Aspects relate to a portable device that may be used to identify a critical intensity and an anaerobic work capacity of an individual. The device may utilize muscle oxygen sensor data, speed data, or power data. The device may utilize data from multiple exercise sessions, or may utilize data from a single exercise session. The device may additionally estimate a critical intensity from a previous race time input from a user.

A vital signs monitoring system, the system including: (a) an ear device including: a curved body adapted to a shape of an ear, an upper end, a lower end, two opposite facing sides, a first side adapted to be proximal a skull and a second side adapted to be proximal an earlobe, the ear device including: (i) a temperature sensor adapted to sense a body temperature from a depression between a lower, jawbone and skull; and (b) a control system, including a processor and a memory, configured and operable to control operation of the ear device, to collect signals received from at least one sensor including the temperature sensor, to process the signals to provide medically significant results.

A visible-light-image physiological monitoring system with thermal detecting assistance is disclosed. The system takes a visible-light image and a thermal image of a body at the same time. A processing unit identifies a body feature of the visible-light image and determines a coordinate of the feature. In a learning mode, an initial temperature of the body feature is determined from the thermal image according to the coordinate of the body feature. After then, a physiological status monitoring mode is executed to monitor the temperature changes of the body feature and output an alarm when the temperature is determined to be abnormal. Therefore, a monitoring accuracy of the visible-light-image physiological monitoring system is increased and avoids transmitting false alarms or no alarms.

A monitoring process, a user health and/or safety monitoring process, the monitoring process including the steps: providing a sensor set including at least one sensor; obtaining a monitoring configuration from a memory element. The monitoring configuration including: a sensor configuration associated with the sensor set and a body profile associated with a subject body and comprising reference data. The monitoring process further providing, in a memory element, measurement data relating to said subject body, said measurement data being acquired by said sensor set; computing, with computing means, a difference between the measurement data and the reference data; comparing, with comparison means, the difference and a predefined condition; changing, and with changing means, the monitoring configuration depending on the result of the comparing step.

The invention disclosed herein relates to improvements in the collection personal health data. It further relates to a Personal Health Monitor (PHM), which may be a Personal Hand Held Monitor (PHHM), that incorporates a Signal Acquisition Device (SAD) and a processor with its attendant screen and other peripherals. The SAD is adapted to acquire signals which can be used to derive one or more measurements of parameters related to the health of a user. The computing and other facilities of the PHM with which the SAD is integrated are adapted to control and analyse signals received from the SAD. The personal health data collected by the SAD may include data related to one or more of blood pressure, pulse rate, blood oxygen level (SpO.sub.2), body temperature, respiration rate, ECG, cardiac output, heart function timing, arterial stiffness, tissue stiffness, hydration, blood viscosity, blood pressure variability, the concentration of constituents of the blood such as glucose or alcohol and the identity of the user.

An example system for monitoring and delivering therapy to a patient includes a monitor module with patient monitoring capability, and a manifold that is operable to provide an electrical connection between the monitor module and cables connecting to sensors for collecting physiologic monitoring data of a patient, and to provide a gas connection between the monitor module and tubing for delivering treatment to or collecting additional physiologic monitoring data from the patient. The manifold includes a connector for mechanically connecting the manifold to the monitor module, and the connector also for mechanically disconnecting the manifold from the monitor module while maintaining the cables and the tubing coupled to the patient. In some examples, the system can also include a cot including a second set of monitoring electronics with patient monitoring capability, the cot including a port for coupling with the connector of the manifold.

An example system for monitoring and delivering therapy to a patient includes a monitor module with patient monitoring capability, and a manifold that is operable to provide an electrical connection between the monitor module and cables connecting to sensors for collecting physiologic monitoring data of a patient, and to provide a gas connection between the monitor module and tubing for delivering treatment to or collecting additional physiologic monitoring data from the patient. The manifold includes a connector for mechanically connecting the manifold to the monitor module, and the connector also for mechanically disconnecting the manifold from the monitor module while maintaining the cables and the tubing coupled to the patient. In some examples, the system can also include a cot including a second set of monitoring electronics with patient monitoring capability, the cot including a port for coupling with the connector of the manifold.

There is provided a recognition system adaptable to a portable device or a wearable device. The recognition system senses a body heat using a thermal sensor, and performs functions such as the living body recognition, image denoising and body temperature prompting according to detected results.

An apparatus for estimating a core body temperature of an object is provided. The apparatus may include a heat flow sensor configured to measure a first heat flux from an object, a first temperature sensor positioned under a thermal conducting material and configured to measure a surface temperature of the object, a second temperature sensor positioned above the thermal conducting material and configured to measure a surface temperature of the thermal conducting material, and a processor configured to obtain a second heat flux by calibrating the first heat flux based on the surface temperature of the object and the surface temperature of the thermal conducting material, and configured to estimate a core body temperature of the object based on the obtained second heat flux and the surface temperature of the object.

There is provided a human falling detection system including an image sensor, a thermal sensor and a microphone. The image sensor captures an image frame that is used to identify a face and a height-width ratio of a human image. The thermal sensor is used as a filter for filtering out a living body and captures a thermal image that is used to identify a height-width ratio of a human thermal image. The microphone records a time stamp of an abrupt sound appearing.