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Benefits of rising trot identified in research

rising-trot

The rising trot significantly reduces the load exerted on a horses back, a Dutch researcher has found.

The research by veterinarian Patricia de Cocq, a keen horsewoman, also gathered some insights into the crouched and elevated riding position used by jockeys, revealing just how difficult that position is.

De Cocq explains that many ridden horses experience back pain that is hard to treat.

She wondered whether riders modify their technique to reduce the load exerted on their horses’ backs.

Analysing the movements of riders on trotting horses, de Cocq discovered that the rising trot significantly reduced the load exerted on horses’ backs.

She also built a computational simulation of a horse and rider that could help riders discover better ways of riding.

Placement of markers on rider and horse. Rider: chin, cervical vertebra 7 (C7), thoracic vertebra 12 (T12), shoulder, elbow, wrist, hip, knee, ankle and toe. Horse: the spinous processes of the 6th thoracic (T6) and the 1st lumbar (L1) vertebrae, dorsal side hind hoofs.

Placement of markers on rider and horse. Rider: chin, cervical vertebra 7 (C7), thoracic vertebra 12 (T12), shoulder, elbow, wrist, hip, knee, ankle and toe. Horse: the spinous processes of the 6th thoracic (T6) and the 1st lumbar (L1) vertebrae, dorsal side hind hooves.

De Coq also found in her research that jockeys were able to ride fast because their centre of mass barely moved at all.

Her findings have been published in The Journal of Experimental Biology.

De Cocq, from Wageningen University in the Netherlands, explains riders have a choice of two techniques when perched on a trotting horse: the easier rising trot – when the rider bobs up and down, standing in the stirrups when off the saddle – and the more technically challenging sitting trot, where the rider remains firmly seated.

As the rising trot was thought to reduce the load exerted on a trotting horse’s back, de Cocq travelled to Hilary Clayton’s laboratory at Michigan State University in the United States to use Clayton’s state-of-the-art three-dimensional motion capture equipment to test the theory.

By filming experienced dressage riders as they trotted using both techniques, and analysing the motion of each horse and rider, de Cocq could see that the centre of mass of riders using the rising trot moved much less during the standing phase than the centre of mass of sitting trot riders, reducing the force exerted on the horse’s back and lessening the chance of injury.

While de Cocq was analysing the data, she came across a paper in the journal, Science (Pfau et al., Science, 325, 289) that explained how the technique used by modern jockeys – where they stand in their stirrups – had significantly improved times in horse racing.

She noticed that the posture of jockeys was similar to the standing phase of the rising trot.

She wondered whether she could build a mathematical model of a horse and rider that would simulate the movement of a rider’s centre of mass and identify factors that could reduce the force exerted by the rider on a horse’s back.

Teaming with Mees Muller and Johan van Leeuwen, de Cocq built three increasingly sophisticated models, representing the horse and rider as systems of springs, dampers and point masses.
trot-stock
Then, by varying the stiffness of the spring representing the rider in the simplest model, de Cocq successfully reproduced the motion of the rider’s centre of mass during the sitting trot and when using the jockey’s standing posture.

Then, when she repeated the calculations using the second model where she added a damper and brief free-fall to the first model, the motion of the centre of mass of the sitting trot rider and the jockey was even more life-like.

But neither model reproduced the motion of a rider’s centre of mass during rising trot until de Cocq and van Leeuwen added a second spring – mimicking the rider’s leg during the standing portion of the stride – to the simulated rider spring.

By alternating between the two springs – activating the leg spring during the standing portion of the stride and the rider spring during the seated portion – de Cocq successfully simulated the rising trot.

Her calculations also showed how difficult the jockey’s technique is. She could only simulate the relatively smooth motion of the jockey’s centre of mass using a narrow range of spring stiffnesses and damping; and only one combination of spring stiffness and damping produced the optimal situation where the jockey’s centre of mass followed an almost flat line.

De Cocq points out that the current technique used by jockeys allows horses to gallop faster than other techniques.

However, it requires a huge amount of strength and training and she says, “If jockeys want to improve even more, they would need to go in a straight line, not move up and down, and that would be a challenge.”

 

de Cocq, P., Muller, M., Clayton, H. M. and van Leeuwen, J. L. (2013). Modelling biomechanical requirements of a rider for different horse-riding techniques at trot. J. Exp. Biol. 216, 1850-1861.

Reporting: Kathryn Knight
Report at journal website

 

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