Testing atlantisom: generate survey sampled length comps for Northeast US Atlantis
Sarah Gaichas and Christine Stawitz
15 May, 2019
Introduction
This page has visualizations for the NEUS model example, test03032016 (note! a not fully calibrated model). For full explanation of methods, see the file linked at the beginning of each section.
Simulate a survey part 4: sample for length composition
Full methods are explained here.
To create a survey, the user specifies the timing of the survey, which species are captured, the spatial coverage of the survey, the species-specific survey efficiency (“q”), and the selectivity at age for each species.
# make defaults that return a standard survey, implement in standard_survey
# users need to map their species groups into these general ones
# large pelagics/reef associated/burrowers/otherwise non-trawlable
# pelagics
# demersals
# selected flatfish
if(initNOBA) funct.groups <- rename(funct.groups, GroupType = InvertType)
survspp <- funct.groups$Name[funct.groups$IsTurnedOn==1 &
funct.groups$GroupType %in% c("FISH", "SHARK")]
if(initCCA) { #Sarah's CCA Grouping
nontrawl <- c("Shark_C","Yelloweye_rockfish","Benthopel_Fish","Pisciv_S_Fish",
"Pisciv_T_Fish","Shark_D","Shark_P")
pelagics <- c("Pisciv_V_Fish","Demersal_S_Fish","Pacific_Ocean_Perch","Mesopel_M_Fish",
"Planktiv_L_Fish","Jack_mackerel","Planktiv_S_Fish","Pacific_sardine",
"Anchovy","Herring","Pisciv_B_Fish")
demersals <- c("Demersal_P_Fish","Planktiv_O_Fish","Demersal_D_Fish",
"Demersal_DC_Fish","Demersal_O_Fish","Darkblotched_rockfish",
"Demersal_F_Fish","Demersal_E_Fish","Bocaccio_rockfish",
"Demersal_B_Fish","Shark_R","Mesopel_N_Fish","Shark_B","Spiny_dogfish",
"SkateRay")
selflats <- c("Pisciv_D_Fish", "Arrowtooth_flounder","Petrale_sole")
}
if(initNEUS) { # Sarah's NEUS Grouping
nontrawl <- c("Pisciv_T_Fish", "Shark_D", "Shark_P", "Reptile", "Mesopel_M_Fish")
pelagics <- c("Planktiv_L_Fish", "Planktiv_S_Fish", "Benthopel_Fish", "Pisciv_S_Fish")
demersals <- c("Pisciv_D_Fish", "Demersal_D_Fish","Demersal_E_Fish",
"Demersal_S_Fish","Demersal_B_Fish","Demersal_DC_Fish",
"Demersal_O_Fish","Demersal_F_Fish",
"Shark_B", "SkateRay")
selflats <- c("Pisciv_B_Fish")
}
if(initNOBA) { # Sarah's NOBA Grouping
nontrawl <- c("Sharks_other", "Pelagic_large","Mesop_fish")
pelagics <- c("Pelagic_small","Redfish_other","Mackerel","Haddock",
"Saithe","Redfish","Blue_whiting","Norwegian_ssh","Capelin")
demersals <- c("Demersals_other","Demersal_large","Flatfish_other","Skates_rays",
"Green_halibut","North_atl_cod","Polar_cod","Snow_crab")
selflats <- c("Long_rough_dab")
}The following settings are for our example standard survey once per year, most areas, with mixed efficiency and selectivity:
# general specifications for bottom trawl survey, with items defined above commented out to avoid wasting time loading already loaded files:
# once per year at mid year
# generalized timesteps all models
runpar <- load_runprm(d.name, run.prm.file)
noutsteps <- runpar$tstop/runpar$outputstep
stepperyr <- if(runpar$outputstepunit=="days") 365/runpar$toutinc
midptyr <- round(median(seq(1,stepperyr)))
annualmidyear <- seq(midptyr, noutsteps, stepperyr)
# ~75-80% of boxes (leave off deeper boxes?)
boxpars <- load_box(d.name, box.file)
boxsurv <- c(2:round(0.8*(boxpars$nbox - 1)))
# define bottom trawl mixed efficiency
ef.nt <- 0.01 # for large pelagics, reef dwellers, others not in trawlable habitat
ef.pl <- 0.1 # for pelagics
ef.dm <- 0.7 # for demersals
ef.fl <- 1.1 # for selected flatfish
# bottom trawl survey efficiency specification by species group
effnontrawl <- data.frame(species=nontrawl, efficiency=rep(ef.nt,length(nontrawl)))
effpelagics <- data.frame(species=pelagics, efficiency=rep(ef.pl,length(pelagics)))
effdemersals <- data.frame(species=demersals, efficiency=rep(ef.dm,length(demersals)))
effselflats <- data.frame(species=selflats, efficiency=rep(ef.fl,length(selflats)))
efficmix <- bind_rows(effnontrawl, effpelagics, effdemersals, effselflats)
# mixed selectivity (using 10 agecl for all species)
# flat=1 for large pelagics, reef dwellers, others not in trawlable habitat
# sigmoid 0 to 1 with 0.5 inflection at agecl 3 for pelagics, reaching 1 at agecl 5, flat top
# sigmoid 0 to 1 with 0.5 inflection at agecl 5 for most demersals and flatfish, reaching 1 at agecl 7, flat top
# dome shaped 0 to 1 at agecl 6&7 for selected demersals, falling off to 0.7 by agecl 10
sigmoid <- function(a,b,x) {
1 / (1 + exp(-a-b*x))
}
# survey selectivity specification by species group
selnontrawl <- data.frame(species=rep(nontrawl, each=10),
agecl=rep(c(1:10),length(nontrawl)),
selex=rep(1.0,length(nontrawl)*10))
selpelagics <- data.frame(species=rep(pelagics, each=10),
agecl=rep(c(1:10),length(pelagics)),
selex=sigmoid(5,1,seq(-10,10,length.out=10)))
seldemersals <- data.frame(species=rep(demersals, each=10),
agecl=rep(c(1:10),length(demersals)),
selex=sigmoid(1,1,seq(-10,10,length.out=10)))
selselflats <- data.frame(species=rep(selflats, each=10),
agecl=rep(c(1:10),length(selflats)),
selex=sigmoid(1,1,seq(-10,10,length.out=10)))
selexmix <- bind_rows(selnontrawl, selpelagics, seldemersals, selselflats)
# use this constant 0 cv for testing
surv_cv_0 <- data.frame(species=survspp, cv=rep(0.0,length(survspp)))
# define bottom trawl survey cv by group
cv.nt <- 1.0 # for large pelagics, reef dwellers, others not in trawlable habitat
cv.pl <- 0.5 # for pelagics
cv.dm <- 0.3 # for demersals
cv.fl <- 0.3 # for selected flatfish
# specify cv by species groups
surv_cv_nontrawl <- data.frame(species=nontrawl, cv=rep(cv.nt,length(nontrawl)))
surv_cv_pelagics <- data.frame(species=pelagics, cv=rep(cv.pl,length(pelagics)))
surv_cv_demersals <- data.frame(species=demersals, cv=rep(cv.dm,length(demersals)))
surv_cv_selflats <- data.frame(species=selflats, cv=rep(cv.fl,length(selflats)))
surv_cv_mix <- bind_rows(surv_cv_nontrawl, surv_cv_pelagics, surv_cv_demersals, surv_cv_selflats)Here we use create_survey on the numbers output of run_truth to create the survey census of age composition.
survey_testNstd <- create_survey(dat = truth$nums,
time = annualmidyear,
species = survspp,
boxes = boxsurv,
effic = efficmix,
selex = selexmix)
# consider saving this interim step if it takes a long time go generateNext we apply the aggregateDensityData function can to resn and structn for survey times, species, and boxes.
# aggregate true resn per survey design
survey_aggresnstd <- aggregateDensityData(dat = truth$resn,
time = annualmidyear,
species = survspp,
boxes = boxsurv)
# aggregate true structn per survey design
survey_aggstructnstd <- aggregateDensityData(dat = truth$structn,
time = annualmidyear,
species = survspp,
boxes = boxsurv)Now we should have inputs to sample_fish on the same scale, and they need to be aggregated across boxes into a single biological sample for the whole survey. The sample_fish applies the median for aggregation and does not apply multinomial sampling if sample=FALSE in the function call.
# define n fish for biological sampling by group
# this could easily be a vector or time series, constant here
ns.nt <- 25 # for large pelagics, reef dwellers, others not in trawlable habitat
ns.pl <- 1000 # for pelagics
ns.dm <- 1000 # for demersals
ns.fl <- 1000 # for selected flatfish
effNnontrawl <- data.frame(species=nontrawl, effN=rep(ns.nt,length(nontrawl)))
effNpelagics <- data.frame(species=pelagics, effN=rep(ns.pl,length(pelagics)))
effNdemersals <- data.frame(species=demersals, effN=rep(ns.dm,length(demersals)))
effNselflats <- data.frame(species=selflats, effN=rep(ns.fl,length(selflats)))
effNmix <- bind_rows(effNnontrawl, effNpelagics, effNdemersals, effNselflats)
# apply default sample fish as before to get numbers
numsstd <- sample_fish(survey_testNstd, effNmix)
#dont sample these, just aggregate them using median (effNmix does nothing)
structnstd <- sample_fish(survey_aggstructnstd, effNmix, sample = FALSE)
resnstd <- sample_fish(survey_aggresnstd, effNmix, sample = FALSE)# now cut these down to a single species for testing
ss_numsstd <- numsstd[numsstd$species == "SkateRay",]
ss_structnstd <- structnstd[structnstd$species == "SkateRay",]
ss_resnstd <- resnstd[resnstd$species == "SkateRay",]
ss_length_stdsurv <- calc_age2length(structn = ss_structnstd,
resn = ss_resnstd,
nums = ss_numsstd,
biolprm = truth$biolprm, fgs = truth$fgs,
CVlenage = 0.1, remove.zeroes=TRUE)Plot samples one species:
Samples for all species and SAVE the file
Now run for all species in the survey.
length_stdsurv <- calc_age2length(structn = structnstd,
resn = resnstd,
nums = numsstd,
biolprm = truth$biolprm, fgs = truth$fgs,
CVlenage = 0.1, remove.zeroes=TRUE)
#save for later use, takes a long time to generate
saveRDS(length_stdsurv, file.path(d.name, paste0(scenario.name, "length_stdsurv.rds")))Runtime for census lengths was <1 hour for NEUS because it is a 50 year run and we are taking lengths only once per year. For standard survey lengths runtime was not reduced because the dimensions (species, timesteps) were identical.
Compare sampled lf with census from here:
length_censussurvsamp <- readRDS(file.path(d.name, paste0(scenario.name, "length_censussurvsamp.rds")))
length_stdsurv <- readRDS(file.path(d.name, paste0(scenario.name, "length_stdsurv.rds")))Comparison plots for other species. Blue bars are the census length sample and red outlines are the survey sample (standardized for comparison; census total n lengths is 1e+8 while sample total n lengths is 1000):
Here as with cohort sampling, the impact of survey selectivity is much larger than sampling error with effN of 1000. We could try effN that is lower, but 1000 lengths may be reasonable from a survey. A sample_lengths function could add further measuremet error on top of this, if desired (though measurement error at the 1 cm level may be negligible).