A semiconductor photodetector includes a semiconductor substrate including a silicon substrate. The semiconductor substrate includes a second main surface as a light incident surface and a first main surface opposing the second main surface. In the semiconductor substrate, carriers are generated in response to incident light. A plurality of protrusions is formed on the second main surface. The protrusion includes a slope inclined with respect to a thickness direction of the semiconductor substrate. At the protrusion, a (111) surface of the semiconductor substrate is exposed as the slope. The height of the protrusion is equal to or more than 200 nm.

A semiconductor device in which a first chip and a second chip are stacked including a first wiring line and a second wiring line by which the first chip and the second chip are electrically connected. The first wiring line and the second wiring line each include a bonding portion for bonding one of a plurality of conductive patterns placed in the first chip and one of a plurality of conductive patterns placed in the second chip. The number of bonding portions included in the first wiring line is larger than the number of bonding portions included in the second wiring line.

First and second images of a semiconductor die or portion thereof are generated. Generating each image includes performing a respective instance of time-domain integration (TDI) along a plurality of pixel columns in an imaging sensor, while illuminating the imaging sensor with light scattered from the semiconductor die or portion thereof. The plurality of pixel columns comprises pairs of pixel columns in which the pixel columns are separated by respective channel stops. While performing a first instance of TDI to generate the first image, a first bias is applied to electrically conductive contacts of the channel stops. While performing a second instance of TDI to generate the second image, a second bias is applied to the electrically conductive contacts of the channel stops. Defects in the semiconductor die or portion thereof are identified using the first and second images.

The present application discloses a display device. The display device comprises: a displaying component, an imaging component, and a placement region indicating component, wherein, the imaging component establishes a communication connection with the displaying component, the placement region indicating component is configured to indicate a placement region of an object to be imaged, an imaging region of the imaging component being the placement region as indicated by the placement region indicating component, the imaging component is configured to image the object to be imaged which is located within the placement region, and the displaying component is configured to display an image generated by the imaging component.

A back-illuminated image sensor includes a first pixel, a second pixel, and a channel stop situated between the first pixel and the second pixel to isolate the first pixel from the second pixel. The channel stop includes a LOCOS structure and a region of doped silicon beneath the LOCOS structure. The back-illuminated image sensor also includes a first electrically conductive contact that extends through the LOCOS structure and forms an ohmic contact with the region of doped silicon. The first electrically conductive contact may be grounded, negatively biased, or positively biased, depending on the application.

In one example, an apparatus comprises: a semiconductor substrate including a front side surface, a first photodiode to generate a first charge, a second photodiode to generate a second charge, a barrier layer between the first photodiode and the second photodiode and configured to control flow of the second charge from the second photodiode to the first photodiode, and a drain region to store the first charge and at least a first part of the second charge. The apparatus further comprises a gate on the front side surface over a first channel region between the first photodiode and the drain region to control the flow of the first charge and the at least the first part of the second charge to the drain region, and a second channel region to conduct at least a second part of the second charge away from the barrier layer when the second photodiode saturates.

Provided are an image sensor with one or more image receivers for image switching, and an imaging system and method therefor. The image sensor includes an image sensor array to generate first image data for a first image; a receiver to receive, into the image sensor, second image data for a second image; an image selection circuit coupled to the image sensor array and the receiver to receive the first image data and the second image data and select one of the first image data and the second image data according to one or more image selection criteria and at least one of the first image data and the second image data; and a transmitter coupled to the image selection circuit to transmit the selected one of the first image data and the second image data from the image sensor.

An object of the present invention is to prevent a sensitivity difference between pixels. There are disposed plural unit cells each including plural photodiodes, plural transfer MOSFETs arranged corresponding to the plural photodiodes, respectively, and a common MOSFET which amplifies and outputs signals read from the plural photodiodes. Each pair within the unit cell, composed of the photodiode and the transfer MOSFET provided corresponding to the photodiode, has translational symmetry with respect to one another. Within the unit cell, there are included a reset MOSFET and selecting MOSFET.

An imaging device includes: a photoelectric converter which converts light into signal charges; a charge accumulation region which is electrically connected to the photoelectric converter, and accumulates the signal charges; a transistor having a gate electrode which is electrically connected to the charge accumulation region; and a contact plug which electrically connects the photoelectric converter to the charge accumulation region, is in direct contact with the charge accumulation region, and comprises a semiconductor material.

Provided is a solid-state imaging device that includes: a first pixel provided with a color filter layer having a transmission band in a visible light wavelength region on a light-receiving surface of a first light-receiving element; a second pixel provided with an infrared pass filter layer having a transmission band in an infrared wavelength region on a light-receiving surface of a second light-receiving element; an infrared cut filter layer that is provided on a position overlapping with the color filter layer and transmits light in the visible light wavelength region by blocking light in the infrared wavelength region; and a cured film provided in contact with the infrared cut filter layer.