The present invention is directed to systems and methods for monitoring characteristics of a subject. A system according to an exemplary embodiment of the invention includes a sensor subsystem including at least one respiratory sensor disposed proximate to the subject and configured to detect a respiratory characteristic of the subject, wherein the sensor subsystem is configured to generate and transmit at least one respiratory signal representing the respiratory characteristic, and at least one physiological sensor disposed proximate to the subject and configured to detect a physiological characteristic of the subject, wherein the sensor subsystem is configured to generate and transmit at least one physiological signal representing the physiological characteristic, and a processor subsystem in communication with the sensor subsystem, the processor subsystem being configured to receive at least one of the at least one respiratory signal and the at least one physiological signal.

A heart monitoring system for a person includes one or more wireless nodes; and wearable appliance in communication with the one or more wireless nodes, the appliance monitoring vital signs.

A system for distinguishing an individual having an abnormal body temperature includes an interface module receiving a visible light image and a thermal image, a determining module executing an image analysis process on the visible light image to recognize an individual in the visible light image and to determine position data of the individual, and a processing module obtaining a temperature value corresponding to the individual from the thermal image according to the position data. The processing module further determines whether the temperature value falls within a predetermined range of abnormal body temperature, and outputs a warning signal when it is determined that the temperature value falls within the predetermined range of abnormal body temperature.

The present invention makes it possible to, even when a stainless steel is adopted in a diaphragm: prevent the diaphragm and a strain sensor from exfoliating from each other; be hardly susceptible to the influence of temperature in an operating environment; not allow the sensitivity of a pressure sensor to be dominated only by the mechanical characteristic of a material constituting the diaphragm; and increase the degree of freedom in design of members constituting the pressure sensor. A pressure sensor according to the present invention is, in order to solve the above problems, characterized in that: the pressure sensor has a diaphragm deforming by the pressure of a fluid, an elastic body covering the whole surface of the diaphragm and joining to the diaphragm on one side, and a strain sensor being arranged by joining on the other side of the elastic body and on an end side apart from a position corresponding to the center of the diaphragm and detecting the deformation of the elastic body working together with the deformation of the diaphragm as a strain; and the elastic body is formed of a material having a linear expansion coefficient close to the linear expansion coefficient of a material constituting the strain sensor.

A method includes: obtaining temperature-related information which is related to temperatures at portions of a cooking container, using a processor; recognizing an edge of the cooking container disposed in a cooking device that cooks by heating, and identifying an overheated portion in the edge where a temperature exceeds a threshold value, based on the temperature-related information using the processor; and transmitting emission instruction information to a light emitter, and causing the light emitter to emit light to the identified overheated portion.

A medical device includes a temperature sensor configured to deliver a temperature signal and an optical sensor configured to deliver an optical signal. The medical device also includes a microcontroller configured to receive the temperature signal and the optical signal. The microcontroller is configured to calculate, in real-time, a body temperature, a pulse rate, a respiratory rate, and a blood oxygen concentration based on the received temperature signal and the received optical signal. The medical device also includes a display configured to display the body temperature, the pulse rate, the respiratory rate, and the blood oxygen concentration of a patient.

The present disclosure relates to a monitor and monitoring system suitable for attachment to the skin of a mammal, including a human. The monitor and monitoring system are designed for continuous wireless real-time measurement of physiological signals and transmission of the measurements through the cloud to a remote computer or mobile device.

A vascular thermography system includes a portable electronic device and a thermal image analyzer in communications therewith. The portable electronic device includes a thermal imager to generate a thermal image of an anatomical area of a patient, a display, a processor configured to display the thermal image on the display, and a transceiver coupled to the processor to transmit the thermal image. The thermal image analyzer receives the thermal image from the portable electronic device, determines an assessment on vascular health of the patient based on comparing the thermal image to a database of thermal images, and transmits the assessment to the portable electronic device.

Embodiments of a vaginal temperature sensing apparatus, a visually sense-able battery power-on indicator (16), manufacturing with cure temperatures that protect a battery, substantially error-free, user-initiated device activation componentry (30) to start battery power, and a timer to automatically terminate flow of battery power. Data can, by an automatic data transform recalculator (138) with body temperature dips in transformed and recalculated diurnal high body temperatures, predict an ovulation event and provide an indication through a zenith based ovulation indicator (106). Systems can include neural network based artificial intelligence to automatically self-improve by using historical or even other, multi user data and user input and improve its indication result.

An actively-powered temperature data logger patch with wireless data communication includes a sealed, flexible battery comprising a printed electrochemical cell with an anode and a cathode, and a flexible circuit including a microprocessor, a temperature sensor configured to sense a temperature of a target subject, a wireless communication transceiver and an antenna. In one example, the flexible battery and flexible circuit are arranged in a covering, stacked arrangement between first and second substrate layers, and the patch configured to conform to a curved surface of the target subject. In another example, the patch is used in an actively-powered medical system for monitoring a body temperature of a patient, and includes an adhesive configured to be removably applied to skin of the patient. An external computing device is capable of two way communication with the wireless communication transceiver of the patch via an electromagnetic field.