A localized sound projection system can coordinate the sounds of speakers to simulate the placement of an auditory cue in a 3D space. The system can include a plurality of speakers configured to output auditory signals and a sound localization controller configured to control the plurality of speakers to coordinate the auditory signals to simulate an origination location of a patient alarm. The sound localization controller can determine adjusted auditory signals and control a plurality of speakers to output the plurality of adjusted auditory signals. A method for dynamically controlling speaker settings in a medical environment can include determining volume settings corresponding to a speaker, monitoring a level of ambient noise corresponding to a room of a patient, controlling the volume settings of the speaker to reduce or increase a sound level output of a speaker. A patient monitoring system can be configured to physically manipulate medical devices in response to audible commands. The system can receive a plurality of vocal commands from a user and can manipulate various settings after confirmation from a user.

A system and method for automatically requesting assistance for a user experiencing a medical emergency is disclosed. The system includes a user device with a sensor to detect sensed information. Based on the sensed information the user device can determine if the user is experiencing a medical emergency. The user device can communicate with nearby devices over one or more networks and send information about the medical emergency to the nearby devices. The information can include the type of medical emergency, the location of the user experiencing the medical emergency, and any instructions for providing the user with assistance.

Aspects herein are directed to an apparel thermo-regulatory system that actively heats or cools a wearer. The apparel thermo-regulatory system comprises an apparel item, a dimensionally stable frame comprising at least one aperture that is affixed to an outer-facing surface of the apparel item at a predetermined location, an absorbent material applied to an exposed face of the dimensionally stable frame, and at least one thermoelectric module that is releasably positioned within the aperture of the dimensionally stable frame.

Provided is a safety checking system that can accurately determine an abnormality of a user or a rearing animal using a lockable space section and can respond to an abnormality, if occurs, more safely, more reliably, and promptly. This invention includes: obtaining, via a management device, sensing data from a sensor detecting biological information of the user or rearing animal using the lockable space section; detecting, via the management device, a significant difference between the sensing data and sensing data obtained in a normal condition or a threshold thereof; requesting, upon detection of the significant difference as necessary, dispatch of an emergency agency to the lockable space section; confirming, via the management device, whether the emergency agency having received the request has arrived at the lockable space section; and causing the management device to issue a signal for carrying out emergency unlocking of a lock in the lockable space section.

A data processing system comprising a processing device configured to collect sets of sensed data representing motion characteristics of a user's gait at a first time and at a second time subsequent to the first time, to process each set of sensed data to form a respective information set dependent on the user's gait at the first and second times, and to compare the first information set with one of (i) the second information set and (ii) a predetermined reference data set in accordance with a predetermined algorithm to identify a condition or change in condition of the user.

Technologies for monitoring a health-risk condition of a user include a virtual reality compute device having one or more near infrared (NIR) sensors. The virtual reality compute device presents a virtual reality (VR) presentation to the user. The virtual reality compute device produces sensor data through the one or more NIR sensors that is indicative of a heart rate of the user and a blood pressure of the user while the VR presentation is presented to the user. The virtual reality compute device determines whether the user is in a health-risk condition based on a comparison of the heart rate of the user to a heart rate safety threshold and a comparison of the blood pressure of the user to a blood pressure safety threshold. The virtual reality compute device performs a health-risk condition response in response to a determination that the user is in the health-risk condition.

A sensor interface is configured to receive a sensor signal. A transmitter generates a transmit signal. A receiver receives the signal corresponding to the transmit signal. Further, a monitor interface is configured to communicate a waveform to the monitor so that measurements derived by the monitor from the waveform are generally equivalent to measurements derivable from the sensor signal.

A system and a method for predicting kinesthetic outcomes from observed position, posture, behavior or activity of an individual 1602, 1702. The system uses kinesthetic activity sensors 102, 104 each collecting one or more of audio, video, or physiological signals and capturing the activity of the individual or an ambient environment of the individual. These signals are delivered into a computer system 106 implementing a learning routine 108 which constructs one or more personalized kinetic state models 1510 of positional states for the individual and transitions between the positional states, and further develops one or more customized multi-dimensional prediction models 1500 for the individual and uses the multidimensional prediction models to predict behaviors, activities and/or positional changes likely to occur in the future, and provides notice of predicted unsafe or undesired outcomes.

An integrated headset communications system is presented. The system includes a curved headband. The system also includes a left-hand side headphone. The system further includes a right-hand side headphone. The system includes external speakers on right-hand side and left-hand side headphones. The system also includes internal speakers on right-hand side and left-hand side headphones. The system further includes two detachable rechargeable battery packs. The system includes a background noise cancellation mechanism. The system also includes a plurality of proximity sensors positioned on the system. The system further includes an automatic volume control safety module. The system includes a plurality of photocells positioned externally on the curved headband. The system also includes a plurality of flashlights and flashing lights positioned externally on the curved headband. The system also includes a data processor. The system further includes a removable system remote controller.

A system for monitoring animal vitals can include a housing, a controller and one or more sensors for sensing vital signs. The housing can be configured to couple to one or more locations on an animal. A system can be adapted for monitoring two or more vital signs simultaneously and for conveying vital sign information to a user. A system can be adapted for alerting a user to the presence or absence of one or more conditions. A system can include a plurality of sensor units and can be adapted for monitoring a plurality of patients simultaneously.