The present invention discloses an isolator and a signal generation method. The isolator includes an input-side circuit, an output-side circuit and a signal transmission unit. The input-side circuit is configured to receive an input signal and to generate an encoding signal according to the input signal. The signal transmission unit is coupled to the input-side circuit and configured to receive and transmit the encoding signal. The output-side circuit is coupled to the signal transmission unit and configured to receive the encoding signal from the signal transmission unit. The encoding signal includes a first portion and a second portion. The first portion is a pulse signal, and the second portion is a non-amplitude encoding signal.

A signal isolator integrated circuit package includes a first circuit having a first input and a first output, a second circuit having a second input and a second output, an isolation barrier layer between the first circuit and the second circuit, wherein the second output of the second circuit is coupled to the first input of the first circuit through the isolation barrier. The signal isolator includes a comparator configured to compare the first input of the first circuit to the second output of the second circuit. The second output can be configured to convey at least three states, including a first state indicative of a logical high of an input signal received at the first input, a second state indicative of a logical low of the input signal, and a third state indicative of a fault condition.

According to one embodiment, a digital isolator includes a first metal portion, a first insulating portion, a second metal portion, a third metal portion, and a first layer. The first insulating portion is provided on the first metal portion. The second metal portion is provided on the first insulating portion. The third metal portion includes first, second, and third portions. The first portion is provided around the first metal portion in a direction perpendicular to a first direction. The second portion is provided on a portion of the first portion with a first conductive layer interposed. The third portion is provided on the second portion and provided around the second metal portion in the perpendicular direction. The first layer contacts the first conductive layer and an other portion of the first portion and is provided around a bottom portion of the second portion.

A portable battery-operated communication device includes a high-speed communication bus, a first high-speed communication processor coupled to the bus and configured for transferring communication signals to a second high-speed communication processor over the bus, and an isolation circuit for the bus with a first terminal coupled to the bus and configured to receive a first communication signal from the first processor via the bus, and a first resistor that is coupled to the first terminal and configured to protect the first terminal from an overcurrent failure condition, in which the isolation circuit is configured to match impendences between the isolation circuit and bus, isolate series inductance associated with the first terminal, protect the first terminal from an overvoltage failure while maintaining signal integrity of the first communication signal, and pass through the first communication signal from the first terminal to a second terminal coupled to the high-speed communication bus.

The present invention discloses an isolator and a signal generation method. The isolator includes an input-side circuit, an output-side circuit and a signal transmission unit. The input-side circuit is configured to receive an input signal and to generate an encoding signal according to the input signal. The signal transmission unit is coupled to the input-side circuit and configured to receive and transmit the encoding signal. The output-side circuit is coupled to the signal transmission unit and configured to receive the encoding signal from the signal transmission unit. The encoding signal includes a first portion and a second portion. The first portion is a pulse signal, and the second portion is a non-amplitude encoding signal.

A mobile communications antenna comprises at least one antenna housing with a housing front side, a housing rear side, a first lateral housing side and a second lateral housing side opposite to the first. In the antenna housing, there are multiple radiating elements or pairs of radiating elements. The antenna further includes at least two amplifier modules, wherein each amplifier module comprises a first connection port and a second connection port and the amplifier modules are mounted on the exterior of the antenna housing. The connection ports are connected to corresponding first and second connection contact devices via plug-in connections. At least one signal processing and/or control unit is disposed in a housing, which is separate from the amplifier modules, in or on the antenna housing of the mobile communications antenna. The at least one signal processing and/or control unit comprises at least one digital interface to a baseband unit or to the mobile communication network and interfaces to the separate amplifier modules.

A system comprising a rack and at least one line replaceable module, the rack further comprising a primary transmission circuit comprising a primary antenna, primary emission components designed to generate an emitted power containing uplink data, and primary receiving components designed to receive downlink data, the line replaceable module comprising a secondary transmission circuit comprising a secondary antenna, secondary receiving components designed to receive the emitted power and the uplink data, and secondary emission components designed to generate the downlink data, the emitted power, the uplink data and the downlink data being transmitted via a shared coupling between the primary antenna and the secondary antenna.

A test system for checking electrical connections, especially solder connections, between electronic components with a circuit board to be checked, characterized in that the test system includes a communication interface with at least three electrically-conductive contact tips, which by contact with a contacting arrangement on the circuit board having a number of contacting locations enable a data exchange with a data memory and/or a communication module of a circuit board, wherein the data exchange occurs according to a communication protocol.

A detector circuit for galvanically isolated transmission of digital signals. The detector circuit includes two differential signal inputs, one input common-mode voltage connection, one alternating voltage coupling, and one differential stage. The detector circuit also includes one operating voltage connection, one operating ground connection, one signal output, one bias current connection, and one rectifier stage. The alternating current coupling includes two capacitors and two resistors. The differential stage includes a first n-channel transistor and a second n-channel transistor. The bias current connection is connected to the differential stage via a third n-channel transistor. The bias current connection is connected to the rectifier stage via a fourth n-channel transistor and a fifth n-channel transistor. The rectifier stage includes five p-channel transistors.

The present document discloses a transmission arrangement for coupling an amplifier to a transmission medium. An input node of the amplifier is couplable to a transmitter and an output node of the amplifier is couplable to a terminal of the transmission medium. The transmission arrangement may comprise a first branch coupled between the input node of the amplifier and an intermediate node which is couplable to a receiver. The transmission arrangement may further comprise a second branch coupled between the output node of the amplifier and the intermediate node. In particular, the first branch comprises a first capacitive element, while the second branch comprises a second capacitive element. Furthermore, at least one of the first and second branches further comprises a phase matching circuit coupled in series with the respective capacitive element.