The base member 3 can be attached to and detached from a base-holding member 5 without using tools and the like. The base-holding member 5 has a positioning mechanism that decides the position of the base member 3 on the base-holding member 5. Here, a reference part that decides the position of the base member 3 on the base-holding member 5 in a direction parallel to an optical fiber installation surface 2, which is an upper surface of the base member 3, is called a horizontal positioning reference part. Also, a reference part that decides the position of the base member 3 on the base-holding member in a direction vertical to the optical fiber installation surface 2 (the direction vertical to the horizontal positioning reference part), which is the upper surface of the base member 3, is called a vertical positioning reference part 6. That is, the horizontal positioning reference part and the vertical positioning reference part 6 are provided on the base-holding member 5.

A fusion splicer includes: a first gear including a first eccentric cam unit; a first rotating member including a first main body having a first abutting surface abutting on the first eccentric cam unit, a first arm unit extending from the first main body and rotatably supported by a main base, and a second arm unit extending from the first main body; a second gear including a second eccentric cam unit; and a second rotating member including a second main body having a second abutting surface abutting on the second eccentric cam unit, a third arm unit extending from the second main body and rotatably supported by the second arm unit, a fourth arm unit extending from the second main body, and a placing unit at a tip end of the fourth arm unit with a groove for receiving one of optical fibers.

On a top face (24a) of a base member (3), V-shaped grooves (15a) and (23a) are provided. On a reverse face (24b) of a base member (3), V-shaped grooves (15b) and (23b) are provided. The V-shaped grooves (15a) and (15b), which are first V-shaped grooves and are for holding optical fibers, and the V-shaped grooves (23a) and (23b), which are second V-shaped grooves and are for holding electrode rods (7), are formed facing each other, respectively. The positions of optical fibers and the electrode rods (7) are determined by the V-shaped grooves (15a) and (15b) and the V-shaped grooves (23a) and (23b), respectively.

A fusion splicing apparatus fusion-splices end faces 1a and 3a of a pair of optical fibers 1 and 3 to each other. The apparatus includes a mirror shaft 21 provided with a mirror 23 that is arranged between the end faces 1a and 3a of the pair of optical fibers 1 and 3 that are faced toward and spaced away from each other and is movable between a first position to reflect an image of the end face 1a and a second position to reflect an image of the end face 3a, a first camera 25 that takes the image of the end face 1a reflected in the first position, and a second camera 27 that takes the image of the end face 3a reflected in the second position.

One or more embodiments of the disclosure relates to an end cap holder for fixing an end cap to aid in alignment with an optical fiber prior to splicing by a splicing device. The use of the end cap holder may provide a method to fix an end cap holder having a different diameter from an optical fiber that the splicing device may be set up or adjusted for.

The present invention relates to a stacked optical fiber storage compartment formed to receive optical fibers, facilitate the connection of optical fibers and optical jumper cords, and facilitate the arranging and grouping of optical fibers. The stacked optical fiber storage compartment according to the present invention comprises: a compartment body including a main body portion having a receiving space and an open upper portion, and an opening and closing cover pivotably coupled on the main body portion to open and close the open upper portion of the main body portion; and an optical fiber connecting unit installed on the main body portion to receive and connect the respective optical fibers withdrawn from each of the tubes for optical cables extending into the compartment body. The optical fiber connecting unit comprises: a support plate mounted on the main body portion; connecting tube storing trays pivotably coupled through a hinge shaft to the support plate, and having optical connecting tube storing portions for connecting optical fibers; first and second keeping trays disposed at both sides of the respective connecting tube storing trays and including first and second keeping receiving portions that keep optical fibers or optical jump fibers and support same; and an optical fiber connecting unit installed on the support plate, and having an optical jump fiber when an optical fiber supported on the first keeping tray or the second keeping tray is jumped to a connecting tube storing tray from among the tube storing trays.

Provided is a defect review technique that can accurately correct coordinate differences with respect to unusual defects in which it is difficult to accurately correct coordinate misalignments by conventional automatic fine alignment. If it is impossible to correct a coordinate misalignment on the basis of a first optical microscope image acquired by a first light source, a defect review apparatus acquires a second optical microscope image using a second light source, and determines whether it is possible to correct the coordinate misalignment on the basis of the second optical microscope image.

An optical fiber holder for holding an optical fiber includes a holder body part on which a first optical fiber and a second optical fiber having a different outer diameter are mountable, a lid body which is disposed to the holder body part, and a fiber posture correction block which is provided on the lid body on a side close to a terminal processing part of the first optical fiber and the second optical fiber. The holder body part includes a first regulating part at an end part thereof on a terminal processing part side, and the first regulating part regulates movement of a first glass fiber of the first optical fiber and a second glass fiber of the second optical fiber. The fiber posture correction block includes a contact part to contact the second optical fiber at an end part thereof on the terminal processing part side.

A splice assembly for a fiber optic cable that has first and second fiber optic cable sections. The splice includes a filament alignment member configured to align an end portion of a first filament section of the first fiber optic cable section with an opposed end portion of a second filament section of the second fiber optic cable section; a first spring positioned adjacent the first end of the filament alignment member; a second spring positioned adjacent the second end of the filament alignment member; and a housing having a passage in which the first spring, filament alignment member and second spring are longitudinally positioned. The filament alignment member is longitudinally moveable relative to the housing by compression of one of the springs in a direction of travel of the filament alignment member against a corresponding stop feature.

A parallel position manipulator includes a top plate, a baseplate and a plurality of prismatic joint actuators. Each actuator includes an actuator joint having five Degrees of Freedom (DOF) at either the base plate or the top plate. When one or more of the actuators extends or contracts, the pivot points, or five DOF actuator joint, of the remaining actuators are allowed to shift in any axis other than that actuator's primary axis of motion.