A mood-conscious interaction device detects at least one physiological data of a user, and turns on a light with a color which corresponds to the physiological data. Thus, other users can know a mood or emotion of the user according to the color of the light, and the moods or emotion of the other users can be made known to the user during communications.

Aspects of the present disclosure are directed toward a medical device having a a core assembly. The core assembly includes a core circuit assembly and a core assembly housing configured to enclose the core circuit assembly. The core assembly housing includes a first portion, and a second portion configured to be coupled to the first portion along a weld seam. The second portion includes at least one weld joint feature, which includes a thinned section of the second portion.

The technology described herein is generally directed towards collecting digital twin datasets from individual users to represent their individual physical, emotional, chemical and/or environmental conditions. A user's digital twin is matched to one or more other digital twins with similar physical, emotional, chemical, and/or environmental conditions. The matched digital twins can share data and learnings via a virtual anonymous relationship. Multiple digital twins that represent users with similar conditions may be found and treated collectively as a group; a user via his or her digital twin can poll the group to receive and process responses from each respondent. A digital twin can be a therapist or a researcher who emulates a patient and uses the emulated digital twin as a proxy to monitor and process the results of other digital twins.

The invention concerns a measurement device to capture at least one vital parameter of a person in a motor vehicle with a steering wheel. The measurement device includes a finger sensor device with an optical sensor device, where the finger sensor device is attached to the steering wheel in the transition zone between a steering wheel spoke and the hub of the steering wheel.

A system for monitoring the respiratory activity of a subject, which comprises one or more signal generating elements being kinematic or light emitting elements, applied to the thorax of a subject, for generating signals that are indicative of movement of the thorax of the subject; a receiver for receiving the generated signals during breathing motion of the subject; and one or more computing devices in data communication with the receiver, for analyzing the breathing motion. The more computing device is operable to calculate, in response to the received generated signals, the magnitude of a maximum displacement in 3D space of the one or more signal generating elements during a cycle of the breathing motion; and to calculate the magnitude of a current displacement in 3D space of the one or more signal generating elements during the breathing motion with respect to a reference tidal volume associated with the maximum displacement in 3D space.

A biological information detecting apparatus includes: an LC resonant pressure sensor including a resonant circuit including a capacitor and an inductor, and having a resonant frequency that changes depending on a change in external pressure applied to the capacitor; and an integrated circuit (IC) chip package including a coil type antenna radiating a radio frequency (RF) signal within a preset frequency band, wherein a change in the resonant frequency results in a change in a power transmission rate depending on a inductive coupling between the resonant frequency and a frequency of the RF signal. The IC chip package includes the coil type antenna disposed in a region overlapping the LC resonant pressure sensor in a plan view of the IC chip package.

A removable smartphone case is disclosed. The removable smartphone case includes a case body configured to receive a smartphone, a radio frequency (RF) front-end connected to the case body and including a semiconductor substrate and an antenna array including at least one transmit antenna configured to transmit radio waves below the skin surface of a person and a two-dimensional array of receive antennas configured to receive radio waves, the received radio waves including a reflected portion of the transmitted radio waves, wherein the semiconductor substrate includes circuits configured to generate signals in response to the received radio waves, a communications interface connected to the case body and configured to transmit digital data that corresponds to the signals generated by the semiconductor substrate from the removable smartphone case, and an alignment feature integrated into the case body and configured to align the antenna array with an object.

This disclosure relates to selection of optimum channel in twin radars for efficient detection of cardiopulmonary signal rates. State-of-the-art solutions involve use of IQ (In-phase and Quadrature) channel radar which need continuous calibration. Distance of the radar from a subject being monitored affects performance. The present disclosure enables enhanced cardiopulmonary signal rate monitoring using a time domain approach, wherein only the data from signal reflected off the radar is considered. The solution is also time window adaptive. Signal property and radar physics-based methods have been implemented for selecting an optimum channel in twin radars thereby enhancing detection of respiration rate and breath rate.

A computer-implemented method of heart rate estimation includes receiving heart beat data, detecting sequential beats within the heart beat data, identifying a beat interval of each sequential beat, and generating a beat array containing the beat intervals of sequential beats within an array window. The beat array is then sorted based on the beat intervals of the sequential beats so as to generate a sorted beat array. A weight array is calculated by applying a weight control parameter to each beat interval in the sorted beat array, wherein the weight array includes a weight value for each beat interval that is proportional to a corresponding beat interval value in the sorted beat array. A weighted median is calculated based on the weight array, and a heart rate estimation for the array window is determined based on the weighted median of the weight array and the sorted beat array.

A user interface component and system for physiological parameters telemetry is provided. A user interface component may be reversibly or irreversibly attached to a garment that allows connection to a user's skin, such as via one or more holes in the garment. Signals transmitted through a conductive transfer layer in the user interface component are provided to a signal receiving unit which can collect and transmit physiological data.