Abstract: A method may include generating, within a device, separate and discrete wavelengths, and generating light intensity profiles based on an interaction between the separate and discrete wavelengths and a multi-wavelength diffractive optic element. The method may include detecting an object from light reflected from the object using the light intensity profiles. The light intensity profiles may include a shorter range light intensity profile and a longer range light intensity profile, each light intensity profile having different energy per solid angle patterns.

Abstract: The present disclosure relates to an assembly for an electronic device, the assembly comprising: a display screen comprising a plurality of pixels arranged in a matrix scheme comprising rows orientated in a first direction and columns orientated in a second direction; and a proximity sensor comprising at least one optical light emitter, each adapted to emit a light beam through one or more first pixels of the display screen, and an optical detector adapted to receive through one or more second pixels of the display screen the light beam emitted by the at least one optical light emitter and reflected on an object; wherein none of the one or more second pixels is in the same row as any of the one or more first pixels, and none of the one or more second pixels is in the same column as any of the one or more first pixels.

Abstract: The present disclosure relates to an assembly for an electronic device comprising: a display screen; an optical light emitter adapted to emit an Infrared or near Infrared light beam through the display screen; the optical light emitter and the display screen being of the type that, when an unpolarized light beam from the optical light emitter passes through a region of the display screen, a white spot of a first intensity is formed in the region; a light polarizer positioned between the optical light emitter and the display screen, the light polarizer being orientated such that a white spot of a second intensity, lower than the first intensity, is formed when the light beam, from the optical light emitter and polarized by the light polarizer, passes through the region of the display screen.

Abstract: The present disclosure is directed to a sensor that detects a distance between the sensor and a target object. The sensor includes a transmission optical structure and/or a light source that polarizes light and minimizes cross talk within the sensor. As a result, detection results of the sensor are improved.

Abstract: A method may include generating, within a device, separate and discrete wavelengths, and generating light intensity profiles based on an interaction between the separate and discrete wavelengths and a multi-wavelength diffractive optic element. The method may include detecting an object from light reflected from the object using the light intensity profiles. The light intensity profiles may include a shorter range light intensity profile and a longer range light intensity profile, each light intensity profile having different energy per solid angle patterns.

Abstract: A method may include generating, within a device, separate and discrete wavelengths, and generating light intensity profiles based on an interaction between the separate and discrete wavelengths and a multi-wavelength diffractive optic element. The method may include detecting an object from light reflected from the object using the light intensity profiles. The light intensity profiles may include a shorter range light intensity profile and a longer range light intensity profile, each light intensity profile having different energy per solid angle patterns.

Abstract: A time of flight detector includes an electromagnetic radiation emitter configured to emit a beam of radiation. A first optical element receives the beam of radiation and generates a collimated beam of radiation. A second optical element defines a narrow imaging field of view sufficient to capture reflected electromagnetic radiation from the collimated beam. An electromagnetic radiation sensor then senses the captured reflected electromagnetic radiation from the collimated beam in the narrow imaging field of view. Further narrowing of the imaging field of view is accomplished by selective enabling a sub-array of photosensitive elements with the electromagnetic radiation sensor.

Abstract: A method may include generating, within a device, separate and discrete wavelengths, and generating light intensity profiles based on an interaction between the separate and discrete wavelengths and a multi-wavelength diffractive optic element. The method may include detecting an object from light reflected from the object using the light intensity profiles. The light intensity profiles may include a shorter range light intensity profile and a longer range light intensity profile, each light intensity profile having different energy per solid angle patterns.

Abstract: A proximity sensor includes a radiation source configured to emit a primary radiation beam and a primary detector configured to pick up a reflected primary radiation beam. The radiation source is further configured to emit stray radiation. The sensor further includes a reference detector arranged to receive the stray radiation. The stray radiation may, for example, be emitted from either a side of the radiation source or a bottom of the radiation source.

Abstract: A time of flight detector includes an electromagnetic radiation emitter configured to emit a beam of radiation. A first optical element receives the beam of radiation and generates a collimated beam of radiation. A second optical element defines a narrow imaging field of view sufficient to capture reflected electromagnetic radiation from the collimated beam. An electromagnetic radiation sensor then senses the captured reflected electromagnetic radiation from the collimated beam in the narrow imaging field of view. Further narrowing of the imaging field of view is accomplished by selective enabling a sub-array of photosensitive elements with the electromagnetic radiation sensor.

Abstract: A proximity sensor includes a radiation source configured to emit a primary radiation beam and a primary detector configured to pick up a reflected primary radiation beam. The radiation source is further configured to emit stray radiation. The sensor further includes a reference detector arranged to receive the stray radiation. The stray radiation may, for example, be emitted from either a side of the radiation source or a bottom of the radiation source.

Abstract: An image sensor includes a pixel array and an image sensor objective optical element. The element is formed by a lenslet array. Each lenslet in the array directs incoming radiation onto a different specific pixel or sub-array of pixels in the pixel array. The lenslets in the array are shaped such that fields of view of next-but-one neighboring ones of the lenslets (i.e., two lenslets spaced from each other by another lenslet) do not overlap until a certain object distance away from the lenslet array.

Abstract: An image sensor includes a pixel array and an image sensor objective optical element. The element is formed by a lenslet array. Each lenslet in the array directs incoming radiation onto a different specific pixel or sub-array of pixels in the pixel array. The lenslets in the array are shaped such that fields of view of next-but-one neighboring ones of the lenslets (i.e., two lenslets spaced from each other by another lenslet) do not overlap until a certain object distance away from the lenslet array.