Abstract: An apparatus for measuring bio-information such as blood pressure is provided. The bio-information measuring apparatus includes: a pulse wave sensor configured to measure a pulse wave signal from an object; a fingerprint sensor configured to obtain fingerprint information of the object; and a processor configured to estimate a contact area of the object based on the fingerprint information, and obtain bio-information based on the pulse wave signal and the contact area.

Abstract: Systems and methods to determine a risk factor related to dehydration and thermal stress of a subject are disclosed. Exemplary implementations may: generate output signals, by one or more sensors worn on a body of a subject, conveying information related to one or more of location of the subject, motion of the subject, temperature of the subject, cardiovascular parameters of the subject; store information related to the subject; obtain the output signals; determine in an ongoing manner, from the output signals, values of a water loss metric that correlates with estimated percentage of bodyweight of the subject lost in water; obtain heat index information for a contextual environment surrounding the subject; determine in an ongoing manner, from the output signals, values of an exertion metric that correlates with exertion of the subject due to work; and determine in an ongoing manner values for an aggregated risk factor of the subject.

Abstract: Systems and methods are provided for injury characterization including detecting matches of an individual subject's record (such as an athlete's record) with collections of other subjects records, based on serial, longitudinal patterns, for facilitating athlete health and training, preventive and rehabilitation medicine, and risk management in athletics.

Abstract: A system that uses biometric data to facilitate learning is provided herein. The system receives at least two data points via a biometric sensor. Information is extracted from the at least two data points and a set of features are identified. Data analysis is then performed on the set of features.

Abstract: Described is a system for activity and behavior detection in a target system. Raw data extracted from various heterogeneous sources of the target system is fused across spatial and temporal scales into a multi-graph representation. Information flows of the multi-graph representation are analyzed using a set of multi-layer information dynamic measures. Based on the set of multi-layer information dynamic measures, at least one of an economic and social indicator of emerging activity of interest in the target system is derived. The indicator is then used for prediction of future activity of interest in the target system.

Abstract: The invention relates to a device for acquiring personal health information and a method therefor, the device: easily and periodically acquiring, anytime and anywhere or without regard to place and time, information on ambient temperature/humidity and health information of an individual, such as the state of skin (including hair), a nose, ears, and a mouth associated with an ENT clinic, the teeth associated with a dental clinic, skin moisture, and body temperature, through image information having multiple functions and a multifunctional health care sensor; enabling the acquired health information to be accumulated over in a personal terminal or computer by analyzing, storing, and making the same into data, and continuously managing the periodically accumulated personal health information such that the personal health information can be used as critical information by which a disease cause and the like can be fundamentally understood during an incidence of disease in the future.

Abstract: A system for detecting patient turns includes a person support apparatus including a person support surface and a support frame, a plurality of load cells for generating load cell data, a sensor for sensing at least one of heart rate data and respiration rate data for an individual, and a computing device coupled to the plurality of load cells and the sensor. The computing device receives the load cell data and the at least one of heart rate data and respiration rate data for the individual, detects that a patient turn has occurred on the person support surface based on the load cell data and the at least one of heart rate data and respiration rate data for the individual, and causes an indication that the patient turn occurred to be logged in an electronic medical record corresponding to the individual.

Abstract: Example methods, apparatus/systems and articles of manufacture for determining intensity of a biological response to a presentation are disclosed. An example method includes accessing galvanic skin response (GSR) data obtained from a subject while exposed to a presentation. The GSR data includes a plurality of trough-to-peak instances. The example method includes generating a GSR intensity profile by assigning trough-to-peak scores to corresponding ones of the trough-to-peak instances, defining a plurality of time windows, and assigning window scores to corresponding ones of the time windows based on the trough-to-peaks scores of the trough-to-peak instances occurring within the corresponding time windows. The example method also includes determining an effectiveness of the presentation based on the window scores of the GSR intensity profile.

Abstract: There is provided a system (100) for assessing delirium in a subject. The system includes a neural activity assessment module (102) for assessing neural activity data associated with the subject. The system also includes a delirium cause assessment module (104) for assessing data relating to at least one factor of a plurality of factors which contribute to the cause of delirium. The system also includes an intervention determination module (106) for determining, based on the assessment performed by the delirium cause assessment module, at least one intervention for reducing the contribution made by the at least one factor. A computer-implemented method and an apparatus are also disclosed.

Abstract: A wearable biometric device to mitigate cognitive dissonance according to various embodiments can be configured to define one or more geo-fences relative to one or more physical locations; detect a geo-fence crossing when the wearable biometric device crosses any of the geo-fences; activate a geo-fence application and a biometric application, in response to the detection of a geofence crossing; monitor behavior transactions of the user while the wearable biometric device is located within the geo-fence; activate a biometric sensor to detect biometric conditions of the user and determine if the biometric conditions of the user exceeds a predetermined threshold; activate a stimuli generating unit to detect if the user experiences a biometric stressor while the wearable biometric device is located within the geo-fence and activate the stimuli generating unit to apply one or more stimuli to the user until the biometric stressor experienced by the user is below the threshold.

Abstract: A device for monitoring a health parameter of a person includes a semiconductor substrate, and an antenna array including at least one transmit antenna connected to the semiconductor substrate and configured to transmit radio waves below the skin surface of a person and a two-dimensional array of receive antennas connected to the semiconductor substrate and configured to receive radio waves, the received radio waves including a reflected portion of the transmitted radio waves, wherein the semiconductor substrate includes circuits configured to generate signals that correspond to an alignment of the antenna array relative to a vein in the person in response to the received radio waves, and means for determining an alignment of the antenna array relative to a vein in the person in response to the generated signals, and means for outputting a signal that is indicative of the determined alignment of the antenna array relative to the vein.

Abstract: An example of a system may include a sensing circuit and an atrial fibrillation (AF) detection circuit. The sensing circuit may be configured to sense a cardiac signal indicative of atrial and ventricular depolarizations. The AF detection circuit may be configured to detect AF using the cardiac signal and may include a detector and a detection enhancer. The detector may be configured to detect the ventricular depolarizations using the cardiac signal, to measure ventricular intervals each between two successively detected ventricular depolarizations, and to detect the AF using the ventricular intervals. The detection enhancer may include a respiratory sinus arrhythmia (RSA) detector configured to detect RSA using the cardiac signal and may be configured to verify each detection of the AF based on whether the RSA is detected.

Abstract: The proposed method relates to the field of providing physical feedback to a user from a virtual application, particularly a computer game or other software applications. The method for interactive physiological and technological synchronization of a user with a virtual environment includes taking the user's biometric and/or kinematic parameters, transferring the user's biometric and/or kinematic parameters to an application program, generating feedback signals in the application program, transmitting the feedback signals to a computing device, processing the feedback signals and supplying feedback pulses which invoke physical sensations in the nervous system of the user through contact with the user's skin, wherein the feedback pulses are supplied using the principle of cascaded distribution of electrical pulses. Also claimed are variants of a wearable apparatus for implementation of the proposed method. The proposed method and apparatus allow for creating a deep-sense reality for the user.

Abstract: Methods and devices include identifying a plurality of target users for the digital therapeutic based on one or more target parameters, conducting outreach to one or more of the plurality of target users using an outreach medium, identifying an activation mechanism to optimize use of the digital therapeutic, and encouraging an engagement level of the digital therapeutic by one or more of the plurality of target users.

Abstract: Systems, methods, devices, and apparatus for positioning a patient's mandible in response to sleep apnea status are provided herein. In one aspect, a system for monitoring and treating sleep apnea in a patient comprises one or more sensors configured to monitor the patient for symptoms associated with sleep apnea; an intraoral appliance worn by the patient, one or more processors, and memory comprising instructions executable by the one or more processors to cause the one or more processors to: receive a set of sensor data from the one or more sensors, detect, using a machine learning algorithm, onset of a sleep apnea event based on the set of sensor data, and transmit a control signal to the intraoral appliance to cause the intraoral appliance to displace a lower jaw of the patient from a first position to a second position in order to treat the sleep apnea event.

Abstract: A patient monitor that acquires a vital sign through a measurement sensor, and that is to be connected to an external measurement apparatus for measuring another vital sign, includes a master clock that is disposed in the patient monitor, and that manages common time information, a first operating system that manages first time information, and a second operating system that manages second time information, and that transmits and receives data to and from the external measurement apparatus. When a predetermined event occurs, the first operating system reads the common time information from the master clock, and updates the first time information. When the predetermined event occurs, the second operating system reads the common time information from the master clock, updates the second time information, and notifies the external measurement apparatus of the updated second time information or the common time information.

Abstract: A wireless patient monitoring device can be fully functional stand-alone patient monitoring device capable of various physiological measurements. The patient monitoring device is small and light enough to be comfortably worn on the patient, such as on the patient's wrist or around the neck. The patient monitoring device can have a monitor instrument removably engaging a disposable base. The base can have outlets for connecting to an acoustic respiration sensor and an oximeter sensor. The patient monitoring device can have pogo pin connectors connecting the monitor instrument and the disposable base so that the monitor instrument can receive sensor data from the sensors connected to the disposable base.

Abstract: A sensor module includes a housing and a sensor assembly disposed within the housing. The sensor assembly includes a base having at least one energy emitter and at least one energy detector, and a guide layer overlying the base in face-to-face relationship. The guide layer has at least one protrusion extending outwardly to accommodate the at least one energy emitter, and a plurality of outwardly extending stabilizing members. The housing has at least one first opening through which the at least one protrusion extends, and a plurality of second openings through which the stabilizing members extend. Some of the stabilizing members have an outwardly extending length that is greater than an outwardly extending length of the at least one protrusion. Some of the stabilizing members are substantially cylindrical and have a circular cross-sectional profile, and some of the stabilizing members are partially cylindrical and have a partially circular cross-sectional profile.

Abstract: Communication device includes first sensor configured to measure a state of a sensing target person to acquire first measurement data, second sensor configured to measure a body temperature to acquire second measurement data, and memory unit configured to store a reference body temperature for a single or each of a plurality of predetermined states of the sensing target person. Communication device further includes state determiner configured to determine whether or not the sensing target person is in the single or any one of the plurality of predetermined states, and abnormality determiner configured to compare the reference body temperature with the body temperature of the sensing target person to determine whether or not the sensing target person has a body temperature abnormality.

Abstract: A biological signal acquirer is attached to a subject and acquires a biological signal of the subject. A transmitter carried by the subject transmits the biological signal. A first communication port and a first camera are installed in a first location and connectable to a network. A second communication port and a second camera are installed in a second location and connectable to the network. A biological information acquiring device is connectable to the network and provided with a switcher. The switcher acquires, when communication establishment between the transmitter and the first communication port is detected, the biological signal through the first communication port as well as a first image taken by the first camera, and acquires, when communication establishment between the transmitter and the second communication port is detected, the biological signal through the second communication port as well as a second image taken by the second camera.

Abstract: A system and apparatus comprising a multi-sensor catheter for right heart and pulmonary artery catheterization is disclosed. The multi-sensor catheter comprises multi-lumen catheter tubing into which at least three optical pressure sensors, and their respective optical fibers, are inserted. The three optical pressure sensors are arranged within a distal end portion of the catheter, spaced apart lengthwise within the distal end portion for measuring pressure concurrently at each sensor location. The sensor locations are configured for placement of at least one sensor in each of the right atrium, the right ventricle and the pulmonary artery, for concurrent measurement of pressure at each sensor location. The sensor arrangement may further comprise an optical thermo-dilution sensor, and another lumen is provided for fluid injection for thermo-dilution measurements. The catheter may comprise an inflatable balloon tip and a guidewire lumen, and preferably has an outside diameter of 6 French or less.

Abstract: The present invention provides an integrated health care surveillance and monitoring system that provides real-time sampling, modeling, analysis, and recommended interventions. The system can be used to monitor infectious and chronic diseases. When faced with outbreak of an infectious disease agent, e.g., influenza virus, the system can identify active cases through pro-active sampling in high risk locations, such as schools or crowded commercial areas. The system can notify appropriate entities, e.g., local, regional and national governments, when an event is detected, thereby allowing for proactive management of a possible outbreak. The system also predicts the best response for deployment of scarce resources.

Abstract: Disclosed herein are platforms, systems, devices, software, and methods for processing and analyzing real-time data to generate predictions of near future events. Machine learning algorithms can be configured for varying levels of aggression to enhance timeliness of the predictions. Ensemble machine learning techniques combining a plurality of trained models configured with higher and lower aggression levels can be used to improve both timeliness and accuracy.

Abstract: Systems and methods for receiving galvanic skin response data from a galvanic skin response sensor that includes multiple electrodes fastened to a hand of a human; monitoring the galvanic skin response data to determine a time for initiating a Blood Pressure (BP) measurement using a blood pressure measurement cuff worn by the human (e.g., in a continuous or on-demand BP measurement mode); at the determined time, initiating the blood pressure measurement using the blood pressure measurement cuff; receiving blood pressure data for the human that results from the blood pressure measurement; and storing a blood pressure value that is based on the blood pressure data.

Abstract: A wearable monitoring system and associated method that is configured to (i) determine three dimensional displacement of the spine of a subject's chest wall with respect to the subject's spine, (ii) process the three dimensional anatomical data, (iii) determine at least one respiratory parameter associated with the monitored subject and value thereof as a function of the three dimensional anatomical data, and (iv) determine a respiratory disorder as a function of the determined respiratory parameter and value thereof.

Abstract: A wearable respiration monitoring system having a transmitter coil that is adapted to generate and transmit multi-frequency AC magnetic fields, a plurality of receiving coils adapted to detect variable strengths in the AC magnetic fields and generate AC magnetic field strength signals representing anatomical displacements of a monitored subject, and at least one accelerometer that is configured to detect and monitor anatomical positions and movement of the subject, and generate and transmit accelerometer signals representing same. The wearable monitoring system further includes an electronics module that is adapted to receive the AC magnetic field strength signals and accelerometer signals, and determine at least one respiratory disorder as a function of the AC magnetic field strength signals and at least one anatomical position of the subject as a function of the accelerometer signals.

Abstract: Systems and methods disclosed herein relate to autonomous agents. A first autonomous agent receives, from a first sensor, a first set of event data indicating events relating to a subject. The first autonomous agent provides the first set of event data to a data aggregator. The first autonomous agent receives, from the data aggregator, correlated event data including events sensed by the first autonomous agent and a second autonomous agent. The first autonomous agent applies machine learning model to the correlated event data to predict a first pattern of activity and determines, based on the first pattern of activity, that a first action is to be performed, causing the first actuator module to perform the first action.

Abstract: A system is provided for automated monitoring the health of a patient. The system is unifying the approach of multi-sensing, robotic platform and cloud computing to monitor the health of the patient with zero or very minimal human intervention. The plurality of physiological parameters and the pathological values is sensed using the plurality of physiological sensors and the plurality of pathological sensors or using a smart phone of the patient. The body of the patient is scanned using a robotic arm. The data sensed by the sensor is then identifies a set of anomalies and send the set of anomalies to cloud server. A cognitive engine present on the cloud server is then diagnoses a disease using cloud computing and send the report to caregiver and doctor. According to another embodiment, a method is also provided for automated monitoring the health of the person using the above mentioned system.

Abstract: A device for obtaining physiological information including plethysmographs of a medical patient and detecting a condition of pneumonia. The portable pneumonia screening device may include one or more sensors configured to obtain physiological information. The pneumonia screener may provide for methods of selecting and interfaces to assist selecting a patient's age group. The screener may match a selected age group from a set of programmed threshold level of oxygen saturation, respiratory, pulse rate, or other physiological parameters to assist pneumonia diagnosis. The pneumonia screener may provide one or more visual and/or audio stimuli, such as an animation, sound or music. The visual and/or audio stimuli may indicate initialization, diagnostic in progress, completion, or other events or progress of events. In some embodiments, the visual and/or auditory stimuli may be used to soothe or intrigue the patient such that patient agitation is reduced during the screening process.

Abstract: The present invention provides a method for analyzing answers to questions in an electronic document. The method comprises reading, into a memory, the user's answers to the questions and a user's answer history information from the user's answers, wherein the user's answer history information is collected at the time the questions are answered. The method further comprises inputting, into a machine learning model, the user's answers to the questions and the user's answer history information from the user's answers to output an analysis result, wherein the machine learning model is trained, in advance, using one or more sets of training data, each set of training data comprising one or more answers to one or more questions and answer history information from the one or more answers, and a correct result which is obtained by manually judging the one or more answers to the one or more questions.

Abstract: The present disclosure includes a medical monitoring hub as the center of monitoring for a monitored patient. The hub includes configurable medical ports and serial ports for communicating with other medical devices in the patient's proximity. Moreover, the hub communicates with a portable patient monitor. The monitor, when docked with the hub provides display graphics different from when undocked, the display graphics including anatomical information. The hub assembles the often vast amount of electronic medical data, associates it with the monitored patient, and in some embodiments, communicates the data to the patient's medical records.

Abstract: In an example implementation according to aspects of the present disclosure, a method may include receiving a first data value from a sensor coupled to a headset. The first data value indicates a condition indicative of condensation local to the sensor. A first delta based on the first data value and a predetermined condensation data value is determined. Based on the first delta surpassing a first threshold, a cooling device coupled to the headset is deactivated.

Abstract: The invention relates to a system and method of implementation of artificial intelligence and tomography imaging to determine the biomechanical degradation or degeneration in human cornea. The invention relates to a combination tool using artificial intelligence and tomography imaging to map the region of degeneration in the cornea. The method of artificial intelligence and corneal tomography imaging includes analysis of changes in the structure of the cornea, constructing the 3D volumes using corneal tomography, meshing the 3D volumes with the elements for biomechanical simulations by using finite element modules, application of artificial intelligence to determine the region of biomechanical degeneration in cornea. The combination tool of the invention is effective in predicting the progression of the disease by analyzing the chronic steepening of the cornea by quantitating the parameters such as increase in curvature, aberrations of the cornea.

Abstract: An action notification device acquires uttered voice data indicating an action of a user and being uttered by the user; detects a moving motion of the user; detects a stationary motion of the user; determines whether a predetermined time has elapsed in a state where the user is stationary; and notifies the user of contents of the action of the user based on the uttered voice data when it is determined that the predetermined time has elapsed in the state where the user is stationary.

Abstract: The present invention relates to a system used in remote laboratory assays, having cartridge (C) with a reagent strip (TR) a reader (L) with a dedicated hardware (HDL) and a dedicated software (SDL), a local remote hardware (HRL) with a dedicated software (SDHL), an external served hardware (HES) with a data base (BD) and a dedicated software (SDS) and an external hardware with an access interface (HEIA) with an interface software connected to the Internet (SICI) and dedicated software (SDIA), which reads the parameters of the cartridge for collecting various types of biological samples and transmits data, allowing the data to be accessed remotely, with the advantages of being easy to use, of optimizing workflows, of being easy for users to learn, of allowing new exams to be easily and conveniently recorded, of being modular, compact, smaller, portable, ergonomic, user-friendly, intuitive, more practical and less expensive.

Abstract: A system for predicting a conversion rate relating to targeted location events for a test campaign includes one or more campaign databases configured to store campaign parameters of a set of historical campaigns. The system further includes a feature engineering module configured to construct a training feature space corresponding to the set of historical campaigns, and to determine a set of labels including a respective conversion rate for each respective historical campaign of the plurality of historical campaigns. The system further includes a model training module configured to machine train a conversion rate prediction model using the training feature space and the set of labels.

Abstract: Devices, systems and methods are disclosed for improving facial recognition and/or speaker recognition models by using results obtained from one model to assist in generating results from the other model. For example, a device may perform facial recognition for image data to identify users and may use the results of the facial recognition to assist in speaker recognition for corresponding audio data. Alternatively or additionally, the device may perform speaker recognition for audio data to identify users and may use the results of the speaker recognition to assist in facial recognition for corresponding image data. As a result, the device may identify users in video data that are not included in the facial recognition model and may identify users in audio data that are not included in the speaker recognition model. The facial recognition and/or speaker recognition models may be updated during run-time and/or offline using post-processed data.

Abstract: A computer implemented method for enabling data coherency between a first data source and a second data source of different structure may be provided. The first data source has a first format and a related first log file. Similar conditions apply to the second data source. The method comprises also determining a first entry in the first log file at which the data have a semantic consistency and storing this as first read barrier. The same applies for an entry in the second data source. Additionally, the method comprises building a third data set derived from data of the first data source and data of the second data source and being coherent with them, using data from the first data source up to the first read barrier and data from the second data source up to the second read barrier.

Abstract: A physiological status monitoring device includes a monitoring module and a fixing module. The monitoring module includes a first housing configured to be arranged at a first side of a flexible object, a monitoring unit arranged in the first housing for monitoring a physiological status of a human body, a first processing unit electrically connected to the monitoring unit for controlling operations of the monitoring unit, and a first magnetic fixing unit connected to the first housing. The fixing module includes a second housing configured to be arranged at a second side of the flexible object, and a second magnetic fixing unit connected to the second housing. Wherein, the first magnetic fixing unit and the second magnetic fixing unit are configured to hold the first housing and the second housing on the flexible object by magnetic force.

Abstract: A multi-sensor interactive patient care pod is disclosed herein. In one embodiment the system may comprise a telemedicine pod having a plurality of physiological sensors and an integrated computing device allowing medical practitioners to remotely gather increased patient information and provide advanced levels of healthcare and service. The system may have sensors for measuring body weight, heart rate, body temperature, blood pressure, breathing rate, oxygen saturation, and any other appropriate parameters. The multi-sensor interactive patient care pod may comprise an enclosed pod in a first orientation, and may open by the combined sliding of its front cowling and lifting of its top cowling to allow patient ingress and egress. The system may further comprise a mobile device that can be placed in any appropriate location, and may further integrate smart technologies such as machine learning, voice and face recognition, self-cleaning, self-driving, and self-locking technologies.

Abstract: A system and method for transmission of a signal for a powered assistive device has a sensor node with a wireless transmitter adapted for digitally transmitting a transmitted signal, the sensor node adapted for receiving and monitoring a sensor signal from a sensor attached to a user, and a master node with a controller and a wireless receiver for receiving the transmitted signal from the wireless transmitter. The master node processes the transmitted signal and communicates a control signal to the powered assistive device. The wireless transmitter transmits the transmitted signal at a first rate when the wireless transmitter adapted to transmit the transmitted signal at a first rate when the sensor signal is indicative of the rest state and to transmit the transmitted signal at a second rate when the sensor signal is indicative of the active state, the second rate being greater than the first rate.

Abstract: A system of generating a pre-operative assessment of a patient includes an assessment system configured to communicate with client electronic devices. The system receives patient information pertaining to a patient, uses the patient information to access one or more medical images associated with the patient, performs one or more image processing techniques on the one or more medical images to identify measurements pertaining to an internal bodily structure of the patient, identifies one or more implant components for the patient, determines whether the one or more implant components are currently stocked, in response to determining that the one or more implant components are not currently stocked, automatically generates and placing an order for the one or more implant components that are not stocked, generates a pre-operative assessment for the patient, and causes the assessment to be displayed on a display device of a client electronic device.

Abstract: Methods and systems for treatment of feeding disorders in individuals by a multi-disciplinary team comprising medical, behavioral, nutritional, and oral-motor skill professionals and/or specialists. For example, in one embodiment, a subject may go through treatment that comprises four phases/process: screening, assessment, intervention, and discharge. The screening process may determine the subject's eligibility for the treatment. The assessment process may establish a baseline from which the specific treatment is determined. The intervention process generally implements the treatment through daily “doses” of treatment meal sessions. The discharge process may ensure that the treatment gains made during the intervention phase are carried into the subject's daily life.

Abstract: The present invention relates to a device, system and method for obtaining a vital signal of a subject. To achieved increased robustness against motion, the device comprises a decomposition unit (12) for performing a spectral decomposition of at least two photoplethysmography detection signals being related to a physiological property of the subject and allowing extraction of a vital sign of the subject to obtain two or more spectral components of the detection signals. A weight is determined per spectral component based on an estimate of the relevance of the respective spectral component to the vital sign, derived from a characteristic of said spectral component.

Abstract: There is provided a system and method for classifying time series data for state identification. The method including: training a machine learning model to classify occurrences of the state; receiving a new time series data stream; determining whether a current sample in the new time series data stream is an occurrence of the state by determining a classified feature vector, the classified feature vector determined by passing the current sample and samples in at least one continuous sampling window into the trained machine learning model, each continuous sampling window including a plurality of preceding samples from the time series data, an epoch for each respective continuous sampling window determined according to a respective exponential decay rate; and outputting the determination of whether the current sample is an occurrence of the state.

Abstract: A method, computer program product, and system includes a processor(s) configuring a sensor(s) (first sensor(s)), to capture data related to an emotional state of an individual and a sensor(s) (second sensor(s)), to capture data related to an environment of the individual. The processor(s) obtains, over a pre-defined period of time, data from the sensors and utilizes data from the second sensor(s) to identify activities in which the individual participated. The processor(s) obtains, from a scheduling resource, a schedule of activities scheduled for the individual. The processor(s) generates a record for each activity. The processor(s) determines, based on data from the first sensor(s) and the record for each activity, emotional states of the individual throughout each activity of the identified activities. The processor(s) generates a rule representing relationships between events during each activity and emotional state of the participant and recommends a schedule of future activities.

Abstract: Two virtual reality (VR) systems are calibrated to share a common reference frame using a calibration step in which multiple VR users clap each other's hands. As two players do so, spikes are detected in the motion data when their hands come in contact. The spikes are used to effect timing synchronization of the disparate systems to align the motions.

Abstract: A monitoring system and method for early detection of fall risk. A rise-state of a subject occupying a bed is detected. In response to the detection of the rise-state, blood pressure measurement of the subject is triggered. An alarm when the measured blood pressure is not within a selected range of blood pressures.

Abstract: A technique relates to an imaging apparatus. Extensions are coupled to a support structure, the extensions being spaced a predefined distance from one another, the extensions having a length that protrudes from the support structure. Light sources are coupled to the extensions such that the light sources are positioned to irradiate a scalp. Sensors are coupled to the extensions, the sensors being positioned at an angle to capture images of the scalp having been irradiated by the light sources.

Abstract: An estimation method and device comprising at least one feature amount is calculated with sound data uttered by a subject, a degree of a psychosomatic state of the subject is calculated based on the calculated feature amount, and the psychosomatic state of the subject are estimated based on the calculated degree.