Snakebot

The SnakeBot, also known as a snake robot, is a biomorphic hyper-redundant robot that resembles a biological snake. Snake robots come in many shapes and sizes, from as long as four stories (earthquake SnakeBot developed by SINTEF^[1]) to a medical SnakeBot developed at Carnegie Mellon University that is thin enough to maneuver around organs inside a human chest cavity. Though SnakeBots can very greatly in size and design, there are two qualities that all SnakeBot share. The small cross-section-to-length ratios allow them to move into and maneuver through tight spaces and their ability to change the shape of their bodies allows them to perform a wide range of behaviors, such as climbing stairs or tree trunks. Additionally, many snake robots are constructed by chaining together several independent links. This redundancy can make them resistant to failure because they can continue to operate even if parts of their body are destroyed. Properties such as high terrainability, redundancy, and the ability to completely seal their bodies make snake robots particularly notable for practical applications and hence as a research topic.^[2]^[3] A SnakeBot is different from a snake-arm robot in that the SnakeBot robot types are usually more self-contained, where a snake-arm robot usually has remote mechanicals from the arm itself, possibly connected to a larger system.

Applications[edit]

Snakebots can be used to reach tight spaces that humans cannot. These environments tend to be long and thin like pipes or highly cluttered like rubble.^[4] Thus, Snakebots are currently being developed to assist search and rescue teams. When a task requires several different obstacles to be overcome, the locomotive flexibility of SnakeBots potentially offers an advantage.^[5]

Locomotion[edit]

Traditional SnakeBots move by changing the shape of their body, similar to actual snakes. Many variants have been created which use wheels or treads for movement. No SnakeBots have been developed yet that can completely mimic the locomotion of real snakes, but researchers have been able to produce new ways of moving that do not occur in nature.

When researchers refer to how a SnakeBot moves they often refer to a specific gait, meaning a periodic mode of locomotion. For example, sidewinding and lateral undulation are both gaits. SnakeBot gaits are often designed by investigating period changes to the shape of the robot. For example, a caterpillar moving by changing the shape of its body to match a sinusoidal wave. Similarly, SnakeBot can move by adapting their shape to different periodic functions. Sidewinder rattlesnakes can use sidewinding to ascend sandy slopes by increasing the portion of the body in contact with the sand to match the reduced yielding force of the inclined sand, allowing them to ascend to the maximum possible sand slope without slip.^[6] Implementing this control scheme in a SnakeBot is capable of sidewinding allowing robot to replicate the success of snakes.^[6]

Current research[edit]

SnakeBots are currently being researched as a new type of robotic, interplanetary probe by engineers at the NASA Ames Research Center. Software for SnakeBot is also being developed by NASA for them, so that they can learn by experiencing the skills to scale obstacles and remember the techniques.

Snake robots are also being developed for search and rescue purposes at Carnegie Mellon University's Biorobotics Lab.^[7]

References[edit]

^ Pål Liljebäck. "Anna Konda – The fire fighting snake robot | ROBOTNOR". Robotnor.no. Retrieved 2016-05-04.
^ Transeth, Aksel Andreas; Pettersen, Kristin Ytterstad (Dec 2006). "Developments in Snake Robot Modeling and Locomotion". 2006 9th International Conference on Control, Automation, Robotics and Vision. pp. 1–8. doi:10.1109/ICARCV.2006.345142. ISBN 978-1-4244-0341-7. S2CID 2337372.
^ Liljebäck, P.; Pettersen, K. Y.; Stavdahl, Ø.; Gravdahl, J. T. (2013). Snake Robots - Modelling, Mechatronics, and Control. Advances in Industrial Control. Springer. doi:10.1007/978-1-4471-2996-7. ISBN 978-1-4471-2995-0.
^ "Modular Snake Robots - The Robotics Institute Carnegie Mellon University". www.ri.cmu.edu. Retrieved 2024-02-02.
^ "Let a Snake-Inspired Robot Be Your Hero Today | NOVA | PBS". www.pbs.org. Retrieved 2022-09-29.
^ ^a ^b Marvi, Hamidreza (2014-10-10). "Sidewinding with minimal slip: Snake and robot ascent of sandy slopes". Science. 346 (6206): 224–229. arXiv:1410.2945. Bibcode:2014Sci...346..224M. doi:10.1126/science.1255718. PMID 25301625. S2CID 23364137. Retrieved 2016-05-04.
^ "SnakeBots - Carnegie Mellon University | CMU". www.cmu.edu. Retrieved 2024-02-02.

External links[edit]

[1] Pål Liljebäck. "Anna Konda – The fire fighting snake robot | ROBOTNOR". Robotnor.no. Retrieved 2016-05-04.

[2] Transeth, Aksel Andreas; Pettersen, Kristin Ytterstad (Dec 2006). "Developments in Snake Robot Modeling and Locomotion". 2006 9th International Conference on Control, Automation, Robotics and Vision. pp. 1–8. doi:10.1109/ICARCV.2006.345142. ISBN 978-1-4244-0341-7. S2CID 2337372.

[3] Liljebäck, P.; Pettersen, K. Y.; Stavdahl, Ø.; Gravdahl, J. T. (2013). Snake Robots - Modelling, Mechatronics, and Control. Advances in Industrial Control. Springer. doi:10.1007/978-1-4471-2996-7. ISBN 978-1-4471-2995-0.

[4] "Modular Snake Robots - The Robotics Institute Carnegie Mellon University". www.ri.cmu.edu. Retrieved 2024-02-02.

[5] "Let a Snake-Inspired Robot Be Your Hero Today | NOVA | PBS". www.pbs.org. Retrieved 2022-09-29.

[sciencemag1-6] Marvi, Hamidreza (2014-10-10). "Sidewinding with minimal slip: Snake and robot ascent of sandy slopes". Science. 346 (6206): 224–229. arXiv:1410.2945. Bibcode:2014Sci...346..224M. doi:10.1126/science.1255718. PMID 25301625. S2CID 23364137. Retrieved 2016-05-04.

[7] "SnakeBots - Carnegie Mellon University | CMU". www.cmu.edu. Retrieved 2024-02-02.

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