Systems and method for positioning a neonate within an imaging device are provided. A capsule incubator, a cart, and a docking incubator are used to move a baby between an imaging device and a incubator, such that a baby can be imagined without having to move the baby from its environment.

Methods, apparatus and systems for wireless monitoring and tracking are described. In one example, a described method of a wireless monitoring system comprises: transmitting a wireless signal that is impacted by a wireless multipath channel in a venue and a modulation of an object undergoing a motion in the venue, to obtain a set of channel information (CI) of the wireless multipath channel; performing a monitoring task by monitoring the object and the motion; determining a plurality of admissible system states of the wireless monitoring system, wherein each admissible system state is associated with a respective setting of at least one of: the wireless signal, a series of sounding signals in the wireless signal, or the monitoring task; choosing one of the admissible system states to be a system state of the wireless monitoring system based on the monitoring task; and applying a setting associated with the chosen admissible system state to the wireless monitoring system.

An infant sleep device may include a platform for supporting an infant, a base upon which the platform is supported, and one or more weight sensors positioned to measure weight of an infant positioned on the platform.

An optical image physiological monitoring system with radar detection assistance is disclosed. The system receives a visible-light image of a body and then identifies a chest feature of the visible-light image and determines a position of the chest feature. A processing unit controls a radar detector to move to aim a chest of the body. After then, a plurality of visible-light images and distance values from the radar detector are received continuously to determine whether the positions of the chest features are in a position change rage. If yes, a breathing frequency of the body is determined by the distance values received simultaneously.

A method for monitoring health of a person by a health monitoring system includes: measuring movement data of a person using a wearable health monitoring device, determined whether the person is in a deep sleep mode based on the movement data, automatically measuring a respiratory rate of the person that is in a deep sleep mode, determining that the person is in one of a plurality of respiration zones, measuring at least one of a body temperature, an ambient temperature, a sleeping position, a smoke or carbon monoxide level, a video, and images of the person, and automatically producing an alarm signal if a predetermined criterion is met based on the respiration zone and at least one of the body temperature, the ambient temperature, the smoke level, the carbon monoxide level, a sleeping position, or the images of the person.

A method for monitoring health of a person by a health monitoring system includes determining if a person wearing a wearable health monitoring device is sleeping or not based on movement data, measuring sleep movements of the person to determine whether the person is in a deep sleep mode when the person is determined to be sleeping, measuring bio-vital signals of the person and at least one of a posture of the person or environmental parameters when the person is determined to be in the deep sleep mode, and automatically producing an alarm signal if a predetermined criterion is met based on the bio-vital signals and at least one of a posture of the person or the environmental parameters.

A platform system for remotely monitoring one or more behavioral event of at least one user is disclosed. The platform system includes at least one computer system having an internet connection and at least one web application, the at least one computer system having a memory for storing an array of contextual data relating to the at least one user; at least one wearable device having a processor and being communicatively connected to the at least one user and being in electronic communication with the at least one computer system, the at least one wearable device having one or more sensors for detecting physiological data of the at least one user, the at least one wearable device having a memory for storing an array of physiological data detected by the one or more sensors; wherein the processor of the at least one wearable device determines a behavioral event relating to the at least one user based on the array of physiological data in view of the array of contextual data, the processor communicating the behavioral event to the computer system; and wherein the computer system provides a notification relating to the behavioral event.

A system and method for providing remote telemedicine, remote rehabilitation or other training is disclosed. Tracking remote physical therapy or training using asynchronous or synchronous feedback between scheduled sessions, where the scheduled sessions can be performed in person or remotely provide for safe and expeditious treatment in situations where in-person sessions cannot be safely conducted and/or when other situations exist making virtual sessions desirable. Tracking subject process between sessions is also accomplished by manual data entry, wearable sensors or video capture by a patient computing device.

Various embodiments of a method and a device for monitoring the health of an infant are disclosed. A wearable infant monitoring device comprising a sensing module 170 comprising: a heart rate sensor 150 configured to provide output data corresponding to heart rate of the infant wearing the infant monitoring device; a microcontroller 100 configured to receive and transmit output data; a vibration motor 140 configured to vibrate whenever the heart rate of the infant falls below a customized range; a BLE module 110 in operational unity with the microcontroller that transmits heart rate data to a user on an individual computing device application 120; a computer device application configured to receive and process the output data and generate the infant's heart rate. A method of monitoring an infant's heart rate using the wearable heart rate monitoring device comprising the heart rate sensor 150 collecting output data, wherein the output data provides information about the infant's heart rate; the microcontroller 100 receiving and transmitting the output data to the BLE module; the BLE module 110 transmitting the output data directly to a user computing device application, which computing device application processes the output data and generates the infant heart rate.

System comprising of a simulating flow control breastfeeding where a tube linking a refillable housing chamber to a prosthetic nipple, an analyzing module linked to a sensor to determine a physical, physiological, or emotional state of the infant/user by mapping the received input parameter with a pre-stored set of parameters from the parameter store via the analyzing module and dynamically interact with the infant/user based on a determined output to promote a non-latching simulating breastfeeding experience to prevent bruised, sore nipples or engorged breasts.