def critical_perp_baseline(sensor_name, inc_angle=None, print_msg=False):
"""Critical Perpendicular Baseline for each satellite"""
# Jers: 5.712e3 m (near_range=688849.0551m)
# Alos: 6.331e3 m (near_range=842663.2917m)
# Tsx : 8.053e3 m (near_range=634509.1271m)
c = 299792458 # m/s, speed of light
wvl = sensor.wavelength(sensor_name)
# Yunjun 5/2016, case for Jers, need a automatic way to get this number
near_range = 688849
rg_bandwidth = sensor.range_bandwidth(sensor_name)
inc_angle = sensor.incidence_angle(sensor_name, inc_angle) / 180 * np.pi
Bperp_c = wvl * (rg_bandwidth/c) * near_range * np.tan(inc_angle)
if print_msg:
print(('Critical Perpendicular Baseline: '+str(Bperp_c)+' m'))
return Bperp_c
def critical_perp_baseline(sensor_name, inc_angle=None, print_msg=False):
"""Critical Perpendicular Baseline for each satellite"""
# Jers: 5.712e3 m (near_range=688849.0551m)
# Alos: 6.331e3 m (near_range=842663.2917m)
# Tsx : 8.053e3 m (near_range=634509.1271m)
c = 299792458 # m/s, speed of light
wvl = sensor.wavelength(sensor_name)
# Yunjun 5/2016, case for Jers, need a automatic way to get this number
near_range = 688849
rg_bandwidth = sensor.range_bandwidth(sensor_name)
inc_angle = sensor.incidence_angle(sensor_name, inc_angle) / 180 * np.pi
Bperp_c = wvl * (rg_bandwidth / c) * near_range * np.tan(inc_angle)
if print_msg:
print(('Critical Perpendicular Baseline: ' + str(Bperp_c) + ' m'))
return Bperp_c