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@ -167,7 +167,7 @@ def cprlon(msg):
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return util.bin2int(msgbin[71:88])
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def position(msg0, msg1, t0, t1):
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def position(msg0, msg1, t0, t1, lat_ref=None, lon_ref=None):
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"""Decode position from a pair of even and odd position message
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(works with both airborne and surface position messages)
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@ -181,7 +181,12 @@ def position(msg0, msg1, t0, t1):
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(float, float): (latitude, longitude) of the aircraft
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"""
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if (5 <= typecode(msg0) <= 8 and 5 <= typecode(msg1) <= 8):
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return surface_position(msg0, msg1, t0, t1)
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if (not lat_ref) or (not lon_ref):
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raise RuntimeError("Surface position encountered, a reference \
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position lat/lon required. Location of \
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receiver can be used.")
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else:
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return surface_position(msg0, msg1, t0, t1, lat_ref, lon_ref)
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elif (9 <= typecode(msg0) <= 18 and 9 <= typecode(msg1) <= 18):
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return airborne_position(msg0, msg1, t0, t1)
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@ -233,17 +238,17 @@ def airborne_position(msg0, msg1, t0, t1):
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# compute ni, longitude index m, and longitude
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if (t0 > t1):
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ni = max(_cprNL(lat_even), 1)
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m = util.floor(cprlon_even * (_cprNL(lat_even)-1) -
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cprlon_odd * _cprNL(lat_even) + 0.5)
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lon = (360.0 / ni) * (m % ni + cprlon_even)
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lat = lat_even
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nl = _cprNL(lat)
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ni = max(_cprNL(lat)- 0, 1)
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m = util.floor(cprlon_even * (nl-1) - cprlon_odd * nl + 0.5)
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lon = (360.0 / ni) * (m % ni + cprlon_even)
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else:
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ni = max(_cprNL(lat_odd) - 1, 1)
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m = util.floor(cprlon_even * (_cprNL(lat_odd)-1) -
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cprlon_odd * _cprNL(lat_odd) + 0.5)
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lon = (360.0 / ni) * (m % ni + cprlon_odd)
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lat = lat_odd
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nl = _cprNL(lat)
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ni = max(_cprNL(lat) - 1, 1)
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m = util.floor(cprlon_even * (nl-1) - cprlon_odd * nl + 0.5)
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lon = (360.0 / ni) * (m % ni + cprlon_odd)
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if lon > 180:
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lon = lon - 360
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@ -255,7 +260,9 @@ def position_with_ref(msg, lat_ref, lon_ref):
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"""Decode position with only one message,
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knowing reference nearby location, such as previously
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calculated location, ground station, or airport location, etc.
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(works with both airborne and surface position messages)
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Works with both airborne and surface position messages.
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The reference position shall be with in 180NM (airborne) or 45NM (surface)
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of the true position.
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Args:
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msg0 (string): even message (28 bytes hexadecimal string)
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@ -279,7 +286,8 @@ def position_with_ref(msg, lat_ref, lon_ref):
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def airborne_position_with_ref(msg, lat_ref, lon_ref):
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"""Decode airborne position with only one message,
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knowing reference nearby location, such as previously calculated location,
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ground station, or airport location, etc.
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ground station, or airport location, etc. The reference position shall
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be with in 180NM of the true position.
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Args:
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msg (string): even message (28 bytes hexadecimal string)
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@ -317,15 +325,83 @@ def airborne_position_with_ref(msg, lat_ref, lon_ref):
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return round(lat, 5), round(lon, 5)
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def surface_position(msg0, msg1, t0, t1):
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# TODO: implement surface positon
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raise RuntimeError('suface position decoding to be implemented soon...')
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def surface_position(msg0, msg1, t0, t1, lat_ref, lon_ref):
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"""Decode surface position from a pair of even and odd position message,
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the lat/lon of receiver must be provided to yield the correct solution.
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Args:
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msg0 (string): even message (28 bytes hexadecimal string)
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msg1 (string): odd message (28 bytes hexadecimal string)
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t0 (int): timestamps for the even message
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t1 (int): timestamps for the odd message
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lat_ref (float): latitude of the receiver
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lon_ref (float): longitude of the receiver
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Returns:
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(float, float): (latitude, longitude) of the aircraft
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"""
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msgbin0 = util.hex2bin(msg0)
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msgbin1 = util.hex2bin(msg1)
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# 131072 is 2^17, since CPR lat and lon are 17 bits each.
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cprlat_even = util.bin2int(msgbin0[54:71]) / 131072.0
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cprlon_even = util.bin2int(msgbin0[71:88]) / 131072.0
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cprlat_odd = util.bin2int(msgbin1[54:71]) / 131072.0
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cprlon_odd = util.bin2int(msgbin1[71:88]) / 131072.0
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air_d_lat_even = 90.0 / 60
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air_d_lat_odd = 90.0 / 59
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# compute latitude index 'j'
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j = util.floor(59 * cprlat_even - 60 * cprlat_odd + 0.5)
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# solution for north hemisphere
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lat_even_n = float(air_d_lat_even * (j % 60 + cprlat_even))
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lat_odd_n = float(air_d_lat_odd * (j % 59 + cprlat_odd))
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# solution for north hemisphere
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lat_even_s = lat_even_n - 90.0
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lat_odd_s = lat_odd_n - 90.0
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# chose which solution corrispondes to receiver location
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lat_even = lat_even_n if lat_ref > 0 else lat_even_s
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lat_odd = lat_odd_n if lat_ref > 0 else lat_odd_s
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# check if both are in the same latidude zone, rare but possible
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if _cprNL(lat_even) != _cprNL(lat_odd):
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return None
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# compute ni, longitude index m, and longitude
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if (t0 > t1):
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lat = lat_even
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nl = _cprNL(lat_even)
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ni = max(_cprNL(lat_even) - 0, 1)
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m = util.floor(cprlon_even * (nl-1) - cprlon_odd * nl + 0.5)
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lon = (90.0 / ni) * (m % ni + cprlon_even)
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else:
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lat = lat_odd
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nl = _cprNL(lat_odd)
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ni = max(_cprNL(lat_odd) - 1, 1)
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m = util.floor(cprlon_even * (nl-1) - cprlon_odd * nl + 0.5)
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lon = (90.0 / ni) * (m % ni + cprlon_odd)
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# four possible longitude solutions
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lons = [lon, lon + 90.0, lon + 180.0, lon + 270.0]
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# the closest solution to receiver is the correct one
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dls = [abs(lon_ref - l) for l in lons]
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imin = min(range(4), key=dls.__getitem__)
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lon = lons[imin]
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return round(lat, 5), round(lon, 5)
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def surface_position_with_ref(msg, lat_ref, lon_ref):
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"""Decode surface position with only one message,
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knowing reference nearby location, such as previously calculated location,
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ground station, or airport location, etc.
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ground station, or airport location, etc. The reference position shall
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be with in 45NM of the true position.
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Args:
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msg (string): even message (28 bytes hexadecimal string)
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junzis
8 years ago