Provided is a method of improving a bandwidth of an antenna using a transmission line stub to enable long-range communication together with broadband matching. According to the method, it is possible to combine a transmission line stub in series or parallel with a feeding point, which is an antenna signal input/output point of a body serving as an antenna, and apply the transmission line stub to an antenna for wide use.

An architecture for, and techniques for fabricating, a thermal decoupling device are provided. In some embodiments, thermal decoupling device can be included in a thermally decoupled cryogenic microwave filter. In some embodiments, the thermal decoupling device can comprise a dielectric material and a conductive line. The dielectric material can comprise a first channel that is separated from a second channel by a wall of the dielectric material. The conductive line can comprise a first segment and a second segment that are separated by the wall. The wall can facilitate propagation of a microwave signal between the first segment and the second segment and can reduce heat flow between the first segment and the second segment of the conductive line.

A sunlight receiving device includes a substrate, and a plurality of resonators arranged on a surface of the substrate at certain intervals so as to form one of a plurality of loops, the plurality of loops partially bordering with each other, each one of the plurality of resonators having a length that resonates with sunlight of a certain wavelength, wherein energy of the sunlight is obtained via a resonator that belongs to one or more of the plurality of loops, the resonator being one of the plurality of resonators.

A system includes an RF input coupled to a plurality of channel filters through an inductive manifold. Each of the channel filters is configured as a series resonator and has a frequency of greater than about 1 GHz. The frequency of the channel filters decreases as their distance from the RF input increases. Components of each of the channel filters, which may include a series inductor, series capacitor, and shunt capacitor, are configured using high-Q transmission lines. A tunable notch filter, such as an absorptive tunable band-stop filter, may be included within the channel filters. The system may be used for protection of wideband receivers.

The reconfigurable resonators for chipless RFID applications provide spiral resonators for a multiple resonator passive RFID transponder tag. Each spiral resonator includes a U-shaped frame of conductive material and has a plurality (K1) of parallel adjusting or shorting elements disposed between the legs of the U-shaped frame. Each resonator has one leg coupled to a transmission line adapted for connection between a receiving antenna and a transmitting antenna (in some embodiments, a single antenna may be used for both receiving and transmitting), and one of the adjusting or shorting elements may be selectively connected to the opposing leg of the frame to configure the resonator to resonate at one of (K1) different resonant frequencies (K frequencies if none of the elements are connected) by a short metal jumper strip to change the length of the spiral resonator.

Electrical devices having variable electrical properties. The variable electrical characteristics or operation of the devices are based on the potential applied to a variable-dielectric constant sector associated with the device. The electronic devices or component may include bends, power splitters, filters, ports, phase shifters, frequency shifters, attenuators, couplers, capacitors, inductors, diplexers, hybrids of beam forming networks.

Flipped radio frequency (RF) and microwave filters and components for compact package assemblies are provided. An example RF filter is constructed by depositing a conductive trace, such as a redistribution layer, onto a flat surface of a substrate, to form an RF filter element. The substrate is vertically mounted on a motherboard, thereby saving dedicated area. Multiple layers of substrate can be laminated into a stack and mounted so that the RF filter elements of each layer are in vertical planes with respect to a horizontal motherboard, providing dramatic reduction in size. Deposited conductive traces of an example flipped RF filter stack can provide various stub configurations of an RF filter and emulate various distributed filter elements and their configuration geometries. The deposited conductive traces can also form other electronic components to be used in conjunction with the RF filter elements. A wirebond or bond via array (BVA) version can provide flipped RF and microwave filters.

Flipped radio frequency (RF) and microwave filters and components for compact package assemblies are provided. An example RF filter is constructed by depositing a conductive trace, such as a redistribution layer, onto a flat surface of a substrate, to form an RF filter element. The substrate is vertically mounted on a motherboard, thereby saving dedicated area. Multiple layers of substrate are laminated into a stack and mounted so that the RF filter elements of each layer are in vertical planes with respect to a horizontal motherboard, providing dramatic reduction in size. Deposited conductive traces of an example flipped RF filter stack provide various stub configurations of an RF filter and emulate various distributed filter elements and their configuration geometries. The deposited conductive traces also form other electronic components to be used in conjunction with the RF filter elements. A wirebond or bond via array (BVATM) version provides flipped RF and microwave filters.

A system includes an RF input coupled to a plurality of channel filters through an inductive manifold. Each of the channel filters is configured as a series resonator and has a frequency of greater than about 1 GHz. The frequency of the channel filters decreases as their distance from the RF input increases. Components of each of the channel filters, which may include a series inductor, series capacitor, and shunt capacitor, are configured using high-Q transmission lines. A tunable notch filter, such as an absorptive tunable band-stop filter, may be included within the channel filters. The system may be used for protection of wideband receivers.

A band-PASS filter disposed on a printed circuit board comprises a first terminal, a second terminal, a first coupling portion, a second coupling portion and a connection portion. The first terminal and the second terminal are used to receive or output electromagnetic signals respectively. The first coupling portion and the second coupling portion are disposed between the first terminal and the second terminal to couple the electromagnetic signals. The connection portion is connected to the first coupling portion and the second coupling portion. The first terminal partly accommodates in a first coupling portion groove. The second terminal partly accommodates in a second coupling portion groove.