Abstract: The present embodiment relates to an optical amplifier which can perform an amplification operation equivalent to a normal operation even with an increase of dark current in a PD forming a part of a light detection circuit for monitoring signal light as an amplification object. In the optical amplifier, a detection controller performs an anomaly determination on a light detection circuit due to an increase of dark current in the PD based on a difference between temporal change amounts of a signal component of a voltage of output signal from a light receiving unit including the PD, and a voltage component in a high frequency region included in the signal component. An amplification controller can perform suitable switching of control on a drive current to a pumping light source, based on the result of the determination.

Abstract: This optical-fiber fusion-splicing device includes: a first heating device (12); a second heating device (13); and a CPU (14) which controls the first heating device (12) and the second heating device (13), wherein the CPU (14) stops heating of the second heating device (13) if heating of the first heating device (12) is started during heating in the second heating device (13), and resumes the heating of the second heating device (13) if the heating of the first heating device (12) is ended, and sets a heating condition after resumption of heating in the second heating device (13), based on at least an interruption time of heating or a change in temperature during heating interruption in the second heating device (13).

Abstract: An optical fiber fusion splicer includes optical fiber holders that hold optical fibers. Each optical fiber holder includes a base, a cover, and a connecting portion. The base includes a setting table on which an optical fiber F is placed so as to be oriented in the longitudinal direction of the base. The cover has pressing members that press the optical fiber F placed on the setting table against the setting table. The connecting portion joins the cover to the base such that the cover is openable away from and closeable over the base and movable in the longitudinal direction of the base.

Abstract: An optical fiber fusion splicer disclosed. The optical fiber fusion splicer includes: a first microscope configured to observe first and second optical fibers from a first direction by receiving light emitted from a first light source; a second microscope configured to observe the first and second optical fibers from a second direction by receiving light emitted from a second light source, the second direction crossing the first direction; a fusion splicing mechanism configured to fusion-splice an end portion of the first optical fiber and an end portion of the second optical fiber; and a control unit configured to control the fusion splicing mechanism. The first microscope is movable in the first direction. The second microscope is secured to not move in the second direction.

Abstract: A slider is attached to a cutter main body of an optical fiber cutter in a forward/backward movable state. A round blade member for making a scratch in an optical fiber is attached to the slider in a rotatable state. An operation lever pin for changing over rotation operation modes from one to another is attached to one end side of a pin member which penetrates a wall of the cutter main body. The rotation operation modes include a non-rotation mode for preventing the round blade member from being rotated and a continuous rotation mode for rotating the round blade member by a predetermined angle with every backward movement of the slider.

Abstract: To provide a method for assembling an optical connector with which the optical connector can be easily assembled. An optical connector is assembled by preparing a holding cap that holds a frame member and a plug housing while maintaining a relative positional relationship between the frame member and the plug housing, inserting a ferrule into the frame member, and connecting the plug housing and the rear housing to each other.

Abstract: An optical fiber fusion splicer includes a base having a fiber groove for containing an optical fiber, a fiber clamp for pressing the optical fiber contained in the fiber groove against the base and load changing means for changing a load for the fiber clamp to press the optical fiber.

Abstract: A heating device for heating an optical fiber reinforcing member includes fiber holders to hold optical fibers covered with the reinforcing member at a fusion-spliced portion, a heater to heat the reinforcing member, a power supply unit to apply a voltage to the heater, and a controller to control the application of a voltage from the power supply unit to the heater. The controller includes a detecting unit that detects a parameter for determining the amount of heat generation of the heater, a storage unit that stores a plurality of heating conditions that vary depending on the parameter value, and a condition instruction unit that selects any of the plurality of heating conditions in accordance with the parameter value detected by the detecting unit and instructs the power supply unit to apply a voltage to the heater on the basis of the selected heating condition.

Abstract: A method of fusion-splicing includes attaching a stab to a stub cap having a non-axisymmetric structure, positioning an embedded optical fiber to a fusion splicing working part by fixing the stub cap thereto; positioning an outside optical fiber to the fusion splicing working part; fusion-splicing the embedded optical fiber and the outside optical fiber; repositioning the embedded optical fiber to a reinforcing working part by fixing the stub cap thereto and repositioning the outside optical fiber to the reinforcing working part such that a relative positional relationship between the embedded optical fiber and the outside optical fiber becomes the same as that at the fusion splicing working part; and reinforcing a spliced portion between the embedded optical fiber and the outside optical fiber while a tension is applied to the embedded optical fiber and the outside optical fiber.

Abstract: The optical fiber cutter 1 comprises a cutter base 3 and a cutter lid 4 attached openably and closably to the cutter base 3. A slider 8 having a blade member for incising an optical fiber is attached to the cutter base 3 so as to be movable widthwise. A switching plate 15 is attached to a rear end part of the cutter base 3, while a switcher 16 is provided on the outer surface side of the switching plate 15. When the switcher 16 is at a first position, the cutter lid 4 engages a stopper, thereby attaining an opening angle of 35°. When the switcher 16 is at a second position, the engagement between the cutter lid 4 and the stopper is released, whereby the cutter lid 4 attains an opening angle of 70°.

Abstract: A simplified optical coupling system having two optical connectors is disclosed. The optical coupling system includes a male connector with a ferrule, a female connector with another ferrule, and a sleeve to receive the ferrules in respective ends thereof. One of connectors provides a latch and a coil spring. The latch engages with a flange of the other connector, and the coil spring put between the flange of the connector having the latch and a base of the latch to secure the engagement of the latch with the flange.

Abstract: A fusion splicer includes a pair of holder installation parts for mutually butting optical fibers in a first direction, and a fusion splicing part for mutually fusing and splicing the optical fibers by a pair of electrodes opposed along a second direction, and the holder installation part includes a base fixed to a body, and a positioning member in which a base fitting part fitted into the base is formed in a lower side, and the positioning member can be attached to and detached from both of the bases after an attitude is reversed, and a center position in a width direction along the second direction in the base fitting part is arranged in a straight line of the first direction passing through a center position between the electrodes even in a state in which the positioning member is fitted into any of the bases.

Abstract: An optical connector and a method for assembling the optical connector with which the optical connector can be easily assembled are provided. An optical connector includes a ferrule assembly including a ferrule that holds an embedded fiber, a sleeve that holds the ferrule assembly, and a rear housing that is connected to the sleeve and through which an optical fiber that is connected to the embedded fiber is inserted. The ferrule assembly is fixed to the sleeve by threadably engaging a male screw of the ferrule assembly with a female screw of the sleeve.

Abstract: A method for fusion splicing of a holey optical fiber with a cladding having a large number of air holes along the axis thereof to another optical fiber includes the use of arc discharge heating. First, the method uses arc discharge heating such that the temperature of a position rearward of an end surface of the holey optical fiber is higher than the temperature of the end surface, thereby making a tip portion of the holey optical fiber transparent. Next, the cores are aligned with one another. Then the method includes performing fusion splicing by second arc discharge heating. The first arc discharge heating is performed between discharge electrodes positioned rearward of the end surface of the holey optical fiber. The arc heating time of the first arc discharge heating is preferably 200 to 400 milliseconds.

Abstract: An optical fiber jacket remover draws a glass fiber out from a coating by cutting the coating in a jacket removing portion and moving an optical fiber holding portion away from a jacket remover main unit in a heated state. The jacket removing portion is provided with a heater supporting member on which a heater is mounted. The heater supporting member is accommodated in a recessed receiving portion formed in a case. A heat insulating space is formed between the recessed receiving portion and the heater supporting member. A side surface of the heater supporting member and an inside surface of a lateral wall of the recessed receiving portion are brought into contact with each other via a lateral rib formed on the heater supporting member, and the heat insulating space is thereby blocked.

Abstract: A heating device for heating an optical fiber reinforcing member includes fiber holders to hold optical fibers covered with the reinforcing member at a fusion-spliced portion, a heater to heat the reinforcing member, a power supply unit to apply a voltage to the heater, and a controller to control the application of a voltage from the power supply unit to the heater. The controller includes a detecting unit that detects a parameter for determining the amount of heat generation of the heater, a storage unit that stores a plurality of heating conditions that vary depending on the parameter value, and a condition instruction unit that selects any of the plurality of heating conditions in accordance with the parameter value detected by the detecting unit and instructs the power supply unit to apply a voltage to the heater on the basis of the selected heating condition.