def _classify_ocean(self, options):
opt = options.ocean
parameter = self._classifier
ocean = ANDCondition()
# Ice Concentration
ocean.add(parameter.sic < opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ocean.flag, "ocean")
def _classify_ocean(self, options):
""" Ocean classification based on sea ice concentration only
since land will be excluded anyway """
opt = options.ocean
parameter = self._classifier
ocean = ANDCondition()
# Ice Concentration
ocean.add(parameter.sic < opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ocean.flag, "ocean")
def _classify_sea_ice(self, options):
opt = options.sea_ice
parameter = self._classifier
ice = ANDCondition()
# Mandatory radar mode flag
ice.add(self._is_radar_mode)
# Stack (Beam) parameters
ice.add(parameter.peakiness_r <= opt.peakiness_r_max)
ice.add(parameter.peakiness_l <= opt.peakiness_l_max)
ice.add(parameter.peakiness <= opt.peakiness_max)
ice.add(parameter.stack_kurtosis < opt.stack_kurtosis_max)
# Ice Concentration
ice.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ice.flag, "sea_ice")
def _transfer_waveform_collection(self):
""" Transfers the waveform data (power & range for each range bin) """
from pysiral.flag import ANDCondition
# Transfer the reformed 18Hz waveforms
self.l1b.waveform.set_waveform_data(self.sgdr.mds_18hz.power,
self.sgdr.mds_18hz.range,
self.sgdr.radar_mode)
# This is from SICCI-1 processor, check of mcd flags
valid = ANDCondition()
valid.add(np.logical_not(self.sgdr.mds_18hz.flag_packet_length_error))
valid.add(np.logical_not(self.sgdr.mds_18hz.flag_obdh_invalid))
valid.add(np.logical_not(self.sgdr.mds_18hz.flag_agc_fault))
valid.add(np.logical_not(self.sgdr.mds_18hz.flag_rx_delay_fault))
valid.add(np.logical_not(self.sgdr.mds_18hz.flag_waveform_fault))
# ku_chirp_band_id (0 -> 320Mhz)
valid.add(self.sgdr.mds_18hz.ku_chirp_band_id == 0)
self.l1b.waveform.set_valid_flag(valid.flag)
def _classify_ocean(self, options):
opt = options.ocean
parameter = self._classifier
ocean = ANDCondition()
# Mandatory radar mode flag
ocean.add(self._is_radar_mode)
# Peakiness Thresholds
ocean.add(parameter.peakiness >= opt.peakiness_min)
ocean.add(parameter.peakiness <= opt.peakiness_max)
# Stack Standard Deviation
ssd_threshold = opt.stack_standard_deviation_min
ocean.add(parameter.stack_standard_deviation >= ssd_threshold)
# Ice Concentration
ocean.add(parameter.sic < opt.ice_concentration_min)
# OCOG Width
ocean.add(parameter.ocog_width >= opt.ocog_width_min)
# Done, add flag
self._surface_type.add_flag(ocean.flag, "ocean")
def _classify_sea_ice(self, options):
"""
Classify waveforms as sea ice
:param options: The option attribute dictionary
:return:
"""
# Pointer
opt = options.sea_ice
month_num = self._month
parameter = self._classifier
# All conditions must be fulfilled
ice = ANDCondition()
# Mandatory radar mode flag
ice.add(self._is_radar_mode)
# Sigma0
sea_ice_backscatter_min = self.get_threshold_value(
opt, "sea_ice_backscatter_min", month_num)
sea_ice_backscatter_max = self.get_threshold_value(
opt, "sea_ice_backscatter_max", month_num)
ice.add(parameter.sigma0 >= sea_ice_backscatter_min)
ice.add(parameter.sigma0 <= sea_ice_backscatter_max)
# Leading Edge Width
leading_edge_width_min = self.get_threshold_value(
opt, "leading_edge_width_min", month_num)
leading_edge_width = parameter.leading_edge_width_first_half + parameter.leading_edge_width_second_half
ice.add(leading_edge_width >= leading_edge_width_min)
# Pulse Peakiness
peakiness_max = self.get_threshold_value(opt, "peakiness_max",
month_num)
ice.add(parameter.peakiness <= peakiness_max)
# Ice Concentration
ice_concentration_min = self.get_threshold_value(
opt, "ice_concentration_min", month_num)
ice.add(parameter.sic > ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ice.flag, "sea_ice")
def _classify_leads(self, options):
"""
Classify leads in sea ice
:param options:
:return:
"""
# Pointer
opt = options.lead
month_num = self._month
parameter = self._classifier
# All conditions must be fulfilled
lead = ANDCondition()
# Mandatory radar mode flag
lead.add(self._is_radar_mode)
# Sigma0
sea_ice_backscatter_min = self.get_threshold_value(
opt, "sea_ice_backscatter_min", month_num)
lead.add(parameter.sigma0 >= sea_ice_backscatter_min)
# Leading Edge Width
leading_edge_width_max = self.get_threshold_value(
opt, "leading_edge_width_max", month_num)
leading_edge_width = parameter.leading_edge_width_first_half + parameter.leading_edge_width_second_half
lead.add(leading_edge_width <= leading_edge_width_max)
# Pulse Peakiness
peakiness_min = self.get_threshold_value(opt, "leading_edge_width_max",
month_num)
lead.add(parameter.peakiness >= peakiness_min)
# Ice Concentration
ice_concentration_min = self.get_threshold_value(
opt, "ice_concentration_min", month_num)
lead.add(parameter.sic > ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(lead.flag, "lead")
def _classify_leads(self, options):
opt = options.lead
parameter = self._classifier
lead = ANDCondition()
# Mandatory radar mode flag
lead.add(self._is_radar_mode)
# Reflectivity
lead.add(parameter.reflectivity <= opt.reflectivity_max)
# Echo Gain
lead.add(parameter.echo_gain <= opt.echo_gain_max)
lead.add(parameter.echo_gain >= opt.echo_gain_min)
# lead.add(parameter.echo_gain >= 150.)
# Ice Concentration
lead.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(lead.flag, "lead")
def _classify_leads(self, options):
opt = options.lead
parameter = self._classifier
lead = ANDCondition()
# Mandatory radar mode flag
lead.add(self._is_radar_mode)
# Check for monthly thresholds and pick index
if type(opt.sea_ice_backscatter_min) is list:
index = self._month - 1
n = len(opt.sea_ice_backscatter_min)
else:
n = 1
index = 0
# Sigma0
sea_ice_backscatter_min = np.full(n, opt.sea_ice_backscatter_min)
lead.add(parameter.sigma0 >= sea_ice_backscatter_min[index])
# Leading Edge Width
leading_edge_width_max = np.full(n, opt.leading_edge_width_max)
leading_edge_width = parameter.leading_edge_width_first_half + \
parameter.leading_edge_width_second_half
lead.add(leading_edge_width <= leading_edge_width_max[index])
# Pulse Peakiness
peakiness_min = np.full(n, opt.peakiness_min)
lead.add(parameter.peakiness >= peakiness_min[index])
# Ice Concentration
lead.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(lead.flag, "lead")
def _classify_sea_ice(self, options):
opt = options.sea_ice
parameter = self._classifier
ice = ANDCondition()
# Mandatory radar mode flag
ice.add(self._is_radar_mode)
# Reflectivity min
# reflectivity = np.array(parameter.reflectivity)
# reflectivity[np.isnan(reflectivity)] = 999.
ice.add(parameter.reflectivity > opt.reflectivity_min)
ice.add(parameter.echo_gain <= opt.echo_gain_max)
# ice.add(parameter.echo_gain < 100.)
# Ice Concentration
ice.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ice.flag, "sea_ice")
def _classify_ocean(self, options):
opt = options.ocean
parameter = self._classifier
ocean = ANDCondition()
# Mandatory radar mode flag
ocean.add(self._is_radar_mode)
# Peakiness Thresholds
ocean.add(parameter.peakiness_old < opt.pulse_peakiness_max)
# Ice Concentration
ocean.add(parameter.sic < opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ocean.flag, "ocean")
def _classify_leads(self, options):
opt = options.lead
parameter = self._classifier
lead = ANDCondition()
# Mandatory radar mode flag
lead.add(self._is_radar_mode)
# Stack (Beam) parameters
lead.add(parameter.peakiness_old > opt.pulse_peakiness_min)
# Ice Concentration
lead.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(lead.flag, "lead")
def _classify_sea_ice(self, options):
""" Sea ice is essentially the valid rest (not-ocean & not lead) """
opt = options.sea_ice
parameter = self._classifier
ice = ANDCondition()
# Mandatory radar mode flag
ice.add(self._is_radar_mode)
# Should not be a lead
ice.add(np.logical_not(self._surface_type.lead.flag))
# High gain value indicates low SNR
ice.add(parameter.echo_gain <= opt.echo_gain_max)
# Ice Concentration
ice.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(ice.flag, "sea_ice")
def _classify_leads(self, options):
""" Follow the procedure proposed by Kirill: Identification of
colocated dips in local elevation & reflectivity """
# Aliases
opt = options.lead
parameter = self._classifier
# Translate window size in km to indices
window_size = self.get_filter_width(opt.filter_width_m,
opt.footprint_spacing_m)
# get local dips in elevation
elevation = parameter.sea_ice_surface_elevation_corrected
elevation -= parameter.mss
hr, hr_mean, hr_sigma, index_list = self.get_elevation_parameters(
elevation, window_size)
# get local dips in reflectivity
delta_r = self.get_delta_r(parameter.reflectivity, window_size,
opt.reflectivity_offset_sdev_factor,
index_list)
# All criterias needs to be fullfilled
lead = ANDCondition()
# Mandatory radar mode flag
lead.add(self._is_radar_mode)
# Local Reflectivity Minimum
lead.add(delta_r >= opt.reflectivity_diff_min)
# Local Elevation Minimum
hr_max = hr_mean - opt.elevation_offset_sdev_factor * hr_sigma
lead.add(hr < hr_max)
# Obligatory Ice Concentration
lead.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(lead.flag, "lead")
def _filter_results(self):
""" These threshold are based on the SICCI code"""
thrs = self._options.filter
valid = ANDCondition()
valid.add(self.leading_edge_width < thrs.maximum_leading_edge_width)
valid.add(self.tail_shape < thrs.maximum_echo_tail_line_deviation)
valid.add(self.retracked_bin > thrs.sensible_seaice_retracked_bin[0])
valid.add(self.retracked_bin < thrs.sensible_seaice_retracked_bin[1])
# Error flag is also computed for other surface types, do not
# overide those
error_flag = self._flag
error_flag[self.indices] = np.logical_not(valid.flag[self.indices])
self._flag = error_flag
def _filter_results(self):
""" Filter the lead results based on threshold defined in SICCI """
thrs = self._options.filter
clf = self._classifier
valid = ANDCondition()
valid.add(self.sigma < thrs.maximum_std_of_gaussion_rise)
valid.add(self.maximum_power_bin > thrs.minimum_bin_count_maxpower)
# sea ice backscatter not available for ERS?
if thrs.minimum_echo_backscatter is not None:
valid.add(clf.sigma0 > thrs.minimum_echo_backscatter)
bin_seperation = np.abs(self.retracked_bin - self.maximum_power_bin)
valid.add(bin_seperation < thrs.maximum_retracker_maxpower_binsep)
valid.add(self.power_in_echo_tail < thrs.maximum_power_in_echo_tail)
valid.add(self.rms_echo_and_model < thrs.maximum_rms_echo_model_diff)
valid.add(self.retracked_bin > thrs.sensible_lead_retracked_bin[0])
valid.add(self.retracked_bin < thrs.sensible_lead_retracked_bin[1])
# Error flag is also computed for other surface types, do not
# overide those
error_flag = self._flag
error_flag[self.indices] = np.logical_not(valid.flag[self.indices])
self._flag = error_flag
def _classify_leads(self, options):
opt = options.lead
parameter = self._classifier
lead = ANDCondition()
# Mandatory radar mode flag
lead.add(self._is_radar_mode)
# Stack (Beam) parameters
lead.add(parameter.peakiness_l >= opt.peakiness_l_min)
lead.add(parameter.peakiness_r >= opt.peakiness_r_min)
lead.add(parameter.peakiness >= opt.peakiness_min)
lead.add(parameter.stack_kurtosis >= opt.stack_kurtosis_min)
ssd_threshold = opt.stack_standard_deviation_max
lead.add(parameter.stack_standard_deviation < ssd_threshold)
# Ice Concentration
lead.add(parameter.sic > opt.ice_concentration_min)
# Done, add flag
self._surface_type.add_flag(lead.flag, "lead")
