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MakieLayout_data_2D_slider.jl
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MakieLayout_data_2D_slider.jl
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using Makie, MakieLayout, Dates, GLMakie, GeometryTypes, SparseArrays, UnicodeFun, Printf
using PlotUtils: optimize_ticks
function MakieLayout.legendelements(plot::BarPlot)
MakieLayout.LegendElement[PolyElement(color = plot.color, strokecolor = plot.strokecolor)]
end
# this is for Precip legend, won't be needed in futur version of MakieLayout
include("Load_Data_v2.jl");
include("DAMM.jl");
include("DAMM_param.jl");
function loaddata()
# Load raw data, functions below can be found in Load_Data.jl
data = loadteros("Input\\TEROS\\")
metdata = loadmet("Input\\MET TOWER\\")
x, y = loadmeta("Input\\Metadata.csv")
Dtime = collect(Dates.DateTime(DateTime(2019, 11, 23, 00, 00, 00)):Dates.Minute(30):now())
SWC = loadSWC(data, Dtime)
Tsoil = loadTsoil(data, Dtime)
Dtime_met_c, Precip_c, Precip_d, Dtime_met_d = Precips(metdata)
Dtime_all = collect(Date(2019, 11, 23):Day(1):today()) # Need same datetime (daily) for SWC data and met data
Tsoil_daily, Tsoil_daily_mean, Tsoil_daily_std = dailyval(Tsoil, Dtime_all)
SWC_daily, SWC_daily_mean, SWC_daily_std = dailyval(SWC, Dtime_all)
Precip_daily = Precipdaily(Precip_d, Dtime_all, Dtime_met_d)
# Until I figure how to deal with missing data (in Makie.jl)
SWC_daily = replace(SWC_daily, missing=>0.0); SWC_daily_mean = replace(SWC_daily_mean, missing=>0.0); SWC_daily_std = replace(SWC_daily_std, missing=>0.0)
Tsoil_daily = replace(Tsoil_daily, missing=>0.0); Tsoil_daily_mean = replace(Tsoil_daily_mean, missing=>0.0); Tsoil_daily_std = replace(Tsoil_daily_std, missing=>0.0)
Precip_c = replace(Precip_c, missing=>0.0);
# Trick until Makie.jl can work with datetime values
Dtime_all_rata = datetime2rata.(Dtime_all)
#Dtime_rata = datetime2rata.(Dtime)
dateticks = optimize_ticks(Dtime_all[1],Dtime_all[end])[1]
x = [0,0,0,1,1,1,2,2,2,3,3,3,4,4,4,5,5,5,6,6,6,7,7,7,0,0,1,1,2,2,3,3,4,4,5,5,6,6,7,7,0,0,0,1,1,1,2,2,2,3,3,3,4,4,4,5,5,5,6,6,6,7,7,7] .+ 1
y = [0,1,2,2,1,0,0,1,2,2,1,0,0,1,2,2,1,0,0,1,2,2,1,0,3,4,4,3,4,3,3,4,4,3,3,4,4,3,4,3,5,6,7,7,6,5,5,6,7,7,6,5,5,6,7,7,6,5,5,6,7,7,6,5] .+ 1
return (
data = data, metdata = metdata, x = x, y = y, Dtime = Dtime, SWC = SWC, Tsoil = Tsoil,
Dtime_met_c = Dtime_met_c, Precip_c = Precip_c, Precip_d = Precip_d, Dtime_met_d = Dtime_met_d, Dtime_all = Dtime_all,
Tsoil_daily = Tsoil_daily, Tsoil_daily_mean = Tsoil_daily_mean, Tsoil_daily_std = Tsoil_daily_std,
SWC_daily = SWC_daily, SWC_daily_mean = SWC_daily_mean, SWC_daily_std = SWC_daily_std,
Precip_daily = Precip_daily, Dtime_all_rata = Dtime_all_rata, dateticks = dateticks,
#Dtime_rata = Dtime_rata
)
end;
Data = loaddata();
# Modeled Rsoil
n_all = size(Data.SWC_daily, 1); # Below are random data, for now
PD = 3.1; porosity = 1-BD/PD # Avoid complexe number problem DAMM
Rsoil_daily = [DAMM.(Data.Tsoil_daily[i,:], Data.SWC_daily[i,:]) for i = 1:n_all];
Rsoil_daily = reduce(vcat, adjoint.(Rsoil_daily));
Rsoil_daily_mean = [mean(filter(x -> x > 0, Rsoil_daily[i,:])) for i = 1:n_all];
Rsoil_daily_std = [std(filter(x -> x > 0, Rsoil_daily[i,:])) for i = 1:n_all];
# Half-hourly
SWC = replace(Data.SWC , missing=>0.0);
Tsoil = replace(Data.Tsoil , missing=>0.0);
n = size(Data.Dtime, 1);
Rsoil_HH = [DAMM.(Tsoil[i,:], SWC[i,:]) for i = 1:n];
Rsoil_HH = reduce(vcat, adjoint.(Rsoil_HH));
Rsoil_HH_mean = [mean(filter(x -> x > 0, Rsoil_HH[i,:])) for i = 1:n];
Rsoil_HH_std = [std(filter(x -> x > 0, Rsoil_HH[i,:])) for i = 1:n];
# Could put this in Load_Data.jl
SWC_mean = [mean(skipmissing(Data.SWC[i,:])) for i = 1:size(Data.SWC,1)];
SWC_std = [std(skipmissing(Data.SWC[i,:])) for i = 1:size(Data.SWC,1)];
Tsoil_mean = [mean(skipmissing(Data.Tsoil[i,:])) for i = 1:size(Data.Tsoil,1)];
Tsoil_std = [std(skipmissing(Data.Tsoil[i,:])) for i = 1:size(Data.Tsoil,1)];
#Rsoil_mean = [mean(skipmissing(Data.SWC[i,:])) for i = 1:size(Data.SWC,1)]
# Create Scene and 2D axis
scene = Scene(resolution = (900, 900), camera=campixel!);
layout = GridLayout(
scene, 5, 3,
colsizes = [Auto(), Auto(), Auto()],
rowsizes = [Fixed(50), Auto(), Auto(), Auto(), Auto()],
alignmode = Outside(10, 10, 10, 10)
)
function formatter(xs)
map(xs) do x
str = @sprintf("%.2f", x)
startswith(str, "0") ? str[2:end] : str
end
end
ticks = CustomTicks((mi, ma, px) -> MakieLayout.locateticks(0.35, 0.48, 5), formatter)
#layout = layoutscene(6, 3, 10, resolution = (900, 900));
ax = Array{LAxis}(undef, 11);
sl = layout[6, 1:2] = LSlider(scene, range=1:n_all);
Text_date = layout[1,1:3] = LText(scene, text= lift(X->Dates.format(Data.Dtime_all[X], "e, dd u yyyy"), sl.value), textsize=40);
ax[1] = layout[5, 1:2] = LAxis(scene, yaxisposition = :right, xticklabelsvisible = false, xticksvisible = false, ylabelpadding = 15, xgridvisible = false, ygridvisible = false, yticklabelalign = (:left, :center), yticklabelsvisible = false, yticksvisible = false);
precipbar = barplot!(ax[1], Data.Dtime_all_rata[1:end], Data.Precip_daily[1:end], color = :blue, strokewidth = 2, strokecolor = :black);
scatter!(ax[1], lift(X-> [Point2f0(Data.Dtime_all_rata[X], 0)], sl.value), marker = :vline, markersize = Vec2f0(0.5, 200), color = :black);
#lines!(ax[1], lift(X-> Point2f0[(X, 0), (X, 60)], sl.value));
xlims!(ax[1], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[1], (0, 60));
ax[2] = layout[5, 1:2] = LAxis(scene, ylabel = to_latex("\\theta (m^3 m^{-3})"), xlabel="Date", ylabelpadding = 15, ygridvisible = false, xgridvisible = false);
lSWC = lines!(ax[2], Data.Dtime_all_rata[1:end], Data.SWC_daily_mean[1:end], color = :blue, linewidth = 2);
bSWC = band!(ax[2], Data.Dtime_all_rata[1:end], Data.SWC_daily_mean[1:end] + Data.SWC_daily_std[1:end], Data.SWC_daily_mean[1:end] - Data.SWC_daily_std[1:end], color = color = RGBAf0(0,0,1,0.3));
xlims!(ax[2], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[2], (0.36, 0.52));
ax[2].xticks[] = ManualTicks(datetime2rata.(Data.dateticks) , Dates.format.(Data.dateticks, "yy-mm-dd"));
ax[3] = layout[4, 1:2] = LAxis(scene, ylabel= to_latex("T_{soil} (°C)"), ylabelpadding = 15, xticklabelsvisible = false, xticksvisible = false, ygridvisible = false, xgridvisible = false);
lTs = lines!(ax[3], Data.Dtime_all_rata[1:end], Data.Tsoil_daily_mean[1:end], color = :red, linewidth = 2);
bTs = band!(ax[3], Data.Dtime_all_rata[1:end], Data.Tsoil_daily_mean[1:end] + Data.Tsoil_daily_std[1:end], Data.Tsoil_daily_mean[1:end] - Data.Tsoil_daily_std[1:end], color = RGBAf0(1,0,0,0.3));
scatter!(ax[3], lift(X-> [Point2f0(Data.Dtime_all_rata[X], 0)], sl.value), marker = :vline, markersize = Vec2f0(0.5,50), color = :black);
#lines!(ax[3], lift(X-> Point2f0[(X, 0), (X, 7)], sl.value));
xlims!(ax[3], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[3], (0, 7));
ax[3].xticks[] = ManualTicks(datetime2rata.(Data.dateticks) , Dates.format.(Data.dateticks, "yy-mm-dd"));
ax[4] = layout[4, 1:2] = LAxis(scene, xticklabelsvisible = false, xticksvisible = false, xgridvisible = false, ygridvisible = false, yaxisposition = :right, ylabelpadding = 15, yticklabelalign = (:left, :center), yticklabelsvisible = false, yticksvisible = false);
lRs = lines!(ax[4], Data.Dtime_all_rata[1:end], Rsoil_daily_mean[1:end], color = :green);
bRs = band!(ax[4], Data.Dtime_all_rata[1:end], Rsoil_daily_mean[1:end] + Rsoil_daily_std[1:end], Rsoil_daily_mean[1:end] - Rsoil_daily_std[1:end], color = RGBAf0(0,1,0,0.3));
xlims!(ax[4], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[4], (0.25, 0.6));
leg = layout[4, 1:2] = LLegend(scene, [[bTs, lTs], [bRs, lRs]], [to_latex("T_{soil} (°C)"), to_latex("R_{soil} (\\mumol m^{-2} s^{-1})")], halign = :right, valign = :top, orientation = :horizontal, framevisible = false);
#LLegend(scene; halign = :right, valign = :top, orientation = :horizontal, framevisible = false);
#push!(leg, to_latex("T_{soil} (°C)"), bTs, lTs);
#push!(leg, to_latex("R_{soil} (\\mumol m^{-2} s^{-1})"), bRs, lRs);
leg2 = layout[5, 1:2] = LLegend(scene, [[bSWC, lSWC], precipbar], [to_latex("\\theta (m^3 m^{-3})"), "Precip (mm)"], halign = :right, valign = :top, orientation = :horizontal, framevisible = false);
#LLegend(scene; halign = :right, valign = :top, orientation = :horizontal, framevisible = false);
#push!(leg2, to_latex("\\theta (m^3 m^{-3})"), bSWC, lSWC);
#push!(leg2, "Precip (mm)", precipbar);
ax[8] = layout[5, 3] = LAxis(scene, xlabel = "Half-hour", yticklabelsvisible = false, yticksvisible = false, xgridvisible = false, ygridvisible = false);
lines!(ax[8], 1:48, lift(X-> SWC_mean[1+(X-1)*48:X*48], sl.value), color = :blue);
band!(ax[8], 1:48, lift(X-> SWC_mean[1+(X-1)*48:X*48] + SWC_std[1+(X-1)*48:X*48], sl.value), lift(X->SWC_mean[1+(X-1)*48:X*48] - SWC_std[1+(X-1)*48:X*48], sl.value), color = RGBAf0(0,0,1,0.3));
ylims!(ax[8], (0.36, 0.52)); xlims!(ax[8], (1, 48));
ax[10] = layout[5, 3] = LAxis(scene, ylabel = "Precip (mm)", xticklabelsvisible = false, xticksvisible = false, yticklabelsvisible = true, yticksvisible = true, yaxisposition = :right, ylabelpadding = 15, yticklabelalign = (:left, :center), xgridvisible = false, ygridvisible = false);
barplot!(ax[10], 1:96, lift(X-> Data.Precip_c[1+(X-1)*96:X*96], sl.value), color = :blue, strokewidth = 2, strokecolor = :black);
ylims!(ax[10], (0, 60)); xlims!(ax[10], (1, 96));
ax[9] = layout[4, 3] = LAxis(scene, xticklabelsvisible = false, xticksvisible = false, yticklabelsvisible = false, yticksvisible = false, xgridvisible = false, ygridvisible = false);
lines!(ax[9], 1:48, lift(X-> Tsoil_mean[1+(X-1)*48:X*48], sl.value), color = :red);
band!(ax[9], 1:48, lift(X-> Tsoil_mean[1+(X-1)*48:X*48] + Tsoil_std[1+(X-1)*48:X*48], sl.value), lift(X->Tsoil_mean[1+(X-1)*48:X*48] - Tsoil_std[1+(X-1)*48:X*48], sl.value), color = RGBAf0(1,0,0,0.3));
ylims!(ax[9], (0, 7)); xlims!(ax[9], (1, 48));
ax[11] = layout[4, 3] = LAxis(scene, ylabel = to_latex("R_{soil} (\\mumol m^{-2} s^{-1})"), xticklabelsvisible = false, xticksvisible = false, yticklabelsvisible = true, yticksvisible = true, yaxisposition = :right, ylabelpadding = 15, yticklabelalign = (:left, :center), xgridvisible = false, ygridvisible = false);
lines!(ax[11], 1:48, lift(X-> Rsoil_HH_mean[1+(X-1)*48:X*48], sl.value), color = :green);
band!(ax[11], 1:48, lift(X-> Rsoil_HH_mean[1+(X-1)*48:X*48] + Rsoil_HH_std[1+(X-1)*48:X*48], sl.value), lift(X-> Rsoil_HH_mean[1+(X-1)*48:X*48] - Rsoil_HH_std[1+(X-1)*48:X*48], sl.value), color = RGBAf0(0,1,0,0.3));
ylims!(ax[11], (0.25, 0.6)); xlims!(ax[11], (1, 48));
cbar = Array{LColorbar}(undef,3);
ax[5] = layout[3, 1] = LAxis(scene, ylabel = "1 Hectar", ylabelpadding = 10, xticklabelsvisible = false, xticksvisible = false, yticklabelsvisible = false, yticksvisible = false);
heatmap!(ax[5], Data.x, Data.y, lift(X-> Matrix(sparse(Data.x, Data.y, Data.SWC_daily[X,:])), sl.value), colormap = :kdc, colorrange = (0.35, 0.48), interpolate = true, show_axis = false);
xlims!(ax[5], (1,8)); ylims!(ax[5], (1,8));
cbar[1] = layout[2, 1] = LColorbar(scene, height = 20, limits = (0.35, 0.48), label = to_latex("\\theta (m^3 m^{-3})"), colormap = :kdc, vertical = false, labelpadding = -5, ticklabelalign = (:center, :center), ticklabelpad = 15, xticks = ticks);
ax[6] = layout[3, 2] = LAxis(scene, yticksvisible = false, yticklabelsvisible = false, xticklabelsvisible = false, xticksvisible = false);
heatmap!(ax[6], Data.x, Data.y, lift(X-> Matrix(sparse(Data.x, Data.y, Data.Tsoil_daily[X,:])), sl.value), colormap = :fire, colorrange = (1, 7), show_axis = false, interpolate = true);
xlims!(ax[6], (1,8)); ylims!(ax[6], (1,8));
cbar[2] = layout[2, 2] = LColorbar(scene, height = 20, limits = (1, 7), label = to_latex("T_{soil} (°C)"), colormap = :fire, vertical = false, labelpadding = -5, ticklabelalign = (:center, :center), ticklabelpad = 15);
ax[7] = layout[3, 3] = LAxis(scene, yticksvisible = false, yticklabelsvisible = false, xticklabelsvisible = false, xticksvisible = false);
heatmap!(ax[7], Data.x, Data.y, lift(X-> Matrix(sparse(Data.x, Data.y, Rsoil_daily[X,:])), sl.value), colormap = :kgy, colorrange = (0.25, 0.6), show_axis = false, interpolate = true);
xlims!(ax[7], (1,8)); ylims!(ax[7], (1,8));
cbar[3] = layout[2, 3] = LColorbar(scene, height = 20, limits = (0.25, 0.6), label = to_latex("R_{soil} (\\mumol m^{-2} s^{-1})"), colormap = :kgy, vertical = false, labelpadding = -5, ticklabelalign = (:center, :center), ticklabelpad = 15);
scene
xlims!(ax[1], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[1], (0, 60));
xlims!(ax[2], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[2], (0.36, 0.52));
xlims!(ax[3], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[3], (0, 10));
xlims!(ax[4], (Data.Dtime_all_rata[1], Data.Dtime_all_rata[end])); ylims!(ax[4], (0.25, 0.8));
xlims!(ax[5], (1,8)); ylims!(ax[5], (1,8));
xlims!(ax[6], (1,8)); ylims!(ax[6], (1,8));
xlims!(ax[7], (1,8)); ylims!(ax[7], (1,8));
ylims!(ax[8], (0.36, 0.52)); xlims!(ax[8], (1, 48));
ylims!(ax[9], (0, 10)); xlims!(ax[9], (1, 48));
ylims!(ax[10], (0, 60)); xlims!(ax[10], (1, 96));
ylims!(ax[11], (0.25, 0.8)); xlims!(ax[11], (1, 48));
# to record some interaction
# record(scene, "images\\Interaction2D.gif") do io
# for i = 1:200
# sleep(0.1)
# recordframe!(io) # record a new frame
# end
# end
# TO DO
# 1. integrate 15 min precip to hourly precip
# 2. Make heatmap and colorbar discrete (5 or 6 levels?)
# 3. Possibly, add black like contour around these 5 or 6 levels
# 4. Make hovering colorbar highlight the heatmap, as in https://ourworldindata.org/coronavirus
#
# 5. Eventually, allow selection of an area by dragging mouse. Heatmap and diurnals will be average of that selection.
# 6. Add nightime as grey shading in the diurnal subplots, also, change half-hour to hour (midnight, 6 am, noon, 6 pm, midnight) or something
#
# 7. Use geomakie.jl to do interactive global maps of soil respiration, using DAMM and global data of Tsoil and SWC
# 8. Using DAMM fitted on many dataset (from COSORE and SRDB), generate global maps of DAMM parameters (possibly using machine learning, as Sagar did for SOC)
# 9. Use those Tsoil, SWC, DAMM params to generate more accurate global map of soil respiration (and possibly, ecosystem respiration)