Last updated: 2020-03-19
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Knit directory: BloomSail/
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library(tidyverse)
library(patchwork)
library(seacarb)
library(metR)
library(scico)
library(cmocean)
# library(broom)
# library(lubridate)
# library(tibbletime)
Profile data are prepared by:
df <-
read_csv(here::here("data/_merged_data_files",
"BloomSail_CTD_HydroC_track_RT.csv"),
col_types = cols(ID = col_character(),
pCO2_analog = col_double(),
pCO2 = col_double(),
Zero = col_character(),
Flush = col_character(),
mixing = col_character(),
Zero_ID = col_integer(),
deployment = col_integer(),
lon = col_double(),
lat = col_double(),
pCO2_RT = col_double()))
# Filter relevant rows and columns
df <- df %>%
filter(type == "P",
Flush == "0",
Zero == "0",
!ID %in% c("180616","180820"),
!(station %in% c("PX1", "PX2", "P14", "P13", "P01"))) %>%
select(date_time, ID, type, station, lat, lon, dep, sal, tem, pCO2_raw = pCO2, pCO2 = pCO2_RT_mean, duration)
# Assign meta information
df <- df %>%
group_by(ID, station) %>%
mutate(duration = as.numeric(date_time - min(date_time))) %>%
arrange(date_time) %>%
ungroup()
meta <- read_csv(here::here("Data/_summarized_data_files",
"Tina_V_Sensor_meta.csv"),
col_types = cols(ID = col_character()))
meta <- meta %>%
filter(!ID %in% c("180616","180820"),
!(station %in% c("PX1", "PX2", "P14", "P13", "P01")))
df <- full_join(df, meta)
rm(meta)
# creating descriptive variables
df <- df %>%
mutate(phase = "standby",
phase = if_else(duration >= start & duration < down & !is.na(down) & !is.na(start), "down", phase),
phase = if_else(duration >= down & duration < lift & !is.na(lift) & !is.na(down ), "low", phase),
phase = if_else(duration >= lift & duration < up & !is.na(up ) & !is.na(lift ), "mid", phase),
phase = if_else(duration >= up & duration < end & !is.na(end ) & !is.na(up ), "up", phase))
df <- df %>%
select(-c(start, down, lift, up, end, comment, p_type, duration, type))
# select downcasst only
df <- df %>%
filter(phase == "down") %>%
select(-phase)
df_highres <- df
# grid observation to 1m depth intervals
df <- df %>%
mutate(dep_int = as.numeric(as.character( cut(dep, seq(0,40,1), seq(0.5,39.5,1))))) %>%
group_by(ID, station, dep_int) %>%
summarise_all("mean", na.rm = TRUE) %>%
ungroup() %>%
select(-dep, dep=dep_int)
# subset complete profiles
profiles_in <- df %>%
filter(dep < 20) %>%
group_by(ID, station) %>%
summarise(nr = n()) %>%
mutate(select = if_else(nr > 18 | station == "P14", "in", "out")) %>%
select(-nr) %>%
ungroup()
df <- full_join(df, profiles_in)
rm(profiles_in)
df %>%
filter(dep < 30) %>%
arrange(date_time) %>%
ggplot(aes(pCO2, dep, col=select))+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_x_continuous(breaks = c(0,300), labels = c(0,300))+
scale_color_brewer(palette = "Set1", direction = -1)+
coord_cartesian(xlim = c(0,400))+
facet_grid(ID~station)
df <- df %>%
filter(select == "in") %>%
select(-select)
# assign mean date_time stamp
cruise_dates <- df %>%
filter(station != "P14") %>%
group_by(ID) %>%
summarise(date_time_ID = mean(date_time)) %>%
ungroup()
# inner_join remove P14 observations lacking date_time_ID
df <- inner_join(cruise_dates, df)
map <- read_csv(here::here("data/Maps","Bathymetry_Gotland_east_small.csv"))
# ggplot()+
# geom_contour_fill(data=map, aes(x=lon, y=lat, z=-elev), na.fill = TRUE)+
# coord_quickmap(expand = 0, xlim = c(18.7, 19.9), ylim = c(57.25,57.6))+
# theme_bw()+
# theme(legend.position="bottom")
df %>%
group_by(station) %>%
summarise(lat = mean(lat),
lon = mean(lon)) %>%
ungroup() %>%
ggplot()+
geom_raster(data=map, aes(lon, lat, fill=-elev))+
scale_fill_scico(palette = "oslo", na.value = "grey",
name="Depth [m]", direction = -1)+
geom_label(aes(lon, lat, label=station))+
coord_quickmap(expand = 0, xlim = c(18.7, 19.9), ylim = c(57.25,57.6))+
theme_bw()
rm(map)
cover <- df %>%
group_by(ID, station) %>%
summarise(date = mean(date_time),
date_time_ID = mean(date_time_ID)) %>%
ungroup()
cover %>%
ggplot(aes(date, station, fill=ID))+
geom_vline(aes(xintercept = date_time_ID, col=ID))+
geom_point(shape=21)+
scale_color_viridis_d()+
scale_fill_viridis_d()
rm(cover)
At stations P07 and P10 discrete samples for lab measurments of CT and AT were collected. Please note that - in contrast to the pCO2 profiles - samples were taken on June 16.
CO2 <-
read_csv(here::here("Data/_summarized_data_files", "Tina_V_Bottle_CO2_lab.csv"),
col_types = cols(ID = col_character()))
CO2 <- CO2 %>%
filter(station %in% c("P07", "P10")) %>%
select(-pH_Mosley) %>%
mutate(CT_AT_ratio = CT/AT)
CO2 <- inner_join(CO2, cruise_dates)
CO2_long <- CO2 %>%
pivot_longer(4:7, names_to = "parameter", values_to = "value")
CO2_long %>%
ggplot(aes(value, dep))+
geom_path(aes(col=ID))+
geom_point(aes(fill=ID), shape=21)+
scale_y_reverse()+
scale_fill_viridis_d()+
scale_color_viridis_d()+
facet_grid(station~parameter, scales = "free_x")+
theme(legend.position = "bottom")
CO2_ts <- CO2_long %>%
filter(dep<10) %>%
group_by(ID, date_time_ID, parameter, station) %>%
summarise(value = mean(value, na.rm = TRUE)) %>%
ungroup()
rm(CO2_long)
CO2_ts %>%
ggplot(aes(date_time_ID, value, col=station))+
#geom_point(aes(lubridate::ymd(ID), value, col=station))+
geom_point()+
geom_path()+
scale_fill_viridis_d()+
scale_color_brewer(palette = "Set1")+
facet_grid(parameter~., scales = "free_y")+
labs(x="Mean transect date")
AT_mean <- CO2_ts %>%
filter(parameter == "AT") %>%
summarise(AT = mean(value, na.rm = TRUE)) %>%
pull()
CO2_ts %>%
filter(parameter == "CT_AT_ratio") %>%
ggplot(aes(lubridate::ymd(ID), value*AT_mean, col=station))+
geom_point()+
geom_path()+
scale_fill_viridis_d()+
scale_color_brewer(palette = "Set1")+
labs(x="Mean transect date", y="CT-AT-ratio * mean AT")
In order to derive CT from measured pCO2 profiles, the mean alkalinity in the upper 20 m and both stations was calculated as:
AT_mean <- CO2 %>%
filter(dep <= 20) %>%
summarise(AT = mean(AT, na.rm = TRUE)) %>%
pull()
AT_mean
[1] 1717.08
Likewise, the mean salinity amounts to:
sal_mean <- CO2 %>%
filter(dep <= 20) %>%
summarise(sal = mean(sal, na.rm = TRUE)) %>%
pull()
sal_mean
[1] 6.894127
CT profiles were calculated from sensor pCO2 and T profiles, and constant salinity and alkalinity values. Note that the impact of fixed vs. measured salinity has only a negligible impact on CT profiles.
df <- df %>%
drop_na()
df <- df %>%
filter(pCO2 > 0)
df <- df %>%
mutate(CT = carb(24, var1=pCO2, var2=1720*1e-6,
S=sal_mean, T=tem, P=dep/10, k1k2="m10", kf="dg", ks="d",
gas="insitu")[,16]*1e6)
rm(sal_mean, AT_mean)
df %>%
write_csv(here::here("Data/_merged_data_files", "BloomSail_CTD_HydroC_CT.csv"))
Mean vertical profiles were calculated for each cruise day (ID). Note that:
# df %>%
# filter(dep < 20) %>%
# arrange(date_time) %>%
# ggplot(aes(CT, dep))+
# geom_point()+
# geom_path()+
# scale_y_reverse()+
# coord_cartesian(ylim = c(30,0))+
# facet_grid(station~ID)
mean_profiles <- df %>%
filter(dep < 25) %>%
select(-c(station,lat, lon, pCO2_raw, date_time)) %>%
group_by(ID, date_time_ID, dep) %>%
summarise_all(list(mean), na.rm=TRUE) %>%
ungroup()
sd_profiles <- df %>%
filter(dep < 25) %>%
select(-c(station,lat, lon, pCO2_raw, date_time)) %>%
group_by(ID, date_time_ID, dep) %>%
summarise_all(list(sd), na.rm=TRUE) %>%
ungroup()
sd_profiles_long <- sd_profiles %>%
pivot_longer(4:7, names_to = "parameter", values_to = "sd")
mean_profiles_long <- mean_profiles %>%
pivot_longer(4:7, names_to = "parameter", values_to = "value")
mean_profiles_long <- inner_join(mean_profiles_long, sd_profiles_long)
rm(sd_profiles, sd_profiles_long)
mean_profiles_long %>%
ggplot(aes(value, dep, col=ID))+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_color_viridis_d()+
facet_wrap(~parameter, scales = "free_x")
all <- mean_profiles_long %>%
filter(parameter %in% c("CT", "tem")) %>%
rename(group = ID)
mean_profiles_long %>%
filter(parameter %in% c("CT", "tem")) %>%
ggplot()+
geom_path(data=all, aes(value, dep, group=group))+
geom_ribbon(aes(xmin = value-sd, xmax=value+sd, y=dep, fill=ID), alpha=0.5)+
geom_path(aes(value, dep, col=ID))+
scale_y_reverse()+
scale_color_viridis_d()+
scale_fill_viridis_d()+
facet_grid(ID~parameter, scales = "free_x")
CT, pCO2, S, and T profiles were plotted individually pdf here and grouped by ID pdf here. The later gives an idea of the differences between stations at one point in time.
pdf(file=here::here("output/Plots/CT_dynamics",
"profiles_individual.pdf"), onefile = TRUE, width = 9, height = 5)
for(i_ID in unique(df$ID)){
for(i_station in unique(df$station)){
if (nrow(df %>% filter(ID == i_ID, station == i_station)) > 0){
# i_ID <- unique(df$ID)[1]
# i_station <- unique(df$station)[1]
p_pCO2 <-
df %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(pCO2, dep, col="grid_RT"))+
geom_point(data = df_highres %>% arrange(date_time) %>% filter(ID == i_ID, station == i_station),
aes(pCO2_raw, dep, col="raw"))+
geom_point(data = df_highres %>% arrange(date_time) %>% filter(ID == i_ID, station == i_station),
aes(pCO2, dep, col="raw_RT"))+
geom_point(aes(pCO2_raw, dep, col="grid"))+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_color_brewer(palette = "Set1")+
labs(y="Depth [m]", x="pCO2 [µatm]", title = str_c(i_ID," | ",i_station))+
coord_cartesian(xlim = c(0,200), ylim = c(30,0))+
theme_bw()+
theme(legend.position = "left")
p_tem <-
df %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(tem, dep))+
geom_point()+
geom_path()+
scale_y_reverse()+
labs(y="Depth [m]", x="Tem [°C]")+
coord_cartesian(xlim = c(14,26), ylim = c(30,0))+
theme_bw()
p_sal <-
df %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(sal, dep))+
geom_point()+
geom_path()+
scale_y_reverse()+
labs(y="Depth [m]", x="Tem [°C]")+
coord_cartesian(xlim = c(6.5,7.5), ylim = c(30,0))+
theme_bw()
p_CT <-
df %>%
arrange(date_time) %>%
filter(ID == i_ID,
station == i_station) %>%
ggplot(aes(CT, dep))+
geom_point()+
geom_path()+
scale_y_reverse()+
labs(y="Depth [m]", x="CT* [µmol/kg]")+
coord_cartesian(xlim = c(1400,1700), ylim = c(30,0))+
theme_bw()
print(
p_pCO2 + p_tem + p_sal + p_CT
)
rm(p_pCO2, p_sal, p_tem, p_CT)
}
}
}
dev.off()
rm(i_ID, i_station)
df_long <- df %>%
select(-c(lat, lon, pCO2_raw)) %>%
filter(dep < 25) %>%
pivot_longer(6:9, values_to = "value", names_to = "parameter")
pdf(file=here::here("output/Plots/CT_dynamics",
"profiles_by_ID.pdf"), onefile = TRUE, width = 9, height = 5)
for(i_ID in unique(df$ID)){
#i_ID <- unique(df$ID)[1]
sub_df_long <- df_long %>%
arrange(date_time) %>%
filter(ID == i_ID)
print(
sub_df_long %>%
ggplot()+
geom_path(data = df_long, aes(value, dep, group=interaction(station, ID)), col="grey")+
geom_path(aes(value, dep, col=station))+
scale_y_reverse()+
labs(y="Depth [m]", title = str_c("ID: ", i_ID))+
theme_bw()+
facet_wrap(~parameter, scales = "free_x")
)
rm(sub_df_long)
}
dev.off()
rm(i_ID, df_long)
Changes of seawater parameters at each depth are calculated from one cruise day to the next and divided by the number of days inbetween.
mean_profiles_long <- mean_profiles_long %>%
group_by(parameter, dep) %>%
arrange(date_time_ID) %>%
mutate(diff_value = value - lag(value, default = first(value)),
diff_time = as.numeric(date_time_ID - lag(date_time_ID)),
diff_value_daily = diff_value / diff_time,
cum_value = cumsum(diff_value)) %>%
ungroup()
mean_profiles_long %>%
arrange(dep) %>%
ggplot(aes(diff_value_daily, dep, col=ID))+
geom_vline(xintercept = 0)+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_color_viridis_d()+
facet_wrap(~parameter, scales = "free_x")+
labs(x="Change of value inbetween cruises per day")
Cumulative changes of seawater parameters were calculated at each depth relative to the first cruise day on July 5.
mean_profiles_long %>%
arrange(dep) %>%
ggplot(aes(cum_value, dep, col=ID))+
geom_vline(xintercept = 0)+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_color_viridis_d()+
facet_wrap(~parameter, scales = "free_x")+
labs(x="Cumulative change of value")
Cumulative positive and negative changes of seawater parameters were calculated separately at each depth relative to the first cruise day on July 5.
mean_profiles_long <- mean_profiles_long %>%
mutate(sign = if_else(diff_value < 0, "neg", "pos")) %>%
group_by(parameter, dep, sign) %>%
arrange(date_time_ID) %>%
mutate(cum_value_sign = cumsum(diff_value)) %>%
ungroup()
mean_profiles_long %>%
write_csv(here::here("Data/_merged_data_files", "BloomSail_CTD_HydroC_CT_cumulative_profiles.csv"))
mean_profiles_long %>%
arrange(dep) %>%
ggplot(aes(cum_value_sign, dep, col=ID))+
geom_vline(xintercept = 0)+
geom_point()+
geom_path()+
scale_y_reverse()+
scale_color_viridis_d()+
scale_fill_viridis_d()+
facet_wrap(~interaction(sign, parameter), scales = "free_x", ncol=4)+
labs(x="Cumulative directional change of value")
Timeseries of changes in seawater parameters were calculated for 5m depth intervals.
timeseries <- mean_profiles_long %>%
mutate(dep = cut(dep, seq(0,30,5))) %>%
group_by(ID, date_time_ID, dep, parameter) %>%
summarise_all(list(mean), na.rm=TRUE)
timeseries %>%
ggplot(aes(date_time_ID, value, col=as.factor(dep)))+
geom_path()+
#geom_errorbar(aes(date_time_ID, ymax=value+sd, ymin=value-sd, col=as.factor(dep)))+
geom_point()+
scale_color_viridis_d(name="Depth [m]")+
facet_wrap(~parameter, scales = "free_y", ncol=1)
Total incremental and cumulative CT changes inbetween cruise dates were calculated for 5m depth intervals.
NCP <- mean_profiles_long %>%
filter(parameter == "CT") %>%
mutate(dep = cut(dep, seq(0,30,5))) %>%
group_by(ID, date_time_ID, dep, sign) %>%
summarise(dCT = sum(diff_value)/1000) %>%
ungroup()
NCP <- NCP %>%
group_by(sign, dep) %>%
arrange(date_time_ID) %>%
mutate(dCT_cum = cumsum(dCT)) %>%
ungroup()
NCP %>%
write_csv(here::here("Data/_merged_data_files", "BloomSail_CTD_HydroC_CT_cumulative_timeseries.csv"))
NCP_grid <- expand_grid(
unique(NCP$date_time_ID),
unique(NCP$dep),
unique(NCP$sign)
)
NCP_grid <- NCP_grid %>%
set_names(c("date_time_ID","dep", "sign"))
NCP <- full_join(NCP, NCP_grid)
rm(NCP_grid)
NCP <- NCP %>%
arrange(sign, dep, date_time_ID) %>%
group_by(sign, dep) %>%
fill(dCT_cum) %>%
ungroup() %>%
mutate(dCT_cum = if_else(is.na(dCT_cum), 0, dCT_cum))
p_iNCP <- NCP %>%
ggplot(aes(date_time_ID, dCT, fill=dep))+
geom_hline(yintercept = 0)+
geom_bar(stat="identity", col="black")+
scale_fill_viridis_d()+
scale_y_continuous(breaks = seq(-100, 100, 0.2))+
facet_grid(rev(sign)~., scales = "free_y", space = "free_y")+
theme(strip.background = element_blank(),
strip.text = element_blank())+
labs(y="integrated, directional CT changes [mol/m2]", x="date")
p_iNCPcum <- NCP %>%
ggplot(aes(date_time_ID, dCT_cum, fill=dep))+
geom_hline(yintercept = 0)+
geom_area(col="black")+
scale_fill_viridis_d()+
scale_y_continuous(breaks = seq(-100, 100, 0.2))+
facet_grid(rev(sign)~., scales = "free_y", space = "free_y")+
theme(strip.background = element_blank(),
strip.text = element_blank())+
labs(y="integrated, cumulative, directional CT changes [mol/m2]", x="date")
(p_iNCP / p_iNCPcum)+
plot_layout(guides = 'collect')
rm(p_iNCP, p_iNCPcum)
As primary production (negative changes in CT) and increase in seawater temperature have a common driver (light), the relation between both changes was investigated.
CT_tem <- mean_profiles %>%
group_by(dep) %>%
arrange(date_time_ID) %>%
mutate(dCT = CT - lag(CT),
dtem = tem - lag(tem),
sign = if_else(dCT < 0, "neg", "pos")) %>%
ungroup() %>%
drop_na()
CT_tem %>%
ggplot()+
geom_hline(yintercept = 0)+
geom_vline(xintercept = 0)+
geom_smooth(aes(dtem, dCT), method = "lm", se=FALSE)+
geom_point(aes(dtem, dCT, fill=ID), shape=21)+
scale_fill_viridis_d()+
guides(fill = guide_legend(override.aes=list(shape=21)))
CT_tem %>%
ggplot(aes(dtem, dCT))+
geom_hline(yintercept = 0)+
geom_vline(xintercept = 0)+
geom_smooth(method = "lm", se=FALSE)+
geom_point(aes(fill=ID), shape = 21)+
scale_fill_viridis_d()+
guides(fill = guide_legend(override.aes=list(shape=21)))+
facet_wrap(~ID)
bin_CT <- 20
CT_hov <- mean_profiles_long %>%
filter(parameter == "CT") %>%
ggplot()+
geom_contour_fill(aes(x=date_time_ID, y=dep, z=value),
breaks = MakeBreaks(bin_CT),
col="black")+
geom_point(aes(x=date_time_ID, y=c(24.5)), size=3, shape=24, fill="white")+
scale_fill_viridis_c(breaks = MakeBreaks(bin_CT),
guide = "colorstrip",
name="CT (µmol/kg)")+
scale_y_reverse()+
theme_bw()+
labs(y="Depth (m)")+
coord_cartesian(expand = 0)+
theme(axis.title.x = element_blank(),
axis.text.x = element_blank())
bin_Tem <- 2
Tem_hov <- mean_profiles_long %>%
filter(parameter == "tem") %>%
ggplot()+
geom_contour_fill(aes(x=date_time_ID, y=dep, z=value),
breaks = MakeBreaks(bin_Tem),
col="black")+
geom_point(aes(x=date_time_ID, y=c(24.5)), size=3, shape=24, fill="white")+
scale_fill_viridis_c(breaks = MakeBreaks(bin_Tem),
guide = "colorstrip",
name="Tem (°C)",
option = "inferno")+
scale_y_reverse()+
theme_bw()+
labs(x="",y="Depth (m)")+
coord_cartesian(expand = 0)
CT_hov / Tem_hov
rm(CT_hov, bin_CT, Tem_hov, bin_Tem)
bin_CT <- 2.5
CT_hov <- mean_profiles_long %>%
filter(parameter == "CT") %>%
ggplot()+
geom_contour_fill(aes(x=date_time_ID, y=dep, z=diff_value_daily),
breaks = MakeBreaks(bin_CT),
col="black")+
geom_point(aes(x=date_time_ID, y=c(24.5)), size=3, shape=24, fill="white")+
scale_fill_divergent(breaks = MakeBreaks(bin_CT),
guide = "colorstrip",
name="CT (µmol/kg)")+
scale_y_reverse()+
theme_bw()+
labs(y="Depth (m)")+
coord_cartesian(expand = 0)+
theme(axis.title.x = element_blank(),
axis.text.x = element_blank())
bin_Tem <- 0.1
Tem_hov <- mean_profiles_long %>%
filter(parameter == "tem") %>%
ggplot()+
geom_contour_fill(aes(x=date_time_ID, y=dep, z=diff_value_daily),
breaks = MakeBreaks(bin_Tem),
col="black")+
geom_point(aes(x=date_time_ID, y=c(24.5)), size=3, shape=24, fill="white")+
scale_fill_divergent(breaks = MakeBreaks(bin_Tem),
guide = "colorstrip",
name="Tem (°C)")+
scale_y_reverse()+
theme_bw()+
labs(x="",y="Depth (m)")+
coord_cartesian(expand = 0)
CT_hov / Tem_hov
rm(CT_hov, bin_CT, Tem_hov, bin_Tem)
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] cmocean_0.2 scico_1.1.0 metR_0.5.0 seacarb_3.2.12
[5] oce_1.2-0 gsw_1.0-5 testthat_2.3.1 patchwork_1.0.0
[9] forcats_0.4.0 stringr_1.4.0 dplyr_0.8.3 purrr_0.3.3
[13] readr_1.3.1 tidyr_1.0.0 tibble_2.1.3 ggplot2_3.3.0
[17] tidyverse_1.3.0
loaded via a namespace (and not attached):
[1] nlme_3.1-137 bitops_1.0-6 fs_1.3.1
[4] lubridate_1.7.4 RColorBrewer_1.1-2 httr_1.4.1
[7] rprojroot_1.3-2 tools_3.5.0 backports_1.1.5
[10] R6_2.4.0 mgcv_1.8-23 DBI_1.0.0
[13] colorspace_1.4-1 withr_2.1.2 sp_1.3-2
[16] tidyselect_0.2.5 gridExtra_2.3 compiler_3.5.0
[19] git2r_0.26.1 cli_1.1.0 rvest_0.3.5
[22] xml2_1.2.2 labeling_0.3 scales_1.0.0
[25] checkmate_1.9.4 digest_0.6.22 foreign_0.8-70
[28] rmarkdown_2.0 pkgconfig_2.0.3 htmltools_0.4.0
[31] highr_0.8 dbplyr_1.4.2 maps_3.3.0
[34] rlang_0.4.5 readxl_1.3.1 rstudioapi_0.10
[37] generics_0.0.2 jsonlite_1.6 RCurl_1.95-4.12
[40] magrittr_1.5 Formula_1.2-3 dotCall64_1.0-0
[43] Matrix_1.2-14 Rcpp_1.0.2 munsell_0.5.0
[46] lifecycle_0.1.0 stringi_1.4.3 yaml_2.2.0
[49] plyr_1.8.4 grid_3.5.0 maptools_0.9-8
[52] formula.tools_1.7.1 promises_1.1.0 crayon_1.3.4
[55] lattice_0.20-35 haven_2.2.0 hms_0.5.2
[58] zeallot_0.1.0 knitr_1.26 pillar_1.4.2
[61] reprex_0.3.0 glue_1.3.1 evaluate_0.14
[64] data.table_1.12.6 modelr_0.1.5 operator.tools_1.6.3
[67] vctrs_0.2.0 spam_2.3-0.2 httpuv_1.5.2
[70] cellranger_1.1.0 gtable_0.3.0 assertthat_0.2.1
[73] xfun_0.10 broom_0.5.3 later_1.0.0
[76] viridisLite_0.3.0 memoise_1.1.0 fields_9.9
[79] workflowr_1.6.0 ellipsis_0.3.0 here_0.1