A robot according to the present disclosure comprises: a microphone; a camera disposed to face a predetermined direction; and a processor configured to: inactivate driving of the camera and activate driving of the microphone, if a driving mode of the robot is set to a user monitoring mode; acquire a sound signal through the microphone; activate the driving of the camera based on an event estimated from the acquired sound signal; confirm the event from the image acquired through the camera; and control at least one constituent included in the robot to perform an operation based on the confirmed event.

A system that includes an electronic baton device with motion and capacitive sensors. The system includes a processor and non-tangible computer readable media having stored programming instructions thereon that, when executed, cause the processor to receive sensor data from the motion and capacitive sensors, and determine an exchange zone to exchange the baton device between an incoming runner and an outgoing runner of a relay, based on the sensor data. The processor determines relay race metrics for each athlete of the relay team, baton metrics associated with each athlete, a usage efficiency in the exchange zone, and a baton transition metrics. The processor selectively displays on a display device the relay race metrics for each athlete, the determined baton metrics, the determined usage efficiency in the exchange zone, and the determined baton transition metrics in one or more selected graphical user interfaces.

According to certain embodiments, a wearable electronic device comprises: a housing; a first electrode and a second electrode disposed on the housing; an A/D converter connected to the first electrode and the second electrode; a pulse generator connected to the first electrode and the second electrode; and a processor operatively connected to the A/D converter and the pulse generator; wherein the processor is configured to: control the pulse generator to output a series of pulse waves to the first electrode when an external object is in contact with the first electrode; and controlling the A/D converter to obtain biometric information from the first electrode and second electrode in response to outputting the series of pulse waves.

Optoelectronic modules operable to measure proximity independent of object surface reflectivity and, in some implementations, operable to measure characteristics (such as surface reflectivity or absorptivity) of stationary or moving objects are disclosed. The optoelectronic modules are operable to determine, for example, pulse rate, peripheral blood circulation, and/or blood oxygen levels of moving objects, such as the appendage of a user, in some instances. The optoelectronic modules can be used to measure peripheral blood circulation, for example, when a user of the optoelectronic module is engaged in physical activity, such as walking, running or cycling.

Disclosed are one or more proximity sensors. At least one of the proximity sensors includes a first dielectric layer, an electrically conductive layer, and an electrode. The first dielectric layer includes an inner surface and an outer surface. The electrically conductive layer is positioned proximate to one of the inner surface or the outer surface of the first dielectric layer. The electrode includes an outer surface. The outer surface of the electrode is positioned proximate the inner surface of the first dielectric layer. The outer surface of the electrode and the electrically conductive layer define a gap.

A human body sensing mat for sensing the movement of a human body, comprises: a substrate; a sensor array including a plurality of fiber sensors for generating signals according to a distance to a specific object, and disposed on the substrate; and a driving unit for applying a voltage to the sensor array, wherein the sensor array includes a plurality of sensing lines arranged in parallel in a first direction, and regarding the plurality of sensing lines, a first distance between neighboring sensing lines connected to different electrodes is greater than a second distance between neighboring sensing lines connected to the same electrode. The human body sensing mat can analyze user's movements and biometric signals regardless of the user's posture.

The face mask with temperature display is a filtering face mask with an integrated temperature display for displaying a measured temperature of the wearer. The face mask includes a filtering sheet having opposed front and rear faces, and at least one strap attached to the filtering sheet for securing the filtering sheet over a portion of a wearer's face in a manner similar to that of a conventional filtering face mask. A visual display is secured to the front face of the filtering sheet and a temperature sensor is secured to the rear face of the filtering sheet. The temperature sensor is in communication with the visual display, such that the visual display can display the measured body temperature of the wearer.

The invention relates to a toilet device for the measurement of micturition parameters, the toilet device comprising a housing that has a housing opening for receiving urine and a capacitive sensor for the time-dependent, contactless measurement of micturition parameters. The invention also relates to a method for the contactless measurement of micturition parameters in a toilet device, said method being carried out more particularly using the toilet device according to the invention.

A method for adjusting the operation of a surgical instrument using machine learning in a surgical suite is disclosed.

Certain embodiments of the present disclosure relate to a monitoring device that includes a housing, contactless sensors coupled to the housing, and a processing device disposed in the housing. In at least one embodiment, the monitoring device is configured to measure pulse wave velocity in a subject.