A method for performing lower limb rehabilitation training comprises the steps of: (a) placing a training object's feet on a pedal in a limb rehabilitation training system, wherein the pedal comprises a pressure sensor and a location information sensor; (b) standing stably on the pedal to enable the pressure sensor on the pedal to record the body weight of the training object; and (c) sitting down on the saddle, thereby enabling: the pressure sensor on the pedal to monitor pressure variation between the training object and the pedal throughout the training of the training object, wherein the rehabilitation evaluating unit evaluates the physical status and rehabilitation status of the training object according to the physiological information and exercise information of the same collected by the sensing unit, and adjusts the exercise frequency and the exercise duration of the training object according to the physical status.

A rehabilitation training system for lower limb rehabilitation comprises a function module comprising: a sensing unit that collects body function data comprising pedal pressure, exercise duration, and exercise mileage; and a mechanical structure module comprising: a driving unit and a linkage unit arranged on a frame; a groove plate for supporting a cam roller, a pedal for supporting the weight of the training object and driving the lower limb of the training object to move; a link for transmitting kinetic energy to the pedal; a rocker for supporting the link; a connecting bulge driving a guide shaft to rotate; a linear bearing supporting the guide shaft and an axis pin for connecting the link and the slider.

A rollator for mobility assistance to a user is provided. The rollator includes a chassis foldable in a compacted configuration, wheels rotatably mounted to the chassis, wheel braking assemblies engageable with the wheels, and a pair of handgrips mountable to the chassis and operatively connected to the chassis. Both handgrips have to be configured in a handgrip displacement configuration to configure the wheel braking assemblies into a displacement configuration of the wheels and wherein both wheel braking assemblies are simultaneously in the displacement configuration. The rollator can include a seat assembly which can be configured in a raised configuration and a seated configuration. In the seated configuration, a pressure equal to or greater than a seat pressure threshold has to be applied on the seat for the wheel braking assemblies to be configured in the displacement configuration.

A smart medical rehabilitation device comprises a driving unit, a linkage unit, a sensing unit and a rehabilitation evaluating unit that are mounted on a frame, wherein the linkage unit comprises a link mechanism and a slide mechanism linked thereto so that the slide mechanism can be moved together with the link mechanism, wherein the slide mechanism is driven by the driving unit to slide along the groove plate, the link mechanism is linked to move with the slide mechanism thus the link mechanism moves to the corresponding position so that the slide mechanism can assist a training object in performing lower limb rehabilitation training, and the rehabilitation evaluating unit evaluates the physical status and rehabilitation status of the training object according to the physiological information and exercise information of the same collected by the sensing unit, and adjusts the exercise frequency and the exercise duration of the training object according to the physical status in real time.

A system includes a wheeled walker having a frame and a plurality of wheel assemblies coupled to the frame for supporting the frame above a walking surface, the frame and the plurality of wheel assemblies defining a volume above the walking surface occupied by at least a portion of a user's legs as the user walks on the walking surface using the wheeled walker, the wheeled walker further having a camera directed toward the volume. The system may include a non-transitory program storage medium storing instructions executable by a processor or programmable circuit to collect image data from the camera, evaluate the user's gait based on the image data, and output a result of the evaluation.

Provided are a mobility and a mobility system which enable a person who requires nursing care with a deteriorated bodily function or cognitive function to lead a life with greater independence. The drive and travel of the mobility by the travel drive unit are controlled by adjusting the current travel state of the mobility to an optimal travel state for ensuring safety while reflecting the user's intention based on the current operation instruction detected by the operation unit, the command signal generated by the voluntary control unit, the travel environment sensed by the environment sensing unit, and the respective types of environmental information acquired by the information acquisition unit.

A body physiotherapy machine contains a conductive sphere member and a body configured to output electric physiotherapy energy to the conductive sphere member. The conductive sphere member is held by a user to contact his/her discomfort or acupuncture points so as to comfort the user and to enhance metabolism by ways of the electric physiotherapy energy, thus maintaining health easily.

There is provided an apparatus comprising one or more resilient members for supporting a human or other animal, wherein the one or more resilient members each comprise one or more sensor elements that are attached to and run at least partially along the length of the respective resilient member, and each of the one or more sensor elements is configured to provide an electrical response proportional to the amount of movement of the respective resilient member.

A method and system for monitoring physiological information. The system comprises: sensors (230), wherein the sensors (230) comprise a motion sensor and a medical monitoring sensor, the motion sensor comprises a first type of sensor (1220) and a second type of sensor (1240), and the medical monitoring sensor is configured to acquire physiological information of a user; a motion assembly (920) executing a control parameter-based operation to move in the surroundings; a tripod head (930); and a processor (210) used to execute operations such as information receiving, map construction, route planning, and control parameter operation.

A notification device is provided that includes a sensor pad, and an electronics module generates one or more notifications in response to signals received from the sensor pad. In a first embodiment, the sensor pad includes a pressure sensor for sensing pressure applied by a patient and generating a pressure signal, and conductive tracings for sensing moisture due to incontinence and generating a moisture detection signal when moisture is detected. In another embodiment, an absorbent sensor pad includes a sensor pad for sensing moisture and includes an absorbent chuck having a moisture-impermeable sheet with an absorbent material on an upper surface thereof, wherein the moisture-impermeable sheet has an aperture for receiving the sensor pad. The absorbent sensor pad may be provided in the form of a diaper.