The technology provides an external device for estimating a core body temperature of a human subject. The wrist monitor device includes a casing sized and shaped to fit onto a wrist of a human subject. The casing has a first face and a second face. In addition there is a cavity in the casing that houses a heat trap. The heat trap has an opening oriented to receive incoming thermal energy from the skin and a shell of a thermal-insulation material that has an inner thermal energy-reflective surface. Detected temperature data is compiled in a database and used to estimate whether an identified individual has a core body temperature indicative of a fever.

A device for measuring temperature includes first and second temperature sensors enclosed in a first material having one or more material components, a contact surface for contacting a body whose temperature is to be measured, at least part of the contact surface being parallel to a lateral direction. The first and second temperature sensors are arranged at different depths from the contact surface and the net thermal conductivity across the device from the contact surface through the first and second temperature sensors is greater than the net lateral thermal conductivity of the device through the first and second temperature sensors.

A substrate layer structure (100) is adapted to carry electronic device, or components, or electro-mechanical, or electro-chemical sensors, or a combination thereof, and is adapted to be attached to a surface of a human or animal body or biological species. The surface of the flexible substrate layer structure is patterned with a pre-fixed geometry formed by one or more slits (101-701, 502-702). The geometry is selected such that a stretchability of the substrate layer structure becomes adapted to the geometry of the body surface under it.

Systems and methods for monitoring temperature using wireless, flexible thermal sensors are disclosed. A wireless, flexible thermal sensor mountable on a body may comprise a substrate, a power source, a thermal actuator configured to receive power from a power source and supply thermal energy to a portion of a skin surface of the body, a temperature sensor configured to detect a change in a temperature related to the thermal actuator, and a comparator configured to receive an electrical signal corresponding to the temperature of the temperature sensor, compare the received signal to a reference signal, and output a signal based on the comparison. The sensor may further comprise a power control element configured to receive a signal corresponding to the output signal of the comparator and alter the delivery of power to the thermal actuator based at least in part on the signal received from the comparator.

The technology provides an external device for estimating a core body temperature of a human subject. The wrist monitor device includes a casing sized and shaped to fit onto a wrist of a human subject. The casing has a first face and a second face. In addition there is a cavity in the casing that houses a heat trap. The heat trap has an opening oriented to receive incoming thermal energy from the skin and a shell of a thermal-insulation material that has an inner thermal energy-reflective surface. Detected temperature data is compiled in a database and used to estimate whether an identified individual has a core body temperature indicative of a fever.

A device for measuring temperature comprising: first and second temperature sensors enclosed in a first material having one or more material components; a contact surface for contacting a body whose temperature is to be measured, at least part of the contact surface being parallel to a lateral direction; wherein the first and second temperature sensors are arranged at different depths from the contact surface and the net thermal conductivity across the device from the contact surface through the first and second temperature sensors is greater than the net lateral thermal conductivity of the device through the first and second temperature sensors.

Systems and methods for non-invasive monitoring of vital signs of a subject use multiple coupling sensors and vital sign sensors in order to determine multiple vital sign states of the subject. The sensors may be carried by support structure such as a wrap, blanket, mattress, cradle, nest and similar structures. Signals generated by the coupling sensors reflect coupling strength and/or reliability between sensors and the patient. Coupling reliability indexes may be determined for each of the temperature sensors and displayed to a user. Positional information/mapping of temperature information can be derived from the coupling sensors, image sensors, and/or the variation of the temperature profile itself over time. The measurements may be used to construct a full-body profile of the subject and provide targeted control of devices that affect vital sign states, such as heating/cooling.

A core body temperature monitoring apparatus placed superdermally over a user's skin, including a first temperature sensor, a second temperature sensor, a thermal insulation layer positioned intermediate the first and second temperature sensor and a heater for heating the apparatus and a subdermal tissue region underlying the user's skin. The subdermal tissue region is configured with variable thermal tissue parameters. A controller includes a switch configured for alternating between a calibration mode, wherein the heater is activated for calculating an instantaneous thermal tissue parameter, and a measurement mode, wherein the heater is inactive and the core body temperature is determined, based on the calculated instantaneous thermal tissue parameter.

An electronic device for estimating human body microclimate temperature is provided. The electronic device may include: a main body; a first temperature sensor configured to measure a first temperature and a second temperature sensor configured to measure a second temperature, the first and second temperature sensors being disposed at different positions in the main body; and a processor, which while the main body is worn on a body part of a user or is carried by the user, is configured to estimate human body microclimate temperature of the user based on a difference between the first temperature and the second temperature.

Aspects of the present disclosure relate to a temperature device including a flexible substrate, and an electrical circuit on a surface of the flexible substrate, the electrical circuit including a heater element having an outer perimeter and an inner perimeter, the inner perimeter surrounding a zone of the surface, the zone is thermally distinct from the heater element, wherein the heater element has a first dimension defining the outer perimeter and a second dimension defining the inner perimeter, wherein a ratio of the first dimension to a second dimension is no greater than 2.1:1, a first thermal sensor disposed in the zone, a second thermal sensor disposed outside of the heater element, a plurality of electrical pads disposed outside of the heater element, and a plurality of conductive traces connecting the first and second thermal sensors and the heater element with the plurality of electrical pads.