Methods and systems for selective image capture based on multi-modal sensor input for a wearable device. Systems comprise a first sensor, a second sensor, and a wearable device. The first sensor is configured to capture a first image, and the second sensor is configured to collect motion data, the motion data corresponding to a relative motion between the user and the wearable device, the relative motion of the wearable device in the environment, or the motion of a body part of the user. The wearable device comprises: a communication module configured to wirelessly transmit the first image to a receiving device; and a processor configured to detect a trigger event based on the motion data collected by the second sensor, the processor further configured to initiate capture of the first image by the first sensor or transmit the first image to the receiving device by the communication module upon detection of the trigger event.

A method includes imaging a first graybody with a focal plane array (FPA), wherein the first graybody has a first emissivity, and imaging a second graybody having a lower emissivity than the first graybody. The method includes using data captured while imaging the first and second graybodies to perform non-uniformity correction (NUC) of the FPA.

The application provides an ear thermometer with a probe cover ejection device. The ear thermometer comprises a holding body and a measuring assembly disposed at one end of the holding body, which comprises a probe, a rotating member, and a socket. The rotating member includes a ring cover with an opening formed in a middle of the ring cover, at least one first abutting portion axially extended from a lateral side of the ring cover, and a lever portion radially extended from the lateral side of the ring cover. The socket includes a circular bottom surface and a closed section and an open section defined on a periphery of the circular bottom surface, a side wall surface vertically provided on the closed section, an accommodating space sandwiched between the side wall surface and the circular bottom surface, and at least one second abutting portion formed on the circular bottom surface. In this way, the dual motions of the radial and axial directions can be used to ensure that the probe cover can be reliably ejected and removed from the probe.

A substrate treatment method in accordance with an exemplary embodiment includes: heating a substrate, for a substrate treatment process, so that a temperature of the substrate reaches a target temperature; calculating the temperature of the substrate using a sensor located facing the substrate while heating the substrate; and controlling an operation of a heating part configured to heat the substrate according to the temperature calculated from the calculating the temperature, wherein the calculating the temperature comprises: measuring a total radiant energy (E.sub.t) radiated from the substrate using the sensor; calculating a corrected total emissivity (ε.sub.t0) by applying a correction value for correcting the total emissivity (ε.sub.t) which is the emissivity of the radiant energy (E.sub.t); and calculating the temperature (T.sub.s) of the substrate using the total radiant energy (E.sub.t) and the corrected total emissivity (ε.sub.t0).

The present invention discloses a wearable device with combined sensing capabilities, which includes a wearable assembly and at least one multi-function sensor module. The wearable assembly is suitable to be worn on apart of a user's body. The wearable assembly includes at least one light-transmissible window. The multi-function sensor module is located inside the wearable assembly, for performing an image sensing function and an infrared temperature sensing function. The multi-function sensor module includes an image sensor module for sensing a physical or a biological feature of an object through the light-transmissible window by way of image sensing; and an infrared temperature sensor module for sensing temperature through the light-transmissible window by way of infrared temperature sensing.

A cap for a thermometer having a probe configured to be placed in contact with a patients body or to be inserted into a body cavity of the patient and a temperature sensor includes a cap housing, a proximity sensor and a proximity sensor electrical conductor. The cap housing is configured to selectively connect with and to be selectively detached from the thermometer and at least partially surround the probe of the thermometer when connected with the thermometer. The proximity sensor is connected with the cap. The proximity sensor electrical conductor is connected with the cap and electrically connected with the proximity sensor. A thermometer including the cap is also provided.

The present disclosure relates to a method and apparatus for storing a commodity and a computer readable storage medium. The method for storing a commodity includes: acquiring a temperature of the commodity; comparing the temperature with temperature thresholds to obtain a comparison result; and determining, according to the comparison result, whether to generate a prompt message for prompting to store the commodity in a thermal insulation device.

A sensor device, an automated transportation system and an operating method for the same are provided. The sensor device essentially includes a thermal sensor array for capturing a two-dimensional thermographic image within a sensing zone and a processing circuit for processing the image so as to obtain a thermal distribution within the sensing zone. The sensing zone is such as a cage of the automated transportation system. The thermal distribution depicts a distribution of one or more thermal sources for determining a status of the sensing zone. For example, the status is capable of indicating a number of people within the sensing zone and a personal status. Therefore, the automated transportation system is driven to operate the cage in response to a control signal that is generated according to a scenario responsive to the status.

A device for monitoring a heap of material, comprises circuitry for executing a plurality of functions. A region of interest function, in a thermal video stream captured by a thermal video camera, defines a region of interest covering the heap of material. A reference spatial property setting function, from pixels within a video frame of the thermal video stream, determines a spatial property of the heap of material; and sets the determined spatial property as a reference spatial property. A region of interest adjusting function determines a respective sample spatial property for regions in the thermal video stream; and adjusts the region of interest such that regions exhibiting a sample spatial property above a threshold are included by the region of interest. A temperature monitoring function over time and within the region of interest, monitors a temperature measure; and if it exceeds a predetermined threshold, generates an alarm event.

An apparatus for detecting and recognizing a gesture provided by an object. The apparatus includes an infrared emitter for emitting infrared signals to be at least partially reflected by the object, an infrared detector for detecting intensity of the infrared signals reflected by the object moving along an axis, a processor associated with the infrared detector for quantizing the intensity of the infrared signals within a measurement cycle into a signal intensity profile, and an adjuster configured to restrict field of detection such that the signal intensity profiles resulting from the object moving along a first axis, or a second axis, perpendicular to the first axis, can be distinguished.