Abstract: Radio frequency (RF) switch comprising an electromagnet formed on a magnet, a transmission line formed on the electromagnet and having a ground line and a signal line, and a movable contact connected to either the ground line or the signal line and capable of electrically coupling the ground line with the signal line. The transmission line is capable of propagating a RF signal if the ground line is electrically decoupled from the signal line. Conversely, the transmission line is incapable of propagating a RF signal if the ground line is electrically coupled with the signal line. The electromagnet can comprise an electromagnetic coil, formed in a layer of dielectric material, electrically coupled to a current source. Preferably, the movable contact is capable of being magnetically actuated, and is latchable. The magnet, the electromagnet, the transmission line, and the movable contact can have dimensions at a micron order of magnitude. The transmission line can be a coplanar waveguide.

Abstract: Radio frequency (RF) switch comprising an electromagnet formed on a magnet, a transmission line formed on the electromagnet and having a ground line and a signal line, and a movable contact connected to either the ground line or the signal line and capable of electrically coupling the ground line with the signal line. The transmission line is capable of propagating a RF signal if the ground line is electrically decoupled from the signal line. Conversely, the transmission line is incapable of propagating a RF signal if the ground line is electrically coupled with the signal line. The electromagnet can comprise an electromagnetic coil, formed in a layer of dielectric material, electrically coupled to a current source. Preferably, the movable contact is capable of being magnetically actuated, and is latchable. The magnet, the electromagnet, the transmission line, and the movable contact can have dimensions at a micron order of magnitude. The transmission line can be a coplanar waveguide.

Abstract: A low power heterojunction field effect transistor (10, 30, 50, 60) capable of operating at low drain currents while having a low intermodulation distortion. A channel restriction region (9, 38, 51) is formed between the gate electrodes (24, 41, 69) and the drain electrodes (25, 46, 65). The channel restriction region (9, 38, 51) depletes the channel layer (13, 33) thereby constricting a channel and lowering a drain saturation current. The channel restriction region (9, 38, 51) may be used to set a desired drain saturation current such that a second derivative of the transconductance with respect to the gate-source voltage is approximately zero and a first derivative of the transconductance with respect to the gate-source voltage is, approximately, a relative maximum at the desired operating point.

Abstract: A low power heterojunction field effect transistor (10, 30, 50, 60) capable of operating at low drain currents while having a low intermodulation distortion. A channel restriction region (9, 38, 51) is formed between the gate electrodes (24, 41, 69) and the drain electrodes (25, 46, 65). The channel restriction region (9, 38, 51) depletes the channel layer (13, 33) thereby constricting a channel and lowering a drain saturation current. The channel restriction region (9, 38, 51) may be used to set a desired drain saturation current such that a second derivative of the transconductance with respect to the gate-source voltage is approximately zero and a first derivative of the transconductance with respect to the gate-source voltage is, approximately, a relative maximum at the desired operating point.

Abstract: A tuning circuit is provided for increasing the power transfer between first and second electrically coupled utilization circuits while controlling the effective source reflection coefficient thereby increasing the power available to the latter wherein the input signal provided at the output of the first utilization circuit is reflected back reducing the power available at the input of the second utilization circuit. The input signal is applied to the first input of the power combiner while a feedback signal proportional to the power loss between the first and second utilization circuits is applied to the second input of the power combiner. The output of the power combiner is increased by the feedback signal for compensating the power loss of the input signal such that the power available to the second utilization circuit is increased.

Abstract: A multithreshold A/D converter has primary and secondary quantizing stages. The threshold reference voltages for the secondary quantizing stages are obtained by amplifying a threshold reference voltage step derived from the primary quantizing stage. Since the secondary threshold reference voltages are derived directly from the primary reference voltages the secondary reference voltages will track deviations occurring within the primary quantizing stage. A reference tracking amplifier is utilized to amplify a portion of the primary reference voltage and apply same to the secondary stage. By using monolithic integrated circuit fabrication techniques to identically match the reference tracking amplifier with the error amplifiers of the primary quantizing stages, the secondary threshold reference voltages will also track deviations in the peak error signals conveyed from the primary to the secondary quantizing stages.