Robot navigation

Robot navigation using visual and sensorimotor information (2013)

Robot localization denotes the robot's ability to establish its own position and orientation within the

Path planning is effectively an extension of localization, in that it requires the determination of the robot's current position and a position of a goal location, both within the same frame of reference or coordinates. Map building can be in the shape of a metric map or any notation describing locations in the robot frame of reference.^{[citation needed}

]

For any mobile device, the ability to navigate in its environment is important. Avoiding dangerous situations such as collisions and unsafe conditions (temperature, radiation, exposure to weather, etc.) comes first, but if the robot has a purpose that relates to specific places in the robot environment, it must find those places. This article will present an overview of the skill of navigation and try to identify the basic blocks of a robot navigation system, types of navigation systems, and closer look at its related building components.

Robot navigation means the robot's ability to determine its own position in its frame of reference and then to plan a path towards some goal location. In order to navigate in its environment, the robot or any other mobility device requires representation, i.e. a map of the environment and the ability to interpret that representation.

Navigation can be defined as the combination of the three fundamental competences:^[1]

Self-localization
Path planning
Map-building and map interpretation

Some robot navigation systems use simultaneous localization and mapping to generate 3D reconstructions of their surroundings.^[2]

Vision-based navigation

Vision-based navigation or optical navigation uses computer vision algorithms and optical sensors, including laser-based range finder and photometric cameras using CCD arrays, to extract the visual features required to the localization in the surrounding environment. However, there are a range of techniques for navigation and localization using vision information, the main components of each technique are:

representations of the environment.
sensing models.
localization algorithms.

In order to give an overview of vision-based navigation and its techniques, we classify these techniques under indoor navigation and outdoor navigation.

Indoor navigation

Egomotion estimation

from a moving camera

The easiest way of making a robot go to a goal location is simply to guide it to this location. This guidance can be done in different ways: burying an inductive loop or magnets in the floor, painting lines on the floor, or by placing beacons, markers, bar codes etc. in the environment. Such Automated Guided Vehicles (AGVs) are used in industrial scenarios for transportation tasks. Indoor Navigation of Robots are possible by IMU based indoor positioning devices.^[3]^[4]

There are a very wider variety of indoor navigation systems. The basic reference of indoor and outdoor navigation systems is "Vision for mobile robot navigation: a survey" by Guilherme N. DeSouza and Avinash C. Kak.

Also see "Vision based positioning" and AVM Navigator.

Autonomous Flight Controllers

Typical Open Source Autonomous Flight Controllers have the ability to fly in full automatic mode and perform the following operations;

Take off from the ground and fly to a defined altitude
Fly to one or more waypoints
Orbit around a designated point
Return to the launch position
Descend at a specified speed and land the aircraft

The onboard flight controller relies on GPS for navigation and stabilized flight, and often employ additional

Satellite-based augmentation systems (SBAS) and altitude (barometric pressure) sensor.^[5]

Inertial navigation

Some navigation systems for airborne robots are based on

inertial sensors.^[6]

Acoustic navigation

Autonomous underwater vehicles can be guided by underwater acoustic positioning systems.^[7] Navigation systems using sonar have also been developed.^[8]

Radio navigation

Robots can also determine their positions using radio navigation.^[9]

References

^ Stachniss, Cyrill. "Robotic mapping and exploration." Vol. 55. Springer, 2009.
^ Fuentes-Pacheco, Jorge, José Ruiz-Ascencio, and Juan Manuel Rendón-Mancha. "Visual simultaneous localization and mapping: a survey." Artificial Intelligence Review 43.1 (2015): 55-81.
S2CID 19472012
.

^ GT Silicon (2017-01-07), An awesome robot with cool navigation and real-time monitoring, archived from the original on 2021-12-12, retrieved 2018-04-04

^ "Flying | AutoQuad".

ISBN 978-3-540-23957-4
.

ISBN 978-1-4614-5659-9
.

ISBN 978-1-4615-3652-9
.

ISBN 978-3-030-22587-2
.

Further reading

Desouza, G.N.; Kak, A.C. (2002). "Vision for mobile robot navigation: A survey". IEEE Transactions on Pattern Analysis and Machine Intelligence. 24 (2): 237–267.
doi:10.1109/34.982903
.

Mobile Robot Navigation Archived 2019-04-05 at the Wayback Machine Jonathan Dixon, Oliver Henlich - 10 June 1997

BECKER, M. ; DANTAS, Carolina Meirelles ; MACEDO, Weber Perdigão, "Obstacle Avoidance Procedure for Mobile Robots". In: Paulo Eigi Miyagi; Oswaldo Horikawa; Emilia Villani. (Org.). ABCM Symposium Series in Mechatronics, Volume 2. 1 ed. São Paulo - SP: ABCM, 2006, v. 2, p. 250-257.
ISBN 978-85-85769-26-0

External links

line tracking sensors for robots and its algorithms

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Retrieved from "https://en.wikipedia.org/w/index.php?title=Robot_navigation&oldid=1200805997"

[1] Stachniss, Cyrill. "Robotic mapping and exploration." Vol. 55. Springer, 2009.

[2] Fuentes-Pacheco, Jorge, José Ruiz-Ascencio, and Juan Manuel Rendón-Mancha. "Visual simultaneous localization and mapping: a survey." Artificial Intelligence Review 43.1 (2015): 55-81.

[3] S2CID 19472012
.

[4] GT Silicon (2017-01-07), An awesome robot with cool navigation and real-time monitoring, archived from the original on 2021-12-12, retrieved 2018-04-04

[5] "Flying | AutoQuad".

[SicilianoKhatib2008-6] ISBN 978-3-540-23957-4
.

[Seto2012-7] ISBN 978-1-4614-5659-9
.

[LeonardDurrant-Whyte2012-8] ISBN 978-1-4615-3652-9
.

[Sergiyenko-9] ISBN 978-3-030-22587-2
.

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