Abstract: An image sensor array is disclosed. The image sensor array includes: a semiconductor substrate; a lateral photo detector structure over the semiconductor substrate, wherein the lateral photo detector structure has a dislocation trapping region protruding to the semiconductor substrate; and an insulating layer disposed over the lateral photo detector structure and further extending to a space between the lateral photo detector structure and the semiconductor substrate; wherein the lateral photo detector structure includes a first type region and a second type region having a polarity opposite to a polarity of the first type region, and the first type region extends at least along a portion of a boundary between an upside of the intrinsic region and the insulating layer. An associated manufacturing method is also disclosed.

Abstract: The present disclosure, in some embodiments, relates to a CMOS image sensor. The CMOS image sensor has an image sensing element disposed within a substrate. A plurality of isolation structures are arranged along a back-side of the substrate and are separated from opposing sides of the image sensing element by non-zero distances. A doped region is laterally arranged between the plurality of isolation structures. The doped region is also vertically arranged between the image sensing element and the back-side of the substrate. The doped region physically contacts the image sensing element.

Abstract: An image sensor for high angular response discrimination is provided. A plurality of pixels comprises a phase detection autofocus (PDAF) pixel and an image capture pixel. Pixel sensors of the pixels are arranged in a semiconductor substrate. A grid structure is arranged over the semiconductor substrate, laterally surrounding color filters of the pixels. Microlenses of the pixels are arranged over the grid structure, and comprise a PDAF microlens of the PDAF pixel and an image capture microlens of the image capture pixel. The PDAF microlens comprises a larger optical power than the image capture microlens, or comprises a location or shape so a PDAF receiving surface of the PDAF pixel has an asymmetric profile. A method for manufacturing the image sensor is also provided.

Abstract: An imaging apparatus includes a plurality of pixels, a signal holding unit, first and second control electrodes. Each of the plurality of pixels includes a photoelectric conversion unit, and an amplification element to amplify signals based on signal charges generated by the photoelectric conversion unit, in which the plurality of pixels output signals for performing a phase contrast detection type of focal point detection. The signal holding unit is in an electrical pathway between an output node of the photoelectric conversion unit and an input node of the amplification element, in which signals for performing the phase contrast detection type of focal point detection are held. The first control electrode is configured to transfer a signal of the photoelectric conversion unit to the signal holding unit. The second control electrode is configured to transfer a signal for performing the phase difference detection type of focal point detection.

Abstract: A semiconductor device includes: a visible light sensing layer, having a first surface and a second surface opposite to the first surface; an infrared ray sensing layer, having a first surface and a second surface opposite to the first surface, and the first surface of the visible light sensing layer attached to the second surface of the infrared ray sensing layer; and a circuitry layer, having a first surface and a second surface opposite to the first surface, and the first surface of the infrared ray sensing layer attached to the second surface of the circuitry layer.

Abstract: Each of multiple pixels includes a photoelectric conversion unit. A first holding unit is configured to hold a charge generated by the photoelectric conversion unit, at a location different from location of the photoelectric conversion unit. A second holding unit is configured to hold a charge held by the first holding unit at a location different from locations of both of the first holding unit and the photoelectric conversion unit. An amplifying unit includes an input node different from the second holding unit and is configured to output a signal based on a charge transferred to the input node from the second holding unit. A first discharge unit includes a charge draining node which is electrically connected to a line where a predetermined voltage is supplied. The first discharge unit discharges a charge held by the first holding unit to the charge draining node.

Abstract: An image sensor array is disclosed. The image sensor array includes: a semiconductor substrate; a lateral photo detector structure over the semiconductor substrate, wherein the lateral photo detector structure has a dislocation trapping region protruding to the semiconductor substrate; and an insulating layer disposed over the lateral photo detector structure and further extending to a space between the lateral photo detector structure and the semiconductor substrate; wherein the lateral photo detector structure includes a first type region and a second type region having a polarity opposite to a polarity of the first type region, and the first type region extends at least along a portion of a boundary between an upside of the intrinsic region and the insulating layer. An associated manufacturing method is also disclosed.

Abstract: Methods for forming image sensor structures are provided. The method includes forming an isolation structure in a substrate and forming a first light sensing region and a second light sensing region. The method further includes forming a first gate structure and a second gate structure, and the first gate structure and the second gate structure are positioned at a front side of the substrate. The method further includes forming a first source/drain structure adjacent to the first gate structure and a second source/drain structure adjacent to the second gate structure and forming an interlayer dielectric layer over the front side of the substrate. The method further includes forming a contact trench through the interlayer dielectric layer and forming a contact in the contact trench.

Abstract: A solid-state image pickup apparatus includes a photoelectric conversion unit, a charge storage unit, and a floating diffusion unit, all disposed on a semiconductor substrate. The solid-state image pickup apparatus further includes a first gate electrode disposed on the semiconductor substrate and extending between the photoelectric conversion unit and charge storage unit, and a second gate electrode disposed on the semiconductor substrate and extending between the charge storage unit and the floating diffusion unit. The solid-state image pickup apparatus further includes a light shielding member including a first part and a second part, wherein the first part is disposed over the charge storage unit and at least over the first gate electrode or the second gate electrode, and the second part is disposed between the first gate electrode and the second gate electrode such that the second part extends from the first part toward a surface of the semiconductor substrate.

Abstract: The present disclosure relates to a CMOS image sensor having a doped region, arranged between deep trench isolation structures and an image sensing element, and an associated method of formation. In some embodiments, the CMOS image sensor has a pixel region disposed within a semiconductor substrate. The pixel region has an image sensing element configured to convert radiation into an electric signal. A plurality of back-side deep trench isolation (BDTI) structures extend into the semiconductor substrate on opposing sides of the pixel region. A doped region is laterally arranged between the BDTI structures and separates the image sensing element from the BDTI structures and the back-side of the semiconductor substrate. Separating the image sensing element from the BDTI structures prevents the image sensing element from interacting with interface defects near edges of the BDTI structures, and thereby reduces dark current and white pixel number.

Abstract: A sensor device is disclosed. The sensor device include: a detector having a contact formation region; an insulating layer disposed over the detector; a conductive pad disposed over the insulating layer opposite to a side of the detector; a contact plug formed in the insulating layer for electrically coupling the contact implant region and the conductive pad; and a read-out integrated circuit bonded to the insulating layer through the conductive pad. An image sensor array and a manufacturing method of a sensor device are also disclosed.

Abstract: A solid-state image pickup apparatus includes a photoelectric conversion unit, a charge storage unit, and a floating diffusion unit, all disposed on a semiconductor substrate. The solid-state image pickup apparatus further includes a first gate electrode disposed on the semiconductor substrate and extending between the photoelectric conversion unit and charge storage unit, and a second gate electrode disposed on the semiconductor substrate and extending between the charge storage unit and the floating diffusion unit. The solid-state image pickup apparatus further includes a light shielding member including a first part and a second part, wherein the first part is disposed over the charge storage unit and at least over the first gate electrode or the second gate electrode, and the second part is disposed between the first gate electrode and the second gate electrode such that the second part extends from the first part toward a surface of the semiconductor substrate.

Abstract: A circuit includes a photodiode electrically coupled to a first node, the first node configured to be charged by a first power supply voltage. A second node is configured to be charged by a second power supply voltage lower than the first power supply voltage, a source follower transistor is electrically coupled between the second node and a column line, and a level shifter is electrically coupled between the first node and the second node.

Abstract: Provided is a back-illuminated solid-state image pickup apparatus having an improved color separation characteristic. A photo detector includes a first photo detector unit and a second photo detector unit disposed deeper than the first photo detector unit with respect to a back surface of a semiconductor substrate, wherein the first photo detector unit includes a first-conductivity-type first semiconductor region where carriers generated through photo-electric conversion are collected as signal carriers. A readout portion includes a first-conductivity-type second semiconductor region extending in a depth direction such that the carriers collected in the first semiconductor region are read out to a front surface of the semiconductor substrate. A unit that reduces the amount of light incident on the second semiconductor region is provided.

Abstract: A circuit includes a signal line and a pixel unit cell. The pixel unit cell includes one or more light sensing elements, a conversion circuit, and a selection switch between the conversion circuit and the signal line. In the pixel unit cell, the conversion circuit is configured to convert charge carriers from the one or more light sensing elements to a voltage signal at an output node of the conversion circuit.

Abstract: An image sensor includes a semiconductor substrate having first and second faces. The sensor includes a plurality of pixel groups each including pixels, each pixel having a photoelectric converter and a wiring pattern, the converter including a region whose major carriers are the same with charges to be accumulated in the photoelectric converter. The sensor also includes a microlenses which are located so that one microlens is arranged for each pixel group. The wiring patterns are located at a side of the first face, and the plurality of microlenses are located at a side of the second face. Light-incidence faces of the regions of the photoelectric converters of each pixel group are arranged along the second face such that the light-incidence faces are apart from each other in a direction along the second face.

Abstract: A photoelectric conversion portion, a charge holding portion, a transfer portion, and a sense node are formed in a P-type well. The charge holding portion is configured to include an N-type semiconductor region, which is a first semiconductor region holding charges in a portion different from the photoelectric conversion portion. A P-type semiconductor region having a higher concentration than the P-type well is disposed under the N-type semiconductor region.

Abstract: A stacked image sensor with a rerouting layer is provided for a high readout rate and a high functionality per footprint area. A pixel chip is arranged over a logic chip. The pixel chip and the logic chip respectively comprise a pixel sensor array and a readout circuit array. A first conductive feature array is arranged under and electrically coupled to the pixel sensor array. The first conductive feature array has a first pitch. A second conductive feature array is arranged over and electrically coupled to the readout circuit array. The second conductive feature array has a second pitch different than the first pitch. The rerouting layer is arranged between the first and second conductive feature arrays. The rerouting layer electrically couples the first conductive feature array to the second conductive feature array while translating between the first and second pitches. A method for manufacturing the stacked image sensor is also provided.

Abstract: An image sensor includes a semiconductor substrate having first and second faces. The sensor includes a plurality of pixel groups each including pixels, each pixel having a photoelectric converter and a wiring pattern, the converter including a region whose major carriers are the same with charges to be accumulated in the photoelectric converter. The sensor also includes a microlenses which are located so that one microlens is arranged for each pixel group. The wiring patterns are located at a side of the first face, and the plurality of microlenses are located at a side of the second face. Light-incidence faces of the regions of the photoelectric converters of each pixel group are arranged along the second face such that the light-incidence faces are apart from each other in a direction along the second face.

Abstract: A photoelectric conversion portion, a charge holding portion, a transfer portion, and a sense node are formed in a P-type well. The charge holding portion is configured to include an N-type semiconductor region, which is a first semiconductor region holding charges in a portion different from the photoelectric conversion portion. A P-type semiconductor region having a higher concentration than the P-type well is disposed under the N-type semiconductor region.