A mobile device such as a smart phone, tablet computer, Internet of things (IoT) device, and/or wearable device includes a sensor module coupled to multiple corresponding sensors. The multiple corresponding sensors include multiple instances of the same type of motion sensor in different physical locations on the mobile device. The sensor module includes a software architecture/algorithm that can configure the multiple corresponding sensors to provide sensor measurements having a higher sampling frequency and/or an improved accuracy. In addition, the sensor module may provide sensor measurements having additional degrees of freedom and/or lower power consumption than can be provided by existing sensor modules. In one example, the multiple corresponding sensors include multiple accelerometers that operate at relatively low power to provide linear acceleration samples, the sensor module processes the multiple linear acceleration samples to generate a measure of angular acceleration used to activate the mobile device.

The present invention relates to a terahertz biometric imaging arrangement configured to be arranged under an at least partially transparent display panel and configured to capture an image of an object located on an opposite side of the transparent display panel, the biometric imaging arrangement comprising: a transmitter element arranged to emit terahertz radiation for illuminating the object; and an image sensor comprising an antenna pixel array arranged to detect terahertz radiation transmitted from the illuminated object, for producing an image.

A non-transitory computer readable medium storing data and computer implementable instructions that, when executed by at least one processor, cause the at least one processor to perform operations for generating cross section views of a wound, the operations including receiving 3D information of a wound based on information captured using an image sensor associated with an image plane substantially parallel to the wound; generating a cross section view of the wound by analyzing the 3D information; and providing data configured to cause a presentation of the generated cross section view of the wound.

A system for obtaining and providing enhanced PAP metrics of a patient's sleep period includes: a pressure support device for use in providing a flow of breathing gas to the patient; a processing unit; and a number of auxiliary devices in wireless communication with the processing unit. Each auxiliary device of the number of auxiliary devices is structured to detect and collect sleep-related data of the patient. The processing unit is programmed to: receive data obtained by a number of sensors of the pressure support device during operation of the pressure support device in providing the flow of breathing gas to the patient; receive supplemental data obtained by the number of auxiliary devices while the pressure support device is not providing the flow of breathing gas to the patient; and determine the enhanced PAP metrics of the sleep period of the patient utilizing the data and the supplemental data.

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 electronic device includes a display panel and a biometric information module. The display panel includes red-light emitting elements, green-light emitting elements, blue-light emitting elements, and light receiving elements that are spaced from each other. The blue-light emitting elements emit blue light in a biometric information mode of the electronic device. The light receiving elements receive at least one of red light and green light in the biometric information mode of the electronic device after the blue-light emitting elements have emitted the blue light. The light receiving elements generate electrical signals in response to the at least one of the red light and the green light. The biometric information module is electrically connected to the display panel and generates biometric information about a skin of a user based on the electrical signals.

Embodiments are provided for cognitive bias detection and correction in self-reported data. In some embodiments, a system can include a processor that executes computer-executable components stored in memory. The computer-executable components include first components that creates an ontology of bias descriptor features to identify cognitive biases. The cognitive biases can include a combination of at least one device-induced cognitive bias, at least one testing-application-induced cognitive bias, or at least one study-design-induced cognitive bias.

The present disclosure generally relates to user interfaces for health monitoring. Exemplary user interfaces for initial setup of health monitoring using a first electronic device and a second electronic device is described. Exemplary user interfaces for recording biometric information for use in health monitoring is described. Exemplary user interfaces for using an input device while recording biometric information for health monitoring is described. Exemplary user interfaces for viewing and managing aspects of health monitoring is described.

A system and method are disclosed for the remote detection of otitis media in children at home or in other locations for use in a telemedicine environment. The system runs on a smartphone application and is easy for a child's caregiver to use. The system also includes a pop-open soundwave guide that directs an audio signal from a smartphone's speaker to the patient's eardrum and back to the smartphone's microphone.

The current subject matter can include non-invasive systems and methods for detecting hemoglobin. In one implementation, a method includes receiving data characterizing a plurality of images associated with palpebral conjunctiva region of one or more patients. The method also includes receiving data indicative of a user selection of a first pixel of a first image of the plurality of images. The method further includes determining, a region of interest associated with the selected first pixel. The determining can include identifying a plurality of pixels adjacent to the first pixel having color parameter values within a predetermined range of a first color parameter value of the first pixel. The method also includes determining a first plurality of parameters associated with the region of interest, and providing the first plurality of parameters.