Abstract: Transceiver and method therein, for baseband processing of signals associated with TDD communication over wire lines. The method involves use of a single streaming I/O N/2-point complex FFT kernel for baseband processing of N-sample transmit and receive signal blocks. The processing comprises converting the N-sample signal blocks into intermediate N/2-point signals.

Abstract: Transceiver device and method therein, for baseband processing of signals associated with TDD communication over wire lines. The method involves use of a single burst I/O N-point complex FFT kernel for baseband processing of receive and transmit signal blocks, where the processing involves simultaneously performing a respective FFT or IFFT of two N-sample signal blocks.

Abstract: Systems and methods according to these exemplary embodiments provide for methods and systems that allow for either reducing signal loss or improving the optical signal strength in a PON for increasing optical signal range.

Abstract: The present invention relates to a method and apparatus for determining power provided by network terminals (103) to a common network node (101). The method comprises the steps of measuring (S201) power received per time unit from each indvidual network terminal, determining (S202) channel power loss per time unit of each individual network terminal and determining (S203) power provided per time unit by each individual network terminal by adding, to the power received per time unit from said each individual network terminal, the corresponding channel power loss per time unit.

Abstract: The present invention relates to a method and devices for fast protection of an optical network system, in particular for a Passive Optical Network (PON), such as a Gigabit-capable Passive Optical Network (GPON). In the method, it is detected that the communication from a first optical network device is lost. Switching of functionality is initiated from a first optical line termination device to a second optical line termination device, and a control message is sent from the second optical line termination device to the first optical network device such that the first optical network device is prevented from moving into initial state. Furthermore, the method comprises determining and setting timing settings for the first optical network device.

Abstract: The present invention relates to an interface and method for enabling interconnection of a host device and a small-formfactor pluggable module. The interface comprises a host device connector operative to receive a mating small-formfactor pluggable module connector and a switching device connected to the host device connector and operative to selectively switch at least one signal carried over the host device connector between at least two separate signal paths of the host device depending on a selected switching mode of the switching device.

Abstract: Systems and methods according to these exemplary embodiments provide for methods and systems that allow for either reducing signal loss or improving the optical signal strength in a PON for increasing optical signal range.

Abstract: The present invention relates to a small-cell antenna arrangement. The antenna arrangement comprises an antenna mounting unit and an active antenna element. The antenna mounting unit is arranged with fastening means from which the active antenna element is detachable. Further, the antenna mounting unit is arranged with a signalling interface via which signals are arranged to be transferred between the active antenna element and a remotely located base station with which the antenna arrangement communicates. Moreover, the antenna mounting unit is arranged with an interface via which the active antenna element is powered.

Abstract: A first network node of a cellular system is configured for communication with a second network node over a twisted pair wire. The first network node includes a receiver for receiving, over the twisted pair wire, an intermediate frequency signal from the second network node, which intermediate frequency signal has been converted from a high frequency signal having a frequency higher than the frequency of the intermediate frequency signal by the second network node, and a down-converter for converting the intermediate frequency signal to a low frequency signal having a frequency lower than the frequency of the intermediate frequency signal. The first network node also includes an up-converter for converting a received low frequency signal to an intermediate frequency signal having a frequency higher than the frequency of the low frequency signal.

Abstract: Embodiments of the present invention a method and an apparatus for stabilizing power supply to a connection device, such as an ONU. The power is supplied via wires using DC voltage and the wires having a first conductor and a second conductor. The currents in the first conductor and in the second conductor are measured and if a difference between the currents is detected as being above a first threshold value the supplied DC voltage will be lowered. Within period of time since it was detected that the difference between the currents were above the first threshold value it is decided if the difference between the currents is diminishing faster than a rate threshold value. In response, the controller is configured to instruct the converter to increase the supplied DC voltage.

Abstract: The present invention relates to a method and devices for fast protection of an optical network system, in particular for a Passive Optical Network (PON), such as a Gigabit-capable Passive Optical Network (GPON). In the method, it is detected that the communication from a first optical network device is lost. Switching of functionality is initiated from a first optical line termination device to a second optical line termination device, and a control message is sent from the second optical line termination device to the first optical network device such that the first optical network device is prevented from moving into initial state. Furthermore, the method comprises determining and setting timing settings for the first optical network device.

Abstract: The present invention relates to a method, device and system for fast protection of an optical network system, in particular for a Passive Optical Network (PON), such as a Gigabit-capable Passive Optical Network (GPON). In the method, communication failure between a first optical network device and a first optical line termination device is detected. Switching of functionality from the first optical line termination device to a second optical line termination device is initiated, and a control message is sent from the second optical line termination device to the first optical network device such that the first optical network device is prevented from moving into initial state. Furthermore, the method comprises determining and setting timing settings for the first optical network device.

Abstract: The present invention relates to a method and devices for fast protection of an optical network system, in particular for a Passive Optical Network (PON), such as a Gigabit-capable Passive Optical Network (GPON). In the method, it is detected that the communication from a first optical network device is lost. Switching of functionality is initiated from a first optical line termination device to a second optical line termination device, and a control message is sent from the second optical line termination device to the first optical network device such that the first optical network device is prevented from moving into initial state. Furthermore, the method comprises determining and setting timing settings for the first optical network device.

Abstract: The present invention relates to a powering method, a powering system, a cabinet and a central office for powering a copper-centric fiber to the x (FTTX) architecture. The architecture comprises at least one point to point or point to multipoint optical distribution network (ODN) between an optical line termination (OLT) or first Ethernet Switch positioned at a central office (CO) and an optical network unit or second Ethernet switch positioned at a cabinet (CAB) or building closer to a network terminal (CPE). The ODN is an active or passive network. The architecture further comprises at least one signalling coaxial or twisted wire pair line between the ONU or second Ethernet switch (ES) and one network terminal (CPE). What particularly characterizes the present invention is that the ONU or the second ES is powered remotely from the central office (CO) via at least one powering twisted wire pair line extending between the central office (CO) and the cabinet (CAB) or building.

Abstract: A system and method of extending a trunk reach of a passive optical network, PON. An optical network termination, ONT, processes upstream and downstream PON signals on a trunk fiber with an optical line termination, OLT, at a central office. An extender device may be implemented at a user's home, a remote node, or at the central office. The extender device includes a time division multiplexing, TDM, unit for multiplexing the PON signals, a forward error correction, FEC1 unit for applying an FEC to the PON signals, and a regenerator for applying optical-electrical-optical, OEO, regeneration to the PON signals.

Abstract: Method and arrangement for protecting optical network systems, the arrangement (20) is based on an optical electrical optical GPON repeater structure. The repeater structure contains two optical modules—a regular ONU transceiver module and a reset-less OLT transceiver module which are working back-to-back. For management purposes, an ONU MAC module comprised in the repeater structure is intercepting the electrical signals from the ONU transceiver. The arrangement comprising the two repeater structures can be used to relay data between two passive optical network (PON) systems thereby opening a way to implement dual homing via the PON domain. Moreover, the arrangement is configured to enabling switch-over of functionality from one PON to the other PON at a communication failure in the former PON.

Abstract: A qualification and monitoring function (604, 606) monitors the line conditions of a last mile access network that is connected with a multi-access broadband network. The qualification and monitoring function (604, 606) sends data to a Resource Manager (602) of the access network upon request. The monitoring function collects, stores, and analyzes performance data, media conditions and stability data using interpretation filters to derive performance indicators. The conditions of the network are also automatically provided to the resource manager (602) for immediate attention if the access network conditions exceed predetermined thresholds.

Abstract: Bandwidth allocation apparatus for apportioning bandwidth resource to at least one communications network node, the apparatus comprising a processor assembly and a logic array, the processor assembly comprises a data processor and a memory, the data processor configured to execute instructions stored in the memory and the logic array comprising a plurality of logic circuits connected in such a manner so as to implement particular processing of data, and the logic array arranged to determine bandwidth demand for the at least one node, and the processor assembly configured to at least in part calculate how the bandwidth is to be apportioned.

Abstract: A method of dynamic bandwidth allocation comprising updating a limit value (Bmax,i,j) of bandwidth, comprising subtracting from an initial value (Nij) a value (Mijk) indicative of previously assigned bandwidth, and adding a predetermined bandwidth value (Tij).

Abstract: The present invention concern a method and an apparatus for stabilizing power supply to a connection device, such as an ONU. The power is supplied via wires, such as telephone wires, using DC voltage and the wires having a first conductor, such as a ring conductor and a second conductor, such as a tip conductor. The currents in the first conductor and in the second conductor are measured and if a difference between the currents is detected as being above a first threshold value the supplied DC voltage will be lowered. Despite the instruction to lower the supplied DC voltage the currents in the first conductor and in the second conductor are continuously measured. Within period of time, e.g. 5 ms, since it was detected that the difference between the currents were above the first threshold value it is decided if the difference between the currents are below a second threshold value and/or if the difference between the currents is diminishing faster than a rate threshold value.