In this paper, we present a feasible solution to the problem of autonomous navigation in initially unknown environments using a pure vision-based approach. The mobile robot performs range sensing with a unique omnidirectional stereovision system, estimates its motion using visual odometry and detects loop closures via a place recognition system as it performs topological map building and localization concurrently. Owing to the importance of performing loop closing regularly, the mobile robot is equipped with an active loop closure detection and validation system that assists it to return to target loop closing locations, validates ambiguous loop closures and provides it with the ability to overturn the decision of an incorrectly committed loop closure. A refined incremental probabilistic framework for an appearance-based place recognition system is fully described and the final system is validated in multiple experiments conducted in indoor, semi-outdoor and outdoor environments. Lastly, the performance of the probabilistic framework is compared with the rank-based framework with additional experiments conducted in the semi-autonomous mode, where the mobile robot, provided with a priori information in the form of a topological map that is built in a separate occasion in an offline manner, is required to reach its target destination.
AngeliAFilliatDDoncieuxSMeyerJ-A (2008) A fast and incremental method for loop-closure detection using bags of visual words. IEEE Transactions on Robotics24: 1027–1037.
2.
BaileyTDurrant-WhyteH (2006) Simultaneous localisation and mapping (SLAM): Part II state of the art. IEEE Robotics and Automation Magazine13: 108–117.
3.
BayHTuytelaarsTGoolLV (2006) SURF: Speeded up robust features. In Proceedings of Ninth European Conference on Computer Vision.
4.
BeeversKRHuangWH (2005) Loop closing in topological maps. In IEEE International Conference on Robotics and Automation, Barcelona, Spain, pp. 4368–4372.
5.
ChahlJSrinivasanM (1997) Reflective surfaces for panoramic imaging. Applied Optics36: 8275–8285.
6.
ChosetHNagataniK (2001) Topological simultaneous localization and mapping (SLAM) toward exact localization without explicit localization. IEEE Transactions on Robotics and Automation17: 125–137.
7.
CumminsMNewmanP (2008) FAB-MAP probabilistic localization and mapping in the space of appearance. The International Journal of Robotics Research27: 647–665.
8.
CumminsMNewmanP (2010) Appearance-only SLAM at large scale with FAB-MAP 2.0. The International Journal of Robotics Research, in press.
9.
DuckettTMarslandSShapiroJ (2000) Learning globally consistent maps by relaxation. In IEEE International Conference on Robotics and Automation, San Francisco, CA, pp. 3841–3846.
10.
FernandezDPriceA (2004) Visual odometry for an outdoor mobile robot. In IEEE Conference on Robotics, Automation and Mechatronics, Singapore, pp. 816–821.
11.
FolkessonJChristensenHI (2007) Graphical SLAM for outdoor applications. Journal of Field Robotics24: 51–70.
12.
HoNJarvisR (2008) Vision based global localisation using a 3D environmental model created by a laser range scanner. In IEEE/RSJ International Conference on Intelligent Robots and Systems, Nice, France.
13.
HsiehP-CTungP-C (2009) A novel hybrid approach based on sub-pattern technique and whitened PCA for face recognition. Pattern Recognition42: 978–984.
JarvisR (1985) Collision-free trajectory planning using distance transforms. Mechanical Engineering Transactions, Journal of the Institution of Engineers10: 187–191.
16.
JarvisR (1992) Optimal pathways for road vehicle navigation. In IEEE Region 10 International Conference Technology Enabling Tomorrow: Computers, Comunications, and Automation Towards the 21st Century, Melbourne, Australia, pp. 876–880.
17.
KawewongATongprasitNTangruamsubSHasegawaO (2011) Online and incremental appearance-based SLAM in highly dynamic environments. The International Journal of Robotics Research30: 33–55.
18.
KröseBBunschotenRVlassisNMotomuraY (1999) Appearance based robot localization. In KraetzschmarG (ed.), IJCAI-99 Workshop Adaptrive Spatial Representations of Dynamic Environments, pp. 53–58.
19.
LabrosseF (2007) The visual compass: Performance and limitations of an appearance-based method. Journal of Field Robotics23: 913–941.
20.
LoweD (2004) Distinctive image features from scale invariant keypoints. International Journal of Computer Vision60: 91–110.
21.
LuiWLD (2011) Autonomous Robot Navigation: Appearance Based Topological SLAM. PhD thesis, Intelligent Robotics Research Centre, Department of Electrical and Computer Systems Engineering, Monash University, Australia, http://arrow.monash.edu.au/hdl/1959.1/473850.
22.
LuiWLDJarvisR (2010 a) An active visual loop closure detection and validation system for topological SLAM. In Australasian Conference on Robotics and Automation, Brisbane, Australia.
23.
LuiWLDJarvisR (2010b) Eye-Full Tower: A GPU-based variable multibaseline omnidirectional stereovision system with automatic baseline selection for outdoor mobile robot navigation. Robotics and Autonomous Systems58: 747–761.
24.
LuiWLDJarvisR (2010c) A pure vision-based approach to topological SLAM. In IEEE/RSJ International Conference on Intelligent Robots and Systems, Taipei, Taiwan, pp. 3784–3791.
25.
MilfordMWyethG (2008) Mapping a suburb with a single camera using a biologically inspired SLAM system. IEEE Transactions on Robotics24: 1038–1053.
Nourani-VataniNPradelierC (2010) Scene change detection for vision-based topological mapping and localization. In IEEE/RSJ International Conference on Intelligent Robots and Systems, Taipei, Taiwan, pp. 3792–3797.
OllisMHermanHSinghS (1999) Analysis and Design of Panoramic Stereo Vision using Equi-angular Pixel Cameras. Technical Report CMU-RI-TR-99-04, The Robotics Institute, Carnegie Mellon University, Pittsburgh, PA.
RadkeRJAndraS.Al-KohafiO.RoysamB. (2005). Image change detection algorithms: A systematic survey. IEEE Transactions on Image Processing14: 294–307.
32.
RuiYHuangTS (1999) Image retrieval: Current techniques, promising directions and open issues. Journal of Visual Communication and Image Representation10: 39–62.
33.
ScaramuzzaDSiegwartR (2008) Appearance-guided monocular omnidirectional visual odometry for outdoor ground vehicles. IEEE Transactions on Robotics24: 1015–1026.
34.
SivicJZissermanA (2003) Video google: A text retrieval approach to object matching in videos. In IEEE International Conference on Computer Vision, pp. 1470–1477.
35.
SmeuldersAWWorringMSantiniSGuptaAJainR (2000) Content-based image retrieval at the end of the early years. IEEE Transaction on Pattern Analysis and Machine Intelligence22: 1349–1380.
36.
TapusASiegwartR (2008) Topological SLAM, Probabilistic Reasoning and Decision Making in Sensory-motor Systems. (Springer Tracts in Advanced Robotics, vol. 46). Berlin: Springer-Verlag, pp. 99–127.
37.
ThrunSBurgardWFoxD (2005) Probabilistic Robotics. Casmbridge, MA: MIT Press.
38.
TomatisNNourbakhshISiegwartR (2002) Hybrid simultaneous localization and map building closing the loop with multi-hypotheses tracking. In IEEE International Conference on Robotics and Automation, Washington, DC, pp. 2749–2754.
39.
TullySKantorGChosetHWernerF (2009) A multi-hypothesis topological SLAM approach for loop closing on edge-ordered graphs. In IEEE/RSJ International Conference on Intelligent Robots and Systems, St. Louis, MO, pp. 11–15.
40.
TungadiFLuiWLDKleemanLJarvisR (2010) Robust online map merging system using laser scan matching and omnidirectional vision. In IEEE/RSJ International Conference on Intelligent Robots and Systems, Taipei, Taiwan.
41.
TurkMPentlandA (1991) Eigenfaces for recognition. Journal of Cognitive Neuroscience3: 71–86.
42.
UlrichINourbakhshI (2000) Appearance-based place recognition for topological localization. In IEEE International Conference on Robotics and Automation, San Francisco, CA, pp. 1023–1029.
43.
UmeyamaS (1991) Least-squares estimation of transformation parameters between two point patterns. IEEE Transactions on Pattern Analysis and Machine Intelligence13: 376–380.
44.
YamauchiB (1997) A frontier-based approach for autonomous exploration. In IEEE International Symposium on Computational Intelligence in Robotics and Automation, Monterey, CA, pp. 146–151.
45.
ZhangAMKleemanL (2009) Robust appearance based visual route following for navigation in large-scale outdoor environments. The International Journal of Robotics Research28: 331–356.
46.
ZhangHLiBYangD (2010) Keyframe detection for appearance-based visual SLAM. In IEEE/RSJ International Conference on Intelligent Robots and Systems, Taipei, Taiwan, pp. 2071–2076.
