def get_pik(orbit):
"""Extract surface echo values (convert in linear amplitude)
Arguments
---------
orbit : string
orbit number
Keywords
--------
amplitude : bool
output as linear amplitude
abs_calib : float
calibration value
"""
pik = raw.read_pik(orbit)
rpb = raw.read_rpb(orbit)
z = np.round(pik.delay_pixel) - 1
x = pik.frame - 1
x = x.values.tolist()
echo = np.zeros(np.size(x))
for i, val in enumerate(x):
try:
echo[i] = rpb[z[i] - 2:z[i] + 2, val].max()
except:
echo[i] = np.nan
out = np.empty(rpb.shape[1])
out[x] = echo
return out
def get_pik(orbit):
"""Extract surface echo values (convert in linear amplitude)
Arguments
---------
orbit : string
orbit number
Keywords
--------
amplitude : bool
output as linear amplitude
abs_calib : float
calibration value
"""
pik = raw.read_pik(orbit)
rpb = raw.read_rpb(orbit)
z = np.round(pik.delay_pixel)-1
x = pik.frame-1
x = x.values.tolist()
echo = np.zeros(np.size(x))
for i, val in enumerate(x):
try:
echo[i] = rpb[z[i]-2:z[i]+2, val].max()
except:
echo[i] = np.nan
out = np.empty(rpb.shape[1])
out[x] = echo
return out
def get_aux(orbit):
"""Interpolate auxilliary values to echo sampling
Arguments
---------
orbit : string
orbit number
"""
aux = raw.read_aux(orbit)
rpb = raw.read_rpb(orbit)
xnew = np.arange(rpb.shape[1])
x = np.linspace(0, rpb.shape[1]-1, aux.UTC.size)
tck = splrep(x, aux.lon, s=0)
lon = splev(xnew, tck, der=0)
tck = splrep(x, aux.lat, s=0)
lat = splev(xnew, tck, der=0)
tck = splrep(x, aux.radius, s=0)
radius = splev(xnew, tck, der=0)
tck = splrep(x, aux.vtan, s=0)
vtan = splev(xnew, tck, der=0)
tck = splrep(x, aux.vrad, s=0)
vrad = splev(xnew, tck, der=0)
tck = splrep(x, aux.SZA, s=0)
sza = splev(xnew, tck, der=0)
tck = splrep(x, aux.pitch, s=0)
pitch = splev(xnew, tck, der=0)
tck = splrep(x, aux.yaw, s=0)
yaw = splev(xnew, tck, der=0)
tck = splrep(x, aux.roll, s=0)
roll = splev(xnew, tck, der=0)
tck = splrep(x, aux.Mag_field, s=0)
mag = splev(xnew, tck, der=0)
tck = splrep(x, aux.HGAout, s=0)
HGAout = splev(xnew, tck, der=0)
tck = splrep(x, aux.HGAin, s=0)
HGAin = splev(xnew, tck, der=0)
tck = splrep(x, aux.Sun_dist, s=0)
sun_dist = splev(xnew, tck, der=0)
rng = radius*1e3 - ellipsoid.lonlat2rad(lon, lat, mars.radius['val'])
out = {'lat':lat, 'lon':lon, 'radius':radius, 'vtan':vtan, 'vrad':vrad,
'sza':sza, 'pitch':pitch, 'yaw':yaw, 'roll':roll, 'mag':mag,
'HGAout':HGAout, 'HGAin':HGAin, 'sun_dist':sun_dist, 'rng':rng}
return pd.DataFrame(out)
def get_aux(orbit):
"""Interpolate auxilliary values to echo sampling
Arguments
---------
orbit : string
orbit number
"""
aux = raw.read_aux(orbit)
rpb = raw.read_rpb(orbit)
xnew = np.arange(rpb.shape[1])
x = np.linspace(0, rpb.shape[1] - 1, aux.UTC.size)
tck = splrep(x, aux.lon, s=0)
lon = splev(xnew, tck, der=0)
tck = splrep(x, aux.lat, s=0)
lat = splev(xnew, tck, der=0)
tck = splrep(x, aux.radius, s=0)
radius = splev(xnew, tck, der=0)
tck = splrep(x, aux.vtan, s=0)
vtan = splev(xnew, tck, der=0)
tck = splrep(x, aux.vrad, s=0)
vrad = splev(xnew, tck, der=0)
tck = splrep(x, aux.SZA, s=0)
sza = splev(xnew, tck, der=0)
tck = splrep(x, aux.pitch, s=0)
pitch = splev(xnew, tck, der=0)
tck = splrep(x, aux.yaw, s=0)
yaw = splev(xnew, tck, der=0)
tck = splrep(x, aux.roll, s=0)
roll = splev(xnew, tck, der=0)
tck = splrep(x, aux.Mag_field, s=0)
mag = splev(xnew, tck, der=0)
tck = splrep(x, aux.HGAout, s=0)
HGAout = splev(xnew, tck, der=0)
tck = splrep(x, aux.HGAin, s=0)
HGAin = splev(xnew, tck, der=0)
tck = splrep(x, aux.Sun_dist, s=0)
sun_dist = splev(xnew, tck, der=0)
rng = radius * 1e3 - ellipsoid.lonlat2rad(lon, lat, mars.radius['val'])
out = {
'lat': lat,
'lon': lon,
'radius': radius,
'vtan': vtan,
'vrad': vrad,
'sza': sza,
'pitch': pitch,
'yaw': yaw,
'roll': roll,
'mag': mag,
'HGAout': HGAout,
'HGAin': HGAin,
'sun_dist': sun_dist,
'rng': rng
}
return pd.DataFrame(out)
