The performance of impulsive, gravity-assist trajectories often improves with the inclusion of one or more maneuvers between flybys. However, grid-based scans over the entire design space can become computationally intractable for even one deep-space maneuver, and few global search routines are capable of an arbitrary number of maneuvers. To address this difficulty a trajectory transcription allowing for any number of maneuvers is developed within a multi-objective, global optimization framework for constrained, multiple gravity-assist trajectories. The formulation exploits a robust shooting scheme and analytic derivatives for computational efficiency. The approach is applied to several complex, interplanetary problems, achieving notable performance without a user-supplied initial guess

Ellison, Donald H.

Englander, Jacob A.

Vavrina, Matthew A.

The performance of impulsive, gravity-assist trajectories often improves with the inclusion of one or more maneuvers between flybys. However, grid-based scans over the entire design space can become computationally intractable for even one deep-space maneuver, and few global search routines are capable of an arbitrary number of maneuvers. To address this difficulty a trajectory transcription allow-ing for any number of maneuvers is developed within a multi-objective, global optimization framework for constrained, multiple gravity-assist trajectories. The formulation exploits a robust shooting scheme and analytic derivatives for com-putational efficiency. The approach is applied to several complex, interplanetary problems, achieving notable performance without a user-supplied initial guess

NASA Technical Reports Server

1GLOBAL OPTIMIZATION OF n-MANEUVER, HIGH-THRUST 
TRAJECTORIES USING DIRECT MULTIPLE SHOOTING 
Matthew A. Vavrina, a.i. solutions
Jacob A. Englander, NASA GSFC
Donald H. Ellison, University of Illinois
February 15, 2015
https://ntrs.nasa.gov/search.jsp?R=20160001875 2019-08-31T03:55:44+00:00Z
n-Impulse, Gravity-Assist Trajectory Optimization
• Optimal number of maneuvers not 
known a priori
– Deep-space maneuvers (DSMs) frequently 
improve performance
– Two (or more) DSMs can be optimal for 
tightly/uniquely constrained trajectory legs
• Missions interested in best performance 
possible, i.e., the global optimum
– Can enable cost- or time-constrained missions
– Often interested in more than 1 objective, 
e.g., max. delivered mass & min. TOF
2
• Problem challenges:
– Grid searches can be intractable for any number & variety of DSMs
– Optimization requires initial guess
– Maneuvers and gravity assists can create highly sensitive optimization problems
DSM 2
DSM 1
Optimal EEJ trajectory w/ 2 DSMs on 1 leg
Method should be:
• Automated
• No requirement of a user-defined initial guess
• Able to search broad design space
• Efficient (medium-fidelity is appropriate)
• Capable of handling multiple objectives
Globally optimize chemical propulsion based trajectories 
with an arbitrary number of maneuvers & gravity assists
Earth
Mars
Jupiter
Objective
3
Prior Approaches to Global Search
4
• Grid search
– Lambert scans over range of event dates & flyby 
bodies
– Strategies developed to include one maneuver per leg
• Patel and Longuski STOUR (Purdue, JPL)
• Lantukh and Russell (UT-Austin)
• Maneuvers limited to specific type v-infinity leveraging or 
broken plane maneuver
• Stochastic search
– Strategically sample design space
– Typically use a direct, Lambert-based trajectory formulation:
• Vary departure date, time to DSM, & DSM components
• Propagate forward to DSM point
• Solve Lambert problem to subsequent body, repeat for all legs
• Guaranteed feasibility for unconstrained problems
– Not limited in maneuver type, but problems are frequently very sensitive to initial guess
– Most approaches not capable of more than 1 DSM
– Global-local hybrid scheme can improve efficacy
Example STOUR plot (TOF vs. LD)
Petropoulos et al., “Trajectories to Jupiter…” JSR, 2000
MGAnDSMs Trajectory Transcription
5
Multiple gravity assist with n deep space maneuvers using shooting scheme s 
 MGAnDSMs
– Aim for robustness & efficiency with an arbitrary number of DSMs with a direct formulation
– Nonlinear programming problem
– Employs forward/backward shooting similar to Byrnes & Bright (CATO)
– Nominally Kepler propagation between maneuvers
– Analytic match point (MP) constraints
– User specifies n, optimizer reduces 1 or more DSM magnitude to zero if <n optimal
𝐜𝑚𝑝 = 𝑟𝑥
+ − 𝑟𝑥
−, 𝑟𝑦
+−𝑟𝑦
−, 𝑟𝑧
+−𝑟𝑧
−, 𝑣𝑥
+−𝑣𝑥
−, 𝑣𝑦
+−𝑣𝑦
−, 𝑣𝑧
+−𝑣𝑧
−, 𝑚+−𝑚−
𝑇
= 𝛆𝑇
Match point 
continuity constraint:
Core Optimization 
Variables
Δtphase
Δt1
Δt2, … Δtn
Δtn+1
Δv1, Δv2, …, Δvn
vinitial
vfinal
MGAnDSMs Mission Formulation
6
• Multiple gravity assists accommodated in mission structure
• Allows for variation of flyby bodies at control nodes of transcription
– Journeys start & end a user-required bodies/states
– Journeys can be composed of multiple phases with variable flyby bodies to improve performance (“null 
gene” approach)
• Zero sphere of influence patched conics
– Flyby constraints ensure physically realizable gravity assist 
• Flexible to numerous mission constraints
MGAnDSMs Global Optimization
7
• Combine monotonic basin hopping (MBH) & sequential quadratic programming 
(SQP)  MBH+SQP
• Stochastic, global search scheme
• No initial guess required
• Adept at multi-modal problems w/ clustered local minima
• Stochastic “hops” evaluated from base solution
Multi-objective Optimization
• MGAnDSMs structured within multi-objective hybrid optimal control 
algorithm (discrete & continuous variables)
• Multi-objective genetic algorithm (GA) serves as outer loop systems 
optimizer around direct-method inner loop trajectory optimizer 
– Outer loop: non-dominated Sorting Genetic Algorithm II (NSGA-II) searches over discrete 
mission parameters, defining trajectory problem for inner loop
• Variables include: Flyby body, target body, launch vehicle, launch C3, launch epoch
– Inner loop: MBH+SQP solves trajectory problem & establishes obj. func. values
– Generates representation of Pareto front (optimal tradeoff between objectives)
Initial generation
TOF TOF
Delivered
Mass
Population evolves via 
genetic operators
Delivered
Mass
Final generation
8
• Established global optimum serves a test case for comparison of MGAnDSMs & a Lambert-
based transcription (MGADSMk); one DSM allowed
• MGAnDSMs identified global optimum in 10 out of 10 cases
• MGADSk identified solution w/in 50 m/s of global optimum, but not the global optimum (1.004 
km/s) after an 8 hour run time
• Order of magnitude improvement in time to best solution
– Median time is 25x faster
Cassini Test Case Comparison
9
Run 
Number
MGAn DSMs
Time to Identify 
Global Optimum 
(minutes)
MGADSMk             
Time to Identify 
Best Solution   
(minutes)
MGADSMk
Time Identify Solution 
within 50 m/s of 
Global Optimum 
(minutes)
MGADSMk 
Best ΔV 
(km/s)
1 5.3 223.8 220.3 1.025
2 7.9 140.9 32.9 1.043
3 8.8 260.8 149.3 1.026
4 12.8 74.3 74.3 1.014
5 63.1 178.1 122.0 1.020
6 4.3 295.4 112.0 1.034
7 5.0 471.3 465.7 1.039
8 6.3 382.9 328.5 1.049
9 9.4 80.6 58.4 1.033
10 38.4 63.6 63.6 1.038
Mean 16.1 217.2 162.7 1.032
Median 8.4 200.9 117.0 1.033
VVEJ
• Evaluated MGAnDSMs multi-objective capability on a multiple gravity assist to Jupiter with up to 
2 DSMs per phase
• Flyby bodies are varied with any combination up to 5 bodies 
• Three objectives: maximize log10(final mass), minimize TOF, minimize Jupiter arrival C3
– Pareto front: 3D surface of equally optimal solutions
• Population size of 256 and the MBH+SQP inner loop is allowed to run for 40 minutes
Example Problem:  Multi-objective Optimization to 
Jupiter
10
Design Variable Value Resolution
Launch window 
open epoch
{1/1/2021, 1/1/2022, 
1/1/2023, 1/1/2024}
1 year
Flyby body
{Venus, Earth, Mars, 
null, null, null}
n/a
Flight time [730, 3467.5] days 182.5 days
Outer-loop Design Variables Common Mission Parameters
Description Value
Launch window 365.24 days
Launch declination [-28.5, 28.5] deg
Launch vehicle curve Atlas V, 551
Chemical Isp 320 s
Jupiter arrival date
Determined by
optimizer
Jupiter insertion orbit semi-major axis
10,054,900 km 
(140.6 RJ)
Jupiter insertion orbit eccentricity 0.911
Maximum number of DSMs 2
Inner-loop objective function Max: log10(final mass)
Inner-loop run time 40 minutes
Best Non-Dominated Front
11
• Representation of 3D Pareto front generated after 100 generations
• 3.5 days of run time on 64-core processor
Example Optimal Jupiter Trajectories
12
Highest Delivered Mass Trajectory
• EVEEJ sequence
• Delivered mass: 3192 kg 
• TOF: 7.9 years
• Arrival C3: 34.1 km/s
Shortest TOF Trajectory
• Direct EJ (2 DSMs optimal)
• Delivered mass: 642 kg 
• TOF: 2.0 years
• Arrival C3: 45.1 km/s
Optimal Jupiter Trajectory with 2 DSMs in 1 Phase
13
EVEJ sequence
• Developed high-thrust trajectory optimization transcription for any number of 
maneuvers between flybys
• Multiple shooting framework & analytic derivatives provide robustness and 
enable outer-loop efficiency
• Formulation allows for an automated, global search without a user-supplied 
initial guess
• Capability to generate Pareto-optimal solutions using multi-objective hybrid 
optimal control algorithm
• General applicability to almost any variety of interplanetary mission
– Flexible to unique trajectory/mission constraints
• Large problems can become computationally tractable
Conclusions
14
Backup
15
• Want to optimize any number of mission design metrics
– e.g., payload mass, TOF, arrival C3
– Often coupled & competing
– Fully map mission trade-offs between optimal solutions
f2: BOL power
f 1
: 
re
tu
rn
 m
a
s
s
Pareto front
Feasible designs
Multi-objective Optimization
• Optimize multiple objectives 
simultaneously
– Entire set of optimal solutions
– Goal: generate representation of 
Pareto front
– Traditionally use repetitions of 
single objective technique
16
• Develops globally-optimal Pareto solutions using non-dominated sorting
– Conducts stochastic, global search with population of designs
• Fitness assignment based on “nearness” to Pareto front
– x1 dominates x2 if:
objpp
objpp
npffp
npffp
1,2,...,      )()(:
and                       
1,2,...,      )()(:
21
21


xx
xx
f2: time of flight
f 1
: 
 f
in
a
l 
m
a
s
s
1
5
2
6
3
7
4
front 1 (Pareto front)
front 2
front 3
f 1
: 
 f
in
a
l 
m
a
s
s
NSGA-II 
• If neither design dominates other, they 
are non-dominant
• Non-dominated sorting:
– Assign fitness based on design’s non-
dominated front
– Designs closer to Pareto front get more 
mating opportunities
17
Initial random population 
generated
Is stopping 
criteria met?
Assign fitness value
Selection
Yes
No
Stop
Crossover
Mutation
• Models Darwinian evolution
– Mimic natural selection & reproduction
• Searches with population of designs
• Globally search design space
• No initial guess required
Genetic Algorithm
18


Global Optimization of N-Maneuver, High-Thrust Trajectories Using Direct Multiple Shooting

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