Abstract: An image formation apparatus according to one or more embodiments may include: an apparatus main body that includes an image formation section configured to form an image on a medium; a fixation device that includes a fixation member configured to heat the medium and is attachable to the apparatus main body in a first direction; and a temperature detector including a lens, provided in the apparatus main body, and configured to detect a temperature of the fixation member through the lens. An optical axis of the lens is inclined with respect to the first direction.

Abstract: The present disclosure provides a forehead thermometer that displays different colors according to detected temperatures and a control circuit thereof, which belong to the technical field of forehead thermometers. The forehead thermometer includes a forehead thermometer body, wherein the forehead thermometer body comprises a housing, an indicator light, a liquid crystal display (LCD) screen comprising a backlight board which is adapted to light up in different colors according to different detected temperatures. The LCD screen is disposed on an upper end face of the housing, and the indicator light is disposed on a side of the housing, and wherein the indicator light is a transparent light guide body capable of guiding light, and an outer end face of the indicator light is located outside the housing; and a light guide plate capable of guiding the light emitted from the backlight board to the indicator light is fixedly disposed in the housing.

Abstract: An assembly of at least one radiation detector, at least one radiation emitter and a housing configured to be positioned inside the ear canal of a person or animal, the detector(s) and emitter(s) being provided in or on the housing, the emitter(s) being configured to emit radiation away from the housing and the detector(s) being configured to receive radiation directed toward the housing. No overlap may be provided between the field of view of the radiation detector(s) and the emitter(s), such as by providing a blocking element.

Abstract: A device for placement in contact with an eye of a user. The device includes at least one detector for measuring at least one property, and a signal processor for determining, based on the at least one property, whether the eye of the user is closed.

Abstract: A temperature measuring device includes at least one first distance sensing unit and a second distance sensing unit for outputting first and second distance sensing signals, respectively; a temperature sensing unit for outputting a temperature sensing signal; a display unit for displaying the temperature measurement value; and a micro processing unit for receiving the first and the second distance sensing signals, and then determining, according to the first and the second distance sensing signals, whether the display unit displays the temperature measurement value calculated according to the temperature sensing signal. As a result, the at least two distance sensing units are used to prevent the temperature measuring device from executing the temperature measurement when the sensing unit of the thermometer obliquely points to a to-be-sensed part of a to-be-measured target to cause a large measurement angle.

Abstract: An electronic device for measuring an ambient temperature (Tair) of the environment of an electronic device is described. It comprises at least one integrated infrared sensor, a blinded window preventing infrared radiation to directly impinge on the integrated infrared sensor and being in thermal contact with the environment as well as with a cover of the device resulting in the blinded window being at a surface temperature (Tsurface). The at least one integrated infrared sensor is adapted for sensing the temperature of the blinded window (Tsurface). The device also comprises at least one absolute temperature sensor for measuring a temperature of the at least one infrared sensor (Tsensor) itself, and a processing means for determining a temperature difference (?T) between the sensed surface temperature (Tsurface) and the temperature of the infrared sensor (Tsensor) and for calculating based thereon the ambient temperature (Tair).

Abstract: A gas sensor is used for determining a concentration of a predetermined gas in a measurement volume. The gas sensor comprises a light source and a detector arranged to receive light that has passed through the measurement volume. During a first measurement period, the detector is used to make a first measurement of an amount of light received in at least one wavelength band which is absorbed by the gas. The first measurement is compared to a predetermined threshold value. If the threshold is crossed, during a second measurement period the detector is used to make a second measurement of an amount of light received in at least one wavelength band which is absorbed by the gas. The concentration of said gas in said measurement volume is calculated using the first and/or second measurement.

Abstract: In one implementation, a multi-vital-sign smartphone system detects multiple vital signs from sensors such as a digital infrared sensor, a photoplethysmogram (PPG) sensor and at least one micro dynamic light scattering (mDLS) sensor, and thereafter in some implementations the vital signs are transmitted to, and stored by, an electronic medical record system.

Abstract: A device measures blood glucose levels, temperature, heart rate, heart rate variability, respiration, SpO2, blood flow, blood pressure, total hemoglobin (SpHb), PVi, methemoglobin (SpMet), acoustic respiration rate (RRa), carboxyhemoglobin (SpCO), oxygen reserve index (ORi), oxygen content (SpOC) and/or EEG of a human.

Abstract: An air conditioner includes an outdoor device and an indoor device. The indoor device includes a control unit, a storage unit, and an infrared sensor unit that detects a human by detecting infrared rays. The infrared sensor unit includes thermal-image acquisition elements that detect infrared rays to acquire thermal image data and a sensor control unit that controls the thermal-image acquisition elements. When receiving the thermal image data from the infrared sensor unit, the control unit determines whether a communication error has occurred in each of the thermal-image acquisition elements. The control unit sets a thermal-image acquisition element that has a number of error determinations equal to or larger than a certain number as a communication-error established element. The control unit does not acquire thermal image data from the communication-error established element.

Abstract: The invention discloses an integrated device for ear temperature measurement and non-contact temperature measurement, comprising a main body shell, a temperature measurement control unit and a display unit in the main body shell and a temperature measurement probe at head of the main body shell. The temperature measurement probe is composed of a shell, a temperature sensor in the shell and a non-contact temperature measurement component on the shell. The non-contact temperature measurement component is dismountable and has a non-contact temperature measurement channel in. After the non-contact temperature measurement component and the shell of the temperature measurement probe are assembled, the non-contact temperature measurement channel and the shell of the temperature measurement probe will form a necessary infrared receiving channel to realize non-contact temperature measurement.

Abstract: A monitoring device includes a housing configured to be attached to a body of a subject. An optical emitter, optical detector, and sensor for measuring motion noise are located within the housing. Light transmissive material is in optical communication with the optical emitter and detector and is configured to deliver light from the optical emitter to one or more locations of the body of the subject and to collect light external to the housing and deliver the collected light to the detector. A signal processor is configured to receive and process signals produced by the optical detector and the motion noise sensor, and to remove noise from the signals produced by the optical detector. The signal processor may generate physiological parameters for the subject such as heart rate, blood flow, blood pressure, VO2max, heart rate variability, respiration rate, and blood gas/analyte level.

Abstract: This document describes techniques for, and systems that enable, in-ear health monitoring. The techniques described herein enable early detection of health conditions (e.g., contagious disease) through use of an in-ear health-monitoring and audio device. These techniques prompt a user, often through the user's smart phone, to listen to audio content through the device, which also takes the user's temperature. Through repetitive use, the techniques are capable of determining a temperature differential for the user, which aids in early detection of a contagious disease or other malady.

Abstract: A system and method for monitoring the health of an animal using multiple sensors is described. The wearable device may include one or more sensors whose resultant signal levels may be analyzed in the wearable device or uploaded to a data management server for additional analysis. In one example, paired thermometers are used to estimate a core temperature of the animal, with one of the thermometers facing inward toward the animal and the other thermometer facing away from the animal.

Abstract: Methods for detection of heat-related symptoms can include use of a thermal sensor to obtain thermal data. Subsets of the thermal data can correspond with multiple subjects. The subsets can be compared to determine whether any of the subjects is a thermal outlier relative to the remaining subjects.

Abstract: The present invention provides an ear thermometer that irradiates liquid crystal with backlight without increasing a battery capacity, to make a body temperature displayed with the liquid crystal easily visible even in a dark place. An MCU 1 displays a body temperature measured by a body temperature measuring part (3) on a liquid crystal display part (5), controls, through input/output ports (P1, P2), a backlight emitting part (7) in such a way that the light quantity of the backlight irradiating the liquid crystal display part (5) from the backlight emitting part (7) is maximized for a first predetermined time, controls the backlight emitting part (7) in such a way that the quantity of the backlight keeps, for a second predetermined time that follows the first predetermined time, a predetermined level that is lower than the maximum, and controls the backlight emitting part (7) in such a way that the quantity of the backlight is zeroed after the second predetermined time elapses.

Abstract: A method for calibrating a thermometer is disclosed. The thermometer comprises a primary temperature sensor for determining the temperature of a target. The thermometer also comprises a reference temperature sensor positioned proximate to the primary temperature sensor and being responsive to an extraneous temperature affecting the primary temperature sensor. One calibration method calibrates the reference temperature sensor. This calibration can utilize a non-electrically conductive liquid bath for temperature control. Another calibration method calibrates the reference temperature sensor and the primary temperature sensor.

Abstract: Embodiments disclosed herein provide a non-intrusive thermal (NIT) monitor for sensing temperatures useful for semiconductor manufacturing applications. In some embodiments, a NIT monitor comprises a thermopile, a fluid housing with a fluid window, and an elongated member positioned between the thermopile and the fluid window for transmitting or reflecting infrared signals corresponding to a temperature of a fluid in the fluid housing. The fluid housing may have a cross-sectional profile to enable the manipulation of the fluid flow under the fluid window, enhancing the speed and accuracy of the temperature sampling. The elongated member, which may be hollow and coated with gold, may an extended piece of the fluid housing or a part of an optics housing. In some embodiments, the NIT monitor is connected to a main conditioning circuit board via a cable for processing the temperature measurements at a remote location.