Abstract: A passive optical device for implementing a direct interconnect network of nodes or clients in a network topology, said device comprising: a housing comprising a plurality of node port connectors and an internal fiber shuffle mechanism, wherein each of said plurality of node port connectors is connected to a node port shuffle cable that extends within the housing to the internal fiber shuffle mechanism, and wherein each of said plurality of node port shuffle cables comprises transmit and receive optical fibers that are cross connected within the internal fiber shuffle mechanism to transmit and receive optical fibers of other of the node port shuffle cables from the plurality of node port connectors to form optical paths between said node port connectors to implement the network topology, and wherein each of said node port connectors is also initially connected to a first-type R-key to maintain in-line connections within the network topology, and wherein said first-type R-key s are replaceable in a pre-determi

Abstract: A method, program, system and apparatus perform dynamic load balancing of coverage areas in a wireless communication network. The dynamic load balancing is performed by evaluating cell congestion based on location information of subscribers in the wireless communication network, collecting network parameters related to the wireless communication network and altering network parameters based on the evaluated cell congestion. After the network parameter is altered, the coverage areas are narrowed. Improvements in cell congestion and quality of server are then determined based on the narrowing of the coverage areas. Altering of the plurality of network parameters and evaluating of the cell congestion are performed continuously until a target quality of service is achieved.

Abstract: Calibrating signal processing paths for a plurality of transmission devices by obtaining calibration data for at least one of the signal processing paths for each of the transmission devices and determining a plurality of calibration weights from the calibration data for each of the transmission devices. A calibration variance is calculated between the plurality of calibration weights and it is determined if the calibration variance is below a calibration variance threshold. Additionally, a phase variation and a magnitude variation are calculated from the calibration data for each of the transmission devices with respect to a reference transmission signal obtained from a reference transmission device and it is determined for each of the transmission devices if the phase variation is below a phase variation threshold and if the magnitude variation is below a magnitude variation threshold.

Abstract: Calibrating signal processing paths for a plurality of transmission devices by obtaining calibration data for at least one of the signal processing paths for each of the transmission devices and determining a plurality of calibration weights from the calibration data for each of the transmission devices. A calibration variance is calculated between the plurality of calibration weights and it is determined if the calibration variance is below a calibration variance threshold. Additionally, a phase variation and a magnitude variation are calculated from the calibration data for each of the transmission devices and it is determined for each of the transmission devices if the phase variation is below a phase variation threshold and if the magnitude variation is below a magnitude variation threshold.

Abstract: Calibrating signal processing paths for a plurality of transmission devices by obtaining calibration data for at least one of the signal processing paths for each of the transmission devices and determining a plurality of calibration weights from the calibration data for each of the transmission devices. A calibration variance is calculated between the plurality of calibration weights and it is determined if the calibration variance is below a calibration variance threshold. Additionally, a phase variation and a magnitude variation are calculated from the calibration data for each of the transmission devices and it is determined for each of the transmission devices if the phase variation is below a phase variation threshold and if the magnitude variation is below a magnitude variation threshold.

Abstract: Calibrating signal processing paths for a plurality of transmission devices by obtaining calibration data for at least one of the signal processing paths for each of the transmission devices and determining a plurality of calibration weights from the calibration data for each of the transmission devices. A calibration variance is calculated between the plurality of calibration weights and it is determined if the calibration variance is below a calibration variance threshold. Additionally, a phase variation and a magnitude variation are calculated from the calibration data for each of the transmission devices with respect to a reference transmission signal obtained from a reference transmission device and it is determined for each of the transmission devices if the phase variation is below a phase variation threshold and if the magnitude variation is below a magnitude variation threshold.

Abstract: A method, program, system and apparatus perform dynamic load balancing of coverage areas in a wireless communication network. The dynamic load balancing is performed by evaluating cell congestion based on location information of subscribers in the wireless communication network, collecting network parameters related to the wireless communication network and altering network parameters based on the evaluated cell congestion. After the network parameter is altered, the coverage areas are narrowed. Improvements in cell congestion and quality of server are then determined based on the narrowing of the coverage areas. Altering of the plurality of network parameters and evaluating of the cell congestion are performed continuously until a target quality of service is achieved.

Abstract: A method and apparatus for hitless path switching whereby synchronous traffic is re-directed from an alternate path back over a primary path. A trace message is inserted at an originating path terminal into an information signal and the information signal is transmitted along the primary path and the alternate path. The information signal experiences different delays along the primary and alternate paths. The receiving path terminal is provided with two pointer processors, one for the primary path and one for the alternate path. The pointer processors use a first and a second buffer, respectively, for storing a number of frames of the respective information signal. The information signals arrive at the selector phase aligned, after the pointer processors perform positive and negative stuffing, respectively.

Abstract: An alarm signal processing circuit is provided for an integrated circuit having alarm signal generating circuitry for generating alarm signals having active and inactive states, and for connecting to a microprocessor. An alarm signal is stored in an alarm register which stores an inactive alarm signal until receipt of an active alarm signal, whereupon it stores the active alarm signal until receipt of an alarm register reset signal from the microprocessor. The alarm signal is also detected by an alarm detector which generates an event signal which is active when the alarm signal changes its status. An event register stores an inactive event signal until receipt of an active event signal, whereupon it stores the active event signal until receipt of an event register reset signal from the microprocessor. The event register outputs an event interrupt signal which is active when the stored event signal is active.