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two_line_elements.py
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two_line_elements.py
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#!/usr/bin/env python
# -*- coding: utf-8 -*-
# Copyright (c) 2011.
# Author(s):
# Martin Raspaud <martin.raspaud@smhi.se>
# This file is part of mpop.
# mpop is free software: you can redistribute it and/or modify it under the
# terms of the GNU General Public License as published by the Free Software
# Foundation, either version 3 of the License, or (at your option) any later
# version.
# mpop is distributed in the hope that it will be useful, but WITHOUT ANY
# WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR
# A PARTICULAR PURPOSE. See the GNU General Public License for more details.
# You should have received a copy of the GNU General Public License along with
# mpop. If not, see <http://www.gnu.org/licenses/>.
"""Module to compute satellite positions from TLE.
"""
import datetime
import sys
import urllib2
import numpy as np
CK2 = 5.413080e-4
CK4 = 0.62098875e-6
E6A = 1.0e-6
QOMS2T = 1.88027916e-9
S = 1.01222928
XJ3 = -0.253881e-5
XKE = 0.743669161e-1
XKMPER = 6378.137
XMNPDA = 1440.0
AE = 1.0
# earth flattening
F = 1/298.257223563
if sys.version_info < (2, 5):
import time
def strptime(string, fmt=None):
"""This function is available in the datetime module only
from Python >= 2.5.
"""
return datetime.datetime(*time.strptime(string, fmt)[:6])
else:
strptime = datetime.datetime.strptime
class Tle(object):
"""The TLE object holds information and methods for orbit position
estimation.
"""
def __init__(self, tle=None, satellite=None):
self.tle = tle
if satellite:
tles_dict = {}
import glob
filelist = glob.glob("/data/24/saf/polar_in/tle2/tle-*.txt")
if len(filelist) > 0:
filelist.sort()
tlef = open(filelist[-1])
tles = [item.strip() for item in tlef]
tlef.close()
for i in xrange(0, len(tles) - 2, 3):
tles_dict[tles[i]] = tles[i+1]+"\n"+tles[i+2]
else:
for fname in ["resource.txt", "weather.txt"]:
url = "http://celestrak.com/NORAD/elements/" + fname
tles = urllib2.urlopen(url).readlines()
tles = [item.strip() for item in tles]
for i in xrange(0, len(tles) - 2, 3):
tles_dict[tles[i]] = tles[i+1]+"\n"+tles[i+2]
self._read_tle(tles_dict[satellite.upper()])
self._preprocess()
def _read_tle(self, lines):
"""Read the raw tle.
"""
def _read_tle_decimal(rep):
"""Read tle decimal point numbers.
"""
num = int(rep[:-2]) * 1.0e-5
exp = int(rep[-2:])
return num * 10 ** exp
tlist = lines.split()
self.tle = {}
self.tle["satnumber"] = tlist[1][:5]
self.tle["classification"] = tlist[1][5:]
self.tle["id_launch_year"] = tlist[2][:2]
self.tle["id_launch_number"] = tlist[2][2:5]
self.tle["id_launch_piece"] = tlist[2][5:]
self.tle["epoch_year"] = int(tlist[3][:2])
self.tle["epoch_day"] = float(tlist[3][2:])
self.tle["epoch"] = (strptime(tlist[3][:2], "%y") +
datetime.timedelta(days=float(tlist[3][2:]) - 1))
self.tle["mean_motion_derivative"] = float(tlist[4])
self.tle["mean_motion_sec_derivative"] = _read_tle_decimal(tlist[5])
self.tle["bstar"] = _read_tle_decimal(tlist[6])
self.tle["ephemeris_type"] = int(tlist[7])
self.tle["element_number"] = int(tlist[8][:-1])
self.tle["inclination"] = float(tlist[11])
self.tle["right_ascension"] = float(tlist[12])
self.tle["excentricity"] = int(tlist[13]) * 10 ** -7
self.tle["arg_perigee"] = float(tlist[14])
self.tle["mean_anomaly"] = float(tlist[15])
self.tle["mean_motion"] = float(tlist[16][:11])
self.tle["orbit"] = int(tlist[16][11:-1])
def _preprocess(self):
"""Derivate some values from raw tle.
"""
self.tle["inclination"] = np.deg2rad(self.tle["inclination"])
self.tle["right_ascension"] = np.deg2rad(self.tle["right_ascension"])
self.tle["arg_perigee"] = np.deg2rad(self.tle["arg_perigee"])
self.tle["mean_anomaly"] = np.deg2rad(self.tle["mean_anomaly"])
self.tle["mean_motion"] *= (np.pi * 2 / XMNPDA)
self.tle["mean_motion_derivative"] *= np.pi * 2 / XMNPDA ** 2
self.tle["mean_motion_sec_derivative"] *= np.pi * 2 / XMNPDA ** 3
self.tle["bstar"] *= AE
n_0 = self.tle["mean_motion"]
k_e = XKE
k_2 = CK2
i_0 = self.tle["inclination"]
e_0 = self.tle["excentricity"]
a_1 = (k_e / n_0) ** (2.0/3)
delta_1 = ((3/2.0) * (k_2 / a_1**2) * ((3 * np.cos(i_0)**2 - 1) /
(1 - e_0**2)**(2.0/3)))
a_0 = a_1 * (1 - delta_1/3 - delta_1**2 - (134.0/81) * delta_1**3)
delta_0 = ((3/2.0) * (k_2 / a_0**2) * ((3 * np.cos(i_0)**2 - 1) /
(1 - e_0**2)**(2.0/3)))
# original mean motion
n_0pp = n_0 / (1 + delta_0)
self.tle["original_mean_motion"] = n_0pp
# semi major axis
a_0pp = a_0 / (1 - delta_0)
self.tle["semi_major_axis"] = a_0pp
self.tle["period"] = np.pi * 2 / n_0pp
self.tle["perigee"] = (a_0pp * (1 - e_0) / AE - AE) * XKMPER
now = self.tle["epoch"]
self.tle["right_ascension_lon"] = (self.tle["right_ascension"]
- gmst(now))
if self.tle["right_ascension_lon"] > np.pi:
self.tle["right_ascension_lon"] -= 2 * np.pi
# pylint: disable-msg=C0103
def get_position(self, current_time):
"""Get cartesian position and velocity.
"""
# for near earth orbits, period must be < 255 minutes
perigee = self.tle["perigee"]
a_0pp = self.tle["semi_major_axis"]
e_0 = self.tle["excentricity"]
i_0 = self.tle["inclination"]
n_0pp = self.tle["original_mean_motion"]
k_2 = CK2
k_4 = CK4
k_e = XKE
bstar = self.tle["bstar"]
w_0 = self.tle["arg_perigee"]
M_0 = self.tle["mean_anomaly"]
W_0 = self.tle["right_ascension"]
t_0 = self.tle["epoch"]
A30 = -XJ3 * AE**3
if perigee < 98:
s = 20/XKMPER + AE
qoms2t = (QOMS2T ** 0.25 + S - s) ** 4
elif perigee < 156:
s = a_0pp * (1 - e_0) - S + AE
qoms2t = (QOMS2T ** 0.25 + S - s) ** 4
else:
qoms2t = QOMS2T
s = S
theta = np.cos(i_0)
xi = 1 / (a_0pp - s)
beta_0 = np.sqrt(1 - e_0 ** 2)
eta = a_0pp * e_0 * xi
C_2 = (qoms2t * xi**4 * n_0pp * (1 - eta**2)**(-3.5) *
(a_0pp * (1 + 1.5 * eta**2 + 4 * e_0 * eta + e_0 * eta**3) +
1.5 * (k_2 * xi) / (1 - eta**2) * (-0.5 + 1.5 * theta**2)*
(8 + 24 * eta**2 + 3 * eta**4)))
C_1 = bstar * C_2
C_3 = (qoms2t * xi ** 5 * A30 * n_0pp * AE * np.sin(i_0) / (k_2 * e_0))
coef = 2 * qoms2t * xi**4 * a_0pp * beta_0**2*(1-eta**2)**(-7/2.0)
C_4 = (coef * n_0pp *
((2 * eta * (1 + e_0 * eta) + e_0/2.0 + (eta**3)/2.0) -
2 * k_2 * xi / (a_0pp * (1 - eta**2)) *
(3*(1-3*theta**2) *
(1 + (3*eta**2)/2.0 - 2*e_0*eta - e_0*eta**3/2.0) +
3/4.0*(1-theta**2)*
(2*eta**2 - e_0*eta - e_0*eta**3)*np.cos(2*w_0))))
C_5 = coef * (1 + 11/4.0 * eta * (eta + e_0) + e_0 * eta**3)
D_2 = 4 * a_0pp * xi * C_1**2
D_3 = 4/3.0 * a_0pp * xi**2 * (17*a_0pp + s) * C_1**3
D_4 = 2/3.0 * a_0pp * xi**3 * (221*a_0pp + 31*s) * C_1**4
# Secular effects of atmospheric drag and gravitation
dt = _days(current_time - t_0) * XMNPDA
M_df = (M_0 + (1 +
3*k_2*(-1 + 3*theta**2)/(2*a_0pp**2 * beta_0**3) +
3*k_2**2*(13 - 78*theta**2 + 137*theta**4)/
(16*a_0pp**4*beta_0**7))*
n_0pp*dt)
w_df = (w_0 + (-3*k_2*(1 - 5*theta**2)/(2*a_0pp**2*beta_0**4) +
3 * k_2**2 * (7 - 114*theta**2 + 395*theta**4)/
(16*a_0pp*beta_0**8) +
5*k_4*(3-36*theta**2+49*theta**4)/
(4*a_0pp**4*beta_0**8))*
n_0pp*dt)
W_df = (W_0 + (-3*k_2*theta/(a_0pp**2*beta_0**4) +
3*k_2**2*(4*theta- 19*theta**3)/(2*a_0pp**4*beta_0**8) +
5*k_4*theta*(3-7*theta**2)/(2*a_0pp**4*beta_0**8))*
n_0pp*dt)
deltaw = bstar * C_3 * np.cos(w_0)*dt
deltaM = (-2/3.0 * qoms2t * bstar * xi**4 * AE / (e_0*eta) *
((1 + eta * np.cos(M_df))**3 - (1 + eta * np.cos(M_0))**3))
M_p = M_df + deltaw + deltaM
w = w_df - deltaw - deltaM
W = (W_df - 21/2.0 * (n_0pp * k_2 * theta)/(a_0pp**2 * beta_0**2) *
C_1 * dt**2)
e = (e_0 -
bstar * C_4 * dt -
bstar * C_5 * (np.sin(M_p) - np.sin(M_0)))
a = a_0pp * (1 - C_1 * dt - D_2 * dt**2 - D_3 * dt**3 - D_4 * dt**4)**2
L = M_p + w + W + n_0pp * (3/2.0 * C_1 * dt**2 +
(D_2 + 2 * C_1 ** 2) * dt**3 +
1/4.0 *
(3*D_3 + 12*C_1*D_2 + 10*C_1**3)*dt**4 +
1.0/5 * (3*D_4 + 12*C_1*D_3 + 6*D_2**2 +
30*C_1**2*D_2 + 15*C_1**4)*dt**5)
beta = np.sqrt(1 - e**2)
n = k_e / (a ** (3/2.0))
# Long-period periodic terms
a_xN = e * np.cos(w)
a_yNL = A30 * np.sin(i_0) / (4.0 * k_2 * a * beta**2)
L_L = a_yNL/2 * a_xN * ((3 + 5 * theta) / (1 + theta))
L_T = L + L_L
a_yN = e * np.sin(w) + a_yNL
U = (L_T - W) % (np.pi * 2)
Epw = U
for i in range(10):
DeltaEpw = ((U - a_yN * np.cos(Epw) + a_xN * np.sin(Epw) - Epw) /
(-a_yN * np.sin(Epw) - a_xN * np.cos(Epw) + 1))
Epw = Epw + DeltaEpw
if DeltaEpw < 10e-12:
break
# preliminary quantities for short-period periodics
ecosE = a_xN * np.cos(Epw) + a_yN * np.sin(Epw)
esinE = a_xN * np.sin(Epw) - a_yN * np.cos(Epw)
e_L = (a_xN**2 + a_yN**2)**(0.5)
p_L = a * (1 - e_L**2)
r = a * (1 - ecosE)
rdot = k_e * np.sqrt(a)/r * esinE
rfdot = k_e * np.sqrt(p_L) / r
cosu = a / r * (np.cos(Epw) - a_xN +
(a_yN * (esinE) / (1 + np.sqrt(1 - e_L**2))))
sinu = a / r * (np.sin(Epw) - a_yN +
(a_xN * (esinE) / (1 + np.sqrt(1 - e_L**2))))
u = np.arctan2(sinu, cosu)
cos2u = np.cos(2*u)
sin2u = np.sin(2*u)
Deltar = k_2/(2*p_L) * (1 - theta**2) * cos2u
Deltau = -k_2/(4*p_L**2) * (7*theta**2 - 1) * sin2u
DeltaW = 3*k_2 * theta / (2 * p_L**2) * sin2u
Deltai = 3*k_2 * theta / (2 * p_L**2) * cos2u * np.sin(i_0)
Deltardot = - k_2 * n / p_L * (1 - theta**2) * sin2u
Deltarfdot = k_2 * n / p_L * ((1 - theta**2) * cos2u -
3/2.0 * (1 - 3*theta**2))
# osculating quantities
r_k = r * (1 - 3/2.0 * k_2 * np.sqrt(1 - e_L**2)/p_L**2 *
(3 * theta**2 - 1)) + Deltar
u_k = u + Deltau
W_k = W + DeltaW
i_k = i_0 + Deltai
rdot_k = rdot + Deltardot
rfdot_k = rfdot + Deltarfdot
M_x = -np.sin(W_k) * np.cos(i_k)
M_y = np.cos(W_k) * np.cos(i_k)
M_z = np.sin(i_k)
N_x = np.cos(W_k)
N_y = np.sin(W_k)
N_z = 0
U_x = M_x * np.sin(u_k) + N_x * np.cos(u_k)
U_y = M_y * np.sin(u_k) + N_y * np.cos(u_k)
U_z = M_z * np.sin(u_k) + N_z * np.cos(u_k)
V_x = M_x * np.cos(u_k) - N_x * np.sin(u_k)
V_y = M_y * np.cos(u_k) - N_y * np.sin(u_k)
V_z = M_z * np.cos(u_k) - N_z * np.sin(u_k)
r_x = r_k * U_x
r_y = r_k * U_y
r_z = r_k * U_z
rdot_x = rdot_k * U_x + rfdot_k * V_x
rdot_y = rdot_k * U_y + rfdot_k * V_y
rdot_z = rdot_k * U_z + rfdot_k * V_z
return r_x, r_y, r_z, rdot_x, rdot_y, rdot_z
def get_latlonalt(self, current_time):
"""Get lon lat and altitude for current time
"""
pos_x, pos_y, pos_z, vel_x, vel_y, vel_z = \
self.get_position(current_time)
del vel_x, vel_y, vel_z
lon = ((np.arctan2(pos_y * XKMPER, pos_x * XKMPER) - gmst(current_time))
% (2 * np.pi))
if lon > np.pi:
lon -= np.pi * 2
if lon <= -np.pi:
lon += np.pi * 2
r = np.sqrt(pos_x ** 2 + pos_y ** 2)
lat = np.arctan2(pos_z, r)
e2 = F * (2 - F)
while True:
lat2 = lat
c = 1/(np.sqrt(1 - e2 * (np.sin(lat2) ** 2)))
lat = np.arctan2(pos_z + c * e2 *np.sin(lat2), r)
if abs(lat - lat2) < 1e-10:
break
alt = r / np.cos(lat)- c
alt *= XKMPER
return lat, lon, alt
# pylint: enable-msg=C0103
def _jdays(current_time):
"""Get the julian day of *current_time*.
"""
d_t = current_time - datetime.datetime(2000, 1, 1, 12, 0)
return _days(d_t)
def _days(d_t):
"""Get the days (floating point) from *d_t*.
"""
return (d_t.days +
(d_t.seconds +
d_t.microseconds / (1000000.0)) / (24 * 3600.0))
def gmst(current_time):
"""Greenwich mean sidereal current_time, in radians.
http://celestrak.com/columns/v02n02/
"""
now = current_time
#now = datetime.datetime(1995, 10, 1, 9, 0)
now0 = datetime.datetime(now.year, now.month, now.day)
epoch = datetime.datetime(2000, 1, 1, 12, 0)
du2 = _days(now - epoch)
d_u = _days(now0 - epoch)
dus = (du2 - d_u) * 86400
t_u = d_u / 36525.0
theta_g_0 = (24110.54841 + t_u * (8640184.812866 +
t_u * (0.093104 - t_u * 6.2 * 10e-6)))
theta_g = (theta_g_0 + dus * 1.00273790934) % 86400
return (theta_g / 86400.0) * 2 * np.pi
if __name__ == "__main__":
pass