An electronic device, and a biological detection control method and apparatus. The electronic device includes: a packaging layer, on which a light-transmitting part is provided; a fingerprint identification unit and a pulse wave detection unit disposed within the packaging layer; and a substrate, the fingerprint identification unit and the pulse wave detection unit being disposed on the substrate and fixedly connected to the substrate, where the pulse wave detection unit directly faces the light-transmitting part.

An intelligent device and wearing method. The method includes, for an intelligent device having a first sensor and a second sensor, obtaining a measurement value of the first sensor, when the measurement value of the first sensor is greater than a first threshold, determining that the intelligent device is in a worn state, when the measurement value of the first sensor is less than a second threshold, determining that the intelligent device is in a not-worn state, where the first threshold is greater than the second threshold, when the measurement value of the first sensor is between the first threshold and second threshold, turning on the second sensor, turning on the second sensor, obtaining a measurement value of the second sensor, and determining, according to the measurement value of the second sensor, that the intelligent device is in the worn state or in the not-worn state.

An electrocardiogram measuring device includes: a first second electrodes configured to receive a first and second electrocardiogram voltages of a first and second body parts in contact therewith, respectively; two amplifiers configured to receive the first and second electrocardiogram voltages from the first and second electrodes; a third electrode configured to contact a third body part and transfer a third electrocardiogram voltage of the third body part; an electrode driver configured to receive the third electrocardiogram voltage and output a driving voltage; a fourth electrode placed adjacent to one of the three electrodes and configured to receive and transmit the output of the electrode driver to one of the three body parts in contact therewith; an AD converter connected to an output terminal of each of the two amplifiers; a microcontroller configured to receive the two digital signals; and a communication means configured to transmit the two digital signals.

The present disclosure relates to a method for emotion-triggered capturing of audio and/or image data by an audio and/or image capturing device. The method includes receiving and analyzing a time-sequential set of data including first physiological data representing a first physiological parameter corresponding to a first person, a second physiological data representing a second physiological parameter corresponding to a second person, and voice audio data including a voice of at least one of the first and the second person, to determine whether a simultaneous change of emotional state of a first person and a second person occurs and transmitting a trigger signal to the capturing device. The present disclosure also relates to a corresponding apparatus and a system comprising the apparatus.

A method of living body detection includes: capturing a plurality of images of an object under test by using an image sensor; calculating variations of brightness values of pixel units of the plurality of images; and, determining whether the object under test is a living body according to the variations.

Various analyte sensor systems for controlling activation of analyte sensor electronics circuitry are provided. Related methods for controlling analyte sensor electronics circuitry are also provided. Various analyte sensor systems for monitoring an analyte in a host are also provided. Various circuits for controlling activation of an analyte sensor system are also provided. Analyte sensor systems utilizing a state machine having a plurality of states for collecting a plurality of digital counts and waking a controller responsive to a wake up signal are also provided. Related methods for such analyte sensor systems are also provided. Systems for controlling activation of analyte sensor electronics circuitry utilizing a magnetic sensor are further provided. One or more display device configured to display one or more analyte concentration values are also provided.

Various analyte sensor systems for controlling activation of analyte sensor electronics circuitry are provided. Related methods for controlling analyte sensor electronics circuitry are also provided. Various analyte sensor systems for monitoring an analyte in a host are also provided. Various circuits for controlling activation of an analyte sensor system are also provided. Analyte sensor systems utilizing a state machine having a plurality of states for collecting a plurality of digital counts and waking a controller responsive to a wake up signal are also provided. Related methods for such analyte sensor systems are also provided. Systems for controlling activation of analyte sensor electronics circuitry utilizing a magnetic sensor are further provided. One or more display device configured to display one or more analyte concentration values are also provided.

Methods, devices, systems, and kits are provided that buffer the time spaced glucose signals in a memory, and when a request for real time glucose level information is detected, transmit the buffered glucose signals and real time monitored glucose level information to a remotely located device, process a subset of the received glucose signals to identify a predetermined number of consecutive glucose data points indicating an adverse condition such as an impending hypoglycemic condition, confirm the adverse condition based on comparison of the predetermined number of consecutive glucose data points to a stored glucose data profile associated with the adverse condition, where confirming the adverse condition includes generating a notification signal when the impending hypoglycemic condition is confirmed, and activate a radio frequency (RF) communication module to wirelessly transmit the generated notification signal to the remotely located device only when the notification signal is generated.

A dependency-based startup method in a multi-modality medical processing system that includes receiving initialization information about a plurality of executable components to be started, the plurality of executable components including an executable modality component configured to communicate with a medical device communicatively coupled to the multi-modality medical processing system. The method also includes receiving dependency information about the executable modality component, the dependency information identifying one or more of the executable components upon which the executable modality component depends and transforming the initialization information and the dependency information into a dependency map that represents the dependencies between the plurality of executable components. Further, the method includes deriving a start order for the plurality of executable components based on the dependency map and starting the plurality of executable components in the multi-modality medical processing system according to the start order.

In the present invention, a catheter identification system for providing information about one or more attributes of a catheter connectable to an electrophysiology (EP) recording or mapping system includes a catheter, a resistor network operably connected to the catheter, the resistor network including at least one identification resistor and an identification resistor measurement circuit operably connected to the catheter and configured to send an identification signal through the at least one resistor in the resistor network to retrieve an altered identification signal from the identification resistor, where the altered identification signal provides information on an attribute of the catheter.