Switch circuits for electrical power are formed of a hybrid coupler configured to receive a signal as an input, and output first and second pulsed wave signals along first and second signal paths, respectively; in a plurality of time frames, wherein the phases of the first and second pulsed wave signals along first and second signal paths are aligned. The switch circuits may be incorporated in time folding power circuits as an exemplary application.

Switch circuits for electrical power are formed of a hybrid coupler configured to receive a signal as an input, and output first and second pulsed wave signals along first and second signal paths, respectively; in a plurality of time frames, wherein the phases of the first and second pulsed wave signals along first and second signal paths are aligned. The switch circuits may be incorporated in time folding power circuits as an exemplary application.

A distributor and a synthesizer with low loss are disclosed. In one example, a distributor/synthesizer has a distribution line that distributes a path from an input branch unit connected to an external transmission line on an input side into n-distributed paths. An output branch unit divides the n-distributed paths into an internal side and an external transmission line on an output side. On the internal side, a phase adjustment unit is arranged between the output branch unit and a coupling terminal, and adjusts the phase. A phase rotation amount from the input branch unit to the output branch unit of each of the n-distributed paths is π/2 [rad], and a phase rotation amount from the output branch unit to the coupling terminal is π [rad] or a real number multiple of π [rad]. The present disclosure can, for example, be applied to an FEM of a signal processing device.

A distributor and a synthesizer with low loss are disclosed. In one example, a distributor/synthesizer has a distribution line that distributes a path from an input branch unit connected to an external transmission line on an input side into n-distributed paths. An output branch unit divides the n-distributed paths into an internal side and an external transmission line on an output side. On the internal side, a phase adjustment unit is arranged between the output branch unit and a coupling terminal, and adjusts the phase. A phase rotation amount from the input branch unit to the output branch unit of each of the n-distributed paths is π/2 [rad], and a phase rotation amount from the output branch unit to the coupling terminal is π [rad] or a real number multiple of π [rad]. The present disclosure can, for example, be applied to an FEM of a signal processing device.

A waveguide power divider device comprises four two-port orthomode junctions arranged with their common waveguides extending in parallel, wherein the two ports of each orthomode junction extend in orthogonal directions, four E-plane T-junctions, each T-junction coupling two of the four orthomode junctions to each other via respective ones of their ports, a four-port turnstile junction, wherein waveguides of the four ports are bent to extend in parallel to an extension direction of a common waveguide of the turnstile junction, and four waveguide twists, each waveguide twist coupling a common waveguide of a respective one of the T-junctions to the waveguide of a respective one of the ports of the turnstile junction, with broad walls of the common waveguide of the T-junction and of the waveguide of the port of the turnstile junction being orthogonal to each other. An array antenna may include one or more such waveguide power divider devices.

A waveguide power divider device comprises four two-port orthomode junctions arranged with their common waveguides extending in parallel, wherein the two ports of each orthomode junction extend in orthogonal directions, four E-plane T-junctions, each T-junction coupling two of the four orthomode junctions to each other via respective ones of their ports, a four-port turnstile junction, wherein waveguides of the four ports are bent to extend in parallel to an extension direction of a common waveguide of the turnstile junction, and four waveguide twists, each waveguide twist coupling a common waveguide of a respective one of the T-junctions to the waveguide of a respective one of the ports of the turnstile junction, with broad walls of the common waveguide of the T-junction and of the waveguide of the port of the turnstile junction being orthogonal to each other. An array antenna may include one or more such waveguide power divider devices.

An electronic power divider for radio frequency signals, and an electronic system containing such electronic power divider, includes one or more inputs designed to be fed by an electromagnetic radio frequency signal having a predetermined wavelength; at least two outputs for the radio frequency signal, each of which is connected to the same input; electric paths adapted to connect each output to the corresponding input, and a system of selective variation of the electric impedance associated with each of the electric paths during the passage of the signal. The impedance variation system is adapted to vary the impedance associated with the paths discreetly between a lower and an upper value, and to simultaneously maintain the value of the impedance associated with two or more paths at least at the lower value.

An electronic power divider for radio frequency signals, and an electronic system containing such electronic power divider, includes one or more inputs designed to be fed by an electromagnetic radio frequency signal having a predetermined wavelength; at least two outputs for the radio frequency signal, each of which is connected to the same input; electric paths adapted to connect each output to the corresponding input, and a system of selective variation of the electric impedance associated with each of the electric paths during the passage of the signal. The impedance variation system is adapted to vary the impedance associated with the paths discreetly between a lower and an upper value, and to simultaneously maintain the value of the impedance associated with two or more paths at least at the lower value.

A device for concentrating an electromagnetic wave includes a waveguide array that includes a central waveguide having a first refractive index and a central axis and feeder waveguides disposed around the central waveguide. Each feeder waveguide has a second refractive index. The waveguide array also includes a support structure coupled to the waveguide arrays and configured to, in a deployed configuration, retain the feeder waveguides of the waveguide array in a substantially symmetric arrangement with respect to the central waveguide to enable concentration of an electromagnetic wave of a particular wavelength in the central waveguide via electromagnetic coupling of the central waveguide with each of the feeder waveguides, with the respective axis of each feeder waveguide oriented substantially parallel to the central axis of the central waveguide and with each feeder waveguide spaced apart from the central waveguide by a distance that is based on the particular wavelength.

A device for concentrating an electromagnetic wave includes a waveguide array that includes a central waveguide having a first refractive index and a central axis and feeder waveguides disposed around the central waveguide. Each feeder waveguide has a second refractive index. The waveguide array also includes a support structure coupled to the waveguide arrays and configured to, in a deployed configuration, retain the feeder waveguides of the waveguide array in a substantially symmetric arrangement with respect to the central waveguide to enable concentration of an electromagnetic wave of a particular wavelength in the central waveguide via electromagnetic coupling of the central waveguide with each of the feeder waveguides, with the respective axis of each feeder waveguide oriented substantially parallel to the central axis of the central waveguide and with each feeder waveguide spaced apart from the central waveguide by a distance that is based on the particular wavelength.