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Data_Capture_Validation.py
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Data_Capture_Validation.py
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# -------------------------------------------------------------------------------
# Name: BRAT Validation
# Purpose: Tests the output of BRAT against a shape file of beaver dams
#
# Author: Braden Anderson
#
# Created: 05/2018
# -------------------------------------------------------------------------------
from SupportingFunctions import write_xml_element_with_path, find_relative_path, find_folder, \
make_folder, find_available_num_suffix, find_available_num_prefix, make_layer
import os
import arcpy
# import matplotlib as mpl # for plot code
# mpl.use('Agg')
# import matplotlib.pyplot as plt
import scipy.stats as stat
import numpy as np
# import glob
import XMLBuilder
reload(XMLBuilder)
XMLBuilder = XMLBuilder.XMLBuilder
def main(in_network, output_name, dams=None, da_threshold=None):
"""
The main function
:param in_network: The output of BRAT (a polyline shapefile)
:param dams: A shapefile containing a point for each dam
:param output_name: The name of the output shape file
:param da_threshold: Drainage area at which stream is presumably too large for dam building
:return:
"""
if da_threshold == "None":
da_threshold = None
arcpy.env.overwriteOutput = True
arcpy.env.workspace = 'in_memory'
proj_path = os.path.dirname(os.path.dirname(os.path.dirname(os.path.dirname(in_network))))
if dams:
dams = copy_dams_to_inputs(proj_path, dams, in_network)
if output_name.endswith('.shp'):
output_network = os.path.join(os.path.dirname(in_network), output_name)
else:
output_network = os.path.join(os.path.dirname(in_network), output_name + ".shp")
arcpy.Delete_management(output_network)
# add catch for old terminology
fields = [f.name for f in arcpy.ListFields(in_network)]
if 'oCC_PT' in fields:
occ_hpe = 'oCC_PT'
else:
occ_hpe = 'oCC_HPE'
# remove Join_Count if already present in conservation restoration output
if 'Join_Count' in fields:
arcpy.DeleteField_management(in_network, 'Join_Count')
dam_fields = ['e_DamCt', 'e_DamDens', 'e_DamPcC', 'ConsVRest', 'BRATvSurv']
other_fields = ['ExCategor', 'HpeCategor', 'mCC_EXvHPE']
new_fields = dam_fields + other_fields
input_fields = ['SHAPE@LENGTH', 'oCC_EX', occ_hpe, 'iGeo_DA', 'oPBRC_CR', 'mCC_EX_CT']
if dams:
arcpy.AddMessage("Adding fields that need dam input...")
set_dam_attributes(in_network, output_network, dams,
dam_fields + ['Join_Count'] + input_fields, new_fields, da_threshold)
else:
arcpy.CopyFeatures_management(in_network, output_network)
add_fields(output_network, other_fields)
arcpy.AddMessage("Adding fields that don't need dam input...")
set_other_attributes(output_network, other_fields + input_fields)
if dams:
clean_up_fields(in_network, output_network, new_fields)
# Makes observed vs. predicted plot. Use the R code on master branch instead.
# if dams:
# plot_name = observed_v_predicted_plot(output_network)
# electivity table output moved to collect_summary_products tool
# if dams:
# make_electivity_table(output_network, output_name)
write_xml(proj_path, in_network, output_network, None)
make_layers(output_network, dams)
def copy_dams_to_inputs(proj_path, dams, in_network):
"""
If the given dams are not in the inputs,
:param proj_path: The path to the project root
:param dams: The path to the given dams
:param in_network: the input Conservation Restoration Network
:return: Filepath to dams in inputs folder
"""
if proj_path in dams:
# The dams input is already in our project folder, so we don't need to copy it over
return
inputs_folder = find_folder(proj_path, "Inputs")
beaver_dams_folder = find_folder(inputs_folder, "*[0-9]*_BeaverDams")
if beaver_dams_folder is None:
beaver_dams_folder = make_folder(inputs_folder, find_available_num_prefix(inputs_folder) + "_BeaverDams")
new_dam_folder = make_folder(beaver_dams_folder, "Beaver_Dam_" + find_available_num_suffix(beaver_dams_folder))
new_dam_path = os.path.join(new_dam_folder, os.path.basename(dams))
coord_sys = arcpy.Describe(in_network).spatialReference
arcpy.Project_management(dams, new_dam_path, coord_sys)
return new_dam_path
def set_dam_attributes(brat_output, output_path, dams, req_fields, new_fields, da_threshold):
"""
Sets all the dam info and updates the output file with that data
:param brat_output: The polyline we're basing everything on
:param output_path: The polyline shapefile with BRAT output
:param dams: The points shapefile of observed dams
:param req_fields: The fields needed to calculate new fields
:param new_fields: Fields to add to the network
:param da_threshold:
:return: Drainage area at which stream is presumably too large for dam building
"""
# snap dams within 5 meters to network if above DA threshold, otherwise snap dams within 60 meters
if da_threshold:
temp_dir = os.path.join(os.path.dirname(os.path.dirname(os.path.dirname(os.path.dirname(brat_output)))), 'Temp')
tmp_above_threshold = arcpy.MakeFeatureLayer_management(brat_output, 'tmp_above_threshold')
above_threshold_shp = os.path.join(temp_dir, 'tmp_above_da_threshold.shp')
tmp_below_threshold = arcpy.MakeFeatureLayer_management(brat_output, 'tmp_below_threshold')
below_threshold_shp = os.path.join(temp_dir, 'tmp_below_da_threshold.shp')
quer_above = """"{}" >= {}""".format('iGeo_DA', 65)
quer_below = """"{}" < {}""".format('iGeo_DA', 65)
arcpy.SelectLayerByAttribute_management(tmp_above_threshold, 'NEW_SELECTION', quer_above)
arcpy.CopyFeatures_management(tmp_above_threshold, above_threshold_shp)
arcpy.SelectLayerByAttribute_management(tmp_below_threshold, 'NEW_SELECTION', quer_below)
arcpy.CopyFeatures_management(tmp_below_threshold, below_threshold_shp)
arcpy.Snap_edit(dams, [[above_threshold_shp, 'EDGE', '5 Meters']])
arcpy.Snap_edit(dams, [[below_threshold_shp, 'EDGE', '60 Meters']])
# snap all dams within 60 meters to network if no DA threshold provided
else:
arcpy.Snap_edit(dams, [[brat_output, 'EDGE', '60 Meters']])
# should select all dams snapped to network
arcpy.SpatialJoin_analysis(brat_output, dams, output_path,
join_operation='JOIN_ONE_TO_ONE', join_type='KEEP_ALL', match_option='INTERSECT')
# add new fields to network
add_fields(output_path, new_fields)
# calculate new field values
with arcpy.da.UpdateCursor(output_path, req_fields) as cursor:
for row in cursor:
dam_num = row[-7] # seventh to last attribute
seg_length = row[-6] # sixth to last attribute
if seg_length is None:
seg_length = 0
occ_ex = row[-5] # fifth to last attribute
# TODO Is it necessary to initialize these values?
occ_hpe = row[-4] # fourth to last attribute
igeo_da = row[-3] # third to last attribute
cons_field = row[-2] # second to last attribute
mcc_ex_ct = row[-1] # last attribute
# eDam_Ct: set equal to join count from snapped dams
row[0] = dam_num
row[1] = dam_num / seg_length * 1000 # calculate surveyed dam density
# BRATvSurv: calculate predicted (BRAT) capacity count vs. observed (surveyed) dam count
if row[0] == 0:
row[4] = -1
else:
row[4] = mcc_ex_ct / row[0]
# e_DamPcC: calculate proportion of predicted capacity occupied by dams
if occ_ex == 0:
row[2] = 0
else:
row[2] = row[1] / row[-5]
# ConsVRest: differentiate management strategies based on dam occupancy
if row[-2] == "Easiest - Low-Hanging Fruit":
if row[2] >= 0.25:
row[3] = "Immediate: Beaver Conservation"
else:
row[3] = "Immediate: Potential Beaver Translocation"
elif row[-2] == "Straight Forward - Quick Return":
row[3] = "Mid Term: Process-based Riparian Vegetation Restoration"
elif row[-1] == "Strategic - Long-Term Investment":
row[3] = "Long Term: Riparian Vegetation Reestablishment"
else:
row[3] = "Low Capacity Habitat"
cursor.updateRow(row)
arcpy.DeleteField_management(output_path, ["Join_Count", "TARGET_FID"])
add_snapped_attribute(dams, brat_output)
def add_snapped_attribute(dams, brat_output):
""" Adds attribute to dams indicating whether point was snapped to network, and therefore used in the validation
: param dams: Shapefile of dams used in validation
: param brat_output: Path to network with BRAT results
: return:
"""
out_dams = os.path.join(os.path.dirname(dams), 'Dams_Snapped.shp')
arcpy.SpatialJoin_analysis(dams, brat_output, out_dams,
join_operation='JOIN_ONE_TO_ONE', join_type='KEEP_ALL', match_option='INTERSECT')
arcpy.AddField_management(out_dams, 'Snapped', 'TEXT')
with arcpy.da.UpdateCursor(out_dams, ['Join_Count', 'Snapped']) as cursor:
for row in cursor:
if row[0] > 0:
row[1] = 'Snapped to network'
else:
row[1] = 'Not snapped to network'
cursor.updateRow(row)
# clean up dam fields
dam_fields = [f.name for f in arcpy.ListFields(dams)]
dam_fields.append('Snapped')
out_fields = [f.name for f in arcpy.ListFields(out_dams)]
for field in out_fields:
if field not in dam_fields:
arcpy.DeleteField_management(out_dams, field)
# only keep edited dam shapefile and rename as original filename
arcpy.Delete_management(dams)
arcpy.Rename_management(out_dams, dams)
def add_fields(output_path, new_fields):
"""
Adds the fields we want to our output shape file
:param output_path: Our output shape file
:param new_fields: All the fields we want to add
:return:
"""
text_fields = ['ExCategor', 'HpeCategor', 'ConsVRest']
for field in new_fields:
if field in text_fields:
arcpy.AddField_management(output_path, field, field_type="TEXT", field_length=50)
else: # we assume that the default is doubles
arcpy.AddField_management(output_path, field, field_type="DOUBLE", field_precision=0, field_scale=0)
def set_other_attributes(output_path, fields):
"""
Sets the attributes of all other things we want to do
:param output_path: The polyline shapefile with BRAT output
:param fields: The fields we want to update
:return:
"""
with arcpy.da.UpdateCursor(output_path, fields) as cursor:
for row in cursor:
# TODO Does this need to be initialized?
seg_length = row[-6] # sixth to last attribute
if seg_length is None:
seg_length = 0
occ_ex = row[-5] # fifth to last attribute
occ_hpe = row[-4] # fourth to last attribute
# Handles Ex_Categor
row[0] = handle_category(occ_ex)
# Handles Hpe_Categor
row[1] = handle_category(occ_hpe)
# Handles mCC_EXtoHPE
if occ_hpe != 0:
row[2] = occ_ex / occ_hpe
else:
row[2] = 0
cursor.updateRow(row)
def handle_category(occ_variable):
"""
Returns a string based on the oCC value given to it
:param occ_variable: The oCC variable that needs to be parsed
:return: oCC category string
"""
if occ_variable == 0:
return "None"
elif 0 < occ_variable <= 1:
return "Rare"
elif 1 < occ_variable <= 5:
return "Occasional"
elif 5 < occ_variable <= 15:
return "Frequent"
elif 15 < occ_variable <= 40:
return "Pervasive"
else:
return "UNDEFINED"
def clean_up_fields(brat_network, out_network, new_fields):
"""
Removes unnecessary fields
:param brat_network: The original, unmodified stream network
:param out_network: The output network
:param new_fields: All the fields we added
:return:
"""
original_fields = [field.baseName for field in arcpy.ListFields(brat_network)]
desired_fields = original_fields + new_fields
output_fields = [field.baseName for field in arcpy.ListFields(out_network)]
remove_fields = []
for field in output_fields:
if field not in desired_fields:
remove_fields.append(field)
if len(remove_fields) > 0:
arcpy.DeleteField_management(out_network, remove_fields)
def make_layers(output_network, dams):
"""
Makes the layers for the modified output
:param output_network: The path to the network that we'll make a layer from
:param dams: Filepath to dams in the project folder
:return:
"""
arcpy.AddMessage("Making layers...")
analysis_folder = os.path.dirname(output_network)
validation_folder_name = find_available_num_prefix(analysis_folder) + "_Validation"
validation_folder = make_folder(analysis_folder, validation_folder_name)
trib_code_folder = os.path.dirname(os.path.abspath(__file__))
symbology_folder = os.path.join(trib_code_folder, 'BRATSymbology')
dam_symbology = os.path.join(symbology_folder, "SurveyedBeaverDamLocations.lyr")
historic_remaining_symbology = os.path.join(symbology_folder, "PercentofHistoricDamCapacityRemaining.lyr")
pred_v_surv_symbology = os.path.join(symbology_folder, "PredictedDamCountvs.SurveyedDamCount.lyr")
management_strategies_symbology = os.path.join(symbology_folder, "CurrentBeaverDamManagementStrategies.lyr")
occupancy_symbology = os.path.join(symbology_folder, "PercentofExistingCapacityOccupiedbySurveyedDams.lyr")
make_layer(validation_folder, output_network, "Percent of Historic Dam Capacity Remaining",
historic_remaining_symbology, is_raster=False, symbology_field="mCC_EXvHPE")
if dams is not None:
make_layer(os.path.dirname(dams), dams, "Surveyed Beaver Dam Locations",
dam_symbology, is_raster=False, symbology_field="Snapped")
make_layer(validation_folder, output_network, "Predicted Dam Count vs. Surveyed Dam Count",
pred_v_surv_symbology, is_raster=False, symbology_field="BRATvSurv")
make_layer(validation_folder, output_network, "Current Beaver Dam Management Strategies",
management_strategies_symbology, is_raster=False, symbology_field="ConsVRest")
make_layer(validation_folder, output_network, "Occupancy Rate of Surveyed Beaver Dams",
occupancy_symbology, is_raster=False, symbology_field="e_DamPcC")
def make_electivity_table(output_network):
"""
Makes table with totals and electivity indices for modeled capacity categories
(i.e., none, rare, occasional, frequent, pervasive)
:param output_network: The stream network output by the BRAT model with fields added from capacity tools
:return:
"""
# convert network data to numpy table
brat_table = arcpy.da.TableToNumPyArray(output_network,
['iGeo_Len', 'e_DamCt', 'mCC_EX_CT', 'e_DamDens', 'oCC_EX', 'ExCategor'],
skip_nulls=True)
tot_length = brat_table['iGeo_Len'].sum()
tot_surv_dams = brat_table['e_DamCt'].sum()
tot_brat_cc = brat_table['mCC_EX_CT'].sum()
avg_surv_dens = tot_surv_dams/(tot_length/1000)
avg_brat_dens = tot_brat_cc/(tot_length/1000)
electivity_table = ['', 'm', 'km', '%', '# of dams', '# of dams', 'dams/km', 'dams/km', '%', '']
add_electivity_category(brat_table, 'None', electivity_table, tot_length, tot_surv_dams)
add_electivity_category(brat_table, 'Rare', electivity_table, tot_length, tot_surv_dams)
add_electivity_category(brat_table, 'Occasional', electivity_table, tot_length, tot_surv_dams)
add_electivity_category(brat_table, 'Frequent', electivity_table, tot_length, tot_surv_dams)
add_electivity_category(brat_table, 'Pervasive', electivity_table, tot_length, tot_surv_dams)
electivity_table.append(['Total', tot_length, tot_length/1000, 'NA', tot_surv_dams, tot_brat_cc,
avg_surv_dens, avg_brat_dens, tot_surv_dams/tot_brat_cc, 'NA'])
# set up proper folder structure and save CSV there
project_folder = os.path.dirname(os.path.dirname(os.path.dirname(os.path.dirname(output_network))))
summary_folder = make_folder(project_folder, "Summary_Products")
tables_folder = make_folder(summary_folder, "SummaryTables")
out_csv = os.path.join(tables_folder, 'Electivity_Index.csv')
np.savetxt(out_csv, electivity_table, fmt='%s', delimiter=',',
header="Segment Type, Stream Length, Stream Length,"
" % of Drainage Network, Surveyed Dams, BRAT Estimated Capacity,"
" Average Surveyed Dam Density, Average BRAT Predicted Density,"
" % of Modeled Capacity, Electivity Index")
def add_electivity_category(brat_table, category, output_table, tot_length, tot_surv_dams):
"""
Calculates values for each modeled capacity category and adds to output table
:param brat_table: The current BRAT Table
:param category: The oCC category to add
:param output_table: The table to output data to
:param tot_length: The total length of the network
:param tot_surv_dams: The total number of surveyed dams in the network
:return:
"""
cat_tbl = brat_table[brat_table['ExCategor'] == category]
length = cat_tbl['iGeo_Len'].sum()
length_km = length/1000
network_prop = 100*cat_tbl['iGeo_Len'].sum()/tot_length
surv_dams = cat_tbl['e_DamCt'].sum()
brat_cc = cat_tbl['mCC_EX_CT'].sum()
surv_dens = surv_dams/length_km
brat_dens = brat_cc/length_km
prop_mod_cap = 100*surv_dams/(brat_cc+0.000001)
electivity = (surv_dams/tot_surv_dams)/(network_prop/100)
output_table.append([category, length, length_km, network_prop, surv_dams,
brat_cc, surv_dens, brat_dens, prop_mod_cap, electivity])
def observed_v_predicted_plot(output_network):
"""
Creates plot comparing observed vs predicted. [This is currently unused]
:param output_network: The Data Validation Network that was created
:return: The filepath to the plot
"""
x, y = clean_values(output_network)
# set up plot
fig = plt.figure()
fig.add_axes()
ax = fig.add_subplot(111)
ax.set(title='Predicted vs. Observed Dam Counts (per reach)',
xlabel='Predicted Number of Dams',
ylabel='Observed Number of Dams')
# set axis range
if max(x) > max(y):
ax.set_xlim(0, round(max(x)+2), 1)
ax.set_ylim(0, round(max(x)+2), 1)
else:
ax.set_xlim(0, round(max(y)+2), 1)
ax.set_ylim(0, round(max(y)+2), 1)
# plot data points, regression line, 1:1 reference
plot_points(x, y, ax)
if len(x) > 1:
plot_regression(x, y, ax)
else:
print "No regression line plotted - only one reach with dams observed"
ax.plot([0, 10], [0, 10], color='blue', linewidth=1.5, linestyle=":", label='Line of Perfect Agreement')
# add legend
legend = plt.legend(loc="upper left", bbox_to_anchor=(1,1))
# save plot
project_folder = os.path.dirname(os.path.dirname(os.path.dirname(os.path.dirname(output_network))))
summary_folder = make_folder(project_folder, "Summary_Products")
tables_folder = make_folder(summary_folder, "SummaryTables")
plot_name = os.path.join(tables_folder, "Predicted_vs_Expected_Plot.png")
plt.savefig(plot_name, bbox_extra_artists=(legend,), bbox_inches='tight')
return plot_name
def clean_values(output_network):
"""
Removes unwanted values from the stream network
:param output_network: The Data Validation Network that was created
:return: Values for x and y
"""
# pull e_DamCt (observed) and oCC_EX (predicted) from output network
mcc_ex_ct = arcpy.da.FeatureClassToNumPyArray(output_network, ['mCC_EX_CT']).astype(np.float)
e_dam_ct = arcpy.da.FeatureClassToNumPyArray(output_network, ['e_DamCt']).astype(np.float)
# pull out none values
x = mcc_ex_ct[np.isnan(e_dam_ct) is False]
y = e_dam_ct[np.isnan(e_dam_ct) is False]
# pull out observed values of zero
x1 = x[np.equal(y, 0) is False]
y1 = y[np.equal(y, 0) is False]
return x1, y1
def plot_points(x, y, axis):
"""
Plots points based on their x and y values
:param x: X values for points
:param y: Y values for points
:param axis: Axis for current graph
:return:
"""
# generate some random jitter between 0 and 1
if len(x) > 0 and x.std() != 0:
jitter = (np.random.rand(*x.shape)-0.5)/x.std()
else:
jitter = (np.random.rand(*x.shape)-0.5)/10
# plot points with predicted dams < observed dams in red
red_x = x[np.greater(y, x) is True]
red_y = y[np.greater(y, x) is True]
jitter_red = jitter[np.greater(y, x) is True]
jitter_red_x = np.add(red_x, jitter_red)
jitter_red_y = np.add(red_y, jitter_red)
axis.scatter(jitter_red_x, jitter_red_y, color="red", label="BRAT Underestimate")
# plot points with expected dams >= observed dams in blue
blue_x = x[np.greater_equal(x, y) is True]
blue_y = y[np.greater_equal(x, y) is True]
jitter_blue = jitter[np.greater_equal(x, y) is True]
jitter_blue_x = np.add(blue_x, jitter_blue)
jitter_blue_y = np.add(blue_y, jitter_blue)
axis.scatter(jitter_blue_x, jitter_blue_y, color="blue", label="BRAT Accurate")
def plot_regression(x, y, axis):
"""
Plots regression points based on their x and y values
:param x: X values for points
:param y: Y values for points
:param axis: Axis for current graph
:return:
"""
# calculate regression equation of e_DamCt ~ mCC_EX_CT and assign to variable
regression = stat.linregress(x, y)
model_x = np.arange(0.0, round(max(x))+2, 0.1)
model_y = regression.slope * model_x + regression.intercept
# plot regression line
axis.plot(model_x, model_y, color='black', linewidth=2.0, linestyle='-', label='Regression line')
# calculate prediction intervals and plot as shaded areas
n = len(x)
error = stat.t.ppf(1-0.025, n-2) * regression.stderr
upper_ci = model_y + error
lower_ci = model_y - error
axis.fill_between(model_x, y1=upper_ci, y2=lower_ci, facecolor='red', alpha=0.3, label="95% Confidence Interval")
# in-plot legend
axis.legend(loc='best', frameon=False)
def write_xml(proj_path, in_network, out_network, plot_name):
"""
Writes relevant data into the XML
:param proj_path: The file path to the BRAT project folder
:param in_network: The input Conservation Restoration network
:param out_network: The newly created Data Validation network
:param plot_name: The file path to the created plot
:return:
"""
xml_file_path = os.path.join(proj_path, "project.rs.xml")
if not os.path.exists(xml_file_path):
arcpy.AddWarning("XML file not found. Could not update XML file")
return
xml_file = XMLBuilder(xml_file_path)
in_network_rel_path = find_relative_path(in_network, proj_path)
path_element = xml_file.find_by_text(in_network_rel_path)
analysis_element = xml_file.find_element_parent(xml_file.find_element_parent(path_element))
write_xml_element_with_path(xml_file, analysis_element, "Vector", "BRAT Data Validation", out_network, proj_path)
# write_xml_element_with_path(xml_file, analysis_element, "Plot", "Obsrved vs Predicted Plot", plot_name, proj_path)
xml_file.write()
if __name__ == "__main__":
main(sys.argv[1],
sys.argv[2],
sys.argv[3],
sys.argv[4])