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| Spiders trained to jump on demand in major robotic engineering breakthrough | Spiders trained to jump on demand in major robotic engineering breakthrough |
| (about 3 hours later) | |
| A spider called Kim has been trained to jump on demand by scientists keen to learn the secrets of her acrobatic ability. | A spider called Kim has been trained to jump on demand by scientists keen to learn the secrets of her acrobatic ability. |
| The circus act study could help engineers design agile mini-robots that are currently beyond human technology. | The circus act study could help engineers design agile mini-robots that are currently beyond human technology. |
| Kim is a “regal jumping spider”, Phidippus regius, a species famed for its astonishing leaps. | |
| Jumping spiders, which measure up to two centimetres across, are able to bound up to six times their body length from a standing start. In comparison, the best a human can achieve is about 1.5 body lengths. | Jumping spiders, which measure up to two centimetres across, are able to bound up to six times their body length from a standing start. In comparison, the best a human can achieve is about 1.5 body lengths. |
| At takeoff, the force on the spider’s legs is equivalent to five times the creature’s body weight. | |
| Lead scientist Dr Mostafa Nabawy, from the University of Manchester, said: “This is amazing and if we can understand these biomechanics we can apply them to other areas of research.” | |
| Dr Nabawy’s team trained Kim to jump different heights and distances on a manmade laboratory platform. | |
| Her jumps were recorded using ultra-high-speed cameras. The scientists also took micro-CT scans of the spider to create a 3D virtual model of her legs and body structure. | |
| The results, published in the journal Scientific Reports, show that Kim used different jumping strategies depending on the challenge she was presented with. | The results, published in the journal Scientific Reports, show that Kim used different jumping strategies depending on the challenge she was presented with. |
| For short distances she favoured a faster, lower trajectory, which used up more energy but minimised flight time. This made the jump more accurate and effective for capturing prey. | |
| Longer distance jumps of the sort used to cross rough terrain were slower and more energy efficient. | Longer distance jumps of the sort used to cross rough terrain were slower and more energy efficient. |
| Insects and spiders jump in a number of different ways, using a spring-like mechanism, direct muscle forces, or internal fluid pressure. | |
| Spiders are known to use the hydraulic fluid pressure system to extend their legs, but what role this played in jumping was unknown. | Spiders are known to use the hydraulic fluid pressure system to extend their legs, but what role this played in jumping was unknown. |
| Study co-author Dr Bill Crowther, also from the University of Manchester, said: “Our results suggest that whilst Kim can move her legs hydraulically, she does not need the additional power from hydraulics to achieve her extraordinary jumping performance. | |
| “Thus, the role of hydraulic movement in spiders remains an open question.” | |
| PA |
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