Abstract: The present disclosure provides an optical system. In one aspect, the optical system includes a plurality of imagers configured to emit an electromagnetic radiation, a plurality of optical sensors configured to receive the electromagnetic radiation from the imagers, and a beam splitting device disposed at an optical path between the imagers and the optical sensors. In one example, the beam splitting device is a multi-way beam splitter configured to receive the electromagnetic radiation from one of the imagers and separate the received electromagnetic radiation into a plurality of portions, each separated portion of the received electromagnetic radiation being directed to one of the optical sensors.

Abstract: An optical element inspecting apparatus for inspecting optical elements for defects. The optical element inspecting apparatus includes an illuminating unit, an image capturing unit, two polarizers, a rotation device, a controller, and a means for composing a plurality of image data captured by the image capturing unit.The optical element to be inspected is placed between the polarizers and is illuminated by the illuminating unit. The light that passes through the polarizers and the optical element is captured by the image capturing unit and stored in memory. The controller controls the rotation device such that the polarizers are rotated by a predetermined amount and a subsequent image data is captured. In this way, a number of image data are captured and all image data are composed to make a composite image data. The optical element is examined to detect flaws therein by using the composite image data.

Abstract: An optical system for magnifying a display panel includes a magnifying lens disposed in front of a display panel. The magnifying lens is constructed with two lenses respectively having convex surfaces opposite each other. At least one of the two convex surfaces is aspherical. A transverse aberration of the magnifying lens is less than the diameter of the pupil of an eye at a point where the eye is positioned. The lens for the optical system is a Fresnel lens whose vortex center is located on its edge. An apparatus for magnifying display panels according to the invention includes an instrument to be viewed distantly and instruments to be viewed not distantly. The instrument to be viewed distantly is disposed distant from the Fresnel lens under a center portion of the Fresnel lens, whereas the instruments to be viewed not distantly are disposed close to the Fresnel lens under an edge portion of the Fresnel lens.

Abstract: An apparatus for focusing an actuator lens within an optical disc carriage held by a baseplate assembly. The apparatus incudes a frame, a cradle assembly mounted to the frame, a tower assembly mounted to the frame, a lever assembly rotatably mounted to the frame, and a gripper assembly mounted to the lever assembly. The cradle assembly includes a baseplate alignment assembly having a source of radiant energy for projecting a beam of radiant energy, a member for determining the tilt alignment of the beam with respect to the tower assembly, and tilt actuators for aligning the tilt of the beam with respect to the tower assembly. The tower assembly includes a video camera having a camera lens, a tower magnifying lens, and a monitor for displaying a representation of a beam of radiant energy passing through the tower magnifying lens and into the video camera.

Abstract: A zoom lens barrel and a method of adjusting the flange back focal distance of the zoom lens barrel is disclosed. The zoom lens barrel includes mounting members for mounting the zoom lens barrel on a camera body; a zoom ring that rotates for zooming relative to the mounting members; an adjustment member that may rotate with or relative to the zoom ring; and a cam ring. The cam ring is screwed to the adjustment member and moves in the optical axis direction due to the rotation of the adjustment member when the adjustment member rotates relative to the zoom ring, and when the adjustment member and the zoom ring both rotate, the zoom ring and the adjustment member rotate together. Lens units move in the optical axis direction due to the rotation of the cam ring.

Abstract: An image display apparatus, e.g., a head-mounted image display apparatus, which uses a compact optical system and yet has minimal aberrations and a large exit pupil diameter. An image displayed on a liquid crystal display device (2) is projected as an enlarged image in a user's eyeball by a convex lens (3). Prism arrays (13 and 14) having the same vertex angle are disposed in parallel to each other between the convex lens (3) and an exit pupil (6) so that the array directions coincide with each other. A parallel beam of light passed through the convex lens (3) has a pupil diameter (a) determined by the numerical aperture of an illumination system (1). The parallel beam first enters the prism array (13) and separates into light beams traveling in four different directions by the prism refracting action. These light beams then enter the prism array (14), which has the same vertex angle as that of the prism array (13). Consequently, the light beams are refracted again to become parallel to each other.

Abstract: There is disclosed a data imprinting apparatus which includes light source means for forming data, light splitting means for splitting light emitted from the light source means, first optical means for guiding one light beam split by the light splitting means onto a first area of the photosensitive surface, and second optical means for guiding the other light beam split by the light splitting means onto a second area of the photosensitive surface, and which can achieve proper data display states in correspondence with different phototaking modes with different phototaking areas.

Abstract: A wide-angle objective lens is comprised, from the object side, of a first lens component which is a negative meniscus lens having its convex surface facing the object side, a second lens component which is a meniscus lens having its convex surface facing the object side and having positive refractive power, a third lens component which is a cemented meniscus lens comprising a positive lens and a negative lens cemented together and having its convex surface facing the object side and having positive refractive power, a fourth lens component which is a positive meniscus lens having its concave surface facing the object side, and a fifth lens component which is a negative meniscus lens having its concave surface facing the object side. The wide-angle objective lens has a stop disposed between the second lens component and third lens component, and satisfies predetermined conditions.

Abstract: A magneto-optic recording magnetic head applies first and second magnetic fields to a magneto-optic disk having a recording film. The first magnetic field is used in a magnetic field modulation mode and the second magnetic field is utilized in a light modulation mode. The head comprises a yoke formed of a magnetic substance and having an opposing surface which opposes the recording film of the magneto-optic disk. A magnetic gap is formed between the yoke and a main magnetic pole magnetically coupled to the yoke. A cross-sectional area of the gap on a plane parallel to the recording film of the magneto-optic recording medium changes depending on whether the first or second magnetic field is generated, to maximize strengths of the first and second magnetic fields in accordance with the distance between the opposing surface of the yoke and the recording film of the disk.