A Smart Strap includes a flexible strap having a first plurality of vibration actuators, a second plurality of vibration actuators, and a motion sensor, with a processor having a processor power source connected to the motion sensor. An actuator power source is connected to the two pluralities of vibration actuators through a first switch and a second switch, respectively. The processor is configured to read acceleration of the motion sensor at a prescribed frequency, and turn on the first plurality of vibration actuators for a first prescribed treatment time when the acceleration exceeds a threshold acceleration value for a threshold time period. The processor is further configured to turn on the second plurality of vibration actuators when the acceleration remains above the threshold acceleration value after the first plurality of vibration actuators are turned on. The processor is configured to transmit an event record to a recording device.

The present invention provides, among other things, apparatus and methods of use for treating a subject in need of assistance with breathing. In some embodiments the subject suffers from airflow obstruction. In some embodiments, the subject suffers from chronic obstructive pulmonary disease.

Disclosed herein are an intelligent massage chair and a control method thereof. The intelligent chair includes a sensing unit mounted on the intelligent chair, and including at least one sensor, and a controller. The controller performs a control to determine a user's body condition based on the information about the user's body acquired through the sensing unit, and to determine an operation mode based on the determined user's body condition, and to add the information about the user's body, when it is determined that the determined operation mode is not an optimum operation mode for the user. One or more of an intelligent massage chair, an autonomous vehicle, a user terminal and a server of the present disclosure can be associated with artificial intelligence modules, drones (unmanned aerial vehicles (UAVs)), robots, augmented reality (AR) devices, virtual reality (VR) devices, devices related to 5G service, etc.

The walking training device includes: a robot leg attached to one leg of a trainee; a treadmill; a load distribution sensor that detects a distribution of a load received from a sole of the trainee; and a walking state distinguishing unit that determines whether the one leg is in a swinging leg state; a control unit that performs a predetermined bending-extending control for the swinging leg state of the one leg by the robot leg when the one leg is in the swinging leg state; a measuring unit that measures a clearance between the one leg in the swinging leg state and the treadmill. The control unit changes control content of the predetermined bending-extending control so that the one leg does not contact the belt of the treadmill during extending control of the one leg, when the clearance is less than a specified value.

The present disclosure provides a finger joint rehabilitation training device, which includes a control member, a data acquisition member, a gas circuit system, and a wearable training member. The wearable training member is provided with a pneumatic component that can expand and contract. The data acquisition member is configured for acquiring hand motion information of a first hand and transmitting the hand motion information to the control member. The hand motion information includes hand pressing information. The control member controls the gas circuit system to inflate the pneumatic component or to draw air from the pneumatic component according to the hand motion information, to make the wearable training member change between a flexion condition and a stretching condition, so as to realize a hand mirror training of a second hand. The hand pressing information is simple and convenient to acquire, which is convenient for the first hand to realize the flexion condition and the stretching condition, and the condition of the second hand is adjusted through the condition of the first hand, so that the wearable training member can be better adjusted, different hand training intensity requirements are met, and a better training effect is achieved.

There is provided a dynamic and proactive system for supporting sitting while detecting and changing sitting postures of a user and method of operation thereof. The system including a frame, a plurality of supports, each configured to support a different body part, and a plurality of joints each configured to move independently of or together with any other of the joints, each of the supports is connected to the frame via a corresponding joint, at least one of the joints is a two dimensional joint which enables a change in angle between the frame and a corresponding support. Each one of the plurality of supports is configured to move with respect to the frame or to another support, thereby enabling any changes in sitting postures of the user. The system comprises sensors, which based on their readings, the system detects user postures and suggests or creates posture changes.

A method for providing vestibular stimulation includes: providing an infant in a vestibular stimulation device; associating sensors to the infant; moving the vestibular stimulation device to provide vestibular stimulation treatment; and obtaining sensor data during the treatment. The vestibular stimulation device includes a holder member; a platform; a mechanical system coupling the holder member to the platform; sensors configured to detect one or more parameters of the infant; and a computing system having a user input and/or output interface operably coupled to the mechanical system and the sensors to provide mechanical data to the mechanical system in order to control movement of the holder member relative to the platform and to collect the one or more parameters of the living subject from the sensors.

A robot includes: a communicator; a driver configured to drive the robot; at least one memory configured to store at least one instruction; and at least one processor configured to execute the at least one instruction to: receive first driving data from an external device in communication with the robot through the communicator and store the first driving data in the memory, control the driver to perform an operation based on the first driving data, identify, based on an error in communication connection between the robot and the external device occurring, second driving data received by the robot from the external device within a threshold period based on a point in time at which the error in communication connection occurs, wherein the second driving data matches with at least a portion of the first driving data, identify third driving data that is at least a portion of the first driving data and is consecutive to the portion of the first driving data that matches with the second driving data, and control the driver to perform an operation after the point in time at which the error in communication connection between the robot and the external device occurs based on the third driving data.

An automated orthotic device with a treatment regimen and a method for using an automated orthotic device with a treatment regimen to provide a plurality of prescribed tension settings. The orthotic device may comprise a body brace, a controller, a data storage means, and a communication means to address the problem of patients being required to visit the physician's office every time an adjustment must be made in the prescribed tension setting in their automated orthotic device. In one embodiment, a plurality of prescribed tension settings in the automated orthotic device are sorted so that as the patient's condition improves, the next prescribed tension setting in the treatment regimen may be applied. In another embodiment, the physician is allowed to edit or supplement a patient's treatment regimen remotely by connecting to the automated orthotic device over a network.

Patient therapy and patient condition sensing devices and methods can be operated as a function of estimated internal hydrostatic pressure of a body part, for example at a position where a pressure or compression therapy is applied. Information relating to a patient's position, posture, ambulation and/or a physiological condition such as blood pressure can be used to control pressure or compression therapy.