Sage Journals: Discover world-class research

Abstract

In this paper we present a method for automatically generating optimal robot paths satisfying high-level mission specifications. The motion of the robot in the environment is modeled as a weighted transition system. The mission is specified by an arbitrary linear temporal-logic (LTL) formula over propositions satisfied at the regions of a partitioned environment. The mission specification contains an optimizing proposition, which must be repeatedly satisfied. The cost function that we seek to minimize is the maximum time between satisfying instances of the optimizing proposition. For every environment model, and for every formula, our method computes a robot path that minimizes the cost function. The problem is motivated by applications in robotic monitoring and data-gathering. In this setting, the optimizing proposition is satisfied at all locations where data can be uploaded, and the LTL formula specifies a complex data-collection mission. Our method utilizes Büchi automata to produce an automaton (which can be thought of as a graph) whose runs satisfy the temporal-logic specification. We then present a graph algorithm that computes a run corresponding to the optimal robot path. We present an implementation for a robot performing data collection in a road-network platform.

Keywords

Motion planning optimal path planning temporal logic

Get full access to this article

View all access options for this article.

References

Antoniotti

Mishra

(1995) Discrete event models + temporal logic = supervisory controller: Automatic synthesis of locomotion controllers. In: IEEE International Conference on Robotics and Automation, Nagoya, Japan, pp. 1441–1446.

Baier

Katoen

J-P

Larsen

(2008) Principles of Model Checking. Cambridge, MA: MIT Press.

Barnat

Brim

Ročkai

(2009) DiVinE 2.0: High-performance model checking. In: High Performance Computational Systems Biology. Los Alamitos, CA: IEEE Computer Society Press, pp. 31–32.

Belta

Habets

LCGJM

(2006) Control of a class of nonlinear systems on rectangles. IEEE Transactions on Automatic Control 51: 1749–1759.

Belta

Isler

Pappas

(2005) Discrete abstractions for robot motion planning and control in polygonal environment. IEEE Transactions on Robotics 21: 864–875.

Clarke

Peled

Grumberg

(1999) Model Checking. Cambridge, MA: MIT Press.

Ding

Smith

Belta

Rus

(2011) LTL control with probabilistic satisfaction guarantees. In: IFAC World Congress, Milan, Italy, to appear.

Fainekos

Girard

Kress-Gazit

Pappas

(2009) Temporal logic motion planning for dynamic robots. Automatica 45: 343–352.

Gastin

Oddoux

(2001) Fast LTL to Büchi automata translation. In: Conference on Computer Aided Verification (Lecture Notes in Computer Science, Vol. 2102). Berlin: Springer, pp. 53–65.

10.

Gerth

Peled

Vardi

Wolper

(1995) Simple on-the-fly automatic verification of linear temporal logic. In: Protocol Specification, Testing and Verification. London: Chapman & Hall, pp. 3–18.

11.

Habets

LCGJM

van Schuppen

(2004) A control problem for affine dynamical systems on a full-dimensional polytope. Automatica 40: 21–35.

12.

Habets

LCGJM

Collins

van Schuppen

(2006) Reachability and control synthesis for piecewise-affine hybrid systems on simplices. IEEE Transactions on Automatic Control 51: 938–948.

13.

Holzmann

(1997) The model checker SPIN. IEEE Transactions on Software Engineering 25: 279–295.

14.

Karaman

Frazzoli

(2008a) Complex mission optimization for multiple-uavs using linear temporal logic. In: American Control Conference, Seattle, WA, pp. 2003–2009.

15.

Karaman

Frazzoli

(2008b) Vehicle routing problem with metric temporal logic specifications. In: IEEE Conference on Decision and Control, Cancún, México, pp. 3953–3958.

16.

Karaman

Rasmussen

Kingston

Frazzoli

(2009) Specification and planning of uav missions: a process algebra approach. In: American Control Conference, St Louis, MO, pp. 1442–1447.

17.

Korte

Vygen

(2007) Combinatorial Optimization: Theory and Algorithms, 4th edn ( Algorithmics and Combinatorics , Vol. 21). Berlin: Springer.

18.

Kress-Gazit

Fainekos

Pappas

(2009) Temporal logic-based reactive mission and motion planning. IEEE Transactions on Robotics 25: 1370–1381.

19.

Lahijanian

Andersson

Belta

(2011) Temporal logic control for Markov decision processes. In: American Control Conference, San Francisco, CA, to appear.

20.

Laporte

(2009) Fifty years of vehicle routing. Transportation Science 43: 408–416.

21.

LaValle

(2006) Planning Algorithms. Cambridge: Cambridge University Press.

22.

LaValle

Kuffner

(2001) Randomized kinodynamic planning. International Journal of Robotics Research 20: 378–400.

23.

Loizou

Kyriakopoulos

(2004) Automatic synthesis of multiagent motion tasks based on LTL specifications. In: IEEE Conference on Decision and Control, Paradise Island, Bahamas, pp. 153–158.

24.

Quottrup

Bak

Izadi-Zamanabadi

(2004) Multi-robot motion planning: A timed automata approach. In: IEEE International Conference on Robotics and Automation, New Orleans, LA, pp. 4417–4422.

25.

Rimon

Koditschek

(1992) Exact robot navigation using artificial potential functions. IEEE Transactions on Robotics and Automation 8: 501–518.

26.

Russell

Norvig

(2003) Artificial Intelligence: A Modern Approach, 2nd edn. Englewood Cliffs, NJ: Prentice Hall.

27.

Smith

Tůmová

Belta

Rus

(2010) Optimal path planning under temporal logic constraints. In: IEEE/RSJ International Conference on Intelligent Robots & Systems, Taipei, Taiwan, pp. 3288–3293.

28.

Tedrake

Manchester

Tobenkin

Roberts

(2010) LQR-trees: Feedback motion planning via sums of squares verification. International Journal of Robotics Research 29: 1038–1052.

29.

Toth

Vigo

, eds (2001) The vehicle routing problem. In: Monographs on Discrete Mathematics and Applications. Philadelphia, PA: SIAM.

30.

Tůmová

Yordanov

Belta

Černá

Barnat

(2010) A symbolic approach to controlling piecewise affine systems. In: IEEE Conference on Decision and Control, Atlanta, GA, pp. 4230–4235.

31.

Vardi

Wolper

(1986) An automata-theoretic approach to automatic program verification. In: Logic in Computer Science, pp. 322–331.

32.

Vardi

Wolper

(1994) Reasoning about infinite computations. Information and Computation 115: 1–37.

33.

Wongpiromsarn

Topcu

Murray

(2010) Receding horizon control for temporal logic specifications. In: Hybrid Systems: Computation and Control, Stockholm, Sweden, pp. 101–110.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

Optimal path planning for surveillance with temporal-logic constraints *

Abstract

Keywords

Get full access to this article

References

Supplementary Material