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Carried out cluster analysis having first set options and determined the data sets on which that cluster analysis should be based on.
location of pre-prepared data
What category of data is the cluster analysis related to
# opt_category
opt_category <- "bgc_doxy"
Define options that are used to determine the nature of the cluster analysis that is carried out.
# Options
# opt_num_clusters
# How many clusters are used in the cluster analysis for each depth 1 (600 m), 2 (1000 m) and 3 (1500 m)
opt_num_clusters_min <- c(8, 8, 4)
opt_num_clusters_max <- c(8, 8, 5)
# Which profile range is used
opt_profile_range <- 3
# options relating to cluster analysis
opt_n_start <- 15
opt_max_iterations <- 500
opt_n_clusters <- 14 # Max number of clusters to try when determining optimal number of clusters
# opt_extreme_determination
# 1 - based on the trend of de-seasonal data - we believe this results in more summer extremes where variation tend to be greater.
# 2 - based on the trend of de-seasonal data by month. grouping is by lat, lon and month.
opt_extreme_determination <- 2
# Options associated with profiles under surface extreme conditions
extreme_type <- c('L', 'N', 'H')
opt_num_clusters_ext_min <- c(4, 4, 4)
opt_num_clusters_ext_max <- c(5, 5, 5)
# Option related to normalising the anomaly profiles.
# TRUE - anomaly profiles are normalised by the surface anomaly. Every depth anomaly is divided by the surface anomaly.
# - The is only carried out for profiles where the abs(surface temp) > 1.
# - This analysis is carried out in addition to the analysis on base anomaly profiles.
# FALSE - The normalisation process is not carried out.
opt_norm_anomaly <- TRUE
theme_set(theme_bw())
map <-
read_rds(paste(path_emlr_utilities,
"map_landmask_WOA18.rds",
sep = ""))
Prepare data for cluster analysis
if (opt_category == "bgc_doxy") {
# ---------------------------------------------------------------------------------------------
# spatial restrictions
# ---------------------------------------------------------------------------------------------
# global
opt_lat_min <- -90
opt_lat_max <- 90
opt_lon_min <- 20
opt_lon_max <- 380
# Mapping latitude limits
opt_map_lat_limit <- c(-85, 85) # global
# ---------------------------------------------------------------------------------------------
# read data - bgc oxygen must have a ph profile
# ---------------------------------------------------------------------------------------------
# read data, applying geographical limits and standardize field names.
anomaly_va <-
read_rds(file = paste0(path_argo_preprocessed, "/doxy_anomaly_va.rds")) %>%
filter (lat >= opt_lat_min &
lat <= opt_lat_max &
lon >= opt_lon_min &
lon <= opt_lon_max) %>%
select(file_id,
date,
year,
month,
lat,
lon,
profile_range,
depth,
prof_measure = doxy,
clim_measure = clim_doxy,
anomaly
)
# ---------------------------------------------------------------------------------------------
# Associated data restrictions and formatting
# ---------------------------------------------------------------------------------------------
# What is the max depth of each profile_range
opt_max_depth <- c(600, 1000, 1500)
# opt_measure_label, opt_xlim and opt_xbreaks are associated with formatting
opt_measure_label <- expression("dissolved oxygen anomaly ( µmol kg"^"-1"~")")
opt_xlim <- c(-40, 40)
opt_xbreaks <- c(-40, -20, 0, 20, 40)
# adjusted to be in scale -1 to 1
opt_measure_label_adjusted <- "adjusted oxygen anomaly"
opt_xlim_adjusted <- c(-1, 1)
opt_xbreaks_adjusted <- c(-1.0, -0.5, 0, 0.5, 1.0)
# Under extreme analysis
opt_extreme_analysis <- FALSE
}
# select profile based on profile_range and the appropriate max depth
anomaly_va <- anomaly_va %>%
filter(profile_range == opt_profile_range & depth <= opt_max_depth[opt_profile_range])
# Simplified table ready to pivot
anomaly_va_id <- anomaly_va %>%
select(file_id,
depth,
anomaly,
year,
month,
lat,
lon)
# wide table with each depth becoming a column
anomaly_va_wide <- anomaly_va_id %>%
select(file_id, depth, anomaly) %>%
pivot_wider(names_from = depth, values_from = anomaly)
# Drop any rows with missing values N/A caused by gaps in climatology data
anomaly_va_wide <- anomaly_va_wide %>%
drop_na()
# Table for cluster analysis
points <- anomaly_va_wide %>%
column_to_rownames(var = "file_id")
# normalisation?
if (opt_norm_anomaly) {
# Get the maximum anomaly for each profile - the normalisation will then fit -1 to 1
anomaly_va_id_normalised <- anomaly_va_id %>%
group_by(file_id) %>%
mutate(abs_ma = max(abs(anomaly))) %>%
ungroup()
# divide each anomaly by the maximum anomaly
anomaly_va_id_normalised <- anomaly_va_id_normalised %>%
mutate(anomaly = anomaly/abs_ma)
# wide table with each depth becoming a column
anomaly_va_wide <- anomaly_va_id_normalised %>%
select(file_id, depth, anomaly) %>%
pivot_wider(names_from = depth, values_from = anomaly)
# Drop any rows with missing values N/A caused by gaps in climatology data
anomaly_va_wide <- anomaly_va_wide %>%
drop_na()
# Table for cluster analysis
points_normalised <- anomaly_va_wide %>%
column_to_rownames(var = "file_id")
}
Based on all floats regardless of surface condition.
for (iType in 1:2) {
for (inum_clusters in opt_num_clusters_min[opt_profile_range]:opt_num_clusters_max[opt_profile_range]) {
if (iType == 1) {
set.seed(1)
kclusts <-
tibble(k = inum_clusters) %>%
mutate(kclust = map(k, ~ kmeans(points, .x, iter.max = opt_max_iterations, nstart = opt_n_start)),
tidied = map(kclust, tidy),
glanced = map(kclust, glance),
augmented = map(kclust, augment, points)
)
profile_id <-
kclusts %>%
unnest(cols = c(augmented)) %>%
select(file_id = .rownames,
cluster = .cluster) %>%
mutate(file_id = as.numeric(file_id),
cluster = as.character(cluster))
# Add cluster to anomaly_va_id
anomaly_cluster <-
full_join(anomaly_va_id, profile_id)
# Add profile_type field
anomaly_cluster <- anomaly_cluster %>%
mutate(profile_type = 'base')
# Check null clusters
anomaly_cluster <- anomaly_cluster %>%
filter(!is.na(cluster))
# Create table to be used for later analysis and Set the number of clusters field
if (!exists('anomaly_cluster_all')) {
anomaly_cluster_all <- anomaly_cluster %>%
mutate(num_clusters = inum_clusters)
} else {
anomaly_cluster_all <-
rbind(
anomaly_cluster_all,
anomaly_cluster %>%
mutate(num_clusters = inum_clusters)
)
}
} else if (iType == 2 & opt_norm_anomaly) {
set.seed(1)
kclusts <-
tibble(k = inum_clusters) %>%
mutate(kclust = map(k, ~ kmeans(points_normalised, .x, iter.max = opt_max_iterations, nstart = opt_n_start)),
tidied = map(kclust, tidy),
glanced = map(kclust, glance),
augmented = map(kclust, augment, points)
)
profile_id <-
kclusts %>%
unnest(cols = c(augmented)) %>%
select(file_id = .rownames,
cluster = .cluster) %>%
mutate(file_id = as.numeric(file_id),
cluster = as.character(cluster))
# Add cluster to anomaly_va
anomaly_cluster_norm <-
full_join(anomaly_va_id_normalised %>% select(-c(abs_ma)) ,
profile_id)
# Add profile_type field
anomaly_cluster_norm <- anomaly_cluster_norm %>%
mutate(profile_type = 'adjusted')
# Check null clusters
anomaly_cluster_norm <- anomaly_cluster_norm %>%
filter(!is.na(cluster))
# Create table to be used for later analysis and Set the number of clusters field
if (!exists('anomaly_cluster_all')) {
anomaly_cluster_all <- anomaly_cluster_norm %>%
mutate(num_clusters = inum_clusters)
} else {
anomaly_cluster_all <-
rbind(
anomaly_cluster_all,
anomaly_cluster_norm %>%
mutate(num_clusters = inum_clusters)
)
}
}
}
}
# Prepare to plot cluster mean
anomaly_cluster_mean <- anomaly_cluster_all %>%
group_by(profile_type, num_clusters, cluster, depth) %>%
summarise(
count_cluster = n(),
anomaly_mean = mean(anomaly, na.rm = TRUE),
anomaly_sd = sd(anomaly, na.rm = TRUE)
) %>%
ungroup()
anomaly_cluster_mean_year <- anomaly_cluster_all %>%
group_by(profile_type, num_clusters, cluster, depth, year) %>%
summarise(
count_cluster = n(),
anomaly_mean = mean(anomaly, na.rm = TRUE),
anomaly_sd = sd(anomaly, na.rm = TRUE)
) %>%
ungroup()
anomaly_year_mean <- anomaly_cluster_all %>%
group_by(profile_type, num_clusters, cluster, year) %>%
summarise(
count_cluster = n(),
anomaly_mean = mean(anomaly, na.rm = TRUE),
anomaly_sd = sd(anomaly, na.rm = TRUE)
) %>%
ungroup()
anomaly_year_mean <- anomaly_year_mean %>%
group_by(profile_type, num_clusters, year) %>%
summarise(anomaly_mean = mean(anomaly_mean, na.rm = TRUE)) %>%
ungroup ()
# Determine profile count by cluster and year
# Count the measurements
cluster_by_year <- anomaly_cluster_all %>%
count(profile_type, num_clusters, file_id, cluster, year,
name = "count_cluster")
# Convert to profiles
cluster_by_year <- cluster_by_year %>%
count(profile_type, num_clusters, cluster, year,
name = "count_cluster")
# total of each type of cluster
cluster_count <- cluster_by_year %>%
group_by(profile_type, num_clusters, cluster) %>%
summarise(count_profiles = sum(count_cluster)) %>%
ungroup()
anomaly_cluster_mean <- left_join(anomaly_cluster_mean, cluster_count)
Base profiles
# create figure of cluster mean profiles
anomaly_cluster_mean %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(data = .x,) +
geom_path(aes(x = anomaly_mean,
y = depth)) +
geom_ribbon(
aes(
xmax = anomaly_mean + anomaly_sd,
xmin = anomaly_mean - anomaly_sd,
y = depth
),
alpha = 0.2
) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")")) +
coord_cartesian(xlim = opt_xlim) +
scale_x_continuous(breaks = opt_xbreaks) +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = opt_measure_label,
y = 'depth (m)'
)
)
[[1]]
[[2]]
Adjusted profiles
if (opt_norm_anomaly) {
# repeat for adjusted profiles profiles
anomaly_cluster_mean %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(data = .x,) +
geom_path(aes(x = anomaly_mean,
y = depth)) +
geom_ribbon(
aes(
xmax = anomaly_mean + anomaly_sd,
xmin = anomaly_mean - anomaly_sd,
y = depth
),
alpha = 0.2
) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")")) +
coord_cartesian(xlim = opt_xlim_adjusted) +
scale_x_continuous(breaks = opt_xbreaks_adjusted) +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = opt_measure_label_adjusted,
y = 'depth (m)'
)
)
}
[[1]]
[[2]]
# cluster means by year
anomaly_cluster_mean_year %>%
filter (profile_type == "base") %>%
mutate(year = as.factor(year)) %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(data = .x, ) +
geom_path(aes(
x = anomaly_mean,
y = depth,
col = year
)) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
facet_wrap(~ cluster) +
coord_cartesian(xlim = opt_xlim) +
scale_x_continuous(breaks = opt_xbreaks) +
scale_color_viridis_d() +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = opt_measure_label,
y = 'depth (m)'
)
)
[[1]]
[[2]]
Adjusted profiles
if (opt_norm_anomaly) {
# Repeat for adjusted profiles
anomaly_cluster_mean_year %>%
filter (profile_type == "adjusted") %>%
mutate(year = as.factor(year)) %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(data = .x, ) +
geom_path(aes(
x = anomaly_mean,
y = depth,
col = year
)) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
facet_wrap(~ cluster) +
coord_cartesian(xlim = opt_xlim_adjusted) +
scale_x_continuous(breaks = opt_xbreaks_adjusted) +
scale_color_viridis_d() +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = opt_measure_label_adjusted,
y = 'depth (m)'
)
)
}
[[1]]
[[2]]
count of each cluster by year
year_min <- min(cluster_by_year$year)
year_max <- max(cluster_by_year$year)
# create figure
cluster_by_year %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(data = .x, aes(
x = year,
y = count_cluster,
col = cluster,
group = cluster
)) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(year_min, year_max, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
title = paste0(
'Count of profiles by year and cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = 'year',
y = 'number of profiles',
col = 'cluster'
)
)
[[1]]
[[2]]
Adjusted profiles
if (opt_norm_anomaly) {
year_min <- min(cluster_by_year$year)
year_max <- max(cluster_by_year$year)
# create figure
cluster_by_year %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(data = .x, aes(
x = year,
y = count_cluster,
col = cluster,
group = cluster
)) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(year_min, year_max, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
title = paste0(
'Count of profiles by year and cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = 'year',
y = 'number of profiles',
col = 'cluster'
)
)
}
[[1]]
[[2]]
count of each cluster by month of year
# Determine profile count by cluster and year
# Count the measurements
cluster_by_year <- anomaly_cluster_all %>%
count(profile_type, num_clusters, file_id, cluster, month,
name = "count_cluster")
# Convert to profiles
cluster_by_year <- cluster_by_year %>%
count(profile_type, num_clusters, cluster, month,
name = "count_cluster")
# create figure
cluster_by_year %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(
data = .x,
aes(
x = month,
y = count_cluster,
col = cluster,
group = cluster
)
) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(1, 12, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
title = paste0(
'Count of profiles by month and cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = 'month',
y = 'number of profiles',
col = 'cluster'
)
)
[[1]]
[[2]]
Adjusted profiles
if (opt_norm_anomaly) {
# create figure
cluster_by_year %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters) %>%
map(
~ ggplot(
data = .x,
aes(
x = month,
y = count_cluster,
col = cluster,
group = cluster
)
) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(1, 12, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
title = paste0(
'Count of profiles by month and cluster \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
x = 'month',
y = 'number of profiles',
col = 'cluster'
)
)
}
[[1]]
[[2]]
location of each cluster on map, spatial analysis
# create figure
anomaly_cluster_all %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters) %>%
map(
~ map +
geom_tile(data = .x,
aes(
x = lon,
y = lat,
fill = cluster
)) +
lims(y = opt_map_lat_limit) +
scale_fill_brewer(palette = 'Dark2') +
labs(
title = paste0(
'cluster spatial distribution \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
)
)
[[1]]
[[2]]
Adjusted profiles
if (opt_norm_anomaly) {
# create figure
anomaly_cluster_all %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters) %>%
map(
~ map +
geom_tile(data = .x,
aes(
x = lon,
y = lat,
fill = cluster
)) +
lims(y = opt_map_lat_limit) +
scale_fill_brewer(palette = 'Dark2') +
labs(
title = paste0(
'cluster spatial distribution \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
),
)
)
}
[[1]]
[[2]]
count of measurements for each cluster on separate maps, spatial analysis
# Count profiles
cluster_by_location <- anomaly_cluster_all %>%
count(profile_type, num_clusters, file_id, lat, lon, cluster,
name = "count_cluster")
# # Add cluster counts to
cluster_by_location <- left_join(cluster_by_location, cluster_count)
# create figure
cluster_by_location %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters) %>%
map(
~ map +
geom_tile(data = .x %>%
count(lat, lon, cluster, count_profiles),
aes(
x = lon,
y = lat,
fill = n
)) +
lims(y = opt_map_lat_limit) +
scale_fill_gradient(low = "blue",
high = "red",
trans = "log10") +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")"), ncol = 2) +
labs(
title = paste0(
'cluster spatial distribution \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
)
)
)
[[1]]
[[2]]
Adjusted profiles
if (opt_norm_anomaly) {
# create figure
cluster_by_location %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters) %>%
map(
~ map +
geom_tile(data = .x %>%
count(lat, lon, cluster, count_profiles),
aes(
x = lon,
y = lat,
fill = n
)) +
lims(y = opt_map_lat_limit) +
scale_fill_gradient(low = "blue",
high = "red",
trans = "log10") +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")"), ncol = 2) +
labs(
title = paste0(
'cluster spatial distribution \n',
'type = ', unique(.x$profile_type), ', ',
'num clusters = ', unique(.x$num_clusters)
)
)
)
}
[[1]]
[[2]]
Cluster analysis of oxygen profiles under temperature extremes
if (opt_category == "bgc_doxy") {
# ---------------------------------------------------------------------------------------------
# read data extreme data for later use
# ---------------------------------------------------------------------------------------------
# load previously created OceanSODA extreme data. date, position and nature of extreme
if (opt_extreme_determination == 1){
extreme_data <- read_rds(file = paste0(path_argo_preprocessed, "/OceanSODA_global_SST_anomaly_field_01.rds")) %>%
select(lon, lat, date, extreme_flag = temp_extreme)
} else if (opt_extreme_determination == 2){
extreme_data <- read_rds(file = paste0(path_argo_preprocessed, "/OceanSODA_global_SST_anomaly_field_02.rds")) %>%
select(lon, lat, date, extreme_flag = temp_extreme)
}
# Under extreme analysis
opt_extreme_analysis <- TRUE
}
if (opt_extreme_analysis){
# date to match to ocean SODA
anomaly_va <- anomaly_va %>%
mutate(date = ymd(format(date, "%Y-%m-15")))
# Add the OceanSODA extreme condition
anomaly_va <- left_join(anomaly_va, extreme_data)
# If extreme is NA set it to N
anomaly_va <- anomaly_va %>% replace_na(list(extreme_flag = 'N'))
anomaly_va <- anomaly_va %>% mutate (profile_type = 'base')
# Create a replica data set with profile_type = adjusted
if (opt_norm_anomaly){
# mark as adjusted
anomaly_va_norm <- anomaly_va %>% mutate (profile_type = 'adjusted')
# Get the maximum anomaly for each profile - the normalisation will then fit -1 to 1
anomaly_va_norm <- anomaly_va_norm %>%
group_by(file_id) %>%
mutate(abs_ma = max(abs(anomaly))) %>%
ungroup()
# Carry out the adjustment
anomaly_va_norm <- anomaly_va_norm %>%
mutate(anomaly = anomaly/abs_ma)
#remove the surface anomaly field
anomaly_va_norm <- anomaly_va_norm %>% select(-c(abs_ma))
# Append to base profiles
anomaly_va <- rbind(anomaly_va, anomaly_va_norm)
}
profile_types <- c('adjusted', 'base')
# loop through profile_type
for (iprofile_type in 1:2) {
sel_profile_type = profile_types[iprofile_type]
# loop through surface condition
for (i in 1:3) {
# ---------------------------------------------------------------------------------------------
# Preparation
# ---------------------------------------------------------------------------------------------
# select profile based on profile_range and he appropriate max depth
anomaly_va_id <- anomaly_va %>%
filter(profile_range == opt_profile_range & depth <= opt_max_depth[opt_profile_range] & extreme_flag == extreme_type[i] & profile_type == sel_profile_type)
# Simplified table ready to pivot
anomaly_va_id <- anomaly_va_id %>%
select(file_id,
depth,
anomaly,
year,
month,
lat,
lon)
# wide table with each depth becoming a column
anomaly_va_wide <- anomaly_va_id %>%
select(file_id, depth, anomaly) %>%
pivot_wider(names_from = depth, values_from = anomaly)
# Drop any rows with missing values N/A caused by gaps in climatology data
anomaly_va_wide <- anomaly_va_wide %>%
drop_na()
# Table for cluster analysis
points <- anomaly_va_wide %>%
column_to_rownames(var = "file_id")
# ---------------------------------------------------------------------------------------------
# cluster analysis
# ---------------------------------------------------------------------------------------------
# loop through number of clusters
for (inum_clusters in opt_num_clusters_ext_min[i]:opt_num_clusters_ext_max[i]) {
set.seed(1)
kclusts <-
tibble(k = inum_clusters) %>%
mutate(
kclust = map(k, ~ kmeans(points, .x, iter.max = opt_max_iterations, nstart = opt_n_start)),
tidied = map(kclust, tidy),
glanced = map(kclust, glance),
augmented = map(kclust, augment, points)
)
profile_id <-
kclusts %>%
unnest(cols = c(augmented)) %>%
select(file_id = .rownames,
cluster = .cluster) %>%
mutate(file_id = as.numeric(file_id),
cluster = as.character(cluster))
# Add cluster to anomaly_va
anomaly_cluster <- full_join(anomaly_va_id, profile_id)
# Plot cluster mean
anomaly_cluster <- anomaly_cluster %>%
filter(!is.na(cluster))
# cluster mean
anomaly_cluster_mean <- anomaly_cluster %>%
group_by(cluster, depth) %>%
summarise(
count_cluster = n(),
anomaly_mean = mean(anomaly, na.rm = TRUE),
anomaly_sd = sd(anomaly, na.rm = TRUE)
) %>%
ungroup()
anomaly_cluster_mean_year <- anomaly_cluster %>%
group_by(cluster, depth, year) %>%
summarise(
count_cluster = n(),
anomaly_mean = mean(anomaly, na.rm = TRUE),
anomaly_sd = sd(anomaly, na.rm = TRUE)
) %>%
ungroup()
anomaly_year_mean <- anomaly_cluster %>%
group_by(cluster, year) %>%
summarise(
count_cluster = n(),
anomaly_mean = mean(anomaly, na.rm = TRUE),
anomaly_sd = sd(anomaly, na.rm = TRUE)
) %>%
ungroup()
anomaly_year_mean <- anomaly_year_mean %>%
group_by(year) %>%
summarise(anomaly_mean = mean(anomaly_mean, na.rm = TRUE)) %>%
ungroup ()
if (!exists('anomaly_cluster_mean_ext')) {
anomaly_cluster_mean_ext <-
anomaly_cluster_mean %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
anomaly_cluster_mean_year_ext <-
anomaly_cluster_mean_year %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
anomaly_year_mean_ext <-
anomaly_year_mean %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
anomaly_cluster_ext <-
anomaly_cluster %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
} else {
anomaly_cluster_mean_ext <-
rbind(
anomaly_cluster_mean_ext,
anomaly_cluster_mean %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
)
anomaly_cluster_mean_year_ext <-
rbind(
anomaly_cluster_mean_year_ext,
anomaly_cluster_mean_year %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
)
anomaly_year_mean_ext <-
rbind(
anomaly_year_mean_ext,
anomaly_year_mean %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
)
anomaly_cluster_ext <-
rbind(
anomaly_cluster_ext,
anomaly_cluster_ext <-
anomaly_cluster %>% mutate(
extreme_order = i,
extreme = extreme_type[i],
num_clusters = inum_clusters,
profile_type = sel_profile_type
)
)
}
}
}
}
}
if (opt_extreme_analysis){
# Determine profile count by cluster and year
# Count the measurements
cluster_by_year <- anomaly_cluster_ext %>%
count(profile_type, num_clusters, extreme, extreme_order, file_id, cluster, year,
name = "count_cluster")
# Convert to profiles
cluster_by_year <- cluster_by_year %>%
count(profile_type, num_clusters, extreme, extreme_order, cluster, year,
name = "count_cluster")
# total of each type of cluster
cluster_count <- cluster_by_year %>%
group_by(profile_type, num_clusters, extreme, extreme_order, cluster) %>%
summarise(count_profiles = sum(count_cluster)) %>%
ungroup()
anomaly_cluster_mean_ext <- left_join(anomaly_cluster_mean_ext, cluster_count)
# create figure of cluster mean profiles
anomaly_cluster_mean_ext %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(data = .x, ) +
geom_path(aes(x = anomaly_mean,
y = depth)) +
geom_ribbon(
aes(
xmax = anomaly_mean + anomaly_sd,
xmin = anomaly_mean - anomaly_sd,
y = depth
),
alpha = 0.2
) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
#facet_wrap(~ cluster) +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")")) +
coord_cartesian(xlim = opt_xlim) +
scale_x_continuous(breaks = opt_xbreaks) +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
),
x = opt_measure_label,
y = 'depth (m)'
)
)
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
Adjusted profiles
if (opt_extreme_analysis){
if (opt_norm_anomaly) {
# create figure of cluster mean profiles
anomaly_cluster_mean_ext %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(data = .x, ) +
geom_path(aes(x = anomaly_mean,
y = depth)) +
geom_ribbon(
aes(
xmax = anomaly_mean + anomaly_sd,
xmin = anomaly_mean - anomaly_sd,
y = depth
),
alpha = 0.2
) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
#facet_wrap(~ cluster) +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")")) +
coord_cartesian(xlim = opt_xlim_adjusted) +
scale_x_continuous(breaks = opt_xbreaks_adjusted) +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
),
x = opt_measure_label_adjusted,
y = 'depth (m)'
)
)
}
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
if (opt_extreme_analysis){
# cluster means by year
anomaly_cluster_mean_year_ext %>%
filter (profile_type == "base") %>%
mutate(year = as.factor(year)) %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(data = .x,) +
geom_path(aes(
x = anomaly_mean,
y = depth,
col = year
)) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
facet_wrap(~ cluster) +
coord_cartesian(xlim = opt_xlim) +
scale_x_continuous(breaks = opt_xbreaks) +
scale_color_viridis_d() +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster by year \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
),
x = opt_measure_label,
y = 'depth (m)'
)
)
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
Adjusted profiles
if (opt_extreme_analysis){
if (opt_norm_anomaly) {
# cluster means by year
anomaly_cluster_mean_year_ext %>%
filter (profile_type == "adjusted") %>%
mutate(year = as.factor(year)) %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(data = .x,) +
geom_path(aes(
x = anomaly_mean,
y = depth,
col = year
)) +
geom_vline(xintercept = 0) +
scale_y_reverse() +
facet_wrap(~ cluster) +
coord_cartesian(xlim = opt_xlim_adjusted) +
scale_x_continuous(breaks = opt_xbreaks_adjusted) +
scale_color_viridis_d() +
labs(
title = paste0(
'Overall mean anomaly profiles by cluster by year \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
),
x = opt_measure_label_adjusted,
y = 'depth (m)'
)
)
}
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
count of each cluster by year
if (opt_extreme_analysis){
# Determine profile count by extreme and cluster and year
# Count the measurements
cluster_by_year <- anomaly_cluster_ext %>%
count(file_id, profile_type, num_clusters, extreme_order, extreme, cluster, year,
name = "count_cluster")
# Convert to profiles
cluster_by_year <- cluster_by_year %>%
count(profile_type, num_clusters, extreme_order, extreme, cluster, year,
name = "count_cluster")
year_min <- min(cluster_by_year$year)
year_max <- max(cluster_by_year$year)
# create figure
cluster_by_year %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(
data = .x,
aes(
x = year,
y = count_cluster,
col = cluster,
group = cluster
)
) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(year_min, year_max, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
x = 'year',
y = 'number of profiles',
col = 'cluster',
title = paste0(
'Count of profiles by year and cluster \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
Adjusted profiles
if (opt_extreme_analysis){
if (opt_norm_anomaly) {
# create figure
cluster_by_year %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(
data = .x,
aes(
x = year,
y = count_cluster,
col = cluster,
group = cluster
)
) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(year_min, year_max, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
x = 'year',
y = 'number of profiles',
col = 'cluster',
title = paste0(
'Count of profiles by year and cluster \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
count of each cluster by month of year
if (opt_extreme_analysis){
# Determine profile count by cluster and year
# Count the measurements
cluster_by_year <- anomaly_cluster_ext %>%
count(file_id, profile_type, num_clusters, extreme_order, extreme, cluster, month,
name = "count_cluster")
# Convert to profiles
cluster_by_year <- cluster_by_year %>%
count(profile_type, num_clusters, extreme_order, extreme, cluster, month,
name = "count_cluster")
# create figure
cluster_by_year %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(
data = .x,
aes(
x = month,
y = count_cluster,
col = cluster,
group = cluster
)
) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(1, 12, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
x = 'month',
y = 'number of profiles',
col = 'cluster',
title = paste0(
'Count of profiles by month and cluster \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
Adjusted profiles
if (opt_extreme_analysis){
if (opt_norm_anomaly) {
# create figure
cluster_by_year %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ ggplot(
data = .x,
aes(
x = month,
y = count_cluster,
col = cluster,
group = cluster
)
) +
geom_point() +
geom_line() +
scale_x_continuous(breaks = seq(1, 12, 2)) +
scale_color_brewer(palette = 'Dark2') +
labs(
x = 'month',
y = 'number of profiles',
col = 'cluster',
title = paste0(
'Count of profiles by month and cluster \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
location of each cluster on map, spatial analysis
if (opt_extreme_analysis){
# create figure combined
anomaly_cluster_ext %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ map +
geom_tile(data = .x,
aes(
x = lon,
y = lat,
fill = cluster
)) +
lims(y = opt_map_lat_limit) +
scale_fill_brewer(palette = 'Dark2') +
labs(
title = paste0(
'cluster spatial distribution \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
Adjusted profiles
if (opt_extreme_analysis){
if (opt_norm_anomaly) {
# create figure combined
anomaly_cluster_ext %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ map +
geom_tile(data = .x,
aes(
x = lon,
y = lat,
fill = cluster
)) +
lims(y = opt_map_lat_limit) +
scale_fill_brewer(palette = 'Dark2') +
labs(
title = paste0(
'cluster spatial distribution \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
location of each cluster on map, spatial analysis
if (opt_extreme_analysis){
# Count profiles
cluster_by_location <- anomaly_cluster_ext %>%
count(profile_type, num_clusters, extreme_order, extreme, file_id, lat, lon, cluster,
name = "count_cluster")
# # Add cluster counts to
cluster_by_location <- left_join(cluster_by_location, cluster_count)
# create figure
cluster_by_location %>%
filter (profile_type == "base") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ map +
geom_tile(data = .x %>%
count(lat, lon, cluster, count_profiles),
aes(
x = lon,
y = lat,
fill = n
)) +
lims(y = opt_map_lat_limit) +
scale_fill_gradient(low = "blue",
high = "red",
trans = "log10") +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")"), ncol = 2) +
labs(
title = paste0(
'cluster spatial distribution \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
Adjusted profiles
if (opt_extreme_analysis){
if (opt_norm_anomaly) {
cluster_by_location %>%
filter (profile_type == "adjusted") %>%
group_split(profile_type, num_clusters, extreme_order) %>%
map(
~ map +
geom_tile(data = .x %>%
count(lat, lon, cluster, count_profiles),
aes(
x = lon,
y = lat,
fill = n
)) +
lims(y = opt_map_lat_limit) +
scale_fill_gradient(low = "blue",
high = "red",
trans = "log10") +
facet_wrap(~ paste0(cluster, " (", formatC(count_profiles, big.mark=",") , ")"), ncol = 2) +
labs(
title = paste0(
'cluster spatial distribution \n',
'profile type: ', unique(.x$profile_type), ', ',
'surface extreme: ', unique(.x$extreme), ', ',
'number clusters: ', unique(.x$num_clusters)
)
)
)
}
}
[[1]]
[[2]]
[[3]]
[[4]]
[[5]]
[[6]]
sessionInfo()
R version 4.2.2 (2022-10-31)
Platform: x86_64-pc-linux-gnu (64-bit)
Running under: openSUSE Leap 15.5
Matrix products: default
BLAS: /usr/local/R-4.2.2/lib64/R/lib/libRblas.so
LAPACK: /usr/local/R-4.2.2/lib64/R/lib/libRlapack.so
locale:
[1] LC_CTYPE=en_US.UTF-8 LC_NUMERIC=C
[3] LC_TIME=en_US.UTF-8 LC_COLLATE=en_US.UTF-8
[5] LC_MONETARY=en_US.UTF-8 LC_MESSAGES=en_US.UTF-8
[7] LC_PAPER=en_US.UTF-8 LC_NAME=C
[9] LC_ADDRESS=C LC_TELEPHONE=C
[11] LC_MEASUREMENT=en_US.UTF-8 LC_IDENTIFICATION=C
attached base packages:
[1] stats graphics grDevices utils datasets methods base
other attached packages:
[1] yardstick_1.2.0 workflowsets_1.0.1 workflows_1.1.3 tune_1.1.2
[5] rsample_1.2.0 recipes_1.0.8 parsnip_1.1.1 modeldata_1.2.0
[9] infer_1.0.5 dials_1.2.0 scales_1.2.1 broom_1.0.5
[13] tidymodels_1.1.1 ggforce_0.4.1 gsw_1.1-1 gridExtra_2.3
[17] lubridate_1.9.0 timechange_0.1.1 argodata_0.1.0 forcats_0.5.2
[21] stringr_1.5.0 dplyr_1.1.3 purrr_1.0.2 readr_2.1.3
[25] tidyr_1.3.0 tibble_3.2.1 ggplot2_3.4.4 tidyverse_1.3.2
loaded via a namespace (and not attached):
[1] googledrive_2.0.0 colorspace_2.0-3 ellipsis_0.3.2
[4] class_7.3-20 rprojroot_2.0.3 fs_1.5.2
[7] rstudioapi_0.15.0 listenv_0.8.0 furrr_0.3.1
[10] farver_2.1.1 prodlim_2019.11.13 fansi_1.0.3
[13] xml2_1.3.3 codetools_0.2-18 splines_4.2.2
[16] cachem_1.0.6 knitr_1.41 polyclip_1.10-4
[19] jsonlite_1.8.3 workflowr_1.7.0 dbplyr_2.2.1
[22] compiler_4.2.2 httr_1.4.4 backports_1.4.1
[25] assertthat_0.2.1 Matrix_1.5-3 fastmap_1.1.0
[28] gargle_1.2.1 cli_3.6.1 later_1.3.0
[31] tweenr_2.0.2 htmltools_0.5.8.1 tools_4.2.2
[34] gtable_0.3.1 glue_1.6.2 Rcpp_1.0.10
[37] cellranger_1.1.0 jquerylib_0.1.4 RNetCDF_2.6-1
[40] DiceDesign_1.9 vctrs_0.6.4 iterators_1.0.14
[43] timeDate_4021.106 xfun_0.35 gower_1.0.0
[46] globals_0.16.2 rvest_1.0.3 lifecycle_1.0.3
[49] googlesheets4_1.0.1 future_1.29.0 MASS_7.3-58.1
[52] ipred_0.9-13 hms_1.1.2 promises_1.2.0.1
[55] parallel_4.2.2 RColorBrewer_1.1-3 yaml_2.3.6
[58] sass_0.4.4 rpart_4.1.19 stringi_1.7.8
[61] highr_0.9 foreach_1.5.2 lhs_1.1.6
[64] hardhat_1.3.0 lava_1.7.0 rlang_1.1.1
[67] pkgconfig_2.0.3 evaluate_0.18 lattice_0.20-45
[70] labeling_0.4.2 tidyselect_1.2.0 here_1.0.1
[73] parallelly_1.32.1 magrittr_2.0.3 R6_2.5.1
[76] generics_0.1.3 DBI_1.2.2 pillar_1.9.0
[79] haven_2.5.1 whisker_0.4 withr_2.5.0
[82] survival_3.4-0 nnet_7.3-18 future.apply_1.10.0
[85] modelr_0.1.10 crayon_1.5.2 utf8_1.2.2
[88] tzdb_0.3.0 rmarkdown_2.18 grid_4.2.2
[91] readxl_1.4.1 git2r_0.30.1 reprex_2.0.2
[94] digest_0.6.30 httpuv_1.6.6 GPfit_1.0-8
[97] munsell_0.5.0 viridisLite_0.4.1 bslib_0.4.1