An electronic device according to one aspect may include a main body, a sensor part disposed on one surface of the main body and configured to detect a light signal of an object, a first output interface comprising a light emitter disposed on one surface of the main body and configured to guide a user through a measurement operation by controlling a light-emitting mode of the light emitter, and a processor configured to control the first output interface according to the measurement operation and estimate the user's bioinformation based on a result of detecting the light signal by the sensor part.

The present disclosure provides apparatuses and computer readable media for measuring sub-epidermal moisture in patients to determine damaged tissue for clinical intervention. The present disclosure also provides methods for determining damaged tissue.

The present disclosure provides apparatuses and computer readable media for measuring sub-epidermal moisture in patients to determine damaged tissue for clinical intervention. The present disclosure also provides methods for determining damaged tissue.

Disclosed herein is an interaction monitoring system, comprising an environment collection module, interaction monitoring module, interaction segmentation module, and display module. The environment collection module detects surrounding environment and generates a data stream. The interaction monitoring module generates a feature data stream by extracting feature value of the data stream. The interaction segmentation module determines a target situation, which indicates a user's state or condition, from the feature data stream and generates a target image or video stream, which indicates the target situation. The display module displays the target image. Other embodiments are described and shown.

Disclosed herein is an interaction monitoring system, comprising an environment collection module, interaction monitoring module, interaction segmentation module, and display module. The environment collection module detects surrounding environment and generates a data stream. The interaction monitoring module generates a feature data stream by extracting feature value of the data stream. The interaction segmentation module determines a target situation, which indicates a user's state or condition, from the feature data stream and generates a target image or video stream, which indicates the target situation. The display module displays the target image. Other embodiments are described and shown.

According to one embodiment, a proficiency determination apparatus includes a processing circuit. The processing circuit acquires first time-series data about biological information of a worker in a predetermined period. The processing circuit calculates second time-series data about a physiological index indicating a mental stress on the worker by analyzing the first time-series data. The processing circuit calculates an appearance condition of the physiological index by analyzing the second time-series data. The processing circuit determines a proficiency of the worker based on the appearance condition of the physiological index.

A pressure compensating non-invasive blood-component measuring device has electrically insulated parallel electrodes mounted on a dielectric membrane (106). A main circuit board (201) provides electrical connections to the electrodes and has an orifice (402) to allow flexing. A housing supports the main circuit board, with a second orifice to facilitate the application of a finger onto the insulated electrodes. A bottom circuit board (401) supports a force sensor (408) and fixing elements (313, 314) secure the bottom circuit board to the top circuit board, such that the bottom circuit board does not contact the housing directly. An intermediate board (316) is guided but not restrained by the fixing elements, and is arranged to apply force onto said force sensor.

A pressure compensating non-invasive blood-component measuring device has electrically insulated parallel electrodes mounted on a dielectric membrane (106). A main circuit board (201) provides electrical connections to the electrodes and has an orifice (402) to allow flexing. A housing supports the main circuit board, with a second orifice to facilitate the application of a finger onto the insulated electrodes. A bottom circuit board (401) supports a force sensor (408) and fixing elements (313, 314) secure the bottom circuit board to the top circuit board, such that the bottom circuit board does not contact the housing directly. An intermediate board (316) is guided but not restrained by the fixing elements, and is arranged to apply force onto said force sensor.

An earpiece having light sources and optical sensors arranged to obtain physiological data from the tragus of an ear. At least one extra light source or optical sensor is provided such that there is redundancy. The redundancy allows for misalignment of the earpiece while still having sufficient number of light sources and optical sensors to continuously obtaining physiological data.

An earpiece having light sources and optical sensors arranged to obtain physiological data from the tragus of an ear. At least one extra light source or optical sensor is provided such that there is redundancy. The redundancy allows for misalignment of the earpiece while still having sufficient number of light sources and optical sensors to continuously obtaining physiological data.