Abstract: An object detection device includes a first optical transceiver that generates a first beam flux and receives a scattered portion of the first beam flux, a second optical transceiver that generates a second beam flux and receives a scattered portion of the second beam flux, and a mirror unit that rotates around a rotation axis. The first beam flux is reflected by the mirror unit and is scanned based on the rotation of the mirror unit, and the scattered portion of the first beam flux is generated by scattering of the first beam flux by an object. The scattered portion of the first beam flux is reflected by the mirror unit before being received by a light receiving portion of the first optical transceiver, and the second beam flux is reflected by the mirror unit and is scanned based on the rotation of the mirror unit.

Abstract: An object detection device includes a first optical transceiver that generates a first beam flux and receives a scattered portion of the first beam flux, a second optical transceiver that generates a second beam flux and receives a scattered portion of the second beam flux, and a mirror unit that rotates around a rotation axis. The first beam flux is reflected by the mirror unit and is scanned based on the rotation of the mirror unit, and the scattered portion of the first beam flux is generated by scattering of the first beam flux by an object. The scattered portion of the first beam flux is reflected by the mirror unit before being received by a light receiving portion of the first optical transceiver, and the second beam flux is reflected by the mirror unit and is scanned based on the rotation of the mirror unit.

Abstract: Provided is a method for producing an inexpensive chalcogenide optical element having high performance. An inside of chalcogenide glass is also heated uniformly by heating the chalcogenide glass with an infrared ray (light LI). Therefore, a molded lens LE hardly causes a crack or the like, a work piece WP as a block of the chalcogenide glass can be softened in a short time, and time required for molding can be shortened. In addition, direct heating with an infrared ray (light LI) allows heating and cooling to be performed in a short time. Therefore, an effect of volatilization, oxidation, crystallization, or the like can be reduced, and the lens LE having a high transmittance can be molded. Press molding can be performed while the temperature of the second mold die 12 is lower than that of the glass. Therefore, the lens LE hardly causing fusion and having an excellent appearance can be molded with a low maintenance frequency.

Abstract: Disclosed is a curable resin composition including: a phosphorus-containing epoxy compound (A2) having a structure represented by formula (1) or (2) below; and a filler (A3), where in the formula (1), R1 and R2 each independently represent a hydrocarbon group having 1 to 6 carbon atoms, and m and n each independently represent an integer of 0 to 4, R1s may be the same or different when m is 2 or more, and R2s may be the same or different when n is 2 or more, and where in the formula (2), R3 and R4 each independently represent a hydrocarbon group having 1 to 6 carbon atoms, and o and p each independently represent an integer of 0 to 5, R3s may be the same or different when o is 2 or more, and R4s may be the same or different when p is 2 or more.

Abstract: The purpose of the present invention is to provide a lens unit which can create an effective light shield despite the simple process by which the lens unit is produced. A non-transmissive filler (BD) is filled and solidified in the gap between the outer periphery of a light shielding member (SH1) and the outer peripheries of a first lens (L1) and a second lens (L2).

Abstract: Disclosed is a mold used as a bottom mold for manufacturing glass molded bodies by accepting molten glass droplets that are dripped in and by compression molding of the molten glass droplets in conjunction with a top mold. The mold is provided with a base material that has a mold surface for compression molding of molten glass drops, and a coating layer formed on the mold surface. The surface of the coating layer formed on the mold surface has a rough surface region that comprises the center of the mold surface, and a mirror finished region that surrounds the outside of the rough surface region and has a lower arithmetic mean roughness Ra than the rough surface region.

Abstract: Disclosed is a mold used as a bottom mold for manufacturing glass molded bodies by accepting molten glass droplets that are dripped in and by compression molding of the molten glass droplets in conjunction with a top mold. The mold is provided with a base material that has a mold surface for compression molding of molten glass drops, and a coating layer formed on the mold surface. The surface of the coating layer formed on the mold surface has a rough surface region that comprises the center of the mold surface, and a mirror finished region that surrounds the outside of the rough surface region and has a lower arithmetic mean roughness Ra than the rough surface region.

Abstract: A die for forming an optical element, comprising: (i) a base member having a base surface which comprises a foundation area including a die surface to form an optical surface of the optical element and a peripheral area provided around the foundation area; (ii) a first layer covering both of the foundation area and the peripheral area and removable by being dissolved in a processing solution; and (iii) a second layer covering a part of the first layer corresponding in position to the foundation area so that a remaining part of the first layer corresponding in position to the peripheral area is not covered by the second layer.

Abstract: A die for forming an optical element, comprising: (i) a base member having a base surface which comprises a foundation area including a die surface to form an optical surface of the optical element and a peripheral area provided around the foundation area; (ii) a first layer covering both of the foundation area and the peripheral area and removable by being dissolved in a processing solution; and (iii) a second layer covering a part of the first layer corresponding in position to the foundation area so that a remaining part of the first layer corresponding in position to the peripheral area is not covered by the second layer.