Thanks to the design of its legs, which faithfully mimic feline morphology, EPFL's four-legged "cheetah-cub robot" shares the advantages of its biological model: it is small, light and runs very fast.
In the long term, this type of machine, which is still in an experimental stage, could be used in search and rescue missions or for exploration. Credit: EPFL
Thanks to its legs, whose design faithfully reproduces feline morphology, EPFL's 4-legged 'cheetah-cub robot' has the same advantages as its model: It is small, light and fast.
Even though it doesn't have a head, you can still tell what kind of animal it is: the robot is definitely modeled upon a cat.
Developed by EPFL's Biorobotics Laboratory (Biorob), the "cheetah-cub robot," a small-size quadruped prototype robot, is described in an article appearing today in the International Journal of Robotics Research.
The purpose of the platform is to encourage research in biomechanics; its particularity is the design of its legs, which make it very fast and stable.
Robots developed from this concept could eventually be used in search and rescue missions or for exploration.
This robot is the fastest in its category, namely in normalized speed for small quadruped robots under 30Kg.
During tests, it demonstrated its ability to run nearly seven times its body length in one second.
Although not as agile as a real cat, it still has excellent auto-stabilization characteristics when running at full speed or over a course that included disturbances such as small steps.
In addition, the robot is extremely light, compact, and robust and can be easily assembled from materials that are inexpensive and readily available.
Faithful reproduction
The machine's strengths all reside in the design of its legs. The researchers developed a new model with this robot, one that is based on the meticulous observation and faithful reproduction of the feline leg.
The number of segments – three on each leg – and their proportions are the same as they are on a cat. Springs are used to reproduce tendons, and actuators – small motors that convert energy into movement – are used to replace the muscles.
"This morphology gives the robot the mechanical properties from which cats benefit, that's to say a marked running ability and elasticity in the right spots, to ensure stability," explains Alexander Sprowitz, a Biorob scientist. "The robot is thus naturally more autonomous."
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