Systems and methods for determining a level of collaboration between a user and an exoskeleton boot are provided. A device, using an exoskeleton boot, can provide a level of force to a limb of a user to aide movement of the limb. The device can measure one or more parameters of the exoskeleton boot during the movement of the limb using the exoskeleton boot. The device can determine one or more biometrics of the user during the movement of the limb using the exoskeleton boot. The device can determine, based on the one or more biometrics and the one or more parameters of the device, a metric indicative of a collaboration between the user and the exoskeleton boot during the movement.

A system may include one or more image sensors, an ear worn device, and a controller. The one or more image sensors may be configured to sense optical information of an environment and produce image data indicative of the sensed optical information. The ear-worn device may include a housing wearable by a user, an acoustic transducer including at least one driver to generate sound, and a controller comprising one or more processors. The controller may be operatively coupled to the image sensor and the ear-worn device. The controller may be configured to receive the image data, determine a field of attention of the user using the image data, detect an object outside of the field of attention using the image data, determine whether to alert the user of the detected object, and provide an alert indicative of the detected object, if it is determined to alert the user.

The present invention concerns a device for controlling a robotic system for assisting the mobility of a user, said robotic system comprising at least one active mobility assistance element capable of assisting a given mobility action of the user, characterized in that the device comprises a detection system capable of detecting a compensatory movement of the user associated with the mobility action, said compensatory movement being a movement made by a user who is disabled, or able-bodied but locally and/or temporarily constrained, in order to perform at least part of the mobility action, and which at least partially substitutes the normal movement an unconstrained, able-bodied user would make in order to perform this mobility action, and a control system capable of controlling the at least one active element when the compensatory movement is detected.

A handheld system of automatic acupoint stimulation has a case, a camera unit, a storage unit, a human-machine-interface (HMI) unit, a processing unit, an acupoint recognizing unit, and an acupoint stimulating unit. The case has an accommodating space and a handle portion. The camera unit is to capture an image from a body part of a user. The storage unit is to store multiple predetermined acupoint data. The HMI unit is to receive an input signal. The processing unit searches for at least one predetermined acupoint datum that is corresponding to the input signal. The acupoint recognizing unit is to receive the at least one predetermined acupoint datum and obtain a reference length and a beginning basis to locate the acupoint. The acupoint stimulating unit is to stimulate the acupoint of the user located by the acupoint recognizing unit.

Disclosed is a rehabilitation robot training system for monitoring and suppressing the compensatory movement of a hemiplegic upper limb. The system includes an upper computer control center, an interaction display screen, a force feedback glove, a position tracker, upper limb rehabilitation robot tail end connectors, an upper limb rehabilitation robot, a base and a pressure cushion. One upper limb rehabilitation robot tail end connector is mounted on a tail end of each of two robotic arms of the upper limb rehabilitation robot, and the upper limb rehabilitation robot tail end connectors are respectively worn on an upper arm and a forearm of a patient to drive an arm to move; the upper computer control center stores and processes data, collected by the position tracker, the force feedback glove and the pressure cushion in real time, of the patient, and monitors and analyses whether the patient does a compensatory gesture.

The present invention provides an upper limb function assessment device and the use method thereof and an upper limb rehabilitation training system and the use method thereof, wherein the upper limb function assessment device includes a display, a depth camera and a central processor, the depth camera is used to capture a user's motion, the display is used to display motion demonstration and the user's motion, and the central processor is connected to the display and the depth camera, respectively. The present invention captures the user's motion precisely with the depth camera, which makes the obtained data more accurate and objective, and also facilitates recording and storage of the obtained data. The central processor determines whether the completion of the motion meets the requirements in assessment scales, allowing the user to come up with an assessment report on his own without requiring a lot of assistance from a physician.

A gait motion assisting apparatus is provided, in which a thigh phase angle calculating unit has a latest data transmission process to transmit a thigh phase angle φ(k) at sampling timing S(k) (k is an integer of 1 or more) to a gait motion timing calculating unit and store the same as a reference thigh phase angle φc. Also, a stored data transmission process transmits, instead of the thigh phase angle φ(k), a currently stored reference thigh phase angle φc to the gait motion timing calculating unit and performs the stored data transmission process only when conditions are satisfied such that a thigh phase angle at one sampling timing is smaller than the currently stored reference thigh phase angle and an absolute value of a deviation therebetween is equal to or less than a predetermined threshold, and performs the latest data transmission process in other cases.

In a state where a drive unit is located on a lateral side of a joint(s) of a wearer wearing clothes and a communication unit and a frame unit are fixed and retained corresponding to the wearer's first and second body sites, respectively, a driving torque of an actuator according to movements of the wearer's joint is transmitted as an assist force to the first and second body sites without giving any physical burdens or hindrances in daily life to the wearer.

A system is provided for supporting an arm of a user that includes a harness configured to be worn by the user, and an arm support coupled to the harness and including an arm rest to support an arm of the user. The arm support is configured to accommodate and follow movement of the arm without substantially interfering in such movement. The arm support may at least partially offset a gravitational force acting on the arm as the user moves and the arm support follows the movement of the user's arm. For example, the arm support may transfer at least a portion of the weight of the user's arm to the torso or other region of the user's body and/or may apply an opposing force to at least partially offset the gravitational force acting on the arm.

A wearable device capable of outputting a torque on a user is provided. The wearable device includes a motor, a motor driver circuit, a communication circuit for receiving movement information about a first user from a server or an electronic device, a frame connected to the motor, and worn on a body part of a second user so as to support the lower body, a sensor, and a processor for controlling the motor driver circuit so that motion information about the second user is obtained using the sensor, the difference between the obtained motion information and the received motion information is calculated, torque strength is determined based on the calculated difference, and a torque of a determined torque strength is output by the motor.