An electrocardiograph (ECG) signal processing method and apparatus to resolve a problem that relatively severe interference caused during single-arm measurement for single-lead ECG collection seriously affects accuracy of heart rate calculation and cardiac rhythm analysis. The method includes collecting, by a measurement device, an ECG signal, extracting a k.sup.th valid QRS complex of the ECG signal, calculating a k.sup.th time difference and a (k+1).sup.th time difference, and determining whether the k.sup.th time difference and the (k+1).sup.th time difference are target time differences. In this way, accuracy of ECG feature extraction is improved, the interference caused during the single-arm measurement is eliminated to the most extent, and the accuracy of heart rate calculation and cardiac rhythm analysis can be effectively guaranteed.

The present invention provides a risky driving prediction method and system based on a brain-computer interface, and an electronic device. The risky driving prediction method based on the brain-computer interface includes: performing, by a driver, at least one responsiveness test item before starting a vehicle; applying a brain-computer interface to acquire an electroencephalogram signal of the driver performing the at least one responsiveness test item, and analyzing the electroencephalogram signal to generate feedback information; and analyzing the feedback information based on a preset test standard to determine whether the driver has a risky driving behavior. Therefore, by using the risky driving prediction method, it can be detected whether the driver is in a state suitable for driving the vehicle without requiring the driver to do any body movement or language response.

The present invention provides a risky driving prediction method and system based on a brain-computer interface, and an electronic device. The risky driving prediction method based on the brain-computer interface includes: performing, by a driver, at least one responsiveness test item before starting a vehicle; applying a brain-computer interface to acquire an electroencephalogram signal of the driver performing the at least one responsiveness test item, and analyzing the electroencephalogram signal to generate feedback information; and analyzing the feedback information based on a preset test standard to determine whether the driver has a risky driving behavior. Therefore, by using the risky driving prediction method, it can be detected whether the driver is in a state suitable for driving the vehicle without requiring the driver to do any body movement or language response.

A computer system or method may be provided for modulating content based on a person's brainwave data, including modifying presentation of digital content at at least one computing device. The content may also be modulated based on a set of rules maintained by or accessible to the computer system. The content may also be modulated based on user input, including through receipt of a presentation control command that may be processed by the computer system of the present invention to modify presentation of content. Content may also be shared with associated brain state information.

A computer system or method may be provided for modulating content based on a person's brainwave data, including modifying presentation of digital content at at least one computing device. The content may also be modulated based on a set of rules maintained by or accessible to the computer system. The content may also be modulated based on user input, including through receipt of a presentation control command that may be processed by the computer system of the present invention to modify presentation of content. Content may also be shared with associated brain state information.

A cranial nerve control device includes: goggles worn on a patient head; a functional electric stimulator adapted to apply peripheral nerve stimulation to a patient; a plurality of module guides provided to the goggles; a functional electric stimulator controller adapted to control the functional electric stimulator; a transcranial current stimulator-combined near-infrared spectroscopy measurement module controller adapted to control the transcranial current stimulator-combined functional near-infrared spectroscopy measurement module; and a simulation device connected to both the transcranial current stimulator-combined near-infrared spectroscopy measurement module controller and the functional electric stimulator to provide feedback of a transcranial current stimulation control signal to the transcranial current stimulator and feedback of a functional electrical stimulation control signal to the functional electric stimulator while monitoring the patient brain activity.

A method for generating stimulation parameters, an electrical stimulation control apparatus and an electrical stimulation system are provided. After receiving a brainwave signal, the brainwave signal is decomposed to obtain a first sub-signal and a second sub-signal. Then, the first sub-signal is analyzed to obtain an intrinsic frequency series, and the second sub-signal is converted to a Boolean signal. Subsequently, the intrinsic frequency series and the Boolean signal, which serve as a set of stimulation parameters, are outputted to the stimulator, enabling the stimulator to generate a stimulus signal.

An electrode for measuring bioelectric signals of an individual includes a dome-like shape support body having a concave contact side facing the individual and an opposite convex connector side. The support body defines a central axis arranged centrally through the contact and connector sides. The electrode includes outer contact pins located on the contact side at a radially outer region of the support body for contacting an area of interest to be measured. The electrode is made of elastomeric material and has conductive properties. The support body is flexible such that after applying the electrode to the individual a force exerted centrally onto the connector side and parallel to the central axis leads to an upwards bending of the radially outer region. The upwards bending leads to tilting of the outer contact pins such that a tip of the outer contact pins moves radially outwards along the area of interest.

A multimodal data acquisition and communication system and method for distributed management of transdiagnostic behavioral therapy (TBT). An exemplary system, method, and apparatus according to certain aspects of the present disclosure may include a patient interface comprising (a) one or more sensors configured to collect quantitative (e.g., physiological data) and qualitative data (e.g., video/audio data) from a patient user during a TBT session, and (b) a mobile computing device, such as a smartphone, comprising a mobile software application configured to establish a data transfer interface with the one or more sensors and provide a graphical user interface to the patient user. The mobile computing device may be communicatively engaged with a cloud-based server over a wireless communications network to enable real-time collection, communication, storage and analysis of TBT data and bi-directional audio/video communication with at least one clinician client device.

An electrode kit for preparing a medical device for a patient. The electrode kit includes a central support member having a device side and a patient side with one or more perforations are defined between. A conductive material extends through the one or more perforations to couple the patient and the medical device. A device side cover is removably coupled to the device side of the central support member, where the central support member is configured to be coupled to the medical device when the device side cover is removed. A patient side cover is removably coupled to the patient side of the central support member, where the central support member is configured to couple to the medical device to the patent when the patient side cover is removed.