def fitness(self, x):
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.__n_legs + 1))
r_P = list([None] * (self.__n_legs + 1))
v_P = list([None] * (self.__n_legs + 1))
DV = list([0.0] * (self.__n_legs + 1))
for i, planet in enumerate(self.seq):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = self.seq[i].eph(t_P[i])
# 3 - We start with the first leg
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(r_P[0], v0, x[5] * T[0] * DAY2SEC,
self.common_mu)
# Lambert arc to reach seq[1]
dt = (1 - x[5]) * T[0] * DAY2SEC
l = lambert_problem(r, r_P[1], dt, self.common_mu, False, False)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# 4 - And we proceed with each successive leg
for i in range(1, self.__n_legs):
# Fly-by
v_out = fb_prop(v_end_l, v_P[i],
x[8 + (i - 1) * 4] * self.seq[i].radius,
x[7 + (i - 1) * 4], self.seq[i].mu_self)
# s/c propagation before the DSM
r, v = propagate_lagrangian(r_P[i], v_out,
x[9 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu)
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[9 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r, r_P[i + 1], dt, self.common_mu, False,
False)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
# Last Delta-v
if self.__add_vinf_arr:
DV[-1] = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
if self.__add_vinf_dep:
DV[0] += x[3]
if self._obj_dim == 1:
return (sum(DV), )
else:
return (sum(DV), sum(T))
def fitness(self, x):
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.__n_legs + 1))
r_P = list([None] * (self.__n_legs + 1))
v_P = list([None] * (self.__n_legs + 1))
DV = list([0.0] * (self.__n_legs + 1))
for i, planet in enumerate(self.seq):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = self.seq[i].eph(t_P[i])
# 3 - We start with the first leg
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(
r_P[0], v0, x[5] * T[0] * DAY2SEC, self.common_mu)
# Lambert arc to reach seq[1]
dt = (1 - x[5]) * T[0] * DAY2SEC
l = lambert_problem(r, r_P[1], dt, self.common_mu, False, False)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# 4 - And we proceed with each successive leg
for i in range(1, self.__n_legs):
# Fly-by
v_out = fb_prop(v_end_l, v_P[i], x[
8 + (i - 1) * 4] * self.seq[i].radius, x[7 + (i - 1) * 4], self.seq[i].mu_self)
# s/c propagation before the DSM
r, v = propagate_lagrangian(
r_P[i], v_out, x[9 + (i - 1) * 4] * T[i] * DAY2SEC, self.common_mu)
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[9 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r, r_P[i + 1], dt,
self.common_mu, False, False)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
# Last Delta-v
if self.__add_vinf_arr:
DV[-1] = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
if self.__add_vinf_dep:
DV[0] += x[3]
if self._obj_dim == 1:
return (sum(DV),)
else:
return (sum(DV), sum(T))
def select_resonance(self, beta, safe_distance):
v_out = fb_prop(self._rvt_in._v, self._rvt_pl._v,
self._planet.radius + safe_distance, beta, self._mu)
self._rvt_out = rvt(self._rvt_in._r, v_out, self._time,
self._rvt_in._mu)
period = self._rvt_out.period()
self._timing_error = math.inf
for resonance in self._resonances:
target = self._period * resonance[1] / resonance[0]
dt = abs(period - target)
if dt < self._timing_error:
self._resonance = resonance
self._timing_error = dt
return self._timing_error, self._resonance
def plot(self, x, ax=None):
"""
ax = prob.plot(x, ax=None)
- x: encoded trajectory
- ax: matplotlib axis where to plot. If None figure and axis will be created
- [out] ax: matplotlib axis where to plot
Plots the trajectory represented by a decision vector x on the 3d axis ax
Example::
ax = prob.plot(x)
"""
import matplotlib as mpl
from mpl_toolkits.mplot3d import Axes3D
import matplotlib.pyplot as plt
from pykep.orbit_plots import plot_planet, plot_lambert, plot_kepler
if ax is None:
mpl.rcParams['legend.fontsize'] = 10
fig = plt.figure()
axis = fig.gca(projection='3d')
else:
axis = ax
axis.scatter(0, 0, 0, color='y')
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.n_legs + 1))
r_P = list([None] * (self.n_legs + 1))
v_P = list([None] * (self.n_legs + 1))
DV = list([None] * (self.n_legs + 1))
for i, planet in enumerate(self._seq):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = planet.eph(t_P[i])
plot_planet(planet,
t0=t_P[i],
color=(0.8, 0.6, 0.8),
legend=True,
units=AU,
axes=axis,
N=150)
# 3 - We start with the first leg
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(r_P[0], v0, x[4] * T[0] * DAY2SEC,
self.common_mu)
plot_kepler(r_P[0],
v0,
x[4] * T[0] * DAY2SEC,
self.common_mu,
N=100,
color='b',
legend=False,
units=AU,
axes=axis)
# Lambert arc to reach seq[1]
dt = (1 - x[4]) * T[0] * DAY2SEC
l = lambert_problem(r, r_P[1], dt, self.common_mu, False, False)
plot_lambert(l, sol=0, color='r', legend=False, units=AU, axes=axis)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# 4 - And we proceed with each successive leg
for i in range(1, self.n_legs):
# Fly-by
v_out = fb_prop(v_end_l, v_P[i],
x[7 + (i - 1) * 4] * self._seq[i].radius,
x[6 + (i - 1) * 4], self._seq[i].mu_self)
# s/c propagation before the DSM
r, v = propagate_lagrangian(r_P[i], v_out,
x[8 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu)
plot_kepler(r_P[i],
v_out,
x[8 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu,
N=100,
color='b',
legend=False,
units=AU,
axes=axis)
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[8 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r, r_P[i + 1], dt, self.common_mu, False,
False)
plot_lambert(l,
sol=0,
color='r',
legend=False,
units=AU,
N=1000,
axes=axis)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
plt.show()
return axis
def pretty(self, x):
"""
prob.plot(x)
- x: encoded trajectory
Prints human readable information on the trajectory represented by the decision vector x
Example::
print(prob.pretty(x))
"""
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.n_legs + 1))
r_P = list([None] * (self.n_legs + 1))
v_P = list([None] * (self.n_legs + 1))
DV = list([0.0] * (self.n_legs + 1))
for i in range(len(self._seq)):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = self._seq[i].eph(t_P[i])
# 3 - We start with the first leg
print("First Leg: " + self._seq[0].name + " to " + self._seq[1].name)
print("Departure: " + str(t_P[0]) + " (" + str(t_P[0].mjd2000) +
" mjd2000) ")
print("Duration: " + str(T[0]) + "days")
print("VINF: " + str(x[3] / 1000) + " km/sec")
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(r_P[0], v0, x[4] * T[0] * DAY2SEC,
self.common_mu)
print("DSM after " + str(x[4] * T[0]) + " days")
# Lambert arc to reach seq[1]
dt = (1 - x[4]) * T[0] * DAY2SEC
l = lambert_problem(r,
r_P[1],
dt,
self.common_mu,
cw=False,
max_revs=0)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
print("DSM magnitude: " + str(DV[0]) + "m/s")
# 4 - And we proceed with each successive leg
for i in range(1, self.n_legs):
print("\nleg no. " + str(i + 1) + ": " + self._seq[i].name +
" to " + self._seq[i + 1].name)
print("Duration: " + str(T[i]) + "days")
# Fly-by
v_out = fb_prop(v_end_l, v_P[i],
x[7 + (i - 1) * 4] * self._seq[i].radius,
x[6 + (i - 1) * 4], self._seq[i].mu_self)
print("Fly-by epoch: " + str(t_P[i]) + " (" + str(t_P[i].mjd2000) +
" mjd2000) ")
print("Fly-by radius: " + str(x[7 + (i - 1) * 4]) +
" planetary radii")
# s/c propagation before the DSM
r, v = propagate_lagrangian(r_P[i], v_out,
x[8 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu)
print("DSM after " + str(x[8 + (i - 1) * 4] * T[i]) + " days")
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[8 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r,
r_P[i + 1],
dt,
self.common_mu,
cw=False,
max_revs=0)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
print("DSM magnitude: " + str(DV[i]) + "m/s")
# Last Delta-v
print("\nArrival at " + self._seq[-1].name)
DV[-1] = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
print("Arrival epoch: " + str(t_P[-1]) + " (" + str(t_P[-1].mjd2000) +
" mjd2000) ")
print("Arrival Vinf: " + str(DV[-1]) + "m/s")
if self._orbit_insertion:
# In this case we compute the insertion DV as a single pericenter
# burn
DVper = np.sqrt(DV[-1] * DV[-1] +
2 * self._seq[-1].mu_self / self._rp_target)
DVper2 = np.sqrt(2 * self._seq[-1].mu_self / self._rp_target -
self._seq[-1].mu_self / self._rp_target *
(1. - self._e_target))
DVinsertion = np.abs(DVper - DVper2)
print("Insertion DV: " + str(DVinsertion) + "m/s")
print("Total mission time: " + str(sum(T) / 365.25) + " years (" +
str(sum(T)) + " days)")
def fitness(self, x):
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.n_legs + 1))
r_P = list([None] * (self.n_legs + 1))
v_P = list([None] * (self.n_legs + 1))
DV = list([0.0] * (self.n_legs + 1))
for i in range(len(self._seq)):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = self._seq[i].eph(t_P[i])
# 3 - We start with the first leg
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(r_P[0], v0, x[4] * T[0] * DAY2SEC,
self.common_mu)
# Lambert arc to reach seq[1]
dt = (1 - x[4]) * T[0] * DAY2SEC
l = lambert_problem(r,
r_P[1],
dt,
self.common_mu,
cw=False,
max_revs=0)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# 4 - And we proceed with each successive leg
for i in range(1, self.n_legs):
# Fly-by
v_out = fb_prop(v_end_l, v_P[i],
x[7 + (i - 1) * 4] * self._seq[i].radius,
x[6 + (i - 1) * 4], self._seq[i].mu_self)
# s/c propagation before the DSM
r, v = propagate_lagrangian(r_P[i], v_out,
x[8 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu)
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[8 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r,
r_P[i + 1],
dt,
self.common_mu,
cw=False,
max_revs=0)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
# Last Delta-v
if self._add_vinf_arr:
DV[-1] = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
if self._orbit_insertion:
# In this case we compute the insertion DV as a single pericenter
# burn
DVper = np.sqrt(DV[-1] * DV[-1] +
2 * self._seq[-1].mu_self / self._rp_target)
DVper2 = np.sqrt(2 * self._seq[-1].mu_self / self._rp_target -
self._seq[-1].mu_self / self._rp_target *
(1. - self._e_target))
DV[-1] = np.abs(DVper - DVper2)
if self._add_vinf_dep:
DV[0] += x[3]
if not self._multi_objective:
return (sum(DV), )
else:
return (sum(DV), sum(T))
def plot(self, x, ax=None):
"""
ax = prob.plot(x, ax=None)
- x: encoded trajectory
- ax: matplotlib axis where to plot. If None figure and axis will be created
- [out] ax: matplotlib axis where to plot
Plots the trajectory represented by a decision vector x on the 3d axis ax
Example::
ax = prob.plot(x)
"""
import matplotlib as mpl
from mpl_toolkits.mplot3d import Axes3D
import matplotlib.pyplot as plt
from pykep.orbit_plots import plot_planet, plot_lambert, plot_kepler
if ax is None:
mpl.rcParams['legend.fontsize'] = 10
fig = plt.figure()
axis = fig.gca(projection='3d')
else:
axis = ax
axis.scatter(0, 0, 0, color='y')
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.__n_legs + 1))
r_P = list([None] * (self.__n_legs + 1))
v_P = list([None] * (self.__n_legs + 1))
DV = list([None] * (self.__n_legs + 1))
for i, planet in enumerate(self.seq):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = planet.eph(t_P[i])
plot_planet(planet, t0=t_P[i], color=(
0.8, 0.6, 0.8), legend=True, units=AU, ax=axis)
# 3 - We start with the first leg
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(
r_P[0], v0, x[5] * T[0] * DAY2SEC, self.common_mu)
plot_kepler(r_P[0], v0, x[5] * T[0] * DAY2SEC, self.common_mu,
N=100, color='b', legend=False, units=AU, ax=axis)
# Lambert arc to reach seq[1]
dt = (1 - x[5]) * T[0] * DAY2SEC
l = lambert_problem(r, r_P[1], dt, self.common_mu, False, False)
plot_lambert(l, sol=0, color='r', legend=False, units=AU, ax=axis)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# 4 - And we proceed with each successive leg
for i in range(1, self.__n_legs):
# Fly-by
v_out = fb_prop(v_end_l, v_P[i], x[
8 + (i - 1) * 4] * self.seq[i].radius, x[7 + (i - 1) * 4], self.seq[i].mu_self)
# s/c propagation before the DSM
r, v = propagate_lagrangian(
r_P[i], v_out, x[9 + (i - 1) * 4] * T[i] * DAY2SEC, self.common_mu)
plot_kepler(r_P[i], v_out, x[9 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu, N=100, color='b', legend=False, units=AU, ax=axis)
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[9 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r, r_P[i + 1], dt,
self.common_mu, False, False)
plot_lambert(l, sol=0, color='r', legend=False,
units=AU, N=1000, ax=axis)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
plt.show()
return axis
def pretty(self, x):
"""
prob.plot(x)
- x: encoded trajectory
Prints human readable information on the trajectory represented by the decision vector x
Example::
print(prob.pretty(x))
"""
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.__n_legs + 1))
r_P = list([None] * (self.__n_legs + 1))
v_P = list([None] * (self.__n_legs + 1))
DV = list([None] * (self.__n_legs + 1))
for i, planet in enumerate(self.seq):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = self.seq[i].eph(t_P[i])
# 3 - We start with the first leg
print("First Leg: " + self.seq[0].name + " to " + self.seq[1].name)
print("Departure: " + str(t_P[0]) +
" (" + str(t_P[0].mjd2000) + " mjd2000) ")
print("Duration: " + str(T[0]) + "days")
print("VINF: " + str(x[4] / 1000) + " km/sec")
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
r, v = propagate_lagrangian(
r_P[0], v0, x[5] * T[0] * DAY2SEC, self.common_mu)
print("DSM after " + str(x[5] * T[0]) + " days")
# Lambert arc to reach seq[1]
dt = (1 - x[5]) * T[0] * DAY2SEC
l = lambert_problem(r, r_P[1], dt, self.common_mu, False, False)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
print("DSM magnitude: " + str(DV[0]) + "m/s")
# 4 - And we proceed with each successive leg
for i in range(1, self.__n_legs):
print("\nleg no. " + str(i + 1) + ": " +
self.seq[i].name + " to " + self.seq[i + 1].name)
print("Duration: " + str(T[i]) + "days")
# Fly-by
v_out = fb_prop(v_end_l, v_P[i], x[
8 + (i - 1) * 4] * self.seq[i].radius, x[7 + (i - 1) * 4], self.seq[i].mu_self)
print(
"Fly-by epoch: " + str(t_P[i]) + " (" + str(t_P[i].mjd2000) + " mjd2000) ")
print(
"Fly-by radius: " + str(x[8 + (i - 1) * 4]) + " planetary radii")
# s/c propagation before the DSM
r, v = propagate_lagrangian(
r_P[i], v_out, x[9 + (i - 1) * 4] * T[i] * DAY2SEC, self.common_mu)
print("DSM after " + str(x[9 + (i - 1) * 4] * T[i]) + " days")
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[9 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem(r, r_P[i + 1], dt,
self.common_mu, False, False)
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
print("DSM magnitude: " + str(DV[i]) + "m/s")
# Last Delta-v
print("\nArrival at " + self.seq[-1].name)
DV[-1] = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
print(
"Arrival epoch: " + str(t_P[-1]) + " (" + str(t_P[-1].mjd2000) + " mjd2000) ")
print("Arrival Vinf: " + str(DV[-1]) + "m/s")
print("Total mission time: " + str(sum(T) / 365.25) + " years")
def _compute_dvs(self, x: List[float]) -> Tuple[
List[float], # DVs
List[Any], # Lambert legs
List[float], # T
List[Tuple[List[float], List[float]]], # ballistic legs
List[float], # epochs of ballistic legs
]:
# 1 - we 'decode' the chromosome recording the various times of flight
# (days) in the list T and the cartesian components of vinf
T, Vinfx, Vinfy, Vinfz = self._decode_times_and_vinf(x)
# 2 - We compute the epochs and ephemerides of the planetary encounters
t_P = list([None] * (self.n_legs + 1))
r_P = list([None] * (self.n_legs + 1))
v_P = list([None] * (self.n_legs + 1))
DV = list([0.0] * (self.n_legs + 1))
for i in range(len(self._seq)):
t_P[i] = epoch(x[0] + sum(T[0:i]))
r_P[i], v_P[i] = self._seq[i].eph(t_P[i])
ballistic_legs: List[Tuple[List[float], List[float]]] = []
ballistic_ep: List[float] = []
lamberts = []
# 3 - We start with the first leg
v0 = [a + b for a, b in zip(v_P[0], [Vinfx, Vinfy, Vinfz])]
ballistic_legs.append((r_P[0], v0))
ballistic_ep.append(t_P[0].mjd2000)
r, v = propagate_lagrangian(r_P[0], v0, x[4] * T[0] * DAY2SEC,
self.common_mu)
# Lambert arc to reach seq[1]
dt = (1 - x[4]) * T[0] * DAY2SEC
l = lambert_problem_multirev(
v,
lambert_problem(r,
r_P[1],
dt,
self.common_mu,
cw=False,
max_revs=self.max_revs))
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
lamberts.append(l)
ballistic_legs.append((r, v_beg_l))
ballistic_ep.append(t_P[0].mjd2000 + x[4] * T[0])
# First DSM occuring at time nu1*T1
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# 4 - And we proceed with each successive leg
for i in range(1, self.n_legs):
# Fly-by
v_out = fb_prop(v_end_l, v_P[i],
x[7 + (i - 1) * 4] * self._seq[i].radius,
x[6 + (i - 1) * 4], self._seq[i].mu_self)
ballistic_legs.append((r_P[i], v_out))
ballistic_ep.append(t_P[i].mjd2000)
# s/c propagation before the DSM
r, v = propagate_lagrangian(r_P[i], v_out,
x[8 + (i - 1) * 4] * T[i] * DAY2SEC,
self.common_mu)
# Lambert arc to reach Earth during (1-nu2)*T2 (second segment)
dt = (1 - x[8 + (i - 1) * 4]) * T[i] * DAY2SEC
l = lambert_problem_multirev(
v,
lambert_problem(r,
r_P[i + 1],
dt,
self.common_mu,
cw=False,
max_revs=self.max_revs))
v_end_l = l.get_v2()[0]
v_beg_l = l.get_v1()[0]
lamberts.append(l)
# DSM occuring at time nu2*T2
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
ballistic_legs.append((r, v_beg_l))
ballistic_ep.append(t_P[i].mjd2000 + x[8 + (i - 1) * 4] * T[i])
# Last Delta-v
if self._add_vinf_arr:
DV[-1] = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
if self._orbit_insertion:
# In this case we compute the insertion DV as a single pericenter
# burn
DVper = np.sqrt(DV[-1] * DV[-1] +
2 * self._seq[-1].mu_self / self._rp_target)
DVper2 = np.sqrt(2 * self._seq[-1].mu_self / self._rp_target -
self._seq[-1].mu_self / self._rp_target *
(1. - self._e_target))
DV[-1] = np.abs(DVper - DVper2)
if self._add_vinf_dep:
DV[0] += x[3]
return (DV, lamberts, T, ballistic_legs, ballistic_ep)
def _fitness_impl(self, decoded_x, logging=False, plotting=False, ax=None):
""" Computation of the objective function. """
saturn_distance_violated = 0
# decode x
t0, u, v, dep_vinf, etas, T, betas, rps = decoded_x
# convert incoming velocity vector
theta, phi = 2.0 * pi * u, acos(2.0 * v - 1.0) - pi / 2.0
Vinfx = dep_vinf * cos(phi) * cos(theta)
Vinfy = dep_vinf * cos(phi) * sin(theta)
Vinfz = dep_vinf * sin(phi)
# epochs and ephemerides of the planetary encounters
t_P = list([None] * (self._n_legs + 1))
r_P = list([None] * (self._n_legs + 1))
v_P = list([None] * (self._n_legs + 1))
lamberts = list([None] * (self._n_legs))
v_outs = list([None] * (self._n_legs))
DV = list([0.0] * (self._n_legs + 1))
for i, planet in enumerate(self.seq):
t_P[i] = epoch(t0 + sum(T[0:i]))
r_P[i], v_P[i] = self.seq[i].eph(t_P[i])
# first leg
v_outs[0] = [Vinfx, Vinfy, Vinfz] # bug fixed
# check first leg up to DSM
saturn_distance_violated += self.check_distance(
r_P[0], v_outs[0], t0, etas[0] * T[0])
r, v = propagate_lagrangian(r_P[0], v_outs[0],
etas[0] * T[0] * DAY2SEC, self.common_mu)
# Lambert arc to reach seq[1]
dt = (1.0 - etas[0]) * T[0] * DAY2SEC
lamberts[0] = lambert_problem(r, r_P[1], dt, self.common_mu, self.cw,
0)
v_end_l = lamberts[0].get_v2()[0]
v_beg_l = lamberts[0].get_v1()[0]
# First DSM occuring at time eta0*T0
DV[0] = norm([a - b for a, b in zip(v_beg_l, v)])
# checking first leg after DSM
saturn_distance_violated += self.check_distance(
r, v_beg_l, etas[0] * T[0], T[0])
# successive legs
for i in range(1, self._n_legs):
# Fly-by
v_outs[i] = fb_prop(v_end_l, v_P[i],
rps[i - 1] * self.seq[i].radius, betas[i - 1],
self.seq[i].mu_self)
# checking next leg up to DSM
saturn_distance_violated += self.check_distance(
r_P[i], v_outs[i], T[i - 1], etas[i] * T[i])
# s/c propagation before the DSM
r, v = propagate_lagrangian(r_P[i], v_outs[i],
etas[i] * T[i] * DAY2SEC,
self.common_mu)
# Lambert arc to reach next body
dt = (1 - etas[i]) * T[i] * DAY2SEC
lamberts[i] = lambert_problem(r, r_P[i + 1], dt, self.common_mu,
self.cw, 0)
v_end_l = lamberts[i].get_v2()[0]
v_beg_l = lamberts[i].get_v1()[0]
# DSM occuring at time eta_i*T_i
DV[i] = norm([a - b for a, b in zip(v_beg_l, v)])
# checking next leg after DSM
saturn_distance_violated += self.check_distance(
r, v_beg_l, etas[i] * T[i], T[i])
# single dv penalty for now
if saturn_distance_violated > 0:
DV[-1] += DV_PENALTY
arr_vinf = norm([a - b for a, b in zip(v_end_l, v_P[-1])])
# last Delta-v
if self._add_vinf_arr:
DV[-1] = arr_vinf
if self._add_vinf_dep:
DV[0] += dep_vinf
# pretty printing
if logging:
print("First leg: {} to {}".format(self.seq[0].name,
self.seq[1].name))
print("Departure: {0} ({1:0.6f} mjd2000)".format(
t_P[0], t_P[0].mjd2000))
print("Duration: {0:0.6f}d".format(T[0]))
print("VINF: {0:0.3f}m/s".format(dep_vinf))
print("DSM after {0:0.6f}d".format(etas[0] * T[0]))
print("DSM magnitude: {0:0.6f}m/s".format(DV[0]))
for i in range(1, self._n_legs):
print("\nleg {}: {} to {}".format(i + 1, self.seq[i].name,
self.seq[i + 1].name))
print("Duration: {0:0.6f}d".format(T[i]))
print("Fly-by epoch: {0} ({1:0.6f} mjd2000)".format(
t_P[i], t_P[i].mjd2000))
print("Fly-by radius: {0:0.6f} planetary radii".format(rps[i -
1]))
print("DSM after {0:0.6f}d".format(etas[i] * T[i]))
print("DSM magnitude: {0:0.6f}m/s".format(DV[i]))
print("\nArrival at {}".format(self.seq[-1].name))
print("Arrival epoch: {0} ({1:0.6f} mjd2000)".format(
t_P[-1], t_P[-1].mjd2000))
print("Arrival Vinf: {0:0.3f}m/s".format(arr_vinf))
print("Total mission time: {0:0.6f}d ({1:0.3f} years)".format(
sum(T),
sum(T) / 365.25))
# plotting
if plotting:
ax.scatter(0, 0, 0, color='chocolate')
for i, planet in enumerate(self.seq):
plot_planet(planet,
t0=t_P[i],
color=pl2c[planet.name],
legend=True,
units=AU,
ax=ax)
for i in range(0, self._n_legs):
plot_kepler(r_P[i],
v_outs[i],
etas[i] * T[i] * DAY2SEC,
self.common_mu,
N=100,
color='b',
legend=False,
units=AU,
ax=ax)
for l in lamberts:
plot_lambert(l,
sol=0,
color='r',
legend=False,
units=AU,
N=1000,
ax=ax)
# returning building blocks for objectives
return (DV, T, arr_vinf, lamberts)
