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    • 1. 发明申请
    • Object Distance Deriving Device
    • 物体距离推导装置
    • US20100103259A1
    • 2010-04-29
    • US12582501
    • 2009-10-20
    • Jun TANIDARyoichi HorisakiYoshizumi NakaoTakashi ToyodaYasuo Masaki
    • Jun TANIDARyoichi HorisakiYoshizumi NakaoTakashi ToyodaYasuo Masaki
    • H04N9/47
    • G01C3/08G01B11/026G02B3/0043G02B7/38G02B27/58
    • An object distance deriving device comprises: a compound-eye imaging device having imaging units with optical lenses randomly arranged for the respective imaging units; and a distance calculation unit to calculate an object distance using images captured by the compound-eye imaging device. The distance calculation unit: sets temporary distances z (S1); calculates an imaging process matrix [Hz] according to a temporary distance z (S2); estimates a high-resolution image by super-resolution processing using the imaging process matrix [Hz] (S3); uses the estimated high-resolution image to calculate an evaluation value distribution E for evaluating the temporary distance z (S4); repeats steps S2 to S4 for all temporary distances z (S5); and determines, as an object distance, one temporary distance z giving a minimum evaluation value in the evaluation value distributions E. This makes it possible to accurately derive the object distance even if the baseline length of the compound-eye imaging device is limited.
    • 物体距离导出装置包括:具有成像单元的复眼成像装置,其具有随机地布置用于各个成像单元的光学透镜; 以及距离计算单元,使用由复眼成像装置拍摄的图像来计算对象距离。 距离计算单元:设定临时距离z(S1); 根据临时距离z(S2)计算成像过程矩阵[Hz]; 使用成像处理矩阵[Hz](S3)通过超分辨率处理估计高分辨率图像; 使用估计的高分辨率图像来计算用于评估临时距离z的评估值分布E(S4); 对于所有临时距离z重复步骤S2至S4(S5); 并且将评估值分布E中给出最小评估值的一个临时距离z确定为对象距离。这使得即使限制复眼目标成像装置的基线长度,也可以准确地导出对象距离。
    • 2. 发明申请
    • COMPOUND-EYE IMAGING DEVICE
    • 化合物成像装置
    • US20090225203A1
    • 2009-09-10
    • US12395971
    • 2009-03-02
    • Jun TanidaRyoichi HorisakiTakashi ToyodaYoshizumi NakaoYasuo Masaki
    • Jun TanidaRyoichi HorisakiTakashi ToyodaYoshizumi NakaoYasuo Masaki
    • H04N5/225
    • H04N5/2254G02B3/0056H04N5/3415
    • 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.
    • 复眼成像装置包括具有9个光学透镜的成像装置主体和用于对由光学透镜形成的单元图像进行成像的固态成像元件。 假设每个光学透镜与固态成像元件的对应的分割区域的组合以对相应的单位图像进行成像,则成像单元,从而形成多个成像单元,各个成像单元具有随机地不同的光学成像 条件。 例如,9个光学透镜的焦距被设定为具有随机值,其中光学透镜被布置成在与固态成像元件的主表面平行的方向上具有相邻光学透镜之间的随机距离。 该复眼成像装置基本上防止由各个成像单元形成的单位图像相同,使得可以容易地增加重建图像的清晰度。
    • 3. 发明授权
    • Compound-eye imaging device
    • 复眼成像装置
    • US08237841B2
    • 2012-08-07
    • US12395971
    • 2009-03-02
    • Jun TanidaRyoichi HorisakiTakashi ToyodaYoshizumi NakaoYasuo Masaki
    • Jun TanidaRyoichi HorisakiTakashi ToyodaYoshizumi NakaoYasuo Masaki
    • H04N5/225G02B13/16
    • H04N5/2254G02B3/0056H04N5/3415
    • 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.
    • 复眼成像装置包括具有9个光学透镜的成像装置主体和用于对由光学透镜形成的单元图像进行成像的固态成像元件。 假设每个光学透镜与固态成像元件的对应的分割区域的组合以对相应的单位图像进行成像,则成像单元,从而形成多个成像单元,各个成像单元具有随机地不同的光学成像 条件。 例如,9个光学透镜的焦距被设定为具有随机值,其中光学透镜被布置成在与固态成像元件的主表面平行的方向上具有相邻光学透镜之间的随机距离。 该复眼成像装置基本上防止由各个成像单元形成的单位图像相同,使得可以容易地增加重建图像的清晰度。
    • 4. 发明授权
    • Optical condition design method for a compound-eye imaging device
    • 复眼成像装置的光学条件设计方法
    • US08115156B2
    • 2012-02-14
    • US12551088
    • 2009-08-31
    • Jun TanidaRyoichi HorisakiYoshizumi NakaoTakashi ToyodaYasuo Masaki
    • Jun TanidaRyoichi HorisakiYoshizumi NakaoTakashi ToyodaYasuo Masaki
    • H01L27/00
    • H04N5/2259H01L27/14625H01L27/14685H04N5/2254H04N5/349
    • An imaginary object plane is set in front of an imaging device body (plane setting step). A part of optical conditions of optical lenses are changed as variables, and positions of points (pixel observation points) on the imaginary object plane where lights coming from pixels of a solid-state imaging element and back-projected through the optical lenses are calculated (pixel observation point calculating step). The dispersion in position of the calculated pixel observation points is evaluated (evaluating step). Finally, a set of values of the variables giving maximum evaluated dispersion of the calculated pixel observation points is determined as optimum optical condition of the optical lenses (condition determining step). This reduces the number of pixels which image the same portions of the target object, making it possible to reduce portions of the same image information in multiple unit images, and to stably obtain a reconstructed image having a high definition.
    • 将虚拟物平面设置在成像装置主体的前方(平面设置步骤)。 光学透镜的光学条件的一部分作为变量而变化,并且在计算出来自固态成像元件的像素并通过光学透镜反投影的光的虚拟物面上的点(像素观察点)的位置( 像素观察点计算步骤)。 评估计算出的像素观察点的位置偏差(评价步骤)。 最后,将给出计算出的像素观察点的最大评估色散的变量的值的集合确定为光学透镜的最佳光学条件(条件确定步骤)。 这减少了对目标对象的相同部分进行成像的像素数量,从而可以减少多个单位图像中相同图像信息的部分,并且稳定地获得具有高清晰度的重建图像。
    • 5. 发明申请
    • Optical Condition Design Method for a Compound-Eye Imaging Device
    • 复合眼成像装置的光学条件设计方法
    • US20100053600A1
    • 2010-03-04
    • US12551088
    • 2009-08-31
    • Jun TanidaRyoichi HorisakiYoshizumi NakaoTakashi ToyodaYasuo Masaki
    • Jun TanidaRyoichi HorisakiYoshizumi NakaoTakashi ToyodaYasuo Masaki
    • G01B9/00
    • H04N5/2259H01L27/14625H01L27/14685H04N5/2254H04N5/349
    • An imaginary object plane is set in front of an imaging device body (plane setting step). A part of optical conditions of optical lenses are changed as variables, and positions of points (pixel observation points) on the imaginary object plane where lights coming from pixels of a solid-state imaging element and back-projected through the optical lenses are calculated (pixel observation point calculating step). The dispersion in position of the calculated pixel observation points is evaluated (evaluating step). Finally, a set of values of the variables giving maximum evaluated dispersion of the calculated pixel observation points is determined as optimum optical condition of the optical lenses (condition determining step). This reduces the number of pixels which image the same portions of the target object, making it possible to reduce portions of the same image information in multiple unit images, and to stably obtain a reconstructed image having a high definition.
    • 将虚拟物平面设置在成像装置主体的前方(平面设置步骤)。 光学透镜的光学条件的一部分作为变量而变化,并且在计算出来自固态成像元件的像素并通过光学透镜反投影的光的虚拟物面上的点(像素观察点)的位置( 像素观察点计算步骤)。 评估计算出的像素观察点的位置偏差(评价步骤)。 最后,将给出计算出的像素观察点的最大评估色散的变量的值的集合确定为光学透镜的最佳光学条件(条件确定步骤)。 这减少了对目标对象的相同部分进行成像的像素数量,使得可以减少多个单位图像中的相同图像信息的部分,并且稳定地获得具有高清晰度的重建图像。
    • 6. 发明申请
    • Object Distance Deriving Device
    • 物体距离推导装置
    • US20090060281A1
    • 2009-03-05
    • US12261706
    • 2008-10-30
    • Jun TANIDATakashi ToyodaYoshizumi NakaoYasuo Masaki
    • Jun TANIDATakashi ToyodaYoshizumi NakaoYasuo Masaki
    • G06K9/00
    • G06T3/00H04N5/3415
    • 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.
    • 物体距离导出装置包括用于捕获n个单位图像的复眼成像单元和用于基于单位图像计算物体与成像单元的物体距离的微处理器。 微处理器预先准备的离散临时距离D1-Dn设置第一临时距离D1,并且在D1处重新排列每个单位图像的像素以创建一个重建图像。 微处理器在D1处反向投影每个单位图像的像素,以产生n个反投影图像。 微处理器在每个xy坐标位置处计算和求和重建图像的像素与每个反向投影图像的像素之间的n个偏差,以计算D1的评估值。 微处理器对该临时距离D2-Dn重复该处理以获得n个评估值。 微处理器确定给出最小评估值的临时距离D1-Dn中的一个作为对象距离。
    • 7. 发明申请
    • Three-Dimensional Object Imaging Device
    • 三维物体成像装置
    • US20080247638A1
    • 2008-10-09
    • US12055762
    • 2008-03-26
    • Jun TanidaTakashi ToyodaYoshizumi NakaoYasuo Masaki
    • Jun TanidaTakashi ToyodaYoshizumi NakaoYasuo Masaki
    • G06T15/00
    • G06T7/557
    • 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.
    • 一种三维物体摄像装置,其特征在于,具备:复眼图像单元和图像重构单元,用于基于由所述摄像单元拍摄的多个单位图像来重构三维物体的图像。 基于由成像单元获得的单位图像,图像重建单元针对形成单位图像的每个像素计算对象和成像单元之间的距离(以下称为“像素距离”),并且逐个像素地重新排列单位图像 在像素距离的平面上创建重建图像。 优选地,图像重建单元将从多个单位图像创建的高频分量重构图像与从多个单位图像创建的低频分量单元图像中选择的较低噪声低频分量单元图像相加,以形成重构的 三维物体的图像。 这使得可以通过简单的过程容易地获得具有高清晰度的重建图像。
    • 8. 发明申请
    • Panoramic Imaging Device
    • 全景影像设备
    • US20090195639A1
    • 2009-08-06
    • US12417818
    • 2009-04-03
    • Takashi TOYODAYoshizumi NakaoYasuo Masaki
    • Takashi TOYODAYoshizumi NakaoYasuo Masaki
    • H04N7/00
    • G02B13/06G02B27/1066G03B37/04H04N5/2254H04N5/23238
    • 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.
    • 全景成像装置包括:光电检测器阵列; 一个透镜阵列,在一个平面上具有一个中心透镜,用于在前面的范围36°接收光,以在光电检测器阵列上形成一个中心单元图像;以及左右右侧透镜,用于在左右范围内接收72 °在捕获角度为180°; 并且面对侧透镜放置的两对棱镜四个。 两对左右棱镜(更倾斜和更小的倾斜对)以72°范围内的36°(分别靠近,远离前范围)分成两对左右范围收集光, 分别在光电检测器阵列上形成与中央单元图像组合的四个侧面单位图像,以再现全景图像而不使用广角镜头或复杂图像校正处理。
    • 9. 发明授权
    • Compound-eye imaging device
    • 复眼成像装置
    • US07700904B2
    • 2010-04-20
    • US12175372
    • 2008-07-17
    • Takashi ToyodaYoshizumi NakaoKouichi KugoYasuo Masaki
    • Takashi ToyodaYoshizumi NakaoKouichi KugoYasuo Masaki
    • H01L27/00
    • H04N5/2254
    • 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. This prevents the light entering each optical lens to form a unit image from interfering with other unit images formed by adjacent optical lenses, thereby obtaining a good quality image, without complicating the manufacturing process and increasing the cost thereof.
    • 复眼成像装置包括布置成三行和三列的矩阵阵列的九个光学透镜,以及用于捕获由光学透镜形成的单元图像的固态成像元件。 在光学透镜的捕获区侧设置具有矩形窗口的杂散光阻挡构件,消除了在固态成像元件和光学透镜之间提供发光的光传播路径的壁 从光学透镜彼此分隔开。 杂散光阻挡构件在每个光学透镜的每个有效入射视角范围之外的范围内阻挡入射光。 这防止进入每个光学透镜的光形成单位图像,从而干扰由相邻光学透镜形成的其它单元图像,从而获得高质量的图像,而不会使制造过程复杂化并增加其成本。
    • 10. 发明授权
    • Compound-eye imaging device having a light shielding block with a stack of multiple flat unit plates
    • 具有具有多个平板单元板堆叠的遮光块的复眼成像装置
    • US07525081B2
    • 2009-04-28
    • US11645700
    • 2006-12-27
    • Takashi ToyodaYoshizumi NakaoYasuo Masaki
    • Takashi ToyodaYoshizumi NakaoYasuo Masaki
    • H01L27/00
    • H01L27/14623H01L27/14627H01L27/14685H04N5/2254H04N5/2257
    • 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.
    • 复眼成像装置包括:具有集成的多个光学透镜的光学透镜阵列; 用于对由所述光学透镜形成的图像进行成像的光电检测器阵列; 以及放置在两个阵列之间的遮光块,用于将两个阵列之间的空间分隔成在垂直于每个光学透镜的光轴的平面上看到的空间矩阵,以便防止从光学透镜发射的光干扰每个 其他。 光屏蔽块由具有不同厚度的两种平面单元板形成,并且堆叠在光学透镜阵列和光电检测器阵列之间。 由于遮光块由堆叠的平板单元板形成,因此容易制造具有密相结构的孔的相邻孔之间的距离小的遮光块,并且也容易适应于光学透镜的焦距的变化。