Abstract: An optical element according to an embodiment includes: a lens array including a plurality of convex shaped lenses provided on a first surface thereof and taking a flat shape at a second surface which is opposite from the first surface; a lens holder comprising concave portions formed to correspond to respective lenses in the lens array, at a surface opposed to the lens array, each of the concave portions having a size which makes it possible for one of the convex shaped lenses corresponding to the concave portion to fit therein; and a drive unit configured to drive at least one of the lens array and the lens holder to bring the convex shaped lenses in the lens array and the concave portions in the lens holder into an isolation state or a contact state.

Abstract: A solid-state imaging device according to an embodiment includes: a plurality of pixels arranged on a first face of a first semiconductor layer, each of the pixels including a photoelectric conversion element converting light entering through a second face of the first semiconductor layer on the opposite side from the first face into a signal charge, the photoelectric conversion element having a pn junction formed with a first semiconductor region formed on the first face and a second semiconductor region formed on a surface of the first semiconductor region; pixel separating regions separating the pixels from one another and formed between the pixels, each of the pixel separating regions including a second semiconductor layer covering faces in contact with the photoelectric conversion elements, and an insulating film with a lower refractive index than a refractive index of the second semiconductor layer to cover the second semiconductor layer.

Abstract: In one embodiment, a solid-state imaging device includes: an imaging optical system including: a first and second surfaces facing each other; a flat reflector provided on the first surface and having an aperture in an outer circumferential portion; and a plurality of reflectors provided on the second surface and located in a plurality of ring-like areas, each of the reflectors being inclined in a radial direction, the reflectors having different diameters from one another; and an imaging element module including: an imaging element including an imaging area having a plurality of pixel blocks each including a plurality of pixels, and receiving and converting light from the imaging optical system into image data; a visible light transmission substrate provided between the imaging optical system and the imaging element; a microlens array provided on a surface of the visible light transmission substrate on the imaging element side; and an image processing unit processing the image data obtained by the imaging ele

Abstract: According to one embodiment, an imaging device includes a substrate, a photodetecting portion, a circuit portion and a through interconnect. The substrate has a first major surface, a second major surface on a side opposite to the first major surface, a recess portion provided on the first major surface and retreated in a first direction going from the first major surface to the second major surface, and a through hole communicating with the first major surface and the second major surface and extending in the first direction. The photodetecting portion is provided above the recess portion and away from the substrate. The circuit portion is electrically connected to the photodetecting portion and provided on the first major surface. The through interconnect is electrically connected to the circuit portion and provided inside the through hole. The recess portion has a first inclined surface. The through hole has a second inclined surface.

Abstract: According to an embodiment, a solid-state imaging device includes: an imaging device including an imaging area including a plurality of pixel blocks each of which includes a plurality of pixels; an image formation lens forming an image on an image formation plane by using light from a subject; an aperture unit including a plurality of aperture elements provided to associate with the plurality of pixel blocks, each of the aperture elements having an aperture portion and a shield portion, light from the image formation lens being filtered by each aperture element; a microlens array including a plurality of microlenses provided to associate with the plurality of aperture elements, each of the microlenses forming an image in the imaging area by using light filtered by an associated aperture element; and a signal processing circuit configured to process a signal of an image taken in the imaging area and estimates a distance to the subject.

Abstract: According to an embodiment, a solid-state imaging device includes: an imaging element formed on a semiconductor substrate; a first optical system configured to focus an image of a subject on an imaging plane; a second optical system including a microlens array including a plurality of microlenses corresponding to the pixel blocks, and re-focusing the image of the imaging plane onto the pixel blocks corresponding to the respective microlenses; a first filter placed on the second optical system, and including a plurality of first color filters corresponding to the microlenses; and a second filter placed on the imaging element, and including a plurality of second color filters corresponding to the first color filters of the first filter. The first and second filters are designed so that the first and second color filters deviate to a periphery of the imaging area, the deviation becoming larger toward the periphery of the imaging area.

Abstract: Certain embodiments provide an infrared imaging device including: an SOI structure that is placed at a distance from a substrate, and includes: heat-sensitive diodes that detect infrared rays and convert the infrared rays into heat; and STI regions that separate the heat-sensitive diodes from one another; an interlayer insulating film that is stacked on the SOI structure; and supporting legs that are connected to the heat-sensitive diodes and vertical signal lines provided in outer peripheral regions of the heat-sensitive diodes. Each of the supporting legs includes: an interconnect unit that transmit signals to the vertical signal lines; and interlayer insulating layers that sandwich the interconnect unit, each bottom side of the interlayer insulating layers being located in a higher position than the SOI structure.

Abstract: Certain embodiments provide a solid-state imaging device including: a photoelectric converting unit that includes a semiconductor layer of a second conductivity type provided on a semiconductor substrate of a first conductivity type, converts incident light entering a first surface of the semiconductor substrate into signal charges, and stores the signal charges; a readout circuit that reads the signal charges stored by the photoelectric converting unit; an antireflection structure that is provided on the first surface of the semiconductor substrate to cover the semiconductor layer of the photoelectric converting unit, includes a fixed charge film that retains fixed charges being non-signal charges, and prevents reflection of the incident light; and a hole storage region that is provided between the photoelectric converting unit and the antireflection structure, and stores holes being non-signal charges.

Abstract: Certain embodiments provide a solid-state imaging device including: a plurality of pixels provided on a semiconductor substrate, each of the pixels having a semiconductor region that converts incident light from a side of a first face of the semiconductor substrate into signal charges and stores the signal charges; a readout circuit provided on a side of a second face that is the opposite side from the first face, and reading out the signal charges stored in the pixels; and a pixel separation structure provided between adjacent ones of the pixels in the semiconductor substrate, the pixel separation structure including a stack film buried in a trench extending from the first face, the stack film including a first insulating film provided along side faces and a bottom face of the trench, and a fixed charge film provided in the trench to cover the first insulating film and retaining fixed charges that are non-signal charges.

Abstract: A piezoelectric substance element has a piezoelectric substance film and a pair of electrodes connected to the piezoelectric substance film on a substrate, and a main component of the piezoelectric substance film is Pb(Zr, Ti)O3, a composition ratio of Zr/(Zr+Ti) is over 0.4 but less than 0.7, the piezoelectric substance film is a film having at last a tetragonal crystal a-domain and a c-domain within a range of ±10° with respect to the surface of the substrate, and a volume rate of the c-domain to the total of the a-domain and the c-domain is equal to or larger than 20% and equal to or smaller than 60%.

Abstract: A solid-state image pickup device has a photoelectric conversion element that converts light incident from a first surface of a substrate into a signal charge and accumulates the signal charge, a transistor that is formed on a second surface side opposite to the first surface of the substrate and reads out the signal charge accumulated by the photoelectric conversion element, a supporting substrate stuck to the second surface of the substrate, and an antireflection coating formed on the first surface of the substrate, wherein the first surface of the substrate includes a curved surface or an inclined surface forming a prescribed angle to the second surface.

Abstract: BiFeO3 precursor solution is coated on the surface of an underlying member. Teat treatment is performed after the coating to form a dielectric film. The dielectric film is heated in a non-oxidizing atmosphere to crystallize the dielectric film. With this method, a ferroelectric material can be obtained which contains constituent elements of Bi, Fe and O and has crystal lattice of a tetragonal or orthorhombic system.