In a non-reciprocal circuit element, a permanent magnet is connected to one main surface of a magnetic plate, and a circuit board is connected to the other main surface of the magnetic plate, with a solder bump lying between the circuit board and the other main surface. The permanent magnet can control the transmission of electrical signal from each of a plurality of signal conductors of circuit board to a corresponding one of a plurality of input/output terminals of the magnetic plate. The non-reciprocal circuit element further includes an underfill material arranged between the magnetic plate and the circuit board. The magnetic plate has a through hole formed therein, the through hole extending from one main surface to the other main surface. The through hole has an empty space in which at least a part of a conductive film arranged in the through hole is exposed.

In a non-reciprocal circuit element, a permanent magnet is connected to one main surface of a magnetic plate, and a circuit board is connected to the other main surface of the magnetic plate, with a solder bump lying between the circuit board and the other main surface. The permanent magnet can control the transmission of electrical signal from each of a plurality of signal conductors of circuit board to a corresponding one of a plurality of input/output terminals of the magnetic plate. The non-reciprocal circuit element further includes an underfill material arranged between the magnetic plate and the circuit board. The magnetic plate has a through hole formed therein, the through hole extending from one main surface to the other main surface. The through hole has an empty space in which at least a part of a conductive film arranged in the through hole is exposed.

A circulator is provided, comprising, first second and third conductors forming three equally spaced junctions and a permanent magnet configured to apply a shaped bias magnetic field to a ferrite resonator in operable communication with the first, second, and third conductors. The permanent magnet comprises a substantially planar monolithic structure having defined thereon at least first and second substantially concentric regions having first and second respective magnetic field strength levels, wherein the second magnetic field strength level is lower than the first magnetic field strength level. The first and second magnetic field strength levels are configured to cooperate to shape an external bias magnetic field of the permanent magnet to counteract at least a portion of a demagnetizing effect resulting from of an overall shape of the ferrite resonator, to achieve a substantially uniform internal magnetic bias within at least a portion of the ferrite resonator.

A circulator is provided, comprising, first second and third conductors forming three equally spaced junctions and a permanent magnet configured to apply a shaped bias magnetic field to a ferrite resonator in operable communication with the first, second, and third conductors. The permanent magnet comprises a substantially planar monolithic structure having defined thereon at least first and second substantially concentric regions having first and second respective magnetic field strength levels, wherein the second magnetic field strength level is lower than the first magnetic field strength level. The first and second magnetic field strength levels are configured to cooperate to shape an external bias magnetic field of the permanent magnet to counteract at least a portion of a demagnetizing effect resulting from of an overall shape of the ferrite resonator, to achieve a substantially uniform internal magnetic bias within at least a portion of the ferrite resonator.

A variable power divider comprising a latching ferrite circulator including an input port, a first output port, a second output port, and at least one winding. The ports meet in a common junction. The variable power divider also includes a controller interface that receives a command signal indicating a desired power division ratio and a driver circuit configured to receive a control signal from the controller interface. The driver circuit generates a first pulse, having a duration and amplitude corresponding to a saturation state of the latching ferrite circulator, in a first direction through the at least one winding. After the first pulse, the driver circuit generates a second pulse in a second direction through the at least one winding opposite the first direction, the second pulse having a duration and amplitude determined from the desired power division ratio and corresponding to a non-saturation state of the latching ferrite circulator.

A variable power divider comprising a latching ferrite circulator including an input port, a first output port, a second output port, and at least one winding. The ports meet in a common junction. The variable power divider also includes a controller interface that receives a command signal indicating a desired power division ratio and a driver circuit configured to receive a control signal from the controller interface. The driver circuit generates a first pulse, having a duration and amplitude corresponding to a saturation state of the latching ferrite circulator, in a first direction through the at least one winding. After the first pulse, the driver circuit generates a second pulse in a second direction through the at least one winding opposite the first direction, the second pulse having a duration and amplitude determined from the desired power division ratio and corresponding to a non-saturation state of the latching ferrite circulator.

An apparatus and a method for electromagnetic signal transition, comprising the steps of receiving an electromagnetic signal having a first physical characteristic arranged to be compatible for the electromagnetic signal to be transmitted on a transmission structure, and transmitting the electromagnetic signal to a substrate integrated waveguide, wherein during the transmission of the electromagnetic signal to the substrate integrated waveguide, the first physical characteristic is converted to a second physical characteristic arranged to be compatible for the electromagnetic signal to be transmitted on the substrate integrated waveguide.

An apparatus and a method for electromagnetic signal transition, comprising the steps of receiving an electromagnetic signal having a first physical characteristic arranged to be compatible for the electromagnetic signal to be transmitted on a transmission structure, and transmitting the electromagnetic signal to a substrate integrated waveguide, wherein during the transmission of the electromagnetic signal to the substrate integrated waveguide, the first physical characteristic is converted to a second physical characteristic arranged to be compatible for the electromagnetic signal to be transmitted on the substrate integrated waveguide.

A hybrid electro-mechanical tuner uses a modified version of the forward injection technique, also called Gamma Boosting Unit (GBU), integrated with a passive slide screw impedance tuner in the same slabline and housing. The modified GBU samples a phase-and-amplitude adjustable portion of the forward travelling signal at the fundamental frequency, amplifies it and injects it back, in reverse direction, into the main signal path through a circulator connected at the idle port of the tuner, after the mechanical tuning probe. The horizontal and vertical control of the forward coupler (wave-probe) of the modified GBU which is attached to the vertical axis in a mobile carriage, is manual or remote and eliminates the need for a dedicated phase shifter and attenuator, making the solution better, simpler and more effective.

A hybrid electro-mechanical tuner uses a modified version of the forward injection technique, also called Gamma Boosting Unit (GBU), integrated with a passive slide screw impedance tuner in the same slabline and housing. The modified GBU samples a phase-and-amplitude adjustable portion of the forward travelling signal at the fundamental frequency, amplifies it and injects it back, in reverse direction, into the main signal path through a circulator connected at the idle port of the tuner, after the mechanical tuning probe. The horizontal and vertical control of the forward coupler (wave-probe) of the modified GBU which is attached to the vertical axis in a mobile carriage, is manual or remote and eliminates the need for a dedicated phase shifter and attenuator, making the solution better, simpler and more effective.