Abstract: Implementations for remotely managing an optical transceiver connected to a network device and optical network is described. A user can use a network device controller and optical transceiver controller in a remote server to communicate with the service agent in the network device and the optical transceiver to configure communications with the optical network through the optical transceiver. The service agent and its controller in the server can perform virtualized transport functions and the network device controller and the network device can, in some instances, implement layer 2/3 demarc.

Abstract: Disclosed is a method and a device for generating report data related to a status of an interface of a network element are presented. The method includes: activating a delay timer when the interface status changes, setting delay-based data to express the interface status at the end of a delay determined by the delay-timer, setting dampening-based data to express the interface status if a penalty value fulfils a pre-determined condition and otherwise to express that the interface is non-utilizable, and setting the report data to express that the interface is utilizable if both the delay-based data and the dampening-based data express that the interface is utilizable. The penalty value is decreased with a dampening rule, and the penalty value is increased when the interface becomes non-utilizable and increasing the penalty value within a time-window is below a desired limit.

Abstract: Disclosed is a method and a device for generating report data related to a status of an interface of a network element are presented. The method includes: activating a delay timer when the interface status changes, setting delay-based data to express the interface status at the end of a delay determined by the delay-timer, setting dampening-based data to express the interface status if a penalty value fulfils a pre-determined condition and otherwise to express that the interface is non-utilizable, and setting the report data to express that the interface is utilizable if both the delay-based data and the dampening-based data express that the interface is utilizable. The penalty value is decreased with a dampening rule, and the penalty value is increased when the interface becomes non-utilizable and increasing the penalty value within a time-window is below a desired limit.

Abstract: A lookup system includes a ternary content-addressable memory TCAM configured to carry out a lookup on the basis of a lookup key so as to produce a preliminary lookup result. The lookup system further includes a subsystem configured to produce a final lookup result on the basis of the preliminary lookup result and auxiliary data including at least a part of bit values of do-not-care bit positions of the lookup key such that the preliminary lookup result is independent of the bit values of the do-not-care bit positions. The required number of TCAM-lines can be reduced because different alternatives of the auxiliary data corresponding to different possible bit values of the do-not-care bit positions of the lookup key are handled with the subsystem instead of the TCAM.

Abstract: A system using the Ethernet OAM functionality for finding the smallest of hop-specific data transfer speeds related to a data transfer path from a first network element (101) to a second network element (102) is presented. The first network element is configured to transmit, to the second network element, first data including an Ethernet OAM message. Each intermediate network element (104, 105) located on the data transfer path is configured to update the first data to indicate so far smallest of the hop-specific data transfer speeds when the first data passes through the intermediate network elements. After receiving the first data, the second network element transmits, to the first network element, second data indicating the smallest of the hop-specific data transfer speeds. Thus, the first network element can be made aware of capacity changes taking place on the data transfer path.

Abstract: A switch device for a network element includes a transfer system (110) for transferring data from ingress line interfaces of the network element to egress line interfaces of the network element in accordance with control information associated with the data. The transfer system includes a control section (111) configured to compare data traffic load to capacity available to the data traffic load at one of the egress line interfaces so as to generate a congestion indicator expressing whether a data flow (113) representing the data traffic load is a potential cause of congestion at the one of the egress line interfaces. The control section is further configured to direct a congestion control action to the data flow if the data flow is a potential cause of congestion. Thus, the congestion management related to the ingress and egress line interfaces can be carried out by the switch device.

Abstract: A switch device for a network element includes a transfer system (110) for transferring data from ingress line interfaces of the network element to egress line interfaces of the network element in accordance with control information associated with the data. The transfer system includes a control section (111) configured to compare data traffic load to capacity available to the data traffic load at one of the egress line interfaces so as to generate a congestion indicator expressing whether a data flow (113) representing the data traffic load is a potential cause of congestion at the one of the egress line interfaces. The control section is further configured to direct a congestion control action to the data flow if the data flow is a potential cause of congestion. Thus, the congestion management related to the ingress and egress line interfaces can be carried out by the switch device.

Abstract: In a system, the functionality is decentralized in a data transmission network so that the need of communications produced by and addressed to data terminals to pass by way of a single point in the data transmission network is diminished. A first data transmission installation is adapted to signal second data transmission installations, each of which is part of a ring-shaped data transmission topology, to be capable of building logical data transmission tunnels directed to the data terminals. Thereby, all the logical data transmission tunnels need not commence or, depending on the direction, terminate at the same point of a data transmission network. In addition, the data transmission installations present in a ring-shaped data transmission topology need not necessarily be taught routing information in order to enable each of these data transmission installations to send data transmission frames to be transmitted to another one of these data transmission installations.

Abstract: In a data communication system according to the invention the functionality of the gateway device is distributed in a data communication network thereby reducing the need to direct the data traffic from and to terminals (212, 213, 214) through a single point in the data communication network. A first data communication device (207) is arranged to make, through signalling, second data communication devices (204, 205, 206) capable of directing the data communications of the terminals to the starting points of the respective logical data communication tunnels (215, 216, 217). This way there is no need for all logical data communication tunnels to start from, or depending on the direction, to end at, the same point in the data communication network.

Abstract: Telecommunication equipment comprises at least one telecommunication device (208, 209) and a rack (201). The thickness of the telecommunication device is smaller than the width and the length of the telecommunication device. The rack comprises mutually parallel first rails (202, 203) that are substantially vertical when the rack is in its operating position, and second and third rails (210, 211) attached to the first rails. The third rail is parallel to the second rail and a distance apart from the second rail. The second and third rails are arranged to mechanically support the telecommunication device so that the telecommunication device is attached to the second and third rails and the thickness of the telecommunication device is in a direction substantially perpendicular to the first rails. Thus, the telecommunication device can be positioned so that its largest surfaces are in upright position. This facilitates the cooling of the telecommunication equipment.

Abstract: A system using the Ethernet OAM functionality for finding the smallest of hop-specific data transfer speeds related to a data transfer path from a first network element (101) to a second network element (102) is presented. The first network element is configured to transmit, to the second network element, first data including an Ethernet OAM message. Each intermediate network element (104, 105) located on the data transfer path is configured to update the first data to indicate so far smallest of the hop-specific data transfer speeds when the first data passes through the intermediate network elements. After receiving the first data, the second network element transmits, to the first network element, second data indicating the smallest of the hop-specific data transfer speeds. Thus, the first network element can be made aware of capacity changes taking place on the data transfer path.

Abstract: A device for detecting originators of a data frame storm includes a processing system (108) configured to detect the data frame storm on the basis of amount of data frames received from various originators. The processing is system is further configured to carry out the following actions when the storm is detected: identify an originator of each received data frame, update a measurement value related to the identified originator, and detect, on the basis the updated measurement value, whether the identified originator is an originator of the data frame storm. Therefore, it is first detected whether a storm of data frames is in general present and, if yes, it is detected, concerning each originator, whether the originator under question is an originator of the data frame storm. The originator-specific detections make it possible to direct restriction actions to data frames related to those originators which cause the data frame storm.

Abstract: In a system, the functionality is decentralized in a data transmission network so that the need of communications produced by and addressed to data terminals to pass by way of a single point in the data transmission network is diminished. A first data transmission installation is adapted to signal second data transmission installations, each of which is part of a ring-shaped data transmission topology, to be capable of building logical data transmission tunnels directed to the data terminals. Thereby, all the logical data transmission tunnels need not commence or, depending on the direction, terminate at the same point of a data transmission network. In addition, the data transmission installations present in a ring-shaped data transmission topology need not necessarily be taught routing information in order to enable each of these data transmission installations to send data transmission frames to be transmitted to another one of these data transmission installations.

Abstract: In a data communication system according to the invention the functionality of the gateway device is distributed in a data communication network thereby reducing the need to direct the data traffic from and to terminals (212, 213, 214) through a single point in the data communication network. A first data communication device (207) is arranged to make, through signalling, second data communication devices (204, 205, 206) capable of directing the data communications of the terminals to the starting points of the respective logical data communication tunnels (215, 216, 217). This way there is no need for all logical data communication tunnels to start from, or depending on the direction, to end at, the same point in the data communication network.