A satellite monitoring system is disclosed. The system may monitor various downlink signals of various satellites. In response to user queries, the system may provide diagnostic and other data related to the characteristics of the downlink signals. In this manner, an independent verification and validation of downlink signal characteristics may be performed. Moreover, the system may take various actions in response to detected anomalies related to the characteristics of the downlink signals, such as automatically generating alerts for users and/or activating an uplink facility, such as a backup uplink facility and/or providing control signals to user devices, such as antenna controllers, to reorient user antennas in response to the characteristics of the downlink signals.

A satellite monitoring system is disclosed. The system may monitor various downlink signals of various satellites. In response to user queries, the system may provide diagnostic and other data related to the characteristics of the downlink signals. In this manner, an independent verification and validation of downlink signal characteristics may be performed. Moreover, the system may take various actions in response to detected anomalies related to the characteristics of the downlink signals, such as automatically generating alerts for users and/or activating an uplink facility, such as a backup uplink facility and/or providing control signals to user devices, such as antenna controllers, to reorient user antennas in response to the characteristics of the downlink signals.

An antenna device includes: multiple H-bridge circuits each of which including a first switch set and a second switch set connected in parallel with one another; a single connection antenna element connected between a point disposed between the two switching elements of the first switch set included in one H-bridge circuit and a point disposed between the two switching elements of the second switch set included in the one H-bridge circuit; and a multiple connection antenna element connected between a point disposed between the two switching elements of the first switch set included in the one H-bridge circuit and a point disposed between the two switching elements of the second switch set included in a different H-bridge circuit.

It is described a device for measuring the interference level of VSAT TDMA terminals, the terminals (13) communicating with a hub station (14) via a satellite (11). The device includes a forward link receiver (21) adapted to receive signals transmitted from the hub station (14) to the terminals (13) via said satellite (11), said receiver being capable of demodulating, decoding and analysing signalling information present in the forward link, including burst time plan, and terminal ID, a return link receiver (22) adapted to receive, demodulate and decode signals transmitted from each terminal (13) to the hub station (14) via said satellite (11) with extraction of the unique terminal network ID, an interfered link receiver (23) adapted to measure received interfering burst power in a link where interference occurs, said receiver being configured and synchronized with the burst time plan found from the forward link or decoded bursts from the return link receiver, performing interfered burst power measurements using power averaging or correlation techniques, and a controller (24) adapted to control and synchronize the receivers, analyse and correlate information received from the receivers to achieve synchronisation between the operational and interfered links(21, 22, 23) and report the power level of the interfering bursts for each terminal ID. Methods for operating the device are also described.

It is described a device for measuring the interference level of VSAT TDMA terminals, the terminals (13) communicating with a hub station (14) via a satellite (11). The device includes a forward link receiver (21) adapted to receive signals transmitted from the hub station (14) to the terminals (13) via said satellite (11), said receiver being capable of demodulating, decoding and analysing signalling information present in the forward link, including burst time plan, and terminal ID, a return link receiver (22) adapted to receive, demodulate and decode signals transmitted from each terminal (13) to the hub station (14) via said satellite (11) with extraction of the unique terminal network ID, an interfered link receiver (23) adapted to measure received interfering burst power in a link where interference occurs, said receiver being configured and synchronized with the burst time plan found from the forward link or decoded bursts from the return link receiver, performing interfered burst power measurements using power averaging or correlation techniques, and a controller (24) adapted to control and synchronize the receivers, analyse and correlate information received from the receivers to achieve synchronisation between the operational and interfered links(21, 22, 23) and report the power level of the interfering bursts for each terminal ID. Methods for operating the device are also described.

An electronic device, a cable, and a method of driving the same are provided. The cable that transmits data and power includes a notification device comprising notification circuitry configured to output a notification when the power is transmitted, a first connector positioned at one end of the cable, a second connector positioned at an other end of the cable, a wire connecting the first and second connectors and including a data line that transmits the data and a power line that transmits the power, and a cable controller connected to the power line and configured to identify a characteristic of power transmitted through the power line and to change a form of the notification output from the notification device based on the identified power characteristic.

An electronic device, a cable, and a method of driving the same are provided. The cable that transmits data and power includes a notification device comprising notification circuitry configured to output a notification when the power is transmitted, a first connector positioned at one end of the cable, a second connector positioned at an other end of the cable, a wire connecting the first and second connectors and including a data line that transmits the data and a power line that transmits the power, and a cable controller connected to the power line and configured to identify a characteristic of power transmitted through the power line and to change a form of the notification output from the notification device based on the identified power characteristic.

To provide a monitoring system capable of monitoring, without stopping operations for a long period of time, a change of the characteristics of an apparatus to be subjected to characteristic measurement, to which high frequency signals are inputted. [Solution] A signal to be monitored and a reference signal are inputted to an input unit 11 , and the input unit inputs one of the inputted signals to an apparatus 15 to be subjected to characteristic measurement. On the basis of an output signal of the apparatus 15 and the reference signal in the cases where the reference signal is inputted to the apparatus, an input/output characteristic calculation unit 12 calculates the input/output characteristics of the apparatus 15 . On the basis of calculation results obtained from the input/output characteristic calculation unit 12, a correction result generating unit 13 generates a correction result signal that indicates the results obtained by correcting an output signal of the apparatus 15 in the cases where the signal to be monitored is inputted to the apparatus. On the basis of the correction result signal generated by the correction result generating unit 13 , a failure determining unit 14 determines whether the apparatus has a failure.

To provide a monitoring system capable of monitoring, without stopping operations for a long period of time, a change of the characteristics of an apparatus to be subjected to characteristic measurement, to which high frequency signals are inputted. [Solution] A signal to be monitored and a reference signal are inputted to an input unit 11 , and the input unit inputs one of the inputted signals to an apparatus 15 to be subjected to characteristic measurement. On the basis of an output signal of the apparatus 15 and the reference signal in the cases where the reference signal is inputted to the apparatus, an input/output characteristic calculation unit 12 calculates the input/output characteristics of the apparatus 15 . On the basis of calculation results obtained from the input/output characteristic calculation unit 12, a correction result generating unit 13 generates a correction result signal that indicates the results obtained by correcting an output signal of the apparatus 15 in the cases where the signal to be monitored is inputted to the apparatus. On the basis of the correction result signal generated by the correction result generating unit 13 , a failure determining unit 14 determines whether the apparatus has a failure.

Systems and methods are disclosed for adjusting Radio Link Monitoring (RLM), Radio Link Failure (RLF) detection, RLF recovery, and/or connection establishment failure detection for wireless devices (16) in a cellular communications network (10) depending on mode of operation. In one embodiment, a node (14, 16) in the cellular communications network (10) determines whether a wireless device (16) (e.g., a Machine Type Communication (MTC) device) is to operate in a long range extension mode of operation or a normal mode of operation. The node (14, 16) then applies different values for at least one parameter depending on whether the wireless device (16) is to operate in the long range extension mode or the normal mode. The at least one parameter includes one or more RLM parameters, one or more RLF detection parameters, and/or one or more RLF recovery parameters. In doing so, signaling overhead and energy consumption within the wireless device (16) when operating in the long range extension mode is substantially reduced.