The present invention provides a windowpane defogging device for a motor vehicle which, upon generation of a fog on a windowpane, comes into a defogging mode to remove the fog generated on the windowpane. The windowpane defogging device includes a relative humidity detecting unit configured to detect a windowpane relative humidity of a driver seat view field region of the windowpane and a windowpane relative humidity of a passenger seat view field region of the windowpane, and a control unit configured to control entry into the defogging mode by determining the generation or non-generation of the fog on the windowpane based on the windowpane relative humidity of the driver seat view field region and the windowpane relative humidity of the passenger seat view field region inputted from the relative humidity detecting unit.

A device may include a first infrared sensor, a second infrared sensor, a temperature detecting component, and an occupancy detecting component. The first infrared sensor may connect to the temperature detecting component through a first temperature signal path and the occupancy detecting component through a first occupancy signal path. The second infrared sensor may connect to the temperature detecting component through a second temperature signal path and the occupancy detecting component through a second occupancy signal path. The temperature detecting component may determine a temperature measurement by calculating an average of a value received from the first temperature signal path and a value received from the second temperature signal path. The occupancy detecting component may determine an occupancy measurement by calculating a difference of the value received from the first occupancy signal path and the value received from the second occupancy signal path.

Pyroelectric detection device, including at least: a substrate; a membrane arranged on the substrate; a pyroelectric detection element arranged on the membrane or forming at least one part of the membrane, and including at least one portion of pyroelectric material arranged between first and second electrodes; a cavity passing through the substrate, emerging opposite a part of the membrane which forms a bottom wall of the cavity, and including side edges formed by the substrate; an element for stiffening the membrane arranged in the cavity, partially filling the cavity, made integral with the side edges of the cavity at at least two distinct anchoring regions, and arranged against the membrane.

Pyroelectric detection device, including at least: a substrate; a membrane arranged on the substrate; a pyroelectric detection element arranged on the membrane or forming at least one part of the membrane, and including at least one portion of pyroelectric material arranged between first and second electrodes; a cavity passing through the substrate, emerging opposite a part of the membrane which forms a bottom wall of the cavity, and including side edges formed by the substrate; an element for stiffening the membrane arranged in the cavity, partially filling the cavity, made integral with the side edges of the cavity at at least two distinct anchoring regions, and arranged against the membrane.

A mobile terminal in accordance with one embodiment of the present disclosure include: a flicker sensor configured to recognize a surrounding environment of the mobile terminal; a time of flight (ToF) sensor configured to measure a depth of a subject and a camera configured to capture the subject to generate an image of the subject; and a controller configured to control the camera to recognize the surrounding environment by operating the flicker sensor in response to a user input for operating the camera, to determine a light output time of the ToF sensor in response to the surrounding environment, and to capture the subject while measuring the depth of the subject by operating the ToF sensor in an operation mode corresponding to the light output time. Other embodiments are also available.

A mobile terminal in accordance with one embodiment of the present disclosure include: a flicker sensor configured to recognize a surrounding environment of the mobile terminal; a time of flight (ToF) sensor configured to measure a depth of a subject and a camera configured to capture the subject to generate an image of the subject; and a controller configured to control the camera to recognize the surrounding environment by operating the flicker sensor in response to a user input for operating the camera, to determine a light output time of the ToF sensor in response to the surrounding environment, and to capture the subject while measuring the depth of the subject by operating the ToF sensor in an operation mode corresponding to the light output time. Other embodiments are also available.

A human body detecting device includes a pyroelectric infrared radial (PIR) sensor, a thermometer, a processor, an amplifying unit, and a plurality of amplification adjusting units. The PIR sensor is configured to sense infrared radiation and then generate an electronic signal. The thermometer is configured to sense an ambient temperature and then generate a temperature value. The microprocessor is electrically connected to the thermometer, and the amplifying unit is electrically connected to the pyroelectric infrared radial sensor and the microprocessor. The amplification adjusting units corresponding to a plurality of temperature intervals are electrically connected to the microprocessor and the amplifying unit. The microprocessor selects to enable one of the amplification adjusting units based on a comparison between the temperature value and the temperature intervals, such that the amplifying unit may modulate the electrical signal according to the enabled amplification adjusting unit.

A human body detecting device includes a pyroelectric infrared radial (PIR) sensor, a thermometer, a processor, an amplifying unit, and a plurality of amplification adjusting units. The PIR sensor is configured to sense infrared radiation and then generate an electronic signal. The thermometer is configured to sense an ambient temperature and then generate a temperature value. The microprocessor is electrically connected to the thermometer, and the amplifying unit is electrically connected to the pyroelectric infrared radial sensor and the microprocessor. The amplification adjusting units corresponding to a plurality of temperature intervals are electrically connected to the microprocessor and the amplifying unit. The microprocessor selects to enable one of the amplification adjusting units based on a comparison between the temperature value and the temperature intervals, such that the amplifying unit may modulate the electrical signal according to the enabled amplification adjusting unit.

A detecting device includes a pyroelectric element that generates charge by a pyroelectric effect in a first detection terminal and a second detection terminal, a chopper amplifier circuit that generates an amplified signal in response to the charge generated in the first detection terminal and the second detection terminal by chopping, and an initialization switch that controls electrical connection between the second detection terminal and a power source for generating an initialized voltage, and the initialization switch is turned on before a start of an amplification operation by the amplifier circuit and is off during the amplification operation.

A detecting device includes a pyroelectric element that generates charge by a pyroelectric effect in a first detection terminal and a second detection terminal, a chopper amplifier circuit that generates an amplified signal in response to the charge generated in the first detection terminal and the second detection terminal by chopping, and an initialization switch that controls electrical connection between the second detection terminal and a power source for generating an initialized voltage, and the initialization switch is turned on before a start of an amplification operation by the amplifier circuit and is off during the amplification operation.