The invention relates to a measuring arrangement (1) for testing skis and snowboards (2) or sports equipment with a planar contact surface, the arrangement comprising a sensor device, onto which at least one ski or snowboard (2) or piece of sports equipment can be laid. The sensor device has a sensor surface (3) which is predominantly sub-divided in a longitudinal and transverse direction into a plurality of sensor-surface sections (4), each of said sensor-surface sections (4) having at least one force sensor which outputs the force acting on the sensor-surface section (4) as an electrical signal that is evaluated by a computer unit (5).

The invention relates to a measuring arrangement (1) for testing skis and snowboards (2) or sports equipment with a planar contact surface, the arrangement comprising a sensor device, onto which at least one ski or snowboard (2) or piece of sports equipment can be laid. The sensor device has a sensor surface (3) which is predominantly sub-divided in a longitudinal and transverse direction into a plurality of sensor-surface sections (4), each of said sensor-surface sections (4) having at least one force sensor which outputs the force acting on the sensor-surface section (4) as an electrical signal that is evaluated by a computer unit (5).

A multi-axial unidirectional power transmission system includes a transmission unit and a resistance unit. The transmission unit includes a first main shaft and a transmission wheel provided on the first main shaft. The resistance unit includes a second main shaft and a damping wheel mounted on the second main shaft. The two transmission wheels and the damping wheel can be placed flat on the body since they are mounted on different main shafts, thereby making the whole plane of the multi-axis unidirectional power transmission system consistent, thus achieving the effects of space saving, convenient storage and convenient transportation.

A multi-axial unidirectional power transmission system includes a transmission unit and a resistance unit. The transmission unit includes a first main shaft and a transmission wheel provided on the first main shaft. The resistance unit includes a second main shaft and a damping wheel mounted on the second main shaft. The two transmission wheels and the damping wheel can be placed flat on the body since they are mounted on different main shafts, thereby making the whole plane of the multi-axis unidirectional power transmission system consistent, thus achieving the effects of space saving, convenient storage and convenient transportation.

The invention relates to a sports boot for the pursuit of ski sport. The sports boot comprises a sensor arrangement (29) having several pressure-sensitive sensors (9a-d) in a distributed layout which are respectively connected or can be connected via cable connections (17a-d) to an electronic signal processing device. At least one first sensor (9a) is positioned in a forefoot portion (31) of the sole arrangement (30) of the sports boot and at least one second sensor (9b) is positioned in a heel portion (32) of the sole arrangement (30). A first cable connection (17a) between the at least one first sensor (9a) and the electronic signal processing device and a second cable connection (17b) between the at least one second sensor (9b) and the electronic signal processing device are respectively starting from the at least one first sensor (9a) and from the at least one second sensor (9b) and each run in the direction towards a sole center region (34) of the sole arrangement (30). The first and second cable connection (17a, 17b) then run out from the sole center region (34) via the heel portion (35) in the direction towards the upper boot portion (28) in which the signal processing device is positioned or can be positioned.

The invention relates to a sports boot for the pursuit of ski sport. The sports boot comprises a sensor arrangement (29) having several pressure-sensitive sensors (9a-d) in a distributed layout which are respectively connected or can be connected via cable connections (17a-d) to an electronic signal processing device. At least one first sensor (9a) is positioned in a forefoot portion (31) of the sole arrangement (30) of the sports boot and at least one second sensor (9b) is positioned in a heel portion (32) of the sole arrangement (30). A first cable connection (17a) between the at least one first sensor (9a) and the electronic signal processing device and a second cable connection (17b) between the at least one second sensor (9b) and the electronic signal processing device are respectively starting from the at least one first sensor (9a) and from the at least one second sensor (9b) and each run in the direction towards a sole center region (34) of the sole arrangement (30). The first and second cable connection (17a, 17b) then run out from the sole center region (34) via the heel portion (35) in the direction towards the upper boot portion (28) in which the signal processing device is positioned or can be positioned.

A multifunctional balance exercise machine comprises a balancing mechanism including loading board, spring, elastic column, and motion-tracking sensor; a first display unit and an electronic control device loaded with motion sensor game program arranged on the exercise equipment; whereby when the fitness user stands on the loading board, the user body weight and the stress applied by feet transmit to the elastic column and the spring via the loading board, cause the elastic column and the spring compressed or stretched, and force the loading board to oscillate, then achieve the effect of balance exercise; furthermore, the motion tracking sensor transmit signal of oscillation data to electronic control device, the processor unit operates the data, and present the image of the motion sensor game via the first display unit to achieve entertaining effect of virtual reality game.

An exercising device includes a base placed on a plane, a cover pivotally connected with the base, and an exercise apparatus mounted between the base and the cover. The cover has a side pivotally mounted on a side of the base. The cover is pivoted relative to the base to open or close a top face of the base. The exercise apparatus includes a leg working unit mounted on the base. Thus, the exercising device is stored easily and conveniently and is adapted to function as furniture. The exercising device also has a dustproof function.

A method of operating an exoskeleton system that includes obtaining a first set of sensor data from one or more sensors associated with one or more leg actuator units of an exoskeleton system during a user activity, the first set of sensor data indicating a first configuration state of the one or more actuator units; determining, based at least in part on the first set of obtained sensor data, to change configuration of the one or more leg actuator units to a second configuration state to support a user during the user activity; and introducing fluid to one or more fluidic actuators of the one or more leg actuator units to generate the second configuration state by causing the one or more fluidic actuators to apply force at the one or more actuator units.

A method of operating an exoskeleton system that includes obtaining a first set of sensor data from one or more sensors associated with one or more leg actuator units of an exoskeleton system during a user activity, the first set of sensor data indicating a first configuration state of the one or more actuator units; determining, based at least in part on the first set of obtained sensor data, to change configuration of the one or more leg actuator units to a second configuration state to support a user during the user activity; and introducing fluid to one or more fluidic actuators of the one or more leg actuator units to generate the second configuration state by causing the one or more fluidic actuators to apply force at the one or more actuator units.