point provided in a supplied CSV file. This file, known as a pointset, can also contain the quantities of one or more ‘opportunities’ that are associated with each point. During evaluation, OTP will sum the opportunities available at each additional minute of travel time, and otpr generates a cumulative sum of the opportunities. For example, you might have a pointset of workplace zones and a column with the number of jobs within each zone. The output will be a cumulative sum of jobs reachable for each minute of travel time by the mode specified when the surface was generated.
Before a surface analysis can be performed, OTP must be started with
the --analyst
switch. To evaluate one or more pointsets
against a surface, the location of the pointset CSV file(s) must be
specified using the --pointSets
switch followed by the file
path. For more information about the required file format for a pointset
CSV file and the switches to start OTP with, see: http://docs.opentripplanner.org/en/dev-1.x/Surface/.
Once an OTP instance has been started in analysis mode, a surface can
be generated by calling the otp_create_surface()
function.
The arguments that can be passed to this function are very similar to
otp_get_times()
. The main differences are the exclusion of
the toPlace
argument and two new function-specific
arguments - getRaster
and rasterPath
. These
are used to request a raster image (a geoTIFF file) of the generated
surface which is saved to the local file system. If the surface is
successfully generated, the function will return the OTP ID number of
the surface - this will be needed for any subsequent evaluation against
the surface.
There are a few things to note regarding the raster image that OTP creates:
# create surface with origin as Manchester city centre
otp_create_surface(otpcon, fromPlace = c(53.479167,-2.244167), date = "01-19-2021",
time = "08:00:00", mode = "TRANSIT", maxWalkDistance = 1600, getRaster = TRUE,
rasterPath = "C:/temp")
#> $errorId
#> [1] "OK"
#>
#> $surfaceId
#> [1] 0
#>
#> $surfaceRecord
#> [1] "{\"id\":0,\"params\":{\"mode\":\"TRANSIT,WALK\",\"date\":\"01-19-2021\",\"walkReluctance\":\"2\",\"arriveBy\":\"FALSE\",\"minTransferTime\":\"0\",\"fromPlace\":\"53.479167,-2.244167\",\"batch\":\"TRUE\",\"transferPenalty\":\"0\",\"time\":\"08:00:00\",\"maxWalkDistance\":\"1600\",\"waitReluctance\":\"1\"}}"
#>
#> $rasterDownload
#> [1] "C:/temp/surface_0.tiff"
#>
#> $query
#> [1] "http://localhost:8080/otp/surfaces?fromPlace=53.479167,-2.244167&mode=TRANSIT,WALK&date=01-19-2021&time=08:00:00&maxWalkDistance=1600&walkReluctance=2&waitReluctance=1&transferPenalty=0&minTransferTime=0&arriveBy=FALSE&batch=TRUE"
Once a surface has been generated, it can be evaluated using the
otp_evaluate_surface()
function. The ID of the surface
(returned by the otp_create_surface()
function) and the
name of a pointset (which is the pointset file name excluding the
extension) must be provided as arguments. The function will return one
or more dataframes for each of the ‘opportunity’ columns in the pointset
CSV file. Each of these dataframes contains four columns:
As noted above, there is a cutoff of 120 minutes for the surface and only data for minutes up to 120 are returned by OTP. This limit is hard-coded in OTP.
If the optional detail
argument is set to TRUE, then a
dataframe called ‘times’ containing the time taken (in seconds) to reach
each point in the pointset file will also be returned. If a point is not
reachable the time will be recorded as NA. This could mean that the
point is genuinely unreachable by the mode (e.g. if it is CAR mode and
the location is only accessible by walking or cycling) or that the point
falls outside of the surface (which might be due to the extent of the
network or the 120 minute limit to the surface extent). The ‘times’
table can be joined with the data from the original pointset file to get
the travel time from the origin to each destination.
<- otp_evaluate_surface(otpcon, surfaceId = 0, pointset = "gm-jobs", detail = TRUE)
response # Look at first few rows of the job opportunity data
head(response$jobs)
#> minutes counts sums cumsums
#> 1 1 0 219 219
#> 2 2 0 441 660
#> 3 3 1 637 1297
#> 4 4 3 1656 2953
#> 5 5 4 2905 5858
#> 6 6 9 4848 10706
# And the last few rows
tail(response$jobs)
#> minutes counts sums cumsums
#> 101 101 1 401 1225495
#> 102 102 1 329 1225824
#> 103 103 1 560 1226384
#> 104 104 2 817 1227201
#> 105 105 0 458 1227659
#> 106 106 1 198 1227857
# Number of job opportunities accesible with 60 minutes from origin by TRANSIT
$jobs$cumsums[60]
response#> [1] 927699
# And a peak at the times dataframe
head(response$times)
#> point time
#> 1 1 3641
#> 2 2 4351
#> 3 3 4835
#> 4 4 5058
#> 5 5 4653
#> 6 6 4244
The example function calls shown above can be extended by passing
additional parameters to the OTP API. This includes the advanced option
to pass any parameter that is not an otpr argument
directly to the OTP API via the extra.params
argument.
Further information is available in the documentation for each
function:
# get help on using the otp_get_times() function
?otp_get_times
If you are new to OTP, then the best place to start is to work through the tutorial, OpenTripPlanner Tutorial - creating and querying your own multi-modal route planner. This includes everything you need, including example data, to get started with OTPv1. The tutorial also has examples of using otpr functions, and helps you get the most from the package, for example using it to populate an origin-destination matrix.
For more guidance on how otpr, in conjunction with OTP, can be used to generate data for input into models, you may be interested in: An automated framework to derive model variables from open transport data using R, PostgreSQL and OpenTripPlanner.
Please cite otpr if you use it. Get citation
information using: citation(package = 'otpr')
:
citation(package = 'otpr')
#>
#> To cite the otpr package in publications, please use the following. You
#> can obtain the DOI for a specific version from:
#> https://zenodo.org/record/4065250
#>
#> Marcus Young (2020). otpr: An API wrapper for OpenTripPlanner. R
#> package version 0.5.0. https://doi.org/10.5281/zenodo.4065250
#>
#> A BibTeX entry for LaTeX users is
#>
#> @Manual{,
#> author = {{Marcus Young}},
#> title = {{otpr: An API wrapper for OpenTripPlanner}},
#> year = {2020},
#> note = {{R package version 0.5.0}},
#> doi = {10.5281/zenodo.4065250},
#> }
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.