Last updated: 2020-03-20
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Knit directory: BloomSail/
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library(tidyverse)
library(data.table)
library(lubridate)
library(DataExplorer)
library(leaflet)
library(readxl)
library(gsubfn)
CTD sensor data including recordings from auxiliary pH, O2, Chla and pCO2 sensors were recorded with a measurement frequency of 15 sec. (In addition, pCO2 data were also internally recorded on the Contros HydroC instrument with higher temporal resolution and will later be used for further analysis after merging with CTD data.)
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/data/TinaV/Sensor/Profiles_Transects")
files <- list.files(pattern = "[.]cnv$")
#file <- files[1]
for (file in files){
start.date <- data.table(read.delim(file, sep="#", nrows = 160))[[78,1]]
start.date <- substr(start.date, 15, 34)
start.date <- mdy_hms(start.date, tz="UTC")
tempo <- read.delim(file, sep="", skip = 160, header = FALSE)
tempo <- data.table(tempo[,c(2,3,4,5,6,7,9,11,13)])
names(tempo) <- c("date", "Dep.S", "Tem.S", "Sal.S", "V_pH", "pH", "Chl", "O2", "pCO2")
tempo$start.date <- start.date
tempo$date <- tempo$date + tempo$start.date
tempo$transect.ID <- substr(file, 1, 6)
tempo$type <- substr(file, 8,8)
tempo$label <- substr(file, 8,10)
tempo$cast <- "up"
tempo[date < mean(tempo[Dep.S == max(tempo$Dep.S)]$date)]$cast <- "down"
if (exists("dataset")){
dataset <- rbind(dataset, tempo)
}
if (!exists("dataset")){
dataset <- tempo
}
rm(start.date)
rm(tempo)
}
CTD <- dataset
rm(dataset, file, files)
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/")
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/data/TinaV/Sensor/Ostergarnsholm")
files <- list.files(pattern = "[.]cnv$")
#file <- files[1]
for (file in files){
start.date <- data.table(read.delim(file, sep="#", nrows = 160))[[78,1]]
start.date <- substr(start.date, 15, 34)
start.date <- mdy_hms(start.date, tz="UTC")
tempo <- read.delim(file, sep="", skip = 160, header = FALSE)
tempo <- data.table(tempo[,c(2,3,4,5,6,7,9,11,13)])
names(tempo) <- c("date", "Dep.S", "Tem.S", "Sal.S", "V_pH", "pH", "Chl", "O2", "pCO2")
tempo$start.date <- start.date
tempo$date <- tempo$date + tempo$start.date
tempo$transect.ID <- substr(file, 1, 6)
tempo$type <- substr(file, 8,8)
tempo$label <- substr(file, 11,12)
tempo$cast <- "up"
tempo[date < mean(tempo[Dep.S == max(tempo$Dep.S)]$date)]$cast <- "down"
if (exists("dataset")){
dataset <- rbind(dataset, tempo)
}
if (!exists("dataset")){
dataset <- tempo
}
rm(start.date)
rm(tempo)
}
OGB <- dataset
rm(dataset, file, files)
OGB <- OGB %>%
mutate(type = if_else(label=="bo", "P", "T"),
label = if_else(label == "bo", "P14", label),
label = if_else(label == "in", "T14", label),
label = if_else(label == "ou", "T15", label))
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/")
CTD <- bind_rows(CTD, OGB) %>%
arrange(date)
rm(OGB)
source("code/eda.R")
eda(CTD, "CTD-raw")
rm(eda)
The output of an automated Exploratory Data Analysis (EDA) performed with the package DataExplorer
can be accessed here:
Link to EDA report of CTD raw data
CTD recordings were cleaned from obviously erroneous readings, by setting values to NA.
class(CTD)
CTD <- data.table(CTD)
# Profiling data
# Temperature
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(Tem.S, Dep.S, col=label, linetype = cast))+
# geom_line()+
# scale_y_reverse()+
# geom_vline(xintercept = c(10, 20))+
# facet_wrap(~transect.ID)
CTD[transect.ID == "180723" & label == "P07" & Dep.S < 2 & cast == "up"]$Tem.S <- NA
# Salinity
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(Sal.S, Dep.S, col=label, linetype = cast))+
# geom_path()+
# scale_y_reverse()+
# facet_wrap(~transect.ID)
CTD[Sal.S < 6]$Sal.S <- NA
# pH
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(pH, Dep.S, col=label, linetype=cast))+
# geom_path()+
# scale_y_reverse()+
# facet_wrap(~transect.ID)
#
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(V_pH, Dep.S, col=label, linetype=cast))+
# geom_path()+
# scale_y_reverse()+
# facet_wrap(~transect.ID)
CTD[pH < 7.5]$V_pH <- NA
CTD[pH < 7.5]$pH <- NA
CTD[transect.ID == "180709" & label == "P03" & Dep.S < 5 & cast == "down"]$pH <- NA
CTD[transect.ID == "180709" & label == "P05" & Dep.S < 10 & cast == "down"]$pH <- NA
CTD[transect.ID == "180718" & label == "P10" & Dep.S < 3 & cast == "down"]$pH <- NA
CTD[transect.ID == "180815" & label == "P03" & Dep.S < 2 & cast == "down"]$pH <- NA
CTD[transect.ID == "180820" & label == "P11" & Dep.S < 15 & cast == "down"]$pH <- NA
CTD[transect.ID == "180709" & label == "P03" & Dep.S < 5 & cast == "down"]$V_pH <- NA
CTD[transect.ID == "180709" & label == "P05" & Dep.S < 10 & cast == "down"]$V_pH <- NA
CTD[transect.ID == "180718" & label == "P10" & Dep.S < 3 & cast == "down"]$V_pH <- NA
CTD[transect.ID == "180815" & label == "P03" & Dep.S < 2 & cast == "down"]$V_pH <- NA
CTD[transect.ID == "180820" & label == "P11" & Dep.S < 15 & cast == "down"]$V_pH <- NA
# pCO2
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(pCO2, Dep.S, col=label, linetype = cast))+
# geom_path()+
# scale_y_reverse()+
# facet_wrap(~transect.ID)
CTD[transect.ID == "180616"]$pCO2 <- NA
# O2
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(O2, Dep.S, col=label, linetype = cast))+
# geom_path()+
# scale_y_reverse()+
# facet_wrap(~transect.ID)
# Chlorophyll
# CTD %>%
# filter(type == "P") %>%
# ggplot(aes(Chl, Dep.S, col=label, linetype = cast))+
# geom_path()+
# scale_y_reverse()+
# facet_wrap(~transect.ID)
CTD[Chl > 100]$Chl <- NA
#### Surface transect data
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, Dep.S, col=label))+
# geom_point()+
# scale_y_reverse()+
# facet_wrap(~transect.ID, scales = "free_x")
#
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, Tem.S, col=label))+
# geom_point()+
# facet_wrap(~transect.ID, scales = "free_x")
#
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, Sal.S, col=label))+
# geom_point()+
# facet_wrap(~transect.ID, scales = "free_x")
#
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, pCO2, col=label))+
# geom_point()+
# facet_wrap(~transect.ID, scales = "free_x")
#
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, pH, col=label))+
# geom_point()+
# facet_wrap(~transect.ID, scales = "free_x")
#
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, Chl, col=label))+
# geom_point()+
# facet_wrap(~transect.ID, scales = "free_x")
CTD[type == "T" & Chl > 10]$Chl <- NA
# CTD %>%
# filter(type == "T") %>%
# ggplot(aes(date, O2, col=label))+
# geom_point()+
# facet_wrap(~transect.ID, scales = "free_x")
Relevant columns were selected and renamed, only observations from regular stations (P01-P13) and transects (T01-T13) were selected and summarized data were written to file.
CTD <-
CTD %>%
select(date_time=date,
ID=transect.ID,
type,
station=label,
dep=Dep.S,
sal=Sal.S,
tem=Tem.S,
pCO2,pH,V_pH,O2,Chl)
# CTD <- CTD %>%
# filter( !(station %in% c("PX1", "PX2", "TX1", "TX2") ))
CTD %>%
write_csv(here::here("data/_summarized_data_files", "Tina_V_Sensor_Profiles_Transects.csv"))
rm(CTD)
CTD <-
read_csv(here::here("data/_summarized_data_files", "Tina_V_Sensor_Profiles_Transects.csv"),
col_types = cols(pCO2 = col_double()))
source("code/eda.R")
eda(CTD, "CTD")
rm(eda)
The output of an automated Exploratory Data Analysis (EDA) performed with the package DataExplorer
can be accessed here:
Link to EDA report of CTD clean data
CTD %>%
arrange(date_time) %>%
filter(type == "P", !(station %in% c("PX1", "PX2"))) %>%
ggplot(aes(tem, dep, col=station))+
geom_path()+
scale_y_reverse()+
labs(x="Temperature (°C)", y="Depth (m)")+
facet_wrap(~ID, labeller = label_both)
CTD %>%
arrange(date_time) %>%
filter(type == "P", !(station %in% c("PX1", "PX2"))) %>%
ggplot(aes(pCO2, dep, col=station))+
geom_path()+
scale_y_reverse()+
labs(x=expression(pCO[2]~(µatm)), y="Depth (m)")+
facet_wrap(~ID, labeller = label_both)
HydroC pCO2 data were provided by KM Contros after applying a drift correction to the raw data, which was based on pre- and post-deployment calibration results.
# Read Contros corrected data file
HC <-
read_csv2(here::here("Data/TinaV/Sensor/HydroC-pCO2/corrected_Contros",
"parameter&pCO2s(method 43).txt"),
col_names = c("date_time", "Zero", "Flush", "p_NDIR",
"p_in", "T_control", "T_gas", "%rH_gas",
"Signal_raw", "Signal_ref", "T_sensor",
"pCO2", "Runtime", "nr.ave")) %>%
mutate(date_time = dmy_hms(date_time),
Flush = as.factor(as.character(Flush)),
Zero = as.factor(as.character(Zero)))
Individual deployments (periods of observations with less than 30 sec between recordings) were identified and relevant deployment periods were subsetted.
HC <- HC %>%
arrange(date_time) %>%
mutate(deployment = cumsum(c(TRUE,diff(date_time)>=30)))
HC <- HC %>%
filter(deployment %in% c(2,6,9,14,17,21,23,27,31,33,34,35,37))
# add counter for date_time observations
HC <- HC %>%
add_count(date_time)
# find triplicated time stamp and select only first observation, and merge
HC_no_triple <- HC %>%
filter(n <= 2)
HC_triple_clean <- HC %>%
filter(n > 2) %>%
slice(1)
HC <- full_join(HC_no_triple, HC_triple_clean)
rm(list=setdiff(ls(), "HC"))
# find duplicated time stamps and shift first by one second backward, and merge
HC %>%
distinct(date_time)
HC <- HC %>%
select(-n) %>%
add_count(date_time)
unique(HC$n)
HC_no_duplicated <- HC %>%
filter(n == 1)
HC_duplicated <- HC %>%
filter(n == 2)
HC_duplicated_first <- HC_duplicated %>%
group_by(date_time) %>%
slice(1) %>%
ungroup() %>%
mutate(date_time = date_time - 1)
HC_duplicated_second <- HC_duplicated %>%
group_by(date_time) %>%
slice(2) %>%
ungroup()
HC_duplicated_clean <- full_join(HC_duplicated_first, HC_duplicated_second) %>%
arrange(date_time)
HC <- full_join(HC_no_duplicated, HC_duplicated_clean)
HC %>%
distinct(date_time)
rm(list=setdiff(ls(), "HC"))
# find duplicated time stamps and shift first by two seconds forward, and merge
HC %>%
distinct(date_time)
HC <- HC %>%
select(-n) %>%
add_count(date_time)
unique(HC$n)
HC_no_duplicated <- HC %>%
filter(n == 1)
HC_duplicated <- HC %>%
filter(n == 2)
HC_duplicated_first <- HC_duplicated %>%
group_by(date_time) %>%
slice(1) %>%
ungroup() %>%
mutate(date_time = date_time + 2)
HC_duplicated_second <- HC_duplicated %>%
group_by(date_time) %>%
slice(2) %>%
ungroup()
HC_duplicated_clean <- full_join(HC_duplicated_first, HC_duplicated_second) %>%
arrange(date_time)
HC <- full_join(HC_no_duplicated, HC_duplicated_clean)
HC %>%
distinct(date_time)
rm(list=setdiff(ls(), "HC"))
# remaining duplicates are observations where other observations with a +/- 1 sec timestamp exist
# for those cases, only the first duplicated observation is selected (similar to triplicate treatment)
HC %>%
distinct(date_time)
HC <- HC %>%
select(-n) %>%
add_count(date_time)
unique(HC$n)
HC_still_no_duplicated <- HC %>%
filter(n == 1)
HC_still_duplicated_first <- HC %>%
filter(n == 2) %>%
group_by(date_time) %>%
slice(1)
HC <- full_join(HC_still_no_duplicated, HC_still_duplicated_first)
HC %>%
distinct(date_time)
rm(list=setdiff(ls(), "HC"))
HC <- HC %>%
select(-n)
# Zeroing ID labelling
HC <- HC %>%
arrange(date_time) %>%
group_by(Zero) %>%
mutate(Zero_ID = as.factor(cumsum(c(TRUE,diff(date_time)>=30)))) %>%
ungroup()
unique(HC$Zero_ID)
# Flush: Identification
HC <- HC %>%
mutate(Flush = 0) %>%
group_by(Zero, Zero_ID) %>%
mutate(start = min(date_time),
duration = date_time - start,
Flush = if_else(Zero == 0 & duration < 600, "1", "0")) %>%
ungroup()
# Flush: Identify equilibration and internal gas mixing periods
HC <- HC %>%
mutate(mixing = if_else(duration < 20, "mixing", "equilibration"))
A pdf with plots of all Flush periods (mixing and equilibration identified) can be found here:
pdf(file=here::here("output/Plots/data_base",
"HydroC_pCO2_deployments.pdf"), onefile = TRUE, width = 7, height = 4)
for (i in unique(HC$deployment)) {
#i <- unique(HC$deployment)[3]
sub <- HC %>%
filter(deployment == i)
start_date <- min(sub$date_time)
print(
sub %>%
ggplot(aes(date_time, pCO2, col=Zero_ID))+
geom_line()+
labs(title = paste("Deployment: ",i, "| Start time: ", start_date))
)
}
dev.off()
rm(sub, start_date, i)
A pdf with pCO2 timeseries plots of all deployments can be found here:
source("code/eda.R")
eda(HC, "HydroC-pCO2")
rm(eda)
The output of an automated Exploratory Data Analysis (EDA) performed with the package DataExplorer
can be accessed here:
Link to EDA report of HydroC pCO2 data data
Individual zeroings were labeled with a counter and a period of 10 min after the zeroing was labelled as Flush period (overriding the internal Flush flag). A mixing flag was introduced, flagging the initial 20 sec of each Flush period as “mixing” and the rest as “equilibration”.
Flush <- HC %>%
filter(Flush == 1)
# Flush: Plot individual periods
pdf(file=here::here("output/Plots/data_base",
"Flush_periods_all.pdf"), onefile = TRUE, width = 7, height = 4)
for (i in unique(Flush$Zero_ID)) {
#i <- unique(Flush$Zero_ID)[5]
print(
Flush %>%
filter(Zero_ID == i) %>%
ggplot(aes(duration, pCO2, col=mixing))+
geom_point() +
scale_color_brewer(palette = "Set1")+
labs(y=expression(pCO[2]~(µatm)), x="Duration of Flush period (s)",
title = paste("Zero_ID: ", i))
)
}
dev.off()
rm(Flush,i)
Summarized pCO2 date were written to file.
HC %>%
write_csv(here::here("Data/_summarized_data_files",
"Tina_V_HydroC_full.csv"))
HC %>%
select(date_time, Zero, Flush, pCO2, deployment, Zero_ID, duration, mixing) %>%
write_csv(here::here("Data/_summarized_data_files",
"Tina_V_HydroC.csv"))
Bottle <- read_csv(here::here("Data/TinaV/Bottle/Tracegases", "BloomSail_bottle_CO2_all.csv"),
col_types = list("c","c","n","n","n","n","n"))
Bottle <- Bottle %>%
select(ID=transect.ID,
station=label,
dep=Dep,
sal=Sal,
CT, AT,
pH_Mosley = pH.Mosley)
Bottle %>%
write_csv(here::here("Data/_summarized_data_files", "Tina_V_Bottle_CO2_lab.csv"))
First, we read the GPS track data.
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/data/TinaV/Track/GPS_Logger_Track")
files <- list.files(pattern = "[.]txt$")
for (file in files){
# if the merged dataset does exist, append to it
if (exists("dataset")){
tempo<-data.table ( read.delim(file, sep=",")[,c(2,3,4)])
names(tempo) <- c("date_time", "lat", "lon")
tempo$date_time<- ymd_hms(tempo$date, tz="UTC")
dataset<-rbind(dataset, tempo)
rm(tempo)
}
# if the merged dataset doesn't exist, create it
if (!exists("dataset")){
dataset<-data.table ( read.delim(file, sep=",")[,c(2,3,4)])
names(dataset) <- c("date_time", "lat", "lon")
dataset$date_time<- ymd_hms(dataset$date_time, tz="UTC")
}
}
track <- dataset
rm(dataset, file, files)
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail")
track %>%
write_csv(here::here("Data/_summarized_data_files",
"TinaV_Track.csv"))
# track_sub <- track %>%
# slice(which(row_number() %% 20 == 1))
#
# bathy <- read_csv(here::here("data/Maps","Bathymetry_Gotland_east.csv"))
#
# track_sub %>%
# ggplot()+
# geom_raster(data=bathy, aes(lon, lat, fill=elev))+
# scale_fill_continuous(na.value = "black", name="Tiefe [m]")+
# geom_path(aes(lon, lat), col="grey80")+
# labs(x="Längengrad (°E)", y="Breitengrad (°N)")+
# coord_quickmap(expand = 0, ylim = c(57.25,57.6), xlim = c(18.6, 19.8))+
# theme_bw()+
# guides(col = guide_legend(nrow = 5))
And than create an interactive map.
track <-
read_csv(here::here("Data/_summarized_data_files",
"TinaV_Track.csv"))
track_sub <- track %>%
slice(which(row_number() %% 20 == 1))
rm(track)
leaflet() %>%
setView(lng = 20, lat = 57.3, zoom = 8) %>%
addLayersControl(baseGroups = c("Ocean Basemap",
"Satellite"),
overlayGroups = c("Track"),
options = layersControlOptions(collapsed = FALSE),
position = 'topright') %>%
addProviderTiles("Esri.WorldImagery", group = "Satellite") %>%
addProviderTiles(providers$Esri.OceanBasemap, group = "Ocean Basemap") %>%
addScaleBar(position = 'topright') %>%
addMeasure(
primaryLengthUnit = "kilometers",
secondaryLengthUnit = 'miles',
primaryAreaUnit = "sqmeters",
secondaryAreaUnit="acres",
position = 'topleft') %>%
addPolylines(data = track_sub, ~lon, ~lat,
color = "red",
group = "Track")
pCO2 data were recorded on VOS Finnmaid in summer 2018.
### June - August 2018
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/data/Finnmaid_2018")
files <- list.files(pattern = "[.]xls$")
#file <-files[1]
for (file in files){
df <- read_excel(file)
df <- df[c(1,2,3,12,7,4,15,8,5,17)]
names(df) <- c("date","Lon","Lat","pCO2","Sal","Tem","cO2","patm", "Teq","xCO2")
df <- df[-c(1),]
df$date <- as.POSIXct(as.numeric(df$date)*60*60*24, origin="1899-12-30", tz="GMT")
df$Lon <- as.numeric(as.character(df$Lon))
df$Lat <- as.numeric(as.character(df$Lat))
df$pCO2 <- as.numeric(as.character(df$pCO2))
df$Sal <- as.numeric(as.character(df$Sal))
df$Tem <- as.numeric(as.character(df$Tem))
df$cO2 <- as.numeric(as.character(df$cO2))
df$patm <- as.numeric(as.character(df$patm))
df$Teq <- as.numeric(as.character(df$Teq))
df$xCO2 <- as.numeric(as.character(df$xCO2))
df <- data.table(df)
df$route <- strapplyc(as.character(file), ".*(.).xls*", simplify = TRUE)
df$ID <- substr(as.character(file), 3, 10)
if (exists("temp")){
temp <- rbind (temp, df)
} else{temp <- df}
}
rm(df, files, file)
temp <- temp[pCO2 != 0]
#### Los Gatos data
setwd("C:/Mueller_Jens_Data/Research/Projects/BloomSail/data/Finnmaid_2018/LGR")
files <- list.files(pattern = "[.]xls$")
#file <-files[1]
for (file in files){
df <- read_excel(file)
df <- df[c(2,3,4,8,6,5,14,7,15,9)]
names(df) <- c("date","Lon","Lat","pCO2","Sal","Tem","cO2","patm", "Teq","xCO2")
df <- df[-c(1),]
df$date <- dmy_hms(df$date)
df <- data.table(df)
df$route <- substr(as.character(file), 12, 12)
df$ID <- substr(as.character(file), 3, 10)
if (exists("temp.LGR")){
temp.LGR <- rbind (temp.LGR, df)
} else{temp.LGR <- df}
}
#Convert O2 sat to O2 concentration #
source(here::here("code", "O2stoO2c.R"))
temp.LGR <- temp.LGR %>%
filter() %>%
mutate(cO2 = O2stoO2c(O2sat = cO2, T=Tem, S=Sal, P=3/10, p_atm = 1013.5))
#### Merge Los Gator and LICOR data files ####
temp$sensor <- "LICOR"
temp.LGR$sensor <- "LosGatos"
temp <- rbind(temp, temp.LGR)
rm(temp.LGR, df, file, files)
#### Assign subareas according to Schneider and Mueller (2018) ####
temp$Area <- with(temp,
ifelse(Lon>12 & Lon<12.6, "1.MEB",
ifelse(Lon>13.1 & Lon<14.3, "2.ARK",
ifelse(Lat>57.5 & Lat<58.5 & route %in% c("E", "G"), "4.EGS",
ifelse(Lat>57.33 & Lat<57.5 & route %in% c("E"), "BS",
ifelse(Lat>56.8 & Lat<57.5 & route=="W", "3.WGS",
ifelse(Lat>58.5 & Lat<59 & Lon>20, "5.NGS",
ifelse(Lon>22 & Lon<24, "6.WGF",
ifelse(Lon>24 & Lon<24.5, "7.HGF", "NaN")))))))))
temp <-temp[complete.cases(temp[,pCO2]),]
temp %>%
write_csv(here::here("Data/_summarized_data_files",
"Finnmaid.csv"))
Include data from crossing large vessels
Include information about HydroC calibration results and raw data correction by Contros
Check results from field response time experiment (high zeroing frequency)
sessionInfo()
R version 3.5.0 (2018-04-23)
Platform: x86_64-w64-mingw32/x64 (64-bit)
Running under: Windows 10 x64 (build 18363)
Matrix products: default
locale:
[1] LC_COLLATE=English_United States.1252
[2] LC_CTYPE=English_United States.1252
[3] LC_MONETARY=English_United States.1252
[4] LC_NUMERIC=C
[5] LC_TIME=English_United States.1252
attached base packages:
[1] stats graphics grDevices utils datasets methods base
other attached packages:
[1] gsubfn_0.7 proto_1.0.0 readxl_1.3.1 leaflet_2.0.2
[5] DataExplorer_0.8.0 lubridate_1.7.4 data.table_1.12.6 forcats_0.4.0
[9] stringr_1.4.0 dplyr_0.8.3 purrr_0.3.3 readr_1.3.1
[13] tidyr_1.0.0 tibble_2.1.3 ggplot2_3.3.0 tidyverse_1.3.0
loaded via a namespace (and not attached):
[1] Rcpp_1.0.2 here_0.1 lattice_0.20-35 assertthat_0.2.1
[5] zeallot_0.1.0 rprojroot_1.3-2 digest_0.6.22 mime_0.7
[9] R6_2.4.0 cellranger_1.1.0 backports_1.1.5 reprex_0.3.0
[13] evaluate_0.14 httr_1.4.1 highr_0.8 pillar_1.4.2
[17] rlang_0.4.5 rstudioapi_0.10 rmarkdown_2.0 labeling_0.3
[21] htmlwidgets_1.5.1 igraph_1.2.4.1 munsell_0.5.0 shiny_1.4.0
[25] broom_0.5.3 compiler_3.5.0 httpuv_1.5.2 modelr_0.1.5
[29] xfun_0.10 pkgconfig_2.0.3 tcltk_3.5.0 htmltools_0.4.0
[33] tidyselect_0.2.5 gridExtra_2.3 workflowr_1.6.0 crayon_1.3.4
[37] dbplyr_1.4.2 withr_2.1.2 later_1.0.0 grid_3.5.0
[41] xtable_1.8-4 nlme_3.1-137 jsonlite_1.6 gtable_0.3.0
[45] lifecycle_0.1.0 DBI_1.0.0 git2r_0.26.1 magrittr_1.5
[49] scales_1.0.0 cli_1.1.0 stringi_1.4.3 fs_1.3.1
[53] promises_1.1.0 xml2_1.2.2 generics_0.0.2 vctrs_0.2.0
[57] tools_3.5.0 glue_1.3.1 crosstalk_1.0.0 hms_0.5.2
[61] networkD3_0.4 fastmap_1.0.1 parallel_3.5.0 yaml_2.2.0
[65] colorspace_1.4-1 rvest_0.3.5 knitr_1.26 haven_2.2.0