Sampling-based algorithms are viewed as practical solutions for high-dimensional motion planning. Recent progress has taken advantage of random geometric graph theory to show how asymptotic optimality can also be achieved with these methods. Achieving this desirable property for systems with dynamics requires solving a two-point boundary value problem (BVP) in the state space of the underlying dynamical system. It is difficult, however, if not impractical, to generate a BVP solver for a variety of important dynamical models of robots or physically simulated ones. Thus, an open challenge was whether it was even possible to achieve optimality guarantees when planning for systems without access to a BVP solver. This work resolves the above question and describes how to achieve asymptotic optimality for kinodynamic planning using incremental sampling-based planners by introducing a new rigorous framework. Two new methods, STABLE_SPARSE_RRT (SST) and SST*, result from this analysis, which are asymptotically near-optimal and optimal, respectively. The techniques are shown to converge fast to high-quality paths, while they maintain only a sparse set of samples, which makes them computationally efficient. The good performance of the planners is confirmed by experimental results using dynamical systems benchmarks, as well as physically simulated robots.
Ai-OmariMARJaradatMAJarrahM (2013) Integrated simulation platform for indoor quadrotor applications. In: 2013 9th International Symposium on Mechatronics and its Applications (ISMA), pp. 1–6.
2.
AlterovitzRPatilSDerbakovaA (2011) Rapidly-exploring roadmaps: weighing exploration vs. refinement in optimal motion planning. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 3706–3712.
3.
AryaSMountDMNetanyahuNSSilvermanRWuAY (1998) An optimal algorithm for approximate nearest neighbor searching fixed dimensions. Journal of the ACM45(6): 891–923.
4.
BarraquandJLatombeJC (1993) Nonholonomic multibody mobile robots: controllability and motion planning in the presence of obstacles. Algorithmica10(2–4): 121–155.
5.
BekrisKKavrakiL (2008) Informed and probabilistically complete search for motion planning under differential constraints. In: First International Symposium on Search Techniques in Artificial Intelligence and Robotics (STAIR), Chicago, IL.
6.
BettsJT (1998) Survey of numerical methods for trajectory optimization. AIAA Journal of Guidance, Control and Dynamics21(2): 193–207.
7.
BobrowJEDubowskySGibsonJS (1985) Time-optimal control of robotic manipulators along prespecified paths. The International Journal of Robotics Research4(3): 3–17.
8.
BranickyMSCurtisMMLevineJMorganS (2006) Sampling-based planning, control, and verification of hybrid systems. In: IEEE Proceedings Control Theory and Applications, pp. 575–590.
9.
BrockettRW (1982) Control theory and singular Riemannian geometry. In: HiltonPJYoungGS (eds.) New Directions in Applied Mathematics. Berlin: Springer-Verlag, pp. 11–27.
10.
CannyJRegeAReifJ (1991) An exact algorithm for kinodynamic planning in the plane. Discrete and Computational Geometry6: 461–484.
11.
ChengPFrazzoliELaValleSM (2004) Improving the performance of sampling-based planners by using a symmetry-exploiting gap reduction algorithm. In: IEEE International Conference on Robotics and Automation (ICRA).
12.
ChengPLaValleSM (2001) Reducing metric sensitivity in randomized trajectory design. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).
13.
ChosetHLynchKMHutchinsonSKantorGBurgardWKavrakiLEThrunS (2005) Principles of Robot Motion. Cambridge, MA: The MIT Press.
14.
ChowW (1940/1941) Über Systeme von linearen partiellen Differentialgleichungen erster Ordnung. Mathematische Annalen117: 98–105.
DobsonABekrisK (2014) Sparse roadmap spanners for asymptotically near-optimal motion planning. The International Journal of Robotics Research33(1): 18–47.
17.
DobsonABekrisKE (2013) Finite-time near-optimality properties of sampling-based motion planners. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Tokyo Big Sight, Japan.
18.
DobsonAKrontirisABekrisK (2012) Sparse roadmap spanners. In: Workshop on Algorithmic Foundations of Robotics (WAFR).
19.
DonaldBRXavierPG (1995) Provably good approximation algorithms for optimal kinodynamic planning for Cartesian robots and open chain manipulators. Algorithmica4(6): 480–530.
20.
DonaldBRXavierPGCannyJReifJ (1993) Kinodynamic motion planning. Journal of the ACM40(5): 1048–1066.
21.
FergusonDStentzA (2006) Anytime RRTs. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 5369–5375.
22.
FernandesCGurvitsLLiZ (1993) Optimal non-holonomic motion planning for a falling cat. In: LiZCannyJ (eds.) Nonholonomic Motion Planning. Dodrecht: Kluwer Academic.
23.
FliessMLévineJMarinPRouchonP (1995) Flatness and defect of nonlinear systems: introductory theory and examples. International Journal of Control61(6): 1327–1361.
24.
FrazzoliEDahlehMAFeronE (2002) Real-time motion planning for agile autonomous vehicles. Journal of Guidance, Control and Dynamics25(1): 116–129.
25.
GlassmanETedrakeR (2010) A quadratic regulator-based heuristic for rapidly exploring state space. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 5021–5028.
26.
GoretkinGPerezAPlattRKonidarisG (2013) Optimal sampling-based planning for linear-quadratic kinodynamic systems. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 2429–2436.
27.
GrimmettGStirzakerD (2001) Probability and Random Processes. 3 edition. Oxford: Oxford University Press.
28.
HeinzingerGJacobsPCannyJPadenB (1989) Time-optimal trajectories for a robot manipulator: a provably good approximation algorithms. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 150–156.
29.
HsuDKavrakiLLatombeJCMotwaniRSorkinS (1998) On finding narrow passages with probabilistic roadmap planners. In: Workshop on Algorithmic Foundations of Robotics (WAFR), pp. 141–153.
30.
HsuDKindelRLatombeJCRockS (2002) Randomized kinodynamic motion planning with moving obstacles. The International Journal of Robotics Research21(3): 233–255.
31.
JansonLPavoneM (2013) Fast marching trees: a fast marching sampling-based method for optimal motion planning in many dimensions. In: International Symposium of Robotics Research (ISRR).
32.
JeonJHCowlagiRPetersSKaramanSFrazzoliETsiotrasPIagnemmaK (2013) Optimal motion planning with the half-car dynamical model for autonomous high-speed driving. In: American Control Conference (ACC), pp. 188–193.
33.
JeonJHKaramanSFrazzoliE (2011) Anytime computation of time-optimal off-road vehicle maneuvers using the RRT*. In: IEEE Conference on Decision and Control (CDC), pp. 3276–3282.
34.
KaramanSFrazzoliE (2010) Incremental sampling-based algorithms for optimal motion planning. In: Robotics: Science and Systems (RSS).
35.
KaramanSFrazzoliE (2011) Sampling-based algorithms for optimal motion planning. The International Journal of Robotics Research30(7): 846–894.
36.
KaramanSFrazzoliE (2013) Sampling-based optimal motion planning for non-holonomic dynamical systems. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 5041–5047.
37.
KaramanSWalterMPerezAFrazzoliETellerS (2011) Anytime motion planning using the RRT*. In: IEEE International Conference on Robotics and Automation (ICRA).
38.
KavrakiLEKolountzakisMNLatombeJC (1998) Analysis of probabilistic roadmaps for path planning. IEEE Transactions on Robotics and Automation14(1): 166–171.
39.
KavrakiLESvestkaPLatombeJCOvermarsM (1996) Probabilistic roadmaps for path planning in high-dimensional configuration spaces. IEEE Transactions on Robotics and Automation12(4): 566–580.
40.
KuffnerJLavalleS (2000) An efficient approach to single-query path planning. In: IEEE International Conference on Robotics and Automation (ICRA).
41.
KuindersmaSPermenterFTedrakeR (2014) An efficiently solvable quadratic program for stabilizing dynamic locomotion. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 2589–2594.
42.
KunzTStilmanM (2014) Kinodynamic RRTs with fixed time step and best-input extension are not probabilistically complete. In: Workshop on Algorithmic Foundations of Robotics (WAFR).
43.
LaddAMKavrakiLE (2004) Measure theoretic analysis of probabilistic path planning. IEEE Transactions on Robotics and Automation20(2): 229–242.
44.
LaddAMKavrakiLE (2005a) Fast tree-based exploration of state space for robots with dynamics. In: Algorithmic Foundations of Robotics VI (Springer Tracts in Advanced Robotics, vol. 17). New York: Springer, pp. 297–312.
45.
LaddAMKavrakiLE (2005b) Motion planning in the presence of drift, underactuation and discrete system changes. In: Robotics: Science and Systems (RSS), pp. 233–240.
46.
LamirauxFFerreEValleeE (2004) Kinodynamic motion planning: connecting exploration trees using trajectory optimization methods. In: IEEE International Conference on Robotics and Automation (ICRA), pp. 3987–3992.
47.
LaumondJPSekhavatSLamirauxF (1998) Robot Motion Planning and Control - Chapter 1: Guidelines in Nonholonomic Motion Planning for Mobile Robots. New York: Springer.
48.
LaValleSKuffnerJ (2001a) Randomized Kinodynamic Planning. The International Journal of Robotics Research20(5): 378–400.
49.
LaValleSKuffnerJ (2001b) Rapidly exploring random trees: Progress and prospects. In: Workshop on Algorithmic Foundations of Robotics (WAFR).
50.
LewisFLSyrmosVL (1995) Optimal Control. New York: John Wiley and Sons Inc.
51.
LiYBekrisKE (2010) Balancing state-space coverage in planning with dynamics. In: IEEE International Conference on Robotics and Automation (ICRA).
52.
LiYBekrisKE (2011) Learning approximate cost-to-go metrics to improve sampling-based motion planning. In: IEEE International Conference on Robotics and Automation (ICRA).
53.
LiYLittlefieldZBekrisKE (2014) Sparse methods for efficient asymptotically optimal kinodynamic planning. In: Workshop on Algorithmic Foundations of Robotics (WAFR), Istanbul, Turkey.
54.
LikhachevMFergusonD (2009) Planning long dynamically-feasible maneuvers for autonomous vehicles. The International Journal of Robotics Research28: 933–945.
55.
LittlefieldZLiYBekrisK (2013) Efficient sampling-based motion planning with asymptotic near-optimality guarantees with dynamics. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).
56.
LittlefieldZKurniawatiHBekrisKKlimenkoE (2015) The importance of a suitable distance function in belief-space planning. In: International Symposium on Robotic Research (ISRR), Sestri Levante, Italy.
57.
MarbleJDBekrisKE (2011) Asymptotically near-optimal is good enough for motion planning. In: International Symposium of Robotics Research (ISRR).
58.
MarbleJDBekrisK (2013) Asymptotically near-optimal planning with probabilistic roadmap spanners. IEEE Transactions on Robotics29(2): 432–444.
59.
NechushtanORavehBHalperinD (2010) Sampling-diagrams automata: a tool for analyzing path quality in tree planners. In: Workshop on Algorithmic Foundations of Robotics (WAFR).
60.
O’DunlaingC (1987) Motion planning with inertial constraints. Algorithmica4(2): 431–475.
61.
OstrowskiJPDesaiJPKumarV (2000) Optimal gait selection for non-holonomic locomotion systems. The International Journal of Robotics Research19(3): 225–237.
62.
PapadopoulosGKurniawatiHPatrikalakisN (2014) Analysis of asymptotically optimal sampling-based motion planning algorithms for Lipschitz continuous dynamical systems. Preprint1405.2872.
63.
ParanjapeAMeierKShiXChungSJHutchinsonS (2013) Motion primitives and 3-D path planning for fast flight through a forest. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).
64.
PhillipsJMBedrosianNKavrakiLE (2004) Guided expansive spaces trees: A search strategy for motion and cost-constrained state spaces. In: IEEE international Conference on Robotics and Automation (ICRA).
65.
PlakuEKavrakiLEVardiMY (2010) Motion planning with dynamics by a synergistic combination of layers of planning. IEEE Transactions on Robotics26(3): 469–482.
66.
RichterCBryARoyN (2013) Polynomial trajectory planning for aggressive quadrotor flight in dense indoor environments. In: International Symposium of Robotics Research (ISRR), Singapore.
67.
SaharGHollerbachJ (1985) Planning of minimum-time trajectories for robot arms. In: IEEE International Conference on Robotics and Automation (ICRA).
68.
SanchezGLatombeJC (2001) A single-query, bi-directional probabilistic roadmap planner with lazy collision checking. In: International Symposium of Robotics Research (ISRR), pp. 403–418.
69.
SchulmanJDuanYHoJLeeAAwwalIBradlowHPanJPatilSGoldbergKAbbeelP (2014) Motion planning with sequential convex optimization and convex collision checking. The International Journal of Robotics Research33(9): 1251–1270.
70.
ShaharabaniDSalzmanOAgarwalPHalperinD (2013) Sparsification of motion-planning roadmaps by edge contraction. In: IEEE International Conference on Robotics and Automation (ICRA).
71.
ShillerZDubowskyS (1988) Global time-optimal motions of robotic manipulators in the presence of obstacles. In: IEEE International Conference on Robotics and Automation (ICRA).
72.
ShillerZDubowskyS (1991) On computing the global time-optimal motions of robotic manipulators in the presence of obstacles. IEEE Transactions on Robotics and Automation7(6): 785–797.
73.
ShkolnikAWalterMTedrakeR (2009) Reachability-guided sampling for planning under differential constraints. In: IEEE International Conference on Robotics and Automation (ICRA).
74.
SpongMW (1997) Underactuated mechanical systems. In: SicilianoBValavanisKP (eds.) Control problems in robotics and automation (Lecture Notes in Control and Information Sciences, vol. 230). New York: Springer, pp. 135–150.
75.
SreenathKLeeTKumarV (2013) Geometric control and differential flatness of a quadrotor UAV with a cable-suspended load. In: IEEE Conference on Decision and Control (CDC), Florence, Italy.
76.
ŞucanIAKavrakiLE (2012) A sampling-based tree planner for systems with complex dynamics. IEEE Transactions on Robotics28(1): 116–131.
77.
SussmannH (1987) A general theorem on local controllability. SIAM Journal of Control and Optimization25(1): 158–194.
78.
TedrakeR (2009) LQR-trees: feedback motion planning on sparse randomized trees. In: Robotics: Science and Systems (RSS), June.
79.
UrmsonCSimmonsR (2003) Approaches for heuristically biasing RRT growth. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 1178–1183.
80.
WangWBalkcomDChakrabartiA (2013) A fast streaming spanner algorithm for incrementally constructing sparse roadmaps. In: IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS).
81.
WebbDvan Den BergJ (2013) Kinodynamic RRT*: asymptotically optimal motion planning for robots with linear differential contstraints. In: IEEE International Conference on Robotics and Automation (ICRA).
82.
ZuckerMKuffnerJBranickyMS (2007) Multiple RRTs for rapid replanning in dynamic environments. In: IEEE International Conference on Robotics and Automation (ICRA).
83.
ZuckerMRatliffNDDraganADPivtoraikoMKlingensmithMDellinCMBagnellJASrinivasaS (2013) CHOMP: covariant Hamiltonian optimization for motion planning. The International Journal of Robotics Research32(9–10): 1164–1193.
