A sensory-and-logic system includes a ring-shaped, electrically-conductive skin sensor sized and shaped to form an electrical connection with human skin, and an electrical component surrounded by the ring-shaped, electrically-conductive skin sensor.

Systems and methods for data compression which facilitate the diagnosis and treatment of neurodevelopmental and neurodegenerative disorders. The methods comprise performing the following operations by a computing device: generating Normalized Data (“ND”) from Original Data (“OD”) that defines a Normalized Waveform (“NW”) that is unitless and scaled from zero to one; processing ND to extract Micro-Movement Data (“MMD”) defining a Micro-Movement Waveform (“MMW”) comprising a plurality of MMD points; and generating compressed data comprising a stochastic signature of MMW. Each MMD point determined based on a value of a peak of NW and a value representing an average of all data point values between a first valley of NW immediately preceding the peak and a second valley of NW immediately following the peak. The stochastic signature is defined by empirically estimated values of at least one parameter representing a Probability Distribution Function (“PDF”) of a continuous family of PDFs.

A biological information measuring apparatus includes a sensor unit, a processing unit that detects biological information on the basis of sensor information received from the sensor unit, and a communication unit that transmits the biological information to a connection target device at a transmission speed corresponding to a scheduled transmission data amount of the biological information.

Systems and methods are provided for determining a pulse rate based on a photoplethysmographic measurement of blood in a portion of subsurface vasculature. A plurality of samples of the photoplethysmographic signal are obtained and a plurality of digital phase-locked loops are operated to generate respective oscillating signals based on the plurality of samples. Respective correlations between the plurality of samples and each of the generated oscillating signals are determined and used to select a subset of the plurality of phase-locked loops. The frequencies of the selected oscillating signals generated by the selected phase-locked loops are determined and used to determine a cardiovascular pulse rate. This method can be performed a plurality of times for a respective plurality of overlapping sets of the obtained plurality of samples to determine pulse rates over time.

A user terminal apparatus, a method for driving the user terminal apparatus, and a computer readable recording medium are provided. The user terminal apparatus includes a display configured to display a user model personalized to a user and to recommend a plurality of graphic images associated with a physical condition of a user through one zone of the displayed user model, Cand an information visualization processor configured to, in response to one image being selected from the plurality of recommended graphic images, control the display to apply the selected graphic image to the user model.

A device for measuring physical activity of a user during swimming is provided, which includes the following: a sensor unit adapted and dimensioned to be coupled with swimming goggles, wherein the sensor unit includes a motion circuitry configured to measure physical motion of the user; an optical cardiac activity circuitry configured to be placed at least partially against a body tissue of the user and to measure cardiac activity of the user; and a wireless communication circuitry configured to transfer data between the device and at least one external device, wherein the wireless communication circuitry is configured to transfer physical activity data of the user to the at least one external device, and the physical activity data includes at least one of motion data obtained using the motion circuitry, cardiac activity data obtained using the cardiac activity circuitry.

This disclosure is directed to medical systems and techniques for enhanced health monitoring using geofencing. In one example, a patient may operate a computing device that is programmed to determine that a current patient location corresponds to a designated area of a medical system in response to receiving, by an input device, input data comprising an indication of the current patient location; in response to the indication, generate output data comprising one or more datasets of patient data for a data submission to a health monitoring service, wherein the patient data is stored in memory for a patient having a medical device configured to generate at least a portion of the patient data; and by an output device, transmit, to the health monitoring service, the output data to complete the data submission.

An autonomous drug delivery system advantageously utilizes physiological monitor outputs so as to automatically give a bolus of a rescue drug or other necessary medication when certain criteria and confidence levels are met. An emergency button is provided to manually trigger administration of the rescue drug. The rescue drug may be an opioid antagonist in response to an analgesia overdose, a hypotensive drug to avert an excessive drop in blood pressure or an anti-arrhythmia drug to suppress abnormal heartbeats, to name a few.

In one embodiment of the present disclosure, an example system may receive a plurality of frames from at least one image sensor associated with a mobile device, at least one of the plurality of frames containing an image of a wound; display a real time video including at least a portion of the plurality of frames and a visual overlay indicating a desired position of the wound; detect, based on at least part of the plurality of frames, that the wound is in the desired position; display an indication to move the mobile device in a desired direction; receive motion data from at least one motion sensor associated with the mobile device; detect that the mobile device has moved in the desired direction; and display an additional indication on the mobile device.

Methods and apparatus, including computer program products, are provided for remote monitoring. In some example implementations, there is provided a method. The method may include receiving, at a remote monitor, a notification message representative of an event detected, by a server, from analyte sensor data obtained from a receiver monitoring an analyte state of a host; presenting, at the remote monitor, the notification message to activate the remote monitor, wherein the remote monitor is configured by the server to receive the notification message to augment the receiver monitoring of the analyte state of the host; accessing, by the remote monitor, the server, in response to the presenting of the notification message; and receiving, in response to the accessing, information including at least the analyte sensor data. Related systems, methods, and articles of manufacture are also disclosed.