Snakes and snake-like robots show how sidewinders conquer sandy slopes

Snakes and snake-like robots show how sidewinders conquer sandy slopes
A sidewinder snake is shown in a sand-filled trackway at Zoo Atlanta. Researchers from Georgia Tech, Carnegie-Mellon University, Zoo Atlanta and Oregon State Univesity studied the snakes to understand the unique motion they use to climb sandy slopes. Credit: Rob Felt

The amazing ability of sidewinder snakes to quickly climb sandy slopes was once something biologists only vaguely understood and roboticists only dreamed of replicating. By studying the snakes in a unique bed of inclined sand and using a snake-like robot to test ideas spawned by observing the real animals, both biologists and roboticists have now gained long-sought insights.

In a study to be published in the October 10 issue of the journal Science, researchers from the Georgia Institute of Technology, Carnegie Mellon University, Oregon State University, and Zoo Atlanta report that sidewinders improve their ability to traverse sandy slopes by simply increasing the amount of their body area in contact with the granular surfaces they're climbing.

As part of the study, the principles used by the sidewinders to gracefully climb dunes were tested using a modular snake robot developed at Carnegie Mellon. Before the study, the snake robot could use one component of sidewinding motion to move across level ground, but was unable to climb the inclined sand trackway the real could readily ascend. In a real-world application – an archaeological mission in Red Sea caves – sandy inclines were especially challenging to the robot.

However, when the robot was programmed with the unique wave motion discovered in the sidewinders, it was able to climb slopes that had previously been unattainable. The research was funded by the National Science Foundation, the Army Research Office, and the Army Research Laboratory.

"Our initial idea was to use the robot as a physical model to learn what the snakes experienced," said Daniel Goldman, an associate professor in Georgia Tech's School of Physics. "By studying the animal and the simultaneously, we learned important general principles that allowed us to not only understand the animal, but also to improve the robot."

The detailed study showed that both horizontal and vertical motion had to be understood and then replicated on the snake-like robot for it to be useful on sloping sand.

"Think of the motion as an elliptical cylinder enveloped by a revolving tread, similar to that of a tank," said Howie Choset, a Carnegie Mellon professor of robotics. "As the tread circulates around the cylinder, it is constantly placing itself down in front of the direction of motion and picking itself up in the back. The snake lifts some body segments while others remain on the ground, and as the slope increases, the cross section of the cylinder flattens."

This video explains research done to understand the motion used by sidewinder snakes to climb sandy slopes and to apply that motion to a snake-like robot. Researchers from Georgia Tech, Carnegie-Mellon and Zoo Atlanta are interviewed. Credit: Credit: Maxwell Guberman

At Zoo Atlanta, the researchers observed several sidewinders as they moved in a large enclosure containing sand from the Arizona desert where the snakes live. The enclosure could be raised to create different angles in the sand, and air could be blown into the chamber from below, smoothing the sand after each snake was studied. Motion of the snakes was recorded using high-speed video cameras which helped the researchers understand how the animals were moving their bodies.

"We realized that the sidewinder snakes use a template for climbing on sand, two orthogonal waves that they can control independently," said Hamid Marvi, a postdoctoral fellow at Carnegie Mellon who conducted the experiments while he was a graduate student in the laboratory of David Hu, an associate professor in Georgia Tech's School of Mechanical Engineering. "We used the snake robot to systematically study the failure modes in sidewinding. We learned there are three different failure regimes, which we can avoid by carefully adjusting the aspect ratio of the two waves, thus controlling the area of the body in contact with the sand."

Limbless animals like snakes can readily move through a broad range of surfaces, making them attractive to robot designers.

Snakes and snake-like robots show how sidewinders conquer sandy slopes
Researchers studied sidewinder snakes to understand the unique motion they use to climb sandy slopes. Shown (l-r) are Dan Goldman of Georgia Tech, Hamid Marvi of Carnegie Mellon and Joe Mendelson of Zoo Atlanta. Credit: Rob Felt

"The snake is one of the most versatile of all land animals, and we want to capture what they can do," said Ross Hatton, an assistant professor of mechanical engineering at Oregon State University who has studied the mathematical complexities of snake motion, and how they might be applied to robots. "The desert sidewinder is really extraordinary, with perhaps the fastest and most efficient natural motion we've ever observed for a snake."

Many people dislike snakes, but in this study, the venomous animals were easy study subjects who provided knowledge that may one day benefit humans, noted Joe Mendelson, director of research at Zoo Atlanta.

"If a robot gets stuck in the sand, that's a problem, especially if that sand happens to be on another planet," he said. "Sidewinders never get stuck in the sand, so they are helping us create robots that can avoid getting stuck in the sand. These venomous snakes are offering something to humanity."

The modular used in this study was specifically designed to pass horizontal and vertical waves through its body to move in three-dimensional spaces. The robot is two inches in diameter and 37 inches long; its body consists of 16 joints, each joint arranged perpendicular to the previous one. That allows it to assume a number of configurations and to move using a variety of gaits – some similar to those of a biological snake.

"This type of robot often is described as biologically inspired, but too often the inspiration doesn't extend beyond a casual observation of the biological system," Choset said. "In this study, we got biology and robotics, mediated by physics, to work together in a way not previously seen."

Choset's robots appear well suited for urban search-and-rescue operations in which robots need to make their way through the rubble of collapsed structures, as well as archaeological explorations. Able to readily move through pipes, the robots also have been tested to evaluate their potential for inspecting nuclear power plants from the inside out.

For Goldman's team, the work builds on earlier research studying how turtle hatchlings, crabs, sandfish lizards, and other animals move about on complex surfaces such as sand, leaves, and loose material. The team tests what it learns from the animals on robots, often gaining additional insights into how the animals move.

"We are interested in how animals move on different types of granular and complex surfaces," Goldman said. "The idea of moving on flowing materials like sand can be useful in a broad sense. This is one of the nicest examples of collaboration between biology and robotics."

More information: Hamidreza Marvi et al., "Sidewinding with minimal slip: snake and robot ascent of sandy slopes," Science 2014. … 1126/science.1255718

Journal information: Science

Citation: Snakes and snake-like robots show how sidewinders conquer sandy slopes (2014, October 9) retrieved 28 May 2024 from
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