Abstract: A compound-eye imaging device comprises an imaging device body having 9 optical lenses and a solid-state imaging element for imaging unit images formed by the optical lenses. Assuming that the combination of each of the optical lenses with a corresponding divided area of the solid-state imaging element to image each of the corresponding unit images is an imaging unit, thereby forming multiple imaging units, the respective imaging units have randomly different optical imaging conditions. For example, the focal lengths of the 9 optical lenses are set to have random values in which the optical lenses are arranged to have random distances between adjacent ones thereof in a direction parallel to the major surface of the solid-state imaging element. This compound-eye imaging device substantially prevents unit images formed by respective imaging units from being the same, making it possible to easily increase the definition of a reconstructed image.

Abstract: An image pickup apparatus includes a first lens for converging light incident thereto through a first field area, a first prism to which light is incident through a second field area at a right of the first field area, a second lens for converging the light emitted from the first prism, a second prism to which light is incident through a third field area at a left of the first field area, and a third lens for converging the light emitted from the second prism. The respective lenses are placed at areas corresponding to the vertices of a triangle in a front view.

Abstract: A center lens for collecting light in a center range and left/right lenses for collecting light in left/right ranges are supported in one plane to form center and left/right unit images. A microprocessor combines the unit images into a wide-angle image. The left/right optical lenses are placed on left-right direction line parallel to the wide-angle direction, while the center lens is placed distant from the left/right lenses above the direction line. Prisms are placed in front of the left/right lenses, and a toroidal lens to vertically modify the light path for light convergence onto each lens is placed in front of the prisms. The toroidal lens has a vertically curved surface having an axis coinciding with the direction line, and a horizontally cured surface having an axis coinciding with a vertical line passing through the center lens. This device can obtain a wide-angle image with a vertically large picture angle.

Abstract: A panoramic imaging device comprises: a photodetector array; a lens array having, on one plane, a center lens for receiving light in a front range of 36° to form a central unit image on the photodetector array, and left and right side lenses for receiving lights in left and right ranges each of 72° in capture angle of 180°; and four prisms in two pairs placed facing the side lenses. The two pairs of left and right prisms (more inclined and less inclined pairs) collect lights in divided two pairs of left and right ranges each of 36° in the 72° range (pairs closer to, and farther from, the front range), respectively, to form four side unit images on the photodetector array which are combined with the central unit image to reproduce a panoramic image without using wide-angle lenses or complex image correction process.

Abstract: A panoramic imaging device comprises: a lens array having a center lens for receiving light entering in a front range of at most 60° in a capture angle and left and right side lenses formed on the same plane as that with the center lens formed thereon and having optical axes parallel to that of the center lens for receiving lights entering in left and right ranges each of at most 60° in the capture angle; and prisms or mirrors placed on light entrance side of the lens array for guiding and reflecting lights entering in the left and right ranges, such that each light entering each side lens is directed along the optical axis of each side lens. Images formed by the center lens and the left and right side lenses are combined into a panoramic image with a picture angle of at least 120°.

Abstract: A compound-eye imaging device comprises: an optical lens array with integrated multiple optical lenses; a photodetector array for imaging images formed by the optical lenses; and a light shielding block placed between the two arrays for partitioning a space between the two arrays into a matrix of spaces as seen on a plane perpendicular to the optical axis of each optical lens so as to prevent lights emitted from the optical lenses from interfering each other. The light shielding block is formed of flat unit plates of two kinds having different thicknesses and stacked between the optical lens array and the photodetector array. Since the light shielding block is formed of stacked flat unit plates, it is easy to manufacture a light shielding block having apertures with dense structure having a small distance between adjacent apertures, and also easy to adapt to variations in focal length of the optical lenses.

Abstract: A compound-eye imaging device comprising: an optical lens array with multiple integrated optical lenses having mutually parallel optical axes; a photodetector array placed at a predetermined distance from the optical lens array for imaging multiple images (referred to as single-eye images) formed by the optical lenses; and a microprocessor for reading the single-eye images imaged by the photodetector array. The image reading mode of the microprocessor is switchable between an all-read mode in which all the single-eye images on the photodetector array are sequentially read, and a partial-read mode in which a part of the single-eye images thereon are selectively read. The image reading speed of the microprocessor is changeable. The compound-eye imaging device enables a high frame rate and a high resolution imaging while reducing an increase in a clock frequency for the frame rate and thus reducing an increase in power consumption.

Abstract: An object distance deriving device comprises a compound-eye imaging unit for capturing n unit images and a microprocessor for calculating an object distance of an object from the imaging unit based on the unit images. The microprocessor sets a first temporary distance D1 from discrete temporary distances D1-Dn prepared in advance, and rearranges pixels of each unit image at D1 to create one reconstructed image. The microprocessor reversely projects the pixels of each unit image at D1 to create n reverse projection images. The microprocessor calculates and sums n deviations each between a pixel of the reconstructed image and that of each reverse projection image at each xy coordinate position to calculate an evaluation value for D1. The microprocessor repeats this process for the temporary distances D2-Dn to obtain n evaluation values. The microprocessor determines one of the temporary distances D1-Dn giving a minimum evaluation value as the object distance.

Abstract: A compound-eye imaging device comprises nine optical lenses arranged in a matrix array of three rows and three columns, and a solid-state imaging element for capturing unit images formed by the optical lenses. A stray light blocking member having a rectangular-shaped window is provided on the capture zone side of the optical lenses, eliminating the need to provide, between the solid-state imaging element and the optical lenses, walls by which light propagation paths of lights emitted from the optical lenses are partitioned from each other. The stray light blocking member blocks incident lights in a range outside each effective incident view angle range of each optical lens.

Abstract: A compound-eye imaging device comprises: an optical lens array with integrated optical lenses; a stop member; a photodetector array for imaging multiple images formed by the optical lenses; and a light shielding block for partitioning a space between the two arrays into a matrix of spaces, with light-passing holes, so as to prevent lights emitted from the optical lenses from interfering each other. The light shielding block is formed of unit plates in a stack, each having light-passing windows. Each light-passing window has blackened surface. The unit plates in the stack are alternately reversed upside down and left-right so as to allow the horizontal positions of the light-passing windows for forming each light-passing hole through the unit plates in the stack to be alternately offset in depth direction of the hole, thereby forming an irregular inner wall surface which serves as a light scattering surface to prevent e.g. ghost.

Abstract: A three-dimensional object imaging device comprises a compound-eye imaging unit and an image reconstructing unit for reconstructing an image of a three-dimensional object based on multiple unit images captured by the imaging unit. Based on the unit images obtained by the imaging unit, the image reconstructing unit calculates a distance (hereafter “pixel distance”) between the object and the imaging unit for each pixel forming the unit images, and rearranges the unit images pixel-by-pixel on a plane at the pixel distance to create a reconstructed image. Preferably, the image reconstructing unit sums a high-frequency component reconstructed image created from the multiple unit images with a lower noise low-frequency component unit image selected from low-frequency component unit images created from the multiple unit images so as to form a reconstructed image of the three-dimensional object. This makes it possible to obtain a reconstructed image with high definition easily by a simple process.

Abstract: A motion detection imaging device comprises: plural optical lenses for collecting light from an object so as to form plural single-eye images seen from different viewpoints; a solid-state imaging element for capturing the plural single-eye images formed through the plural optical lenses; a rolling shutter for reading out the plural single-eye images from the solid-state imaging element along a read-out direction; and a microprocessor for detecting movement of the object by comparing the plural single-eye images read out from the solid-state imaging element. The plural optical lenses are arranged so that the positions of the plural single-eye images formed on the solid-state imaging element are displaced from each other by a predetermined distance in the read-out direction, and so that the respective single-eye images formed on the solid-state imaging element partially overlap each other in the read-out direction.

Abstract: A compound-eye imaging device comprises: an optical lens array with integrated optical lenses; a stop member for shielding unnecessary ambient light from entering the optical lenses; a photodetector array formed of a semiconductor substrate and placed at a predetermined distance from the optical lens array for imaging images formed by the optical lenses; a light shielding block placed between the two arrays; and an optical filter for transmitting light from the optical lenses in a specific wavelength range. The optical filter is a part of, and integral with, the photodetector array. The optical filter can be a deposited film formed by depositing silicon oxide and titanium oxide on a glass plate provided for protecting a surface of, and integrally formed on, the semiconductor substrate. This enables to easily omit an optical filter separately provided between the two arrays, thereby reducing the thickness of the imaging device.

Abstract: A skin area detection imaging device for detecting a skin area of a human body as an object comprises: two optical lenses to form two unit images on an imaging element by collecting light from the object illuminated by near-infrared light; a rolling shutter for sequentially reading the unit images; and two LEDs for emitting lights with different wavelengths (850 nm and 940 nm) in the near-infrared range. A microprocessor switches on the two LEDs when reading the two unit images, respectively. The skin area of one read unit image is displayed with brightness different from that of the other unit image based on difference in reflectance to various wavelengths of near-infrared light. The microprocessor compares the two unit images to determine, as a skin area, an area having difference in brightness larger than a predetermined value. This makes it possible to detect the skin area in a short time.

Abstract: A panoramic imaging device comprises: a lens array with lenses in a matrix; an imaging element; and prisms for mirror-reflecting lights entering in left/right ranges in a capture range to guide them to side lenses in left/right columns. Light in a front range is inverted up/down by center lenses and formed as up/down inverted images on the imaging element. Lights in the left/right ranges are inverted up/down and left/right by the prisms with the side lenses and formed as up/down and left/right inverted images on the imaging element. The images in the left/right ranges are read in one direction. The images in the front range are read in an opposite direction. The read images are combined as is, without inverting the images, to reproduce a panoramic image. This can prevent the entire device from becoming large in volume, and imaging processing from becoming complex.

Abstract: A panoramic imaging device comprises: a photodetector array; a lens array having, on one plane, a center lens for receiving light in a front range of 36° to form a central unit image on the photodetector array, and left and right side lenses for receiving lights in left and right ranges each of 72° in capture angle of 180°; and four prisms in two pairs placed facing the side lenses. The two pairs of left and right prisms (more inclined and less inclined pairs) collect lights in divided two pairs of left and right ranges each of 36° in the 72° range (pairs closer to, and farther from, the front range), respectively, to form four side unit images on the photodetector array which are combined with the central unit image to reproduce a panoramic image without using wide-angle lenses or complex image correction process.

Abstract: A motion detection imaging device comprises an imaging element and an optical lens system for collecting light entering in a capture range to form images on the imaging element. The optical lens system comprises: an optical lens array having center lenses for collecting light in a front capture range and left/right side lenses for collecting lights in side capture ranges; and prisms for guiding lights in the side capture ranges to the side lenses. The imaging device further comprises: a timing generator for allowing images formed by the lenses to be imaged with a time difference between in-row images; and a microprocessor for reproducing wide angle images from the in-row images by one operation of a shutter to detect movement of a target based on difference between the wide angle images. The imaging device with simple structure can monitor, with high probability, a target moving fast in a wide range.

Abstract: A compound-eye imaging device comprises: an optical lens array with integrated optical lenses; a stop member; a photodetector array for imaging multiple images formed by the optical lenses; and a light shielding block for partitioning a space between the two arrays into a matrix of spaces, with light-passing holes, so as to prevent lights emitted from the optical lenses from interfering each other. The light shielding block is formed of unit plates in a stack, each having light-passing windows. Each light-passing window has blackened surface. The unit plates in the stack are alternately reversed upside down and left-right so as to allow the horizontal positions of the light-passing windows for forming each light-passing hole through the unit plates in the stack to be alternately offset in depth direction of the hole, thereby forming an irregular inner wall surface which serves as a light scattering surface to prevent e.g. ghost.

Abstract: A panoramic imaging device comprises: a lens array having a center lens for receiving light entering in a front range of at most 60° in a capture angle and left and right side lenses formed on the same plane as that with the center lens formed thereon and having optical axes parallel to that of the center lens for receiving lights entering in left and right ranges each of at most 60° in the capture angle; and prisms or mirrors placed on light entrance side of the lens array for guiding and reflecting lights entering in the left and right ranges, such that each light entering each side lens is directed along the optical axis of each side lens. Images formed by the center lens and the left and right side lenses are combined into a panoramic image with a picture angle of at least 120°.

Abstract: A photographic device includes an image sensor in which a plurality of pixels are arrayed. A horizontal scan circuit selects in order vertical drive lines to which the pixels are connected. And a vertical scan circuit reads voltages, due to accumulated electric charges, from the pixels in the horizontal row which is selected. A plurality of lenses are provided to the image sensor, arranged along the direction parallel to the vertical drive lines. Each of these lenses images an image of the same photographic region upon a pixel region which it confronts. The accumulated electric charges are read out from each pixel, arrayed in order. An image processing unit acquires a plurality of images of the photographic region spaced apart in time. And a moving body detection unit performs moving body detection from the differences between this plurality of images of the photographic region.