A method is disclosed including receiving from a user a request to associate an avatar in a computer-implemented virtual world with a wearable device, creating an association between the avatar and the wearable device in response to the request, and receiving from the wearable device activity metric data for the user generated by a sensor of the wearable device. The activity metric data is generated by the wearable device in response to the wearable device sensing the user performing an activity. The method further including determining based on the received activity metric data a type of the sensed activity, determining at least one attribute of the avatar that corresponds to the determined type of the activity, determining an amount to adjust the at least one attribute based on the received activity metric data, and adjusting the determined at least one attribute of the avatar by the determined amount.

A movement-assessment device and methods for using the testing device includes a peg board device having a plurality of apertures on a top surface, and a plurality of photo-optical gate sensors. A computing device, comprising a touchscreen interface, communicates with the peg board device.

An interactive gaming system is disclosed. The system comprises at least one sensor that conveys information to the system about the physical, intellectual, mental, emotional, psychological or other type of ability of a user. The system uses the information to assess the existence and extent of a disability, and then implements a change to an aspect of the gaming environment, thus optimizing the gaming experience for the game player by accounting for the game player's disabilities.

Aspects include methods, systems and computer program products for evaluating a patient for a movement disorder. The method comprises defining a patient to be evaluated and deploying a unmanned aerial vehicle (UAV) to a location of the patient. The UAV includes a patient evaluation feature and at least one sensor operably coupled to the patient evaluation feature. The UAV is positioned relative to the patient to measure a patient motor characteristic. The patient motor characteristic is measured with the at least one sensor. A movement disorder is determined based at least in part on the measured patient motor characteristic. A signal is transmitted based on the detecting the movement disorder.

A holding instrument includes a holding portion that holds a measurement apparatus. The measurement apparatus includes a gyro sensor that detects change in a measured part of a user and a controller that performs a process of measuring biological information of the user based on output of the gyro sensor. The holding instrument is embraced by the user during use while the holding portion is holding the measurement apparatus.

The systems and methods described herein are directed towards collecting and recording sensor data pertaining to physical contact experienced by players in a contact sport (e.g., football). The data can be collected and recorded through the use of one or more sensors worn by the player. In some cases, the sensor data can be associated with in-game video recordings of physical contact experienced by the players. Information about the physical contact can be displayed for users to view via a graphical user interface. Warnings may also be provided.

The present invention relates to methods of using a therapeutic system. In particular, the present invention relates to procedures and methods of using a system having hardware, software, and appliance components for assessing and entraining a non-nutritive suck (NNS) pattern in a patient. The methods include configuring the hardware and software systems to receive data from an orofacial stimulation appliance and to generate a precise therapeutic pulse profile that is actuated as a tactile stimulus. The methods also include collecting data using the orofacial stimulation appliance and delivering the tactile stimulus via the orofacial stimulation appliance to entrain an organized NNS pattern.

A system and method for a therapeutic apparatus that includes an external casing of a first therapeutic apparatus, wherein the external casing comprises of a plush body, the external casing comprising at least one compartment; a therapeutic module system that comprises of a set of interaction devices and a wireless communication system, wherein the therapeutic module system may be removably oriented into the at least one compartment; the set of interaction devices comprising of: sensing inputs that comprise of a auditory sensing system, a haptic sensing system, an olfaction sensing system, and other biosensing systems, and output systems that comprise of at least an auditory feedback and haptic feedback systems; and a processing system that comprises configuration to assess the state of a subject through the sensing inputs and control the output systems in response to the sensing inputs.

The present invention relates to methods of using a therapeutic system. In particular, the present invention relates to procedures and methods of using a system having hardware, software, and appliance components for assessing and entraining a non-nutritive suck (NNS) pattern in a patient. The methods include configuring the hardware and software systems to receive data from an orofacial stimulation appliance and to generate a precise therapeutic pulse profile that is actuated as a tactile stimulus. The methods also include collecting data using the orofacial stimulation appliance and delivering the tactile stimulus via the orofacial stimulation appliance to entrain an organized NNS pattern.

A system (100) and a method for analyzing a physiological condition of a user. The system (100) comprises one or more sensors (102a, 102b) to measure one or more parameters including temperature and relative humidity from the user's skin and/or a corresponding temperature and relative humidity from the user's environment via an air gap. A signal representative of the measured parameters is generated. The system (100) also includes at least one transceiver (108) communicably connectable to the sensing unit (102) via one or more communication interfaces, wherein the transceiver (108) is configurable to analyze one or more received signals to initiate one or more events based on the analyzed parameters of the user. The system (100) further includes a processing unit (110) to receive one or more signals from the transceiver (108) and uses artificial intelligence and machine learning techniques to alert users of an impending physiological condition.