There is provided an optical sensor package including a substrate, a base layer, an optical detection region, a light source and a light blocking wall. The base layer is arranged on the substrate. The light detection region and the light source are arranged on the base layer. The light blocking wall is arranged on the base layer, and located between the light detection region and the light source to block light directly propagating from the light source to the light detection region.

A camera system including a photoelectric convertor including a first and second electrode, and a photoelectric conversion layer; and a correction circuit correcting a signal corresponding to a potential change of the second electrode. The photoelectric convertor has a photoelectric conversion characteristic in which rate of change of the photoelectric conversion efficiency with respect to a first bias voltage between the first electrode and the second electrode when the first bias voltage is in a first voltage range, is greater than the rate of change with respect to a second bias voltage when the second bias voltage is in a second voltage range that is higher than the first voltage range, and a bias voltage between the first electrode and the second electrode exists in the first voltage range, and the correction circuit corrects the signal so that variation of an output regarding an amount of incident light becomes linear.

A carrier substrate is configured to carry at least one electronic chip and includes a mounting front face. An encapsulating cover is mounted on the front face of the carrier substrate through a mounting. This mounting includes at least one seating surface through which the cover and the carrier substrate make contact. At least one adhesive bead is located elsewhere than the seating surface in order to securely fasten the encapsulation cover and the carrier substrate.

An image sensor with embedded wells for accommodating light emitters includes a semiconductor substrate including an array of doped sensing regions respectively corresponding to an array of photosensitive pixels of the image sensor. The semiconductor substrate forms an array of wells. Each well is aligned with a respective doped sensing region to facilitate detection, by the photosensitive pixel that includes said respective doped sensing region, of light emitted to the photosensitive pixel by a light emitter disposed in the well. The image sensor further includes, between adjacent doped sensing regions, a light-blocking barrier to reduce propagation of light to the doped sensing-region of each photosensitive pixel from wells not aligned therewith.

A semiconductor structure includes a substrate, a plurality of micro semiconductor devices and a fixing structure. The micro semiconductor devices are disposed on the substrate. The fixing structure is disposed between the substrate and the micro semiconductor devices. The fixing structure includes a plurality of conductive layers and a plurality of supporting layers. The conductive layers are disposed on the lower surfaces of the micro semiconductor devices. The supporting layers are connected to the conductive layers and the substrate. The material of each of the conductive layers is different from the material of each of the supporting layers.

An electronic device is disclosed in the present disclosure. The electronic device comprises a substrate, a first layer and a second layer. The first layer is disposed on the substrate, and the second layer is disposed on the substrate and surrounds the first layer. An interface between the first layer and the second layer forms a light guiding channel, thereby improving the intensity of a light received by an optical sensor.

An imaging device includes: a photoelectric converter including first and second electrodes, and a photoelectric conversion layer located between the first electrode and the second electrode; a voltage supply circuit applying a bias voltage between the first electrode and the second electrode; an amplifier transistor including a gate electrically connected to the second electrode, the amplifier transistor configured to output a signal corresponding to a potential of the second electrode; and a detection circuit configured to detect a level of the signal from the amplifier transistor. The voltage supply circuit applies the bias voltage in a first voltage range when the level detected by the detection circuit is greater than or equal to a first threshold value, and applies the bias voltage in a second voltage range that is greater than the first voltage range when the level detected by the detection circuit is less than a second threshold value.

A photoconductor assembly includes a substrate formed of an undoped and single-crystal semiconductor material that is configured to absorb electromagnetic energy, a plurality of electrodes arranged normal to the substrate, and a power supply that applies a voltage to the electrodes for modulating the electromagnetic energy through the substrate.

The present disclosure provides an optical detection pixel unit, an optical detection pixel circuit, an optical detection method and a display device. The optical detection pixel unit comprise a photosensitive element and a detection transistor, wherein the photosensitive element has a first electrode connected with a photovoltage terminal, and a second electrode connected with a gate of the detection transistor; the photosensitive element is configured to detect an optical signal under the control of the photovoltage terminal; and the detection transistor has a first electrode connected with a detection voltage line, and a second electrode connected with a reading line.

A carrier substrate is configured to carry at least one electronic chip and includes a mounting front face. An encapsulating cover is mounted on the front face of the carrier substrate through a mounting. This mounting includes at least one seating surface through which the cover and the carrier substrate make contact. At least one adhesive bead is located elsewhere than the seating surface in order to securely fasten the encapsulation cover and the carrier substrate.