Fiber optic terminals having at least one loopback assembly comprising a loopback optical fiber providing optical communication between a first output connection port and a second output connection port of the terminal along with fiber optic networks using the terminals are disclosed. The loopback optical fiber is terminated with a first optical connector and a second optical connector. The first optical connector is attached to the first output connection port of the terminal and the second optical connector of the loopback assembly attached to the second output connection port of the terminal, thereby allowing the network operator to send a test signal to the terminal and receive a return signal when the terminal is installed in a fiber optic network.

An adjustable attenuation wrap plug for insertion into a signal port at an end product includes a housing with a protruding input prong and output prong, wherein a signal cable is coupled to the input prong and the output prong. The adjustable attenuation wrap plug further includes a ratchet mechanism at least partially disposed in the housing, wherein the ratchet mechanism is configurable to alter a shape of the signal cable.

A loop back connector and methods for testing lines in a fiber optic network are disclosed. The loop back connector includes a ferrule having an interface side constructed for optical connection to a multifiber optical cable. The loop back connector also includes first and second optical loop back paths, each having first and second terminal ends positioned at the interface side. The terminal ends of each loop back path are adapted to be aligned to fibers in the multifiber optical cable. The method includes injecting a signal on a first optical path at a first location, looping back the signal at a second location onto a second optical path, and receiving the signal on the second optical path at the first location.

An optical test instrument, in combination with a removable connector cartridge is provided. A method of replacing a damaged or worn optic fiber interface is also provided. The optical test instrument has casing having a cartridge receiving cavity therein with an inner end provided with a test instrument optical port; and an outer end provided with a cartridge receiving opening. The connector cartridge is sized and configured to be inserted in the cartridge receiving cavity. The connector cartridge has a cartridge inner end for facing the test instrument optical port when in use, and a cartridge outer end for receiving an optic fiber from a device under test (DUT). The connector cartridge houses a fiber optic cable extending between the cartridge inner end and the cartridge outer end. The connector cartridge is removably connectable to the instrument casing to allow replacement of the connector cartridge when the cartridge outer end is worn or damaged.

An adjustable attenuation wrap plug for insertion into a signal port at an end product includes a housing with a protruding input prong and output prong, wherein a signal cable is coupled to the input prong and the output prong. The adjustable attenuation wrap plug further includes a ratchet mechanism at least partially disposed in the housing, wherein the ratchet mechanism is configurable to alter a shape of the signal cable.

An optical module with detachable optical port includes a module body and an optical port plastic part. The optical port of the module body is provided with a groove for inserting the optical port plastic part, and the optical port plastic part and the groove are detachably connected. A test method for an AOC optical module is provided, where the AOC optical module is the above-mentioned optical module with detachable optical port. According to the optical module with a detachable optical port, the detachable optical port plastic part can be disassembled and replaced independently without disassembling the module body, which can make this optical module scheme more convenient to change into the AOC module by replacing the plastic part of the optical port, and there is no need to re-do the performance test, which effectively improves the flexibility of the product scheme.

Optical devices including an optical splitter and a duplex optical connector are disclosed. In one embodiment, an optical device includes an optical splitter having an input, a network output, and a pass-through output, wherein the optical splitter is configured to split an input signal received at the input into a network optical signal at the network output and a pass-through output signal at the pass-through output. The optical device further includes a duplex connector having an input connection point and a pass-through connection point, an input waveguide optically coupling the input connection point to the input of the optical splitter, and a pass-through waveguide optically coupling the pass-through connection point to the pass-through output of the optical splitter.

A loop back connector and methods for testing lines in a fiber optic network are disclosed. The loop back connector includes a ferrule having an interface side constructed for optical connection to a multifiber optical cable. The loop back connector also includes first and second optical loop back paths, each having first and second terminal ends positioned at the interface side. The terminal ends of each loop back path are adapted to be aligned to fibers in the multifiber optical cable. The method includes injecting a signal on a first optical path at a first location, looping back the signal at a second location onto a second optical path, and receiving the signal on the second optical path at the first location.

Fiber optic terminals having at least one loopback assembly comprising a loopback optical fiber providing optical communication between a first output connection port and a second output connection port of the terminal along with fiber optic networks using the terminals are disclosed. The loopback optical fiber is terminated with a first optical connector and a second optical connector. The first optical connector is attached to the first output connection port of the terminal and the second optical connector of the loopback assembly attached to the second output connection port of the terminal, thereby allowing the network operator to send a test signal to the terminal and receive a return signal when the terminal is installed in a fiber optic network.

An optical test instrument, in combination with a removable connector cartridge is provided. A method of replacing a damaged or worn optic fiber interface is also provided. The optical test instrument has casing having a cartridge receiving cavity therein with an inner end provided with a test instrument optical port; and an outer end provided with a cartridge receiving opening. The connector cartridge is sized and configured to be inserted in the cartridge receiving cavity. The connector cartridge has a cartridge inner end for facing the test instrument optical port when in use, and a cartridge outer end for receiving an optic fiber from a device under test (DUT). The connector cartridge houses a fiber optic cable extending between the cartridge inner end and the cartridge outer end. The connector cartridge is removably connectable to the instrument casing to allow replacement of the connector cartridge when the cartridge outer end is worn or damaged.