Abstract
Robotic horseback-riding simulators have been successfully used as a substitute for real horses in areas of therapy, riding lessons, fitness, and entertainment, and several have been developed. However, recent research has illuminated significant differences in motion, response, and feel between a real horse and a simulator, which may result in incorrect posture and muscle memory for the rider. In this study, we developed a hybrid kinematic structure horseback-riding simulator to provide more realistic motion than currently available ones. The basic system has 4 degrees of freedom and provides a base motion platform. An additional revolving system with 2 degrees of freedom is mounted on the base platform. Real horse motion data were captured, normalized, filtered, and fitted to provide the motion trajectory. Furthermore, active neck, saddle, and tail mechanisms were implemented to provide realistic simulation. For interactive horse riding, bridle and beat sensors were included to control the simulator motion and a large screen was installed for virtual reality effect. Expert tests were conducted to evaluate the developed horseback-riding system, the results of which indicated that the developed simulator was considered sufficient for riding lessons and therapeutic use.
Highlights
Horse riding is a sport with a long history and is known to be good for improving a rider’s flexibility and sense of balance
We developed a new robotic horsebackriding simulator based on a hybrid kinematic machine (HKM)[15] consisting of a position platform and a revolving module
We propose a new horseback-riding simulator based on the concept of an HKM
Summary
Horse riding is a sport with a long history and is known to be good for improving a rider’s flexibility and sense of balance. It has been favored for entertainment, fitness, and physical therapy. Despite the many advantages, real horse riding has lacked popularity, in highly populated urban areas, due to the cost, difficulty to learn, and injury risk. To address these problems, various robotic devices have been developed to simulate riding. Shinomiya et al developed a horseback-riding therapeutic device with a 6-degrees of freedom (DOF) parallel
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