Abstract: A proximity sensor includes a light source, an optical sensing element, and an integration circuit. The light source is turned on and off several times during a measurement time interval. When the light source is turned on and off, the optical sensing element senses the surrounding light to generate a first current and a second current, respectively. The integration circuit integrates the first current and the second current to generate a first integration signal and a second integration signal respectively for determining whether an object is approaching. When the light source is turned on, the present second integration signal is stored, and a stored first integration signal is used as a starting value to integrate the first current. When the light source is turned off, the present first integration signal is stored, and the stored second integration signal is used as a starting value to integrate the second current.

Abstract: A high-sensitivity light sensor includes a light sensing element, a first integrator, a comparator, and a second integrator. The light sensing element senses a light during a measurement time interval to generate a current. The first integrator integrates the current to generate a first integration signal. The comparator compares the first integration signal with a threshold value. While the first integration signal is greater than the threshold value, the comparison signal is at a first level. The second integrator is coupled to the first integrator and integrates the first integration signal to generate a second integration signal. The light sensor of the present invention uses two integrators to integrate the sensed voltage twice. Therefore, the light sensor of the present invention has a higher sensitivity.

Abstract: An optical sensing device is provided. The optical sensing device includes a first optical sensor and a filter layer. The first optical sensor is configured to receive a first optical signal. The filter layer covers the first optical sensor, and is configured to filter out the first optical signal when the first optical signal is incident on the filter layer at an incident angle not within a specific range.

Abstract: An electronic device includes an OLED display having a plurality of pixels and an ambient light sensor disposed under a first pixel of the plurality of pixels. In a first sensing interval, the ambient light sensor generates a first sensing value. The first sensing interval includes a first period and a second period. The first pixel has a first brightness in the first period and has a second brightness the second period. In a second sensing interval, which has the same time length as the first sensing interval, the ambient light sensor generates a second sensing value. The first pixel has the second brightness in the second sensing interval. The first pixel has an identical hue in the first sensing interval and the second sensing interval. The ambient light sensor acquires an ambient light intensity according to the first sensing value and the second sensing value.

Abstract: A light sensor includes a light sensing element, a first integrator and a sigma-delta analog-to-digital converter. The light sensing element senses light during a measurement period to generate a first current. The first integrator is coupled to the light sensing element and configured to receive the first current and generates a first integration signal. The sigma-delta analog-to-digital converter is coupled to the first integrator and used to convert the first integration signal to a sensing value.

Abstract: An optical sensing module has a light source and an optical sensing integrated circuit device. The optical sensing integrated circuit device has an optical sensor and a grating. The optical sensor and the light source are arranged along a first direction. The grating is formed over the optical sensor and has multiple parallel wires. The multiple wires are perpendicular to the first direction.

Abstract: An electronic device includes: a OLED display including a first display area, wherein a saturation of the first display area remains constant in a first period; a display driver for driving the OLED display and changing a brightness coefficient of the first display area from a first brightness coefficient to a second brightness coefficient during the first period; an ambient light sensor under the first display area for sensing light, wherein during the first period, the ambient light sensor generates a first sensing value when the brightness coefficient of the first display area is the first brightness coefficient and generates a second sensing value when the brightness coefficient of the first display area is the second brightness coefficient; and a controller for calculating an ambient light intensity according to the first brightness coefficient, the second brightness coefficient, the first sensing value and the second sensing value.

Abstract: A complementary metal-oxide-semiconductor depth sensor element having a photogate formed in a photosensitive area on a substrate. A first transfer gate and a second transfer gate are formed respectively on two sides of the photogate in intervals. A first floating doped area and a second floating doped area are formed respectively on the outer sides of the first transfer gate and the second transfer gate. A semiconductor area is formed on the substrate. A lightly doped region is formed on the semiconductor area. The photogate, the first and second transfer gates and the first and second floating doped area are commonly formed on the lightly doped region. With the lightly doped region, the linear performance that the majority carriers move in the photogate is also affected to achieve the purpose for increasing the reaction rate.

Abstract: A method for determining non-contact gesture is applied to a device for the same. The device has an image sensor to detect an image sensing data, an inertial measurement sensor to detect an inertial sensing data, and a processor to determine if an object data is detected and to determine if an inertial event is occurred. The image sensing data in the same and/or adjacent image frame with the inertial events are excluded so that the image sensing data used to determine the gesture are those not influenced by the inertial events. Therefore, the accuracy of determining the gesture is enhanced.

Abstract: A complementary metal-oxide-semiconductor depth sensor element having a photogate formed in a photosensitive area on a substrate. A first transfer gate and a second transfer gate are formed respectively on two sides of the photogate in intervals. A first floating doped area and a second floating doped area are formed respectively on the outer sides of the first transfer gate and the second transfer gate. A semiconductor area is formed on the substrate. A lightly doped region is formed on the semiconductor area. The photogate, the first and second transfer gates and the first and second floating doped area are commonly formed on the lightly doped region. With the lightly doped region, the linear performance that the majority carriers move in the photogate is also affected to achieve the purpose for increasing the reaction rate.

Abstract: An optical sensing module has a light source and an optical sensing integrated circuit device. The optical sensing integrated circuit device has an optical sensor and a grating. The optical sensor and the light source are arranged along a first direction. The grating is formed over the optical sensor and has multiple parallel wires. The multiple wires are perpendicular to the first direction.

Abstract: A method for sensing depth of an object in three-dimensional space a Time-Of-Flight Sensing procedure and a Proximity-Sensing procedure are respectively operated in the same one period of time. The obtained information of the two procedures are manipulated to acquire the depth information of the measured object. With the result of the Time-Of-Flight Sensing procedure having high accuracy and the result of the Proximity-Sensing procedure having high resolution, the acquired depth information of the measured object is more precise.

Abstract: A complementary metal-oxide-semiconductor depth sensor element comprises a photogate formed in a photosensitive area on a substrate. A first transfer gate and a second transfer gate are formed respectively on two sides of the photogate in intervals. A first floating doped area and a second floating doped area are formed respectively on the outer sides of the first transfer gate and the second transfer gate. The first and second floating doped regions have dopants of a first polarity and the semiconductor area has dopants of a second polarity opposite to the first polarity. Since the photogate and at least parts of the first and second transfer gates connect to the same semiconductor area and no other dopants of polarity opposite to the second polarity. Therefore, the majority carriers from the photogate excited by lights drift, but not diffuse, to transfer to the first and second transfer gates.

Abstract: An optical sensor module is provided. The optical sensor module includes a light source, a first lens and a sensor device. The light source is arranged for generating a light signal. The first lens has a first optical center axis. The sensor device is disposed in correspondence with one side of the first lens. The sensor device includes a light sensitive area, and a center of the light sensitive area deviates from the first optical center axis. The sensor device is arranged for receiving a reflected signal reflected from an object in response to the light signal, and accordingly generating a sensing result.

Abstract: A three-dimensional image sensing device includes a light source, a sensing module, and a signal processing module. The sensing module includes a pixel array, a control unit, and a light source driver. The light source generates flashing light with a K multiple of a frequency of flicker noise or a predetermined frequency. The pixel array samples the flashing light to generate a sampling result. The control unit executes an image processing on the sampling result to generate a spectrum. The light source driver drives the light source according to the K multiple of the frequency or the predetermined frequency. The signal processing module generates the K multiple of the frequency according to the spectrum, or outputs the predetermined frequency to the light source driver, and generates depth information according to a plurality of first images/a plurality of second images during turning-on/turning-off of the light source included in the sampling result.

Abstract: An optical sensor module is provided. The optical sensor module includes a light source, a first lens and a sensor device. The light source is arranged for generating a light signal. The first lens has a first optical center axis. The sensor device is disposed in correspondence with one side of the first lens. The sensor device includes a light sensitive area, and a center of the light sensitive area deviates from the first optical center axis. The sensor device is arranged for receiving a reflected signal reflected from an object in response to the light signal, and accordingly generating a sensing result.

Abstract: A control method of an electronic apparatus is provided. The electronic apparatus has a non-contact gesture sensitive region. The control method includes: identifying at least one object type of at least one non-contact object within the non-contact gesture sensitive region in a plurality of object types; determining respective numbers of non-contact objects corresponding to the identified at least one object type; detecting motion information of the at least one non-contact object within the non-contact gesture sensitive region; recognizing a non-contact gesture corresponding to the at least one non-contact object according to the identified at least one object type, the respective numbers of non-contact objects and the motion information; and enabling the electronic apparatus to perform a specific function according to the non-contact gesture.

Abstract: A method for determining non-contact gesture is applied to a device for the same. The device has an image sensor to detect an image sensing data, an inertial measurement sensor to detect an inertial sensing data, and a processor to determine if an object data is detected and to determine if an inertial event is occurred. The image sensing data in the same and/or adjacent image frame with the inertial events are excluded so that the image sensing data used to determine the gesture are those not influenced by the inertial events. Therefore, the accuracy of determining the gesture is enhanced.

Abstract: A complementary metal-oxide-semiconductor depth sensor element comprises a photogate formed in a photosensitive area on a substrate. A first transfer gate and a second transfer gate are formed respectively on two sides of the photogate in intervals. A first floating doped area and a second floating doped area are formed respectively on the outer sides of the first transfer gate and the second transfer gate. The first and second floating doped regions have dopants of a first polarity and the semiconductor area has dopants of a second polarity opposite to the first polarity. Since the photogate and at least parts of the first and second transfer gates connect to the same semiconductor area and no other dopants of polarity opposite to the second polarity. Therefore, the majority carriers from the photogate excited by lights drift, but not diffuse, to transfer to the first and second transfer gates.

Abstract: A method for sensing depth of an object in three-dimensional space a Time-Of-Flight Sensing procedure and a Proximity-Sensing procedure are respectively operated in the same one period of time. The obtained information of the two procedures are manipulated to acquire the depth information of the measured object. With the result of the Time-Of-Flight Sensing procedure having high accuracy and the result of the Proximity-Sensing procedure having high resolution, the acquired depth information of the measured object is more precise.