The present invention provides a treadmill for allowing an exerciser to perform walking or running exercise on an endless belt. The treadmill is selected to be operated in a forward movement mode or in a reverse movement mode. In the reverse movement mode, a control unit of the treadmill controls a driving device to drive a top surface of the endless belt to slide forward for allowing the exerciser to simulate backward walking. When a detecting device detects that the exerciser enters a warning area in front of a normal range of movement, a reaction mechanism would be triggered to control the driving device to slow down or stop the endless belt. In the forward movement mode, the control unit controls the driving device to drive the top surface of the endless belt to slide backward and to disable the reaction mechanism.

A platform for enabling omnidirectional movement of an exercising machine is disclosed. The platform may comprise a hemispherical inner body comprising a hollow cavity. The hollow cavity may be used for accommodating an exercising machine into the hollow cavity. The exercising machine may be one of a treadmill, treadclimber, and bicycle. The platform may further comprise an outer body. The outer body may be rotatably engaged with the hemispherical inner body. The rotatable engagement may allow an omnidirectional movement of the hemispherical inner body in a horizontal plane and an inclination and declination of the exercising machine. The platform further comprises a communication unit. The communication unit may be connected with the hemispherical inner body for receiving user's inputs for movement. At least one of the hemispherical inner body and the exercising machine may move based on the user's inputs for movement. The platform may also find use in virtual shopping environments to help a user in buying products.

An omnidirectional treadmill apparatus. The omnidirectional treadmill apparatus includes: a plurality of segments which are continuously arranged along the direction of a first axis, each of which having a belt part; a first rotation unit for rotating the plurality of segments along the direction of the first axis; and a second rotation unit for rotating the belt part of each segment in the direction of a second axis which is perpendicular to the first axis, wherein the belt part has a toothed surface which is tooth-engaged with the second rotation unit.

Systems and methods are presented for performing exercises to strengthen, e.g., the transversus abdominis and related muscles. The systems and methods may involve one or more independent belts, allowing a full range of continuous motion. The systems and methods may further use a resistance-control mechanism that allows a user to adjust the force required to move the one or more belts, thereby controlling the rate of motion in the forward and/or backward directions. The systems and methods may further use a unidirectional resistance mechanism that allows the user to increase the resistance of the one or more belts in one direction, while allowing the one or more belts to move freely in the other direction.

A treadmill system includes a deck, an endless tread belt covering at least a portion of the deck, and a motion transducer positioned to detect movement of the tread belt. The treadmill system also includes a processor and memory where the memory includes instructions executable by the processor to receive an output of the motion transducer, determine an exercise type performed on the tread belt, and calculate an amount of work performed by a user on the tread belt based on the output of the motion transducer and the determined type of exercise.

A manual non-motorized exercise treadmill with the ability to provide adjustable resistance to perform strength training resistance movements and simulate the movements of an exercise drive sled in a stationary location is described. A treadmill deck of the treadmill is supported by friction-reduction rollers, a front treadmill roller and a rear treadmill roller. The treadmill is operated by the user pushing and/or pulling with the feet of the user via a belt or harness attached to adjustable stationary hand bars. Variable resistance allows for increased or decreased difficulty in achieving the exercise according to the preference and ability of the user. The resistance is configured to be applied to the rollers and/or belt, making it more difficult for the user to manually move the treadmill belt. The treadmill belt is configured to oscillate for both concentric and eccentric exercises not provided by conventional treadmills.

The present invention provides a running exercise equipment and a virtual reality interaction method thereof, in combination with virtual reality technology. The method includes: generating a virtual scene to the user based on the scene data; acquiring behavior data of a user when the user performs an action according to the virtual scene; generating scene update information based on the behavior data of the user, updating the scene data according to the scene update information; and controlling an action of the running exercise equipment according to the scene update information.

The present invention provides a running exercise equipment and a virtual reality interaction method thereof, in combination with virtual reality technology. The method includes: generating a virtual scene to the user based on the scene data; acquiring behavior data of a user when the user performs an action according to the virtual scene; generating scene update information based on the behavior data of the user, updating the scene data according to the scene update information; and controlling an action of the running exercise equipment according to the scene update information.

Systems and methods are presented for performing exercises to strengthen, e.g., the transversus abdominis and related muscles. The systems and methods may involve one or more independent belts, allowing a full range of continuous motion. The systems and methods may further use a resistance-control mechanism that allows a user to adjust the force required to move the one or more belts, thereby controlling the rate of motion in the forward and/or backward directions. The systems and methods may further use a unidirectional resistance mechanism that allows the user to increase the resistance of the one or more belts in one direction, while allowing the one or more belts to move freely in the other direction.

A treadmill for backward walking is disclosed. The treadmill may include a static frame and dynamic platform pivotally mounted to the static frame. A C-shaped support handle includes side portions that may be grasped or otherwise used by a user to stabilize their position, and a cross member against which the user may lean, e.g. with the user's hips or back. A user may press against a treadmill belt with the user's feet, against resistance from a brake, to move the treadmill belt away from the user's body.