A photosensitive resin composition comprising (A) a vinyl ether compound, (B) an epoxy-containing silicone resin, and (C) a photoacid generator is provided. The composition enables pattern formation using radiation of widely varying wavelength, and the patterned film has high transparency, light resistance, and heat resistance.

A camera system includes two or more sensor arrays and an optical path. The sensor arrays are on the same sensor chip. Each sensor array includes the same field of view (FOV) as each other sensor array. The optical path includes a main lens and a metalens that are shared by each sensor array, and a microlens associated with each sensor array. The metalens splits incident light into different spectrums of light and directs each respective spectrum to a corresponding sensor array. The different spectrums of light include at least two of visible light, near infrared light, shortwave infrared and longwave infrared, and at least one sensor array includes single-photon avalanche diodes. The image processor that provides image processing, object recognition and object tracking and/or image fusion functionality may be on the same sensor chip as the sensor arrays.

An endoscope includes an image pickup module, and the image pickup module includes: an image pickup device an external electrode being disposed on a back surface of the image pickup device; a wiring element provided with a through-hole passing through a first main surface and a second main surface, a first electrode on the first main surface being bonded with the external electrode; a signal cable bonded with a second electrode on the second main surface of the wiring element; and a first resin that seals a first bump bonding the first electrode and the external electrode and a second bump bonding the second electrode and the signal cable, and fills the through-hole.

Misalignment of a substrate portion which integrates an image sensor and a substrate is suppressed. An imaging apparatus comprises: an imaging optical system including at least one optical element; a holding member holding the imaging optical system; an image sensor configured to capture a subject image formed by the imaging optical system; a substrate having the image sensor mounted thereon; and a bonding member fixing a substrate portion to the holding member, the substrate portion integrating the image sensor and the substrate, wherein the bonding member is partly in contact with a surface of the substrate portion, and at at least two positions in a part of the surface of the substrate portion in contact with the bonding member, the surface of the substrate portion faces different directions.

The present application provides a chip package structure and an electronic device, which could reduce a chip package thickness and implement ultra-thinning of chip package. The chip package structure includes a chip, a substrate, a lead and a lead protection adhesive; the lead is configured to electrically connect the chip and the substrate; the lead protection adhesive is configured to support the lead, where a highest point of the lead protection adhesive is not higher than a highest point of an upper edge of the lead.

An artifact caused by secondary reflection is reduced. An imaging device according to an embodiment includes: a diffuser (110) that converts incident light into scattered light whose diameter is expanded in accordance with a propagation distance and outputs the scattered light; and a light receiver (132) that converts light diffused by the diffuser into an electric signal.

A sensor arrangement including at least one electro-optical sensor which is secured to a receiving structure of a sensor holder. The electro-optical sensor includes a sensor housing with an optically active sensor layer that is arranged thereon. The optically active sensor layer forms a light-sensitive plane. The sensor holder includes a non-adjustable receiving structure which compensates for a previously determined deviation in shape of the electro-optical sensor from a desired shape.

Alignment accuracy between an imaging element and a filming lens is improved. An imaging apparatus includes an imaging element, a wiring substrate, a sealing section, and fitting sections. The imaging element includes an imaging chip and pads. A light transmission section that transmits incident light is arranged on the imaging chip, and the imaging chip generates an image signal on the basis of the incident light that has transmitted through the light transmission section. The pads are arranged on a bottom surface of the imaging chip which is a surface different from the surface on which the light transmission section is arranged and convey the generated image signal. The wiring substrate includes wiring that is connected to the pads, and the imaging element is arranged on a front surface of the wiring substrate. The sealing section is arranged adjacent to side surfaces of the imaging chip which are the surfaces adjacent to the bottom surface of the imaging chip and seals the imaging chip. The fitting sections are arranged in the sealing section, and part of a lens unit for forming an optical image on the imaging element is fitted into the fitting sections.

An imaging device to which a simple mounting method can be applied is configured. The imaging device is provided with an imaging element, a wiring substrate, and a sealing portion. The imaging element is provided with an image pickup chip over which an light transmitting portion transmitting incident light is arranged and which generates an image signal on the basis of the incident light that has passed through the light transmitting portion, and a pad which is arranged on a bottom surface of the image pickup chip different from a surface on which the light transmitting portion is arranged, which the pad transmitting the generated image signal. The wiring substrate has wiring connected to the pad and extending to a region outside the imaging element, and has the imaging element arranged on a surface thereof. The sealing portion is arranged adjacent to a side surface which is a surface adjacent to the bottom surface of the imaging element, and seals the imaging element.

A chip scale package structure is provided. The chip scale package structure includes an image sensor chip and a chip. The image sensor chip includes a first redistribution layer including a conductive wire and a conductive pad formed on the conductive wire, wherein the conductive pad is exposed from the surface of the first redistribution layer. The chip includes a plurality of through silicon via (TSV) and a second redistribution layer including a conductive wire and a conductive pad formed on the conductive wire, wherein the conductive pad is exposed from the surface of the second redistribution layer. The area of the chip is smaller than that of the image sensor chip. The second redistribution layer of the chip bonds to the first redistribution layer of the image sensor chip.