Provided is a system for measuring biological signals of a user, which includes a sensor module configured to acquire ballistocardiogram (BCG) signals of a user via a present channel, where the present channel is at least one channel of the sensor module, a decomposition module configured to decompose the BCG signals to decomposed signals, a reconstruction module configured to reconstruct at least a portion of the decomposed signals to reconstructed signals, a processing module configured to process the reconstructed signals to at least one of a heart rate, respiration rate, phases of respiration, and blood pressure, and a display module configured to display at least one output corresponding to the at least one of the heart rate, the respiration rate, phases of respiration, and the blood pressure on a display device.

A dynamic analysis apparatus, including a processor which selects one or more frame images from a plurality of frame images of a dynamic image that is obtained by performing radiation imaging of a subject including a target site in a living body, recognizes a shape of a predetermined body part from each of the selected one or more frame images and calculates an evaluation value of the recognized shape of the body part.

The invention relates to a method for measuring the human heartbeat rate, comprising the steps of: 1) obtaining a video of the measured subject; 2) parsing the video into a series of image frames; 3) arranging the multiple generated image frames in sequential order; 4) detecting the position of the region of the face in each image; 5) obtaining the facial fluctuation frequency of the measured object according to the change of the position of the face region in the image frame system.

The invention relates to a method for measuring the human heartbeat rate, comprising the steps of: 1) obtaining a video of the measured subject; 2) parsing the video into a series of image frames; 3) arranging the multiple generated image frames in sequential order; 4) detecting the position of the region of the face in each image; 5) obtaining the facial fluctuation frequency of the measured object according to the change of the position of the face region in the image frame system.

The utility model relates to a device for measuring the heartbeat, respiration, and body temperature of a human body, comprising of a shell and a base, wherein a PCB board, a buzzer, and a multi-point infrared temperature sensor and a camera are arranged in the shell. The infrared temperature sensor is used for temperature sampling of M×N sampling points, where M≧3, N≧3, and the camera is used for acquiring the video image of the measured object.

A system, method and apparatus is disclosed, comprising a biomathetical model for optimizing cognitive performance in the face of sleep deprivation that integrates novel and nonobvious biomathematical models for quantifying performance impairment for both chronic sleep restriction and total sleep deprivation; the dose-dependent effects of caffeine on human vigilance; and the pheonotypical response of a particular user to caffeine dosing, chronic sleep restriction and total sleep deprivation in user-friendly software application which itself may be part of a networked system.

A system, method and apparatus is disclosed, comprising a biomathetical model for optimizing cognitive performance in the face of sleep deprivation that integrates novel and nonobvious biomathematical models for quantifying performance impairment for both chronic sleep restriction and total sleep deprivation; the dose-dependent effects of caffeine on human vigilance; and the pheonotypical response of a particular user to caffeine dosing, chronic sleep restriction and total sleep deprivation in user-friendly software application which itself may be part of a networked system.

A multi-application-transceiver device, control computer, computer implemented method and computer program product for operating the multi-application-transceiver device is disclosed. At least one signal transceiver receives a reflected signal in response to an original signal sent by the at least one signal transceiver. The reflected signal is reflected from at least one target object. A signal conversion unit converts the reflected signal into digital format. A digital signal processor component pre-processes the converted reflected signal using an alterable rule engine with a received rule set to discriminate a state inn change of the at least one target object against an earlier state of the at least one target object in the context of a particular monitoring application. A middleware component communicates with at least one remote computing device wherein communicate includes to send the pre-processed signal to the remote computing device, and to receive from the at least one remote computing device the rule set for the alterable rule engine. The received rule set defines an application specific setting for the at least one signal transceiver and for the digital signal processor component to enable the particular monitoring application.

The present invention provides an apparatus for the measurement and monitoring of the breathing volume of a subject. In certain embodiments, the invention further provides a method of using the apparatus to diagnose a subject as suffering from a respiratory disorder. In other embodiments, the apparatus and method can be used to monitor the breathing volume of a subject, while compensating for random body movement of the subject during the monitoring period.

The present invention provides an apparatus for the measurement and monitoring of the breathing volume of a subject. In certain embodiments, the invention further provides a method of using the apparatus to diagnose a subject as suffering from a respiratory disorder. In other embodiments, the apparatus and method can be used to monitor the breathing volume of a subject, while compensating for random body movement of the subject during the monitoring period.