A receiver or transmitter designed for a broad range of frequencies requires a pre-select filter for incoming signals or a post-select filter for outgoing signals to minimize spurious signal responses. In conventional receivers, several discrete RF filters are used and a switched filter bank is created utilizing a large amount of space. A filter bank comprising a plurality of stacked shielded filters would enable different filter technologies and topologies to be used together, as other passive and active circuits may be combined into the one surface mountable component in order to save on PCB space.

Disclosed is radio frequency switch circuitry that includes a switch branch having a first branch terminal coupled to a first signal port and a second branch terminal coupled to a second signal port, and a branch control terminal, wherein the switch branch has both an on-state and an off-state to control passage of a radio frequency signal between the first signal port and the second signal port in response to a control signal applied to the control terminal. The radio frequency switch circuitry further includes an isolation inductor coupled between the first branch terminal and the second branch terminal such that the isolation inductor is in parallel with the switch branch, wherein the isolation inductor has a given inductance that provides resonance with a total off-state capacitance of the switch branch in the off-state at a center frequency of the radio frequency signal.

A micro-electro-mechanical system (MEMS) transfer switch is disclosed. The transfer switch comprises a single-pole, N-throw switch section having N selectable switches. Each selectable switch of the N selectable switches has an input, a control terminal and an output. An electrically conductive line is coupled to each of the selectable switches of the N selectable switches. The transfer switch includes a single-pole, M-throw switch section having M selectable switches coupled to the conductive line, each selectable switch of the M selectable switches having an output, a control terminal and an input. The single-pole, N-throw switch section and the single-pole, M-throw switch section are packaged in a single micro-electro-mechanical system (MEMS) die. The N and M are numbers between two and eight and the N selectable switches and the M selectable switches are different switches.

A microwave switch. In some embodiments, the microwave switch includes a substrate, a signal conductor, a first ground conductor, on a first side of the signal conductor, and a second ground conductor, on a second side of the signal conductor. The signal conductor, the first ground conductor, and the second ground conductor may be planar conductors on a planar top surface of the substrate. The signal conductor may have a first portion composed of a superconducting material, and a second portion having a reduced cross section, a cross-sectional area of the second portion being less than 120 nm.

A microelectromechanical systems (MEMS) device comprising: a substrate; a signal conductor supported on the substrate; ground conductors supported on the substrate on either side of the signal conductor; and a MEMS bridge at least one end of which is mechanically connected to the substrate by way of at least one anchor, the MEMS bridge comprising an electrically conductive switching portion, the electrically conductive switching portion comprising a switching signal conductor region and a switching ground conductor region, the switching signal conductor region being provided over the signal conductor and the switching ground conductor region being provided over a said ground conductor, the electrically conductive switching region being movable relative to the said signal and ground conductors respectively to thereby change the inductances between the switching signal conductor region and the signal conductor and between the switching ground conductor region and the respective ground conductor, wherein there is no continuous electrically conductive path extending from the switching conductor region to the at least one anchor. Capacative and ohmic switches, a varactor, a phase shifter, a tuneable power splitter/combiner, tuneable attenuator, SPDT switch and antenna apparatus comprising said devices.

An array antenna and a network device are provided. The array antenna includes n radiating elements, a power splitter or a phase shifter, and a switching switch. The power splitter or the phase shifter includes n output ends and m input ends. The switching switch includes m first ports, K second ports, and a switch element, where the m first ports are respectively connected to the m input ends; and the K second ports are configured to couple an input signal. The switch element is configured to switch a connection relationship between the m first ports and the K second ports, so as to selectively output the input signal to at least one first port.

Selector switch provided with: a structure based on at least one phase change material placed between a first conducting element and a second conducting element, the phase change material being capable of changing state, means of heating the phase change material provided with at least one first heating electrode and at least one other heating electrode, the structure based on a phase change material being configured to form a confined active zone of the phase change material at a distance from the conducting elements.

Disclosed is a high frequency switch including a substrate, a pair of ground sections provided on the substrate, a center conductor provided between the pair of ground sections, and a photoconductive semiconductor element provided on the center conductor and extending between the center conductor and the pair of ground sections.

A microelectromechanical system (MEMS) switch implemented with a coplanar waveguide. The MEMS switch includes an input terminal, an output terminal. The MEMS switch includes a beam extending between the input terminal and the output terminal. The beam includes a first edge and a second edge coupled to a gate of the MEMS switch. The beam includes a third edge proximate the input terminal. The first edge includes a first set of finger contacts proximate a first corner of the beam and a second set of finger contacts proximate a second corner of the beam. The beam includes a fourth edge proximate the output terminal, the fourth edge opposing the third edge. The MEMS switch has a first anchor coupled to the input terminal. The first anchor includes a first segment extending from a region proximate the input terminal to a region overlying the first set of finger contacts.

A device for switching a differential signal includes an input port, a first output port, a second output port, a first micro electromechanical system (MEMS) switch, and a second MEMS switch. The first and second MEMS switches selectively couple the input port to either the first output port or the second output port. The differential input port is separated into two single-ended paths. One single-ended path is switched through the first MEMS switch, and the other single-ended path is switched through the second MEMS switch. The single-ended paths are spatially matched with respect to length and orientation, and are at least partially distributed through at least two layers of electrical conductors, with adjacent layers of electrical conductors separated by electrically insulating layers.