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Migratory fishes population are vulnerable as they are often more prone to human impact when migrating in rivers and to the ocean (McDowall, 1992). They are often counted at stations when they perform the migrations at some of their lifestages, and these counts provide valuable indices to the population size and trend. The objective of the stacomi project is to provide a common database for people monitoring fish migration, so that data from watershed are shared, and stocks exchanging between different basins are better managed. The stacomi database, is an open-source database, it managed with a JAVA interface, and results from that database are treated directly with the stacomiR project.
The package is available from CRAN, a development version is available from R-Forge.
Launch the graphical interface
The program can be launched with options
stacomiR.dbname
: databasenamestacomiR.host
: the name of the host, default to
[“localhost”]stacomiR.port
: the name of the port, default to
[“5432”]stacomiR.user
: a string with the user name
e.g. [“postgres”]stacomiR.password
: a string with the user passwordstacomiR.ODBClink
: a string with name of the ODBC link,
this options is used by stacomirtools to use ODBC connexion it is
currently deprecatedstacomiR.path
: a string with the path to where some
output are written, defaut ‘~’ path to the user document folder in
windowsstacomiR.printqueries
: a boolean, default FALSE, with
the side effect of printing queries to the console#here is an example to connect with interactive use
options(
stacomiR.dbname = "bd_contmig_nat",
stacomiR.host = readline(prompt = "Enter host: "),
stacomiR.port = "5432",
stacomiR.user = readline(prompt = "Enter user: "),
stacomiR.password = readline(prompt = "Enter password: ")
)
# the schema of connection is passed by sch
stacomi(database_expected = TRUE, sch= "iav")
The open source postgresql database comprises a common schema with dictionaries, and different schema for different users. Each user can save its own schema and send it to others. The database comprises tables related to infrastructure, operations and fish samples. Contact the authors to get a copy of the database.
A migration report is always built on a section of a river, this is called the station. A station of fish migration monitoring is a section of a watercourse where fish upstream or downstream migration is monitored. The station covers the whole section of a single river, but can extend to several natural or artificial channels. A station consists physically of as many dams as hydrographic sections monitored (river, channels, etc.). According to the local settings, it corresponds to one river location with a counting device, or to one or several dams. For example, in the figure below we can see a station with three crossing device (DF 1 to 3) and two counting device (DC 1 to 2), the first one beeing a trap counting device (DC1) and the other a video-counting device (DC2).
The concept of dam used in the context of fish migration monitoring database refers to a system blocking or guiding the migratory flow like :
weir,
electric guide barrier,
netting dam,
etc.
A crossing device (DF) is a passageway that allows and concentrates the migratory flow between upstream and downstream sections of a dam. They can be of various type :
fishway,
spillway,
fish elevator,
eel trapping ladder,
etc.
It is possible to have more than one crossing device on the same dam.
A counting device (DC) is a set of equipment installed on a crossing device used to monitor fish migration. It can be :
a video counting device,
a trap,
an accoustic counting device,
…
An operation corresponds to the monitoring of a counting device during a time span.
A sample corresponds to a batch of fishes passing during a monitoring operation. Sample characteristics (length, weight, sex, body measurements) are attached to the sample. For each sample the species and the stage (which corresponds to a maturation stage and is related to migratory behaviour) is recorded. Samples correspond to multiple fish of the same species and stage or to individual records.
The database also handles, marking-recapture operations, pathologies, samples collection (scale, fin sample for genetic…), fate of fishes (released, death, farmed, etc.), etc… Some tables are also used to insert information about environmental condition such as turbidity, atmospheric pressure, temperature, flow …
The package relies on S4 classes. Referential classes are used to access data from the database (taxa, stages, counting devices…). Report classes are built from referential classes and have different methods to access the database connect methods, generate calculations calcule method, or plot results. For instance, the migration report class comprises slots for :
DC The counting device (camera, trap, acoustic device…)
taxa The species list from the database and the taxa selected
stage The stages list from the database and the stage selected
starting date The date of beginning
ending date The last date of the report
Read the help files e.g. ? report_mig
to get
documentation on the following classes.
Class | Command | description |
---|---|---|
report_mig | new("report_mig") |
Migration report (single) |
report_mig_mult | new("report_mig_mult") |
Migr. (several DC,taxa…) |
report_annual | new("report_annual") |
Multi year migration counts |
report_dc | new("report_dc") |
Counting device operation |
report_df | new("report_df") |
Fishway operation |
report_mig_env | new("report_env") |
Migration crossed with env. factors |
report_mig_char | new("report_df") |
Migration with fish characteristics |
report_mig_interannual | new("report_mig_interannual") |
Comp. between years |
report_sample_char | new("report_sample_char") |
Sample characteristics |
report_ge_weight | new("report_ge_weight") |
Trend in glass eel weight |
report_silver_eel | new("report_siver_eel") |
Silver eel migration & stage |
report_sea_age | new("report_sea_age") |
Set sea age for Salmon |
report_species | new("report_species") |
Species composition |
Examples are provided with each of the class, you can access them
simply by typing ? report_mig_mult
. The program is intented
to be used in conjuntion with the database, to test it without access,
use the argument database_expected=FALSE
.
## launches the application in the command line without connection to the database
stacomi(database_expected=FALSE)
The following code is only run when there is a connection to the
database. The program will create an object of the class
report_mig_mult, and run it for several DC, here 5 is a vertical slot
fishway, and 6 and 12 are two glass eel trapping ladder located at the
Arzal dam in the Vilaine river (France). We are evaluating the migration
of all stages of eel (glass eel CIV, yellow eel AGJ and silver eel AGG).
Glass eel and yellow eel migrate to the watershed while silver eels are
migrating back to the ocean. Data are loaded from the database with the
charge
method and the calcule
method will
interpolate daily migration from monitoring operations which do not
necessarily span a day, and convert the glass eel weight in numbers.
require(stacomiR)
stacomi(
database_expected=TRUE)
r_mig_mult=new("report_mig_mult")
r_mig_mult=choice_c(r_mig_mult,
dc=c(5,6,12),
taxa=c("Anguilla anguilla"),
stage=c("AGG","AGJ","CIV"),
datedebut="2011-01-01",
datefin="2011-12-31")
r_mig_mult<-charge(r_mig_mult)
# launching charge will also load classes associated with the report
# e.g. report_ope, report_df, report_dc
r_mig_mult<-connect(r_mig_mult)
# calculations
r_mig_mult<-calcule(r_mig_mult,silent=TRUE)
The previous line generates data not only about the report_mig_mult class, but also runs dependent classes which describe how the fishway (DF) and counting devices (DC) have been operated. Sometimes there are no data but only because the camera was not working. There are also information about the operations (e.g. periods at which a trap content has been evaluated). Here we load what would have been generated if we had run the previous lines.
One graph per DC, taxa and stage. Below as an example, the glass eel migration in weight and number (top), the periods and type of operation for DF and DC, and the operation (trapping periods) (middle), a summary of migration per month (bottom).
# Without a connection at the database we can launch these lines to generate the graph
# To obtain titles in french use Sys.setenv(LANG = "fr")
# the
require(stacomiR)
stacomi(
database_expected=FALSE)
data("r_mig_mult")
data("r_mig_mult_ope")
assign("report_ope",r_mig_mult_ope,envir=envir_stacomi)
data("r_mig_mult_df")
assign("report_df",r_mig_mult_df,envir=envir_stacomi)
data("r_mig_mult_dc")
assign("report_dc",r_mig_mult_dc,envir=envir_stacomi)
# The two lines below avoid an error in MacOSX, the r_mig_mult currently has CET
# which for some reason provides a failure when testing the vignette in MaxOSX (twice the same date in seq.POSIXt)
attr(r_mig_mult@data$ope_date_debut, "tzone") <- "UTC"
attr(r_mig_mult@data$ope_date_fin, "tzone") <- "UTC"
r_mig_mult <- calcule(r_mig_mult,silent=TRUE)
# restrict to glass eel
r_mig_mult@stage@stage_selected <- r_mig_mult@stage@stage_selected[3]
r_mig_mult@dc@dc_selected <- r_mig_mult@dc@dc_selected[3]
r_mig_mult <- calcule(r_mig_mult,silent=TRUE)
plot(r_mig_mult, plot.type="standard", silent=TRUE)
Summary of migration for different stages and counting devices
This section provides a short example for the function calculating
Durif’s stages. Those maturity stages for silver eels are calculated
from body characteristics. The dataset coef_durif
corresponds to classification scores are calculated by multiplying the
metrics BL = body length, W = weight, MD = mean eye diameter (Dv+Dh)/2,
and FL length of the pectoral fin, with each parameter p as
S=Constant+BLp(bl)+Wp(W)… The function
fun_stage_durif
choose the stage achieving the highest
score (Durif
et al., 2009)
require(stacomiR)
data("coef_durif")
# load a dataset of class report_silver_eel with data slot already prepared
# here is an example of output
data("r_silver")
r_silver <- calcule(r_silver)
plot(r_silver, plot.type="3")
#######################################
# To use the function fun_stage_durif manually
# create a matrix with columns BL","W","Dv","Dh","FL"
#############################################
# here it is extracted from the data at hand
silver_eel<-as.matrix(r_silver@calcdata[[1]][,c("BL","W","Dv","Dh","FL")])
head(silver_eel) # to see the first lines
#> BL W Dv Dh FL
#> 25710 830 1074 8.14 8.70 39.79
#> 25711 714 740 8.24 8.52 38.04
#> 25712 720 755 6.92 6.87 34.01
#> 25713 860 1101 10.53 10.43 44.47
#> 25714 716 752 7.42 8.76 33.78
#> 25715 690 622 7.83 9.25 29.58
stage <- fun_stage_durif(silver_eel) # apply the function to the matrix
stage[1:10] # look at the first 10 elements in vector silver
#> 25710 25711 25712 25713 25714 25715 25716 25717 25718 25719
#> "FIII" "FIII" "FIII" "FIV" "FIII" "FIII" "FV" "FV" "FIII" "FIII"
The STACOMI project is released under GPL-2.
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.