A vital-signs monitor patch containing at least two electrodes, a circuit assembly, and a patch body having a chamber in which the circuit assembly is housed. The patch body also contains at least one flexible portion adjacent to the circuit assembly chamber, with at least one electrode attached to the flexible portion. The electrodes are configured for attaching the patch to the skin of a patient.

A wearable device supports continuous wearability and operation with a supplemental set of removable and replaceable batteries that recharge a first set of batteries powering the device. In an aspect, the wearable system includes a head portion coupled to an appendage of a user, where the head portion includes an electronic system powered by a first set of batteries, and a modular housing releasably engageable to the head portion that includes a second set of batteries. In this manner, the modular housing can be removed and recharged independent from the head portion, and then recoupled to the head portion to recharge the first set of batteries. Thus, in an aspect, the first set of batteries can continuously power the electronic system without a need for removal of the head portion. Such a system can be particularly advantageous for continuous, uninterrupted health and fitness monitoring.

A device and method for increasing a patient's compliance with a therapy relating to an upper airway disorder includes a receiving unit, a processing unit, and a display unit. The receiving unit is configured to receive vital sign data including glucose level data of the patient, and therapy data including information regarding the therapy of the patient. The processing unit is configured to process the therapy data and the vital sign data in order to determine feedback information based on the therapy data and the vital sign data. Lastly, the display unit is configured to display the feedback information based on the therapy data and the vital sign data.

A method is provided. The method includes identifying whether an amount of change in the pressure detected through an atmospheric pressure sensor is greater than or equal to a specified first threshold, in response to the amount of change in the pressure being greater than or equal to the first threshold, waking up a biometric sensor module including a plurality of electrodes in which some of the plurality of electrodes are disposed to come into contact with a body part of a user when the electronic device is worn, and others thereof are disposed to not come into contact with a body part of the user when the electronic device is worn, and identifying whether an interrupt signal, indicating that a state in which the plurality of electrodes are electrically connected is maintained for a specified first time or more, is received from the biometric sensor module.

The present invention relates to a wearable device for acquiring physiological information of a subject. To combine the advantages of a contact sensor and a contactless sensor, the wearable device comprises an optical emitter (10) for emitting light into the subject's skin, an optical sensor (20) for receiving light scattered back from the subject's skin in response to the emission of light into the subject's skin, the received light representing or allowing the derivation of physiological information of the subject, and a carrier (30) for being held at the subject's skin and for carrying said emitter (10) and said sensor (20) such that a light receiving area (12), at which the emitted light enters the subject's skin, substantially corresponds to a light reflecting area (22), at which at least part of the scattered light leaves the subject's skin and is received by said optical sensor, the optical sensor (20) is arranged between the optical emitter (10) and the light receiving area (12) and is at least partially transparent for the light emitted by the optical emitter or the optical emitter (10) is arranged between the optical sensor (20) and the light reflecting area (22) and is at least partially transparent for the light reflected from the light reflecting area.

A cardiac physiological parameter measuring method, a device, a terminal and a computer storage medium, comprising: by means of one or more vibration sensors, acquiring vibration information of a subject to be tested that is in a supine state, the vibration sensors being configured to be disposed below the left shoulder of the subject to be tested; generating hemodynamic related information on the basis of the vibration information determining an MC feature point of an MC event on the basis the hemodynamic related information.

A device for measuring penile erectile function and an erectile function test system are provided. The device for measuring penile erectile function may include a body unit having a mesh structure formed of stretchable material and configured to surround at least a portion of a penis, a sensor unit arranged on the mesh structure of the body unit and configured to measure first data representing position information on penis, a storage unit configured to store the first data, and a communication unit configured to communicate the first data with a computing device.

Disclosed embodiments describe techniques for body part biomarker and consistency pattern generation using motion analysis. Sensors are attached to a body part of an individual, where the sensors enable collection of motion data of the body part, and where the sensors include at least one inertial measurement unit (IMU) and at least one sensor determining muscle activation. Data is collected from the sensors, where the sensors provide electrical information based on a microexpression of movement of the body part during a movement performance protocol. Processors are used to analyze the electrical information from the sensors. Biomarker information for the individual is generated using the analyzing of the electrical information from the movement performance protocol. Additional data is collected from a subsequent attaching of sensors to the body part of the individual and the additional data is analyzed. Consistency pattern information is generated from the biomarkers.

A super modular monitoring system is disclosed. The system may include a lattice having a plurality of intersections, and which may be formed of a flexible conductive material having a shape comprising repeating geometric patterns. The lattice of the system may serve as the primary sensor of the super modular monitoring system. The system may also include any number of secondary sensors with each being disposed at an intersection of the plurality of intersections of the lattice. The secondary sensors may be in electrical communication with the primary sensor, which may include transmission of both power and data. The system may further include a monitoring system in electrical communication with the lattice. One or more lattices of the system may be coupled together to form a super lattice. The primary and secondary sensors may transmit data simultaneously to the monitoring system for further analysis.

A system for providing pilot or controller support in a reduced crew transport environment may include a set of sensors configured to collect a set of measurements of a set of physiological signals of a user. The system may further include an emotional analyzer model usable to generate at least one emotional parameter value corresponding to the set of measurements. The system may also include a natural language processing model usable to generate a natural language statement corresponding to the at least one emotional parameter value for output to the pilot.