Disclosed are systems and techniques for determining biometrics of a user of a bed system based on force data. A bed system can include a support element having at least one leg, at least one force sensor of the at least one leg, the force sensor being configured to sense a force applied to the bed system or the leg, and a controller. The controller can receive at least one force data-stream from the at least one force sensor, the at least one force data-stream representing a force sensed by the force sensor, determine a biometric parameter of a user on the bed system at predetermined time intervals based on processing the at least one force data-stream, generate an aggregate biometric parameter of the user based on aggregating the biometric parameters for the predetermined time intervals, and return the aggregate biometric parameter of the user.

The present invention relates to chest radiography. In order to improve image quality and consistency, there is provided a breathing status determination device, which comprises an input unit, a processing unit, and an output unit. The input unit is configured to receive a sequence of depth images that is continuously captured with a sensor having a field of view covering a torso of a patient positioned for a chest radiography image examination. The processing unit is configured to analyse the received sequence of depth images to determine a change of depth values inside one or more region-of-interests (ROIs) overtime that represents a respiratory motion of the patient, and to determine a breathing signal based on the determined change of depth values inside the one or more ROIs over time. The output unit is configured to provide the determined breathing signal.

A method, a sensor and a system for the sensor includes a device for processing the measurement signal of the sensor, such as measuring electronics, and a device for communicating measurement results and/or data relating to the measurement results for further processing. The sensor is a radar-based sensor, such as a frequency-modulated continuous-wave MIMO radar-based sensor, configured to detect persons in the monitored area and to measure and detect movement, such as breathing frequency, location, velocity and/or shape of the monitored person. The sensor or a monitoring system connected to the sensor is configured to determine at least one of the following states of the person: breaks or interruptions with breathing of the monitored person, e.g. in order to recognize sleep apnea, and/or immobility of the monitored person, e.g. in order to avoid bedsores or pressure ulcers, and the sensor and/or the monitoring system is configured to provide an alarm based on the determined state of the person.

A method, a sensor and a system for the sensor includes a device for processing the measurement signal of the sensor, such as measuring electronics, and a device for communicating measurement results and/or data relating to the measurement results for further processing. The sensor is a radar-based sensor, such as a frequency-modulated continuous-wave MIMO radar-based sensor, configured to detect persons in the monitored area and to measure and detect movement, such as breathing frequency, location, velocity and/or shape of the monitored person. The sensor or a monitoring system connected to the sensor is configured to determine at least one of the following states of the person: breaks or interruptions with breathing of the monitored person, e.g. in order to recognize sleep apnea, and/or immobility of the monitored person, e.g. in order to avoid bedsores or pressure ulcers, and the sensor and/or the monitoring system is configured to provide an alarm based on the determined state of the person.

In one embodiment, an assessment system includes an electrical stimulation device configured to generate current, stimulation electrodes configured to apply the current generated by the electrical stimulation device to a neck of a subject at a location that results in stimulation of a phrenic nerve of the subject, a movement sensor configured to sense movement of an upper abdomen of the subject caused by twitching of a diaphragm of the subject responsive to the stimulation of the phrenic nerve, and a controller configured to receive data sensed by the movement sensor, analyze the received data to evaluate the activity of the diaphragm, and generate an assessment of the subject's respiratory function or phrenic nerve.

A biological condition measurement apparatus has: a transmitting section that transmits a transmission signal in a frequency band equal to or higher than a millimeter wave band at predetermined time intervals; a receiving section that receives a plurality of reflection signals generated by reflection of the transmission signal on a plurality of measurement subjects; a measuring section that measures a plurality of times of flight from the transmission of the transmission signal by the transmitting section until the reception of the plurality of reflection signals by the receiving section; and an identifying section that identifies a biological condition of each of a plurality of the measurement subjects on the basis of a mode of change of times of flight represented by a plurality of pieces of time-of-flight data representing times of flight that fluctuate in a time range equal to or lower than a first threshold.

A device for treating chest wall injuries, including rib fractures, flail chest injuries or surgical incisions is described herein. The device includes a localized airtight compartment external to the chest wall and fully covering the area of injury, and is capable of varying the pressure within the compartment, and providing dynamic real-time counter forces that act reciprocal to the intrathoracic pressure changes that occur during ventilation. In a preferred embodiment, the device has the capability of sensing the patient's chest wall motion created by ventilation, and includes a pressure control component capable of varying the pressure within the airtight compartment such that it opposes pressure changes within the chest. The apparatus would be particularly useful in preventing the paradoxical movement of flail chest injuries. The device would also lessen pain experienced by patients with thoracic injuries such as rib fractures and post operative suffering.

A system, apparatus, and method using multiple complementary sensors for the monitoring and wireless communication of several respiration characteristicsthat is badge-size, wearable on the outside of clothing, and non-invasive.

The disclosed technology provides solutions for protecting the health of ride-sharing passengers by detecting passenger illnesses, and taking precautions to safely address potentially exposed vehicles. A process of the disclosed technology can include steps for: collecting sensor-data corresponding with one or more AV passengers, determining a likelihood that at least one of the AV passengers is suffering from a physical illness, and transmitting a wellness notification to a fleet management system if the likelihood exceeds a predetermined threshold. Systems and machine-readable media are also provided.

An elongation sensor, which includes an elastic, electrically insulating core, and at least two resistive elements arranged helically around the elastic core in opposite directions and in contact with each other. A wearable article including a flexible support, at least one elongation sensor arranged on the flexible support so as to have a length varying when a wearer of the wearable article breathes or when muscles of the wearer are contracted or relaxed, and at least one flexible strip arranged on the flexible support. Also, detecting breathing of a subject with the wearable article.