An amplifier arrangement has a plurality of function strings, which are required for nominal operation. In addition, the amplifier arrangement has a redundancy circuit and a redundant function string including a redundant converter and a redundant amplifier. If a function string is faulty, the redundancy circuit supplies the input signals of the faulty function string to the redundant function string. In addition, a high-frequency system with an inner housing and an outer housing is described, wherein an air gap separates the inner housing and the outer housing from one another so that high-frequency signals can be transmitted via the air gap between the inner housing and the outer housing.

A differential amplifier is provided. The differential amplifier includes a first load, a second load, a current source, a differential pair circuit, a first and a second switch circuit. The differential pair circuit includes a first transistor, a second transistor, a third transistor, and a fourth transistor. The first switch circuit controls the first and the second transistors, and the second switch circuit controls the third and the fourth transistors. Through the control and selection of the first and second switch circuits, a differential pair is selected in the differential pair circuit to receive and process a first input signal and a second input signal for signal.

Method of operating a power combiner network (1), the power combiner network (1) comprising a power combiner device (10) having N secondary ports (11(1, 2, N)) combining into one primary port (12), wherein respective N secondary port (11(1, 2, . . . , N)) is provided with a phase shifter arrangement (13) and a load control arrangement (14). Respective phase shifter arrangement (13) is configured to set a phase of a signal fed through respective N secondary port (11(1, 2, . . . , N)). Respective load control arrangement (14) is configured to set the N secondary ports (11(1, 2, . . . , N)) in an active or in an inactive operation mode. For I inactive secondary ports (11(1)) the load control arrangement (14) is further configured to set a phase of the signal reflected from the I inactive secondary ports (11(1)). The method comprises the method steps of; step A (100), selecting which of the N secondary ports (11(1, 2, . . . , N)) that should be set in an inactive operation mode and which of the N secondary ports (11(1, 2, . . . , N)) that should be set in an active operation mode, step B (110), setting selected I inactive secondary ports (11(1)) in an inactive operation mode by means of the load control arrangement (14), step C (120), retrieving a phase required for respective I inactive secondary port (11(1)) and retrieving a phase required for respective A active secondary port (11(2)) in order for respective A active secondary port (11(2)) to minimize the reflected signal from the power combiner device (10) and provide desired power to the primary port (12), step D (130), setting respective load control arrangement (14) for respective I inactive secondary port (11(1)) according to respective retrieved phase, and step E (140), setting respective phase shifter arrangement (13) for respective A active secondary port (11(2)) according to respective retrieved phase.

A power amplifier provides reduction of click and pop in audio applications. The power amplifier includes a first amplifier and an auxiliary amplifier. The auxiliary amplifier is used to ramp the power amplifier output from ground to an offset voltage to reduce the “click and pop” sound. The first amplifier and the auxiliary amplifier having a shared feedback loop. An output of the first amplifier and an output of the auxiliary amplifier may be switchably coupled to the shared feedback loop. A wave generator controls a switch to couple the first amplifier output or the auxiliary amplifier output to the shared feedback loop.

Systems, methods, and apparatuses for improving reliability and/or reducing the likelihood of breakdown of an amplifier or a component thereof. A system can include a sensing circuit electrically coupled to a transistor of the amplifier and configured to sense an AC voltage associated with the transistor. A protection circuit can be electrically coupled to the sensing circuit and the amplifier and can be configured to supply a DC voltage to the transistor of the amplifier based on the AC voltage sensed by the sensing circuit.

A particle accelerator system including a particle accelerator that accelerates charged particles, a signal source that outputs high frequency power for accelerating the charged particles in the particle accelerator, an amplifying unit that amplifies the high frequency power from the signal source, and supplies the high frequency power to the particle accelerator, the amplifying unit including a plurality of semiconductor amplifiers using a semiconductor, and a control unit that controls an operation of the amplifying unit. The control unit controls output of at least one of the plurality of semiconductor amplifiers.

A power amplification device capable of detaching an element relating to the power amplification of an RF signal from an element relating to the combining of RF signals. The amplifying unit is provided with a plurality of groups of amplifier circuits that amplifies the power of a RF signal and the plurality of groups of amplifier circuits each includes a predetermined number of the amplifier circuits. A combining unit includes a first combiner and a second combiner. The first combiner is provided in association with the group of the amplifier circuits, combines RF signals output from the amplifier circuits belonging to the corresponding group, and outputs the RF signal after combining. The second combiner combines the RF signals output from each first combiner and outputs the RF signal after combining. The amplifying unit is attachable to and detachable from the combining unit.

A power amplification device comprises an amplifying unit and a combining unit. The amplifying unit is provided with a plurality of groups of amplifier circuits that amplifies the power of a radio frequency signal. The plurality of groups of amplifier circuits each includes a predetermined number of the amplifier circuits. The combining unit includes a plurality of combiners. The amplifying unit is housed by a first housing and the combining unit is housed by a second housing which is separate from the first housing. The amplifying unit is configured to be attachable to and detachable from the combining unit. The amplifying unit is configurable by one or more control voltages to perform amplification in classes AB, B and/or C. The amplification in classes AB, B, and/or C is compatible with a type of the combiner.

Method of operating a power combiner network (1), the power combiner network (1) comprising a power combiner device (10) having N secondary ports (11(1, 2, N)) combining into one primary port (12), wherein respective N secondary port (11(1, 2, . . . , N)) is provided with a phase shifter arrangement (13) and a load control arrangement (14). Respective phase shifter arrangement (13) is configured to set a phase of a signal fed through respective N secondary port (11(1, 2, . . . , N)). Respective load control arrangement (14) is configured to set the N secondary ports (11(1, 2, . . . , N)) in an active or in an inactive operation mode. For I inactive secondary ports (11(1)) the load control arrangement (14) is further configured to set a phase of the signal reflected from the I inactive secondary ports (11(1)). The method comprises the method steps of; step A (100), selecting which of the N secondary ports (11(1, 2, . . . , N)) that should be set in an inactive operation mode and which of the N secondary ports (11(1, 2, . . . , N)) that should be set in an active operation mode, step B (110), setting selected I inactive secondary ports (11(1)) in an inactive operation mode by means of the load control arrangement (14), step C (120), retrieving a phase required for respective I inactive secondary port (11(1)) and retrieving a phase required for respective A active secondary port (11(2)) in order for respective A active secondary port (11(2)) to minimize the reflected signal from the power combiner device (10) and provide desired power to the primary port (12), step D (130), setting respective load control arrangement (14) for respective I inactive secondary port (11(1)) according to respective retrieved phase, and step E (140), setting respective phase shifter arrangement (13) for respective A active secondary port (11(2)) according to respective retrieved phase.

A transmission and emission assembly for a multibeam antenna and a multibeam antenna are disclosed. In one aspect, the assembly includes a plurality of radiating elements forming a radiating surface, an emission distribution network arranged upstream from the radiating surface and including a plurality of emission ports, a receiving distribution network arranged upstream from the radiating surface and including a plurality of receiving ports, a plurality of low-noise amplifiers and a capability for interconnecting each receiving port to at least one low-noise amplifier. The emission distribution network and the receiving distribution network are separate from one another and are arranged in a same unit separate from the communication module. The receiving distribution network and the radiating elements are thermally separated.