An image sensor includes a plurality of photoelectric detectors, a plurality of color filters, and at least one pixel isolation region between adjacent ones of the photoelectric detectors. The color filters include a white color filter, and the color filters correspond to respective ones of the photoelectric detectors. The at least one pixel isolation region serves to physically and at least partially optically separate the photoelectric detectors from one another.

A sensor includes a plurality of image sensors, wherein each image sensor of the plurality of image sensors is configured to detect a first spectrum of light. The sensor further includes a depth sensing pixel bonded to each image sensor of the plurality of image sensors, wherein the depth sensing pixel is configured to detect a second spectrum of light different from the first spectrum.

Provided is an image sensor having improved performance. An image sensor in accordance with an embodiment of the present invention including a pixel array in which a plurality of pixels are two-dimensionally arranged, wherein each of the plurality of pixels may include: a photoelectric conversion element formed in a substrate; a transfer gate overlapping with a portion of the photoelectric conversion element and formed on the substrate; and a color filter over the photoelectric conversion element, wherein the plurality of pixels include two adjacent pixels which have the same color filter, and wherein one of the two adjacent pixels comprises an incident light control pattern.

An improvement is achieved in the performance of a semiconductor device. A semiconductor device includes an n.sup.-type semiconductor region formed in a p-type well, an n-type semiconductor region formed closer to a main surface of a semiconductor substrate than the n.sup.-type semiconductor region, and a p.sup.-type semiconductor region formed between the n.sup.-type semiconductor region and the n-type semiconductor region. A net impurity concentration in the n.sup.-type semiconductor region is lower than a net impurity concentration in the n-type semiconductor region. A net impurity concentration in the p.sup.-type semiconductor region is lower than a net impurity concentration in the p-type well.

An image sensor includes a sensing layer, filter units, and a grid structure. The filter units are disposed on the sensing layer. The grid structure is disposed on the filter units, and includes grating portions. The grating portions form a number of grating groups, and each of the grating groups is separated from each other.

A groove-type through hole passing through a silicon layer and a first interlayer insulating film is formed in a region around a chip formation region including a photodiode. In the groove-type through hole, a wall-like wall-type conductive pass-through portion corresponding to the groove-type through hole is formed. An electrode pad is in contact with the wall-type conductive pass-through portion. The electrode pad is electrically connected to a first interconnection through the wall-type conductive pass-through portion.

An image sensor including a substrate, a trench isolation, a plurality of image sensing units, at least one phase detection unit, and an interconnection layer is provided. The trench isolation is in the substrate, and a plurality of active areas of the substrate are separated from each other by the trench isolation. The image sensing units and the at least one phase detection unit are in the active areas arranged in an array, and a sensing area of the at least one phase detection unit is smaller than a sensing area of each of the image sensing units. The interconnection layer is disposed on the image sensing units and the at least one phase detection unit. In addition, a method of fabricating an image sensor is also provided.

A pixel cell with a photosensitive region formed in association with a substrate, a color filter formed over the photosensitive region, the color filter comprising a first material layer and a second material layer formed in association with the first shaping material layer.

A solid-state imaging device includes a layout in which one sharing unit includes an array of photodiodes of 2 pixels by 4n pixels (where, n is a positive integer), respectively, in horizontal and vertical directions.

A solid-state imaging device has a sensor substrate having a pixel region on which photoelectric converters are arrayed; a driving circuit provided on a front face side that is opposite from a light receiving face as to the photoelectric converters on the sensor substrate; an insulation layer, provided on the light receiving face, and having a stepped construction wherein the film thickness of the pixel region is thinner than the film thickness in a periphery region provided on the outside of the pixel region; a wiring provided to the periphery region on the light receiving face side; and on-chip lenses provided to positions corresponding to the photoelectric converters on the insulation layer.