Abstract: A Substrate Integrated Wave (SIW) coupled to a Suspended Substrate Stripline (SSS) filter for introducing a notch response has a substrate having metal layers formed on a top surface and a bottom surface thereof. A filter circuit is formed on the top surface of the substrate. A top ground plate is provided and has an air cavity formed on a bottom surface of the top ground plate. The air cavity on the top ground plate is positioned directly above the filter circuit when the top ground plate is positioned on the top surface of the substrate. A bottom ground plate is provided and has an air cavity formed on a top surface of the bottom ground plate. The air cavity on the bottom ground plate is positioned directly below the filter circuit when the bottom ground plate is positioned on the bottom surface of the substrate. A SIW cavity resonator is coupled to the filter circuit by means of an aperture to create a notch response in the SSS filter.

Abstract: A Substrate Integrated Wave (SIW) coupled to a Suspended Substrate Stripline (SSS) filter for introducing a notch response has a substrate having metal layers formed on a top surface and a bottom surface thereof. A filter circuit is formed on the top surface of the substrate. A top ground plate is provided and has an air cavity formed on a bottom surface of the top ground plate. The air cavity on the top ground plate is positioned directly above the filter circuit when the top ground plate is positioned on the top surface of the substrate. A bottom ground plate is provided and has an air cavity formed on a top surface of the bottom ground plate. The air cavity on the bottom ground plate is positioned directly below the filter circuit when the bottom ground plate is positioned on the bottom surface of the substrate. A SIW cavity resonator is coupled to the filter circuit by means of an aperture to create a notch response in the SSS filter.

Abstract: A device having a stripline to substrate integrated waveguide (SIW) transition structure has a substrate having a top surface and a bottom surface. A first metal ground layer is formed on the top surface of the substrate. A second metal ground layer is formed on the bottom surface of the substrate. A set of metallic vias are used to connect both ground layers. The stripline to SIW transition structure is embedded within the substrate between the first metal ground layer and the second metal ground layer. The stripline to SIW transition structure has a first transmission line embedded within the substrate. An impedance transformer is coupled to one end of the first transmission line. A coupling structure is coupled to the impedance transformer. The coupling structure has a pair of transmission lines. The pair of transmission lines diverge outward and upward from the impedance transformer.

Abstract: A coaxial tunable band stop filter utilizes tuning elements, such as PIN diodes and varactor diodes, for electrically tuning a coaxial resonator to change the resonance frequency of the coaxial resonators. A voltage is applied to the tuning elements to change their capacitance, such that they electrically lengthen and shorten the coaxial resonator. The variable voltages work to change the center frequency across a bandwidth. When the resonators are electrically extended or shortened in length, the center frequency in the bandwidth is changed accordingly. The bandwidth for the coaxial tunable band stop filter is tunable to increase and decrease based on the position of the center frequency. A ninety degree transmission line is used for coupling the components of the filter. A digital control is used for manipulating the tuning elements.

Abstract: A coaxial tunable band stop filter utilizes tuning elements, such as PIN diodes and varactor diodes, for electrically tuning a coaxial resonator to change the resonance frequency of the coaxial resonators. A voltage is applied to the tuning elements to change their capacitance, such that they electrically lengthen and shorten the coaxial resonator. The variable voltages work to change the center frequency across a bandwidth. When the resonators are electrically extended or shortened in length, the center frequency in the bandwidth is changed accordingly. The bandwidth for the coaxial tunable band stop filter is tunable to increase and decrease based on the position of the center frequency. A ninety degree transmission line is used for coupling the components of the filter. A digital control is used for manipulating the tuning elements.