Monitoring and access control systems for network communication equipment of a network facility. A login device, to receive a credential of a user, is associated with a piece of network communication equipment arrangeable in a network facility. A monitor device is associated with the piece of network communication equipment to receive data associated with an access of the piece of network communication equipment. And, the data associated with the access of the piece of network communication equipment is auditable by a party to provide accountability of services performed on the piece of network communication equipment arrangeable in the network facility. A security device arranged with the piece of network communication equipment may un-lock or lock a portion of the piece of network communication equipment based at least in part on the credential received from the user.

Novel tools and techniques are provided for implementing installation of optical fiber, non-fiber lines, and/or power lines in a ground surface. In various embodiments, a foldable base might be placed in a channel in a ground surface. The foldable base might include a base portion, two side wall portions, at least two points of articulation, and two plug contacts. Each point of articulation allows each side wall portion to fold relative with the base portion, forming a cavity. One or more lines may be placed within the cavity. A plug, placed above the lines in the cavity, may engage with the two plug contacts to secure the plug to the foldable base. Capping material, placed in microchannel on a top surface of the plug, may flow beyond the microchannel and over any openings between the plug and the foldable base and between the foldable base and edges of the channel.

Disclosed is a scheme of transmitting at least two or more transmission signals, in which at least two or more pure random noise signals are contained, through multiple paths, according to one embodiment of the present invention. To implement such a scheme, a complementary noise generator may be used in a high-speed communication method and system with enhanced security according to the present invention. Here, the complementary noise generator refers to an apparatus in which a total sum of summing altogether at least two or more generated noises becomes 0. Namely, the complementary noise generator can generate m noises, and the sum of the in noises becomes 0. By injecting a plurality of noises having such feature into different paths, a channel capacity of each channel is reduced, thereby making a single wiretapping difficult. In comparison, because a receiver receiving a plurality of transmission signals with injected noises receives all noise signals and then sums up the noise signals, the noises are offset, and it is possible to effectively receive the original signal (random key K) intended for transmitting by a transmitter.

An assembly for retaining and securing an optical cable includes a retaining element and a housing with an insertion seat. The retaining element has a first retaining wall, a second retaining wall and a connection part connecting the first and second retaining walls. The connection part is configured to resiliently deform upon insertion of the retaining element in the insertion seat to allow mutual approach of said first and second retaining walls.

A fiber management tray (20) is disclosed. The fiber management tray (20) includes a tray body (22) defining a fiber storage region (24) for storing excess optical fiber length (26). The tray body (22) also includes a splice mount (28) for mounting at least one optical splice (30). The fiber management tray (20) includes a restricted access region (32) and an unrestricted access region (34) on the tray body (22). The splice mount (28) and the fiber storage region (24) are provided at the unrestricted access region (34), and an optical splitter component (36) is provided at the restricted access region (32).

Novel tools and techniques are provided for implementing installation of optical fiber, non-fiber lines, and/or power lines in a ground surface. In various embodiments, a foldable base might be placed in a channel in a ground surface. The foldable base might include a base portion, two side wall portions, at least two points of articulation, and two plug contacts. Each point of articulation allows each side wall portion to fold relative with the base portion, forming a cavity. One or more lines may be placed within the cavity. A plug, placed above the lines in the cavity, may engage with the two plug contacts to secure the plug to the foldable base. Capping material, placed in microchannel on a top surface of the plug, may flow beyond the microchannel and over any openings between the plug and the foldable base and between the foldable base and edges of the channel.

A cable access terminal includes: a base; a moving portion attached to the base; and a cover that is configured to prevent access to an upper area of the moving portion. The moving portion may be configured to prevent access to a base area in a closed position; the cover may be configured to prevent access to a first side of an adapter as a result of the cover being secured to the moving portion; and the moving portion may be structurally configured to permit access to the first side of the adapter and to the base area when the fastener is removed and to prevent access to the first side of the adapter and to the base area, while permitting access to the second side of the adapter, when the fastener is in place, so as to provide only limited access to users unauthorized to access the base area.

An elongated, marked protective sheath is disclosed which is closed along each side and open at each end and which has an elongated and flexible core material contained within the entire length of the elongated, marked protective sheath and extending from each open end. The elongated, marked protective sheath may be imprinted with anti-theft indicia indicating that elongated, marked protective sheath contains only fiber optic cable and does not contain copper. The core material extending from one end of the sheath may be tied to the front end of a fiber optic cable and then pulled into the sheaththus pulling the fiber optic cable into the sheath. In this manner, the fiber optic cable will be almost completely contained within the elongated sheath which has the aforementioned markings thereon to alert individuals that the sheath only contains fiber optic cable and does not contain copper.

Described herein is a fiber laser coupler, comprising a fiber laser cable enclosed in a housing, the housing includes a circuit and a temperature sensitive variable resistance element (TSVRE) coupled to the circuit, wherein the TSVRE is in thermal contact with one or more locations within the housing and is configured to provide a resistance in the circuit associated with a temperature of the TSVRE, wherein the circuit is further configured to couple to a processor configured to determine a temperature of the TSVRE based on reading the resistance in the circuit.

A fiber management tray (20) is disclosed. The fiber management tray (20) includes a tray body (22) defining a fiber storage region (24) for storing excess optical fiber length (26). The tray body (22) also includes a splice mount (28) for mounting at least one optical splice (30). The fiber management tray (20) includes a restricted access region (32) and an unrestricted access region (34) on the tray body (22). The splice mount (28) and the fiber storage region (24) are provided at the unrestricted access region (34), and an optical splitter component (36) is provided at the restricted access region (32).