Techniques including controlling coupling and uncoupling of RF ports included in an RF switch matrix including first-side RF ports and second-side RF ports, where each of the first-side RF ports is configured to be selectively coupled to at least one of two or more of the second-side RF ports, identifying one or more of the second-side RF ports as active ports including an active port, causing the RF switch matrix to couple the active port to a signal port included in the first-side RF ports, obtaining at least one of a bit error rate and a signal to noise ratio for a demodulation of an RF stream received via the active port, and causing, in response to at least one of the bit error rate or the signal to noise ratio, the RF switch matrix to couple the signal port to a spare port included in the second-side RF ports.

Techniques including controlling coupling and uncoupling of RF ports included in an RF switch matrix including first-side RF ports and second-side RF ports, where each of the first-side RF ports is configured to be selectively coupled to at least one of two or more of the second-side RF ports, identifying one or more of the second-side RF ports as active ports including an active port, causing the RF switch matrix to couple the active port to a signal port included in the first-side RF ports, obtaining at least one of a bit error rate and a signal to noise ratio for a demodulation of an RF stream received via the active port, and causing, in response to at least one of the bit error rate or the signal to noise ratio, the RF switch matrix to couple the signal port to a spare port included in the second-side RF ports.

The present technology relates to a transmitter, a transmission method, a receiver, and a reception method, and particularly to a transmitter, a transmission method, a receiver, and a reception method that can keep upsizing and cost increase to a minimum. The transmitter and the receiver have a detection mode and a communication mode as operation modes. The detection mode detects contact between a first waveguide on the side of the transmitter and a second waveguide on the side of the receiver. The communication mode sends or receives a modulated signal, acquired through frequency conversion of a baseband signal, via the first and second waveguides. The transmitter sends a given signal to the first waveguide in the detection mode. The transmitter and the receiver go from the detection mode to the communication mode in response to a given signal received by the receiver via the second waveguide and send and receive the modulated signal via the first and second waveguides in the communication mode. The present technology is applicable, for example, to communication via waveguides.

The present technology relates to a transmitter, a transmission method, a receiver, and a reception method, and particularly to a transmitter, a transmission method, a receiver, and a reception method that can keep upsizing and cost increase to a minimum. The transmitter and the receiver have a detection mode and a communication mode as operation modes. The detection mode detects contact between a first waveguide on the side of the transmitter and a second waveguide on the side of the receiver. The communication mode sends or receives a modulated signal, acquired through frequency conversion of a baseband signal, via the first and second waveguides. The transmitter sends a given signal to the first waveguide in the detection mode. The transmitter and the receiver go from the detection mode to the communication mode in response to a given signal received by the receiver via the second waveguide and send and receive the modulated signal via the first and second waveguides in the communication mode. The present technology is applicable, for example, to communication via waveguides.

A method of operating an RF system, the method including controlling coupling and uncoupling of RF ports included in an M by N radio frequency (RF) switch matrix including N first-side RF ports and M second-side RF ports, wherein each of the first-side RF ports may be selectively coupled to at least one of two or more of the second-side RF ports, such that RF signals are carried between selectively coupled ports; identifying one or more of the second-side RF ports as active ports, the active ports including a first active port; causing the RF switch matrix to couple the first active port to a first signal port included in the first-side RF ports; obtaining a first indication of reduced performance for a first piece of RF communication equipment coupled to the first active port; and causing, in response to the first indication, the RF switch matrix to couple the first signal port to a first spare port, wherein the first spare port is included in the second-side RF ports and is not included in the active ports.

A method of operating an RF system, the method including controlling coupling and uncoupling of RF ports included in an M by N radio frequency (RF) switch matrix including N first-side RF ports and M second-side RF ports, wherein each of the first-side RF ports may be selectively coupled to at least one of two or more of the second-side RF ports, such that RF signals are carried between selectively coupled ports; identifying one or more of the second-side RF ports as active ports, the active ports including a first active port; causing the RF switch matrix to couple the first active port to a first signal port included in the first-side RF ports; obtaining a first indication of reduced performance for a first piece of RF communication equipment coupled to the first active port; and causing, in response to the first indication, the RF switch matrix to couple the first signal port to a first spare port, wherein the first spare port is included in the second-side RF ports and is not included in the active ports.

A connection management method, a controller, and a server cabinet are provided The method comprises: sending a command to the switch to instruct the switch to send a signal to a designated port of the switch; receiving from a compute node connected to the designated port of the switch, a response to the signal received by the compute node from the designated port of the switch; and based on pre-acquired location information of the compute node, associating the pre-acquired location information of the compute node with the designated port of the switch.

A connection management method, a controller, and a server cabinet are provided The method comprises: sending a command to the switch to instruct the switch to send a signal to a designated port of the switch; receiving from a compute node connected to the designated port of the switch, a response to the signal received by the compute node from the designated port of the switch; and based on pre-acquired location information of the compute node, associating the pre-acquired location information of the compute node with the designated port of the switch.

The present application provides an antenna system for use in an electronic device. The antenna system includes a conductive substrate having a width, which corresponds to the distance between two opposite side edges of the conductive substrate proximate one end of the device. The antenna system further includes a pair of conductive arms, where each conductive arm in the pair of conductive arms has a connected end, which couples to the conductive substrate at alternative ones of the opposite side edges of the conductive substrate proximate the one end of the device. Each conductive arm further has an open end which extends away from the respective coupled side edge toward the other one of the opposite side edges in a direction of extension. The open ends of the conductive arms in the pair extend toward one another, stopping short of touching or overlapping the other conductive arm in the pair in the direction of extension away from the respective coupled side edge. Correspondingly, a gap is present between the respective open ends of the pair of conductive arms. A signal source is coupled to each of conductive arms proximate the respective open ends of the pair of conductive arms for supplying a signal. The signal source is coupled to at least one of the conductive arms via a respective feed line conductor, where the feed line conductor, that is coupled to the open end of the at least one of the pair of conductive arms, extends in the direction of extension which traverses at least a portion of the gap between the open ends of the conductive arms.

A telemetry system with a matrixed telemetry switch unit array and a method for determining the switch position of a telemetry switch unit. The switch units include steering diodes and parallel signal paths each with unique resistance values. The signal paths correspond to switch positions and are closed when the switch unit is in the corresponding switch position. A signal source is electrically connected to an input current path and output current path of the array with a corresponding telemetry switch unit coupled into the signal path. A plurality of sensing signals are applied through the array and the resultant signals are measured. The switch position is determined from the resultant signals indicating the resistance value of the switch signal path currently coupled into the array signal path while accounting for the voltage drop of the steering diodes.