Abstract: An RF bridge circuit without a balun transformer. The RF bridge circuit may include a resistive bridge and a differential detector. The resistive bridge may generate a differential signal that is indicative of a differential imbalance across the resistive bridge. Specifically, the differential signal may be indicative of the ratio of the impedance associated with a DUT and the impedance associated with a reference device. The differential detector may be connected directly to the resistive bridge and may sense the differential signal. The differential detector may convert the differential signal into a differential or single-ended IF signal. The RF bridge circuit may process the differential signal without the use of a balun transformer. The differential detector may include a balanced differential mixer, such as a diode ring, a FET quad, a Gilbert cell, and a harmonic mixer. Alternatively, the differential detector may include a balanced differential sampler, such as a harmonic sampler and a sampling bridge.

Abstract: A bandpass sampling system (10) of this invention employs a conventional mixer (14) driven by a frequency-tunable LO (16) to upconvert a signal frequency band to an IF frequency band that is above the signal frequency band. The IF frequency band is passed through an IF bandpass filter (18) to provide to subsequent digitization stages (20, 24) an IF bandpass range of signal frequency components. In this architecture, the IF bandpass filter acts as an anti-alias filter for the digitization stages. The LO frequency is selected to place the upconverted signal frequency band within the pass band of the IF bandpass filter. The resultant IF bandpass signal is sampled and digitized at a rate that is commensurate with the IF bandwidth, but typically much lower than the IF bandpass center frequency. Signal sampling is carried out by a sample-and-hold or a track-and-hold circuit (20), the output of which is applied to an ADC (24) that is clocked (22) at the same rate as the sampling circuit.

Abstract: An adaptive feedforward control loop is provided to stabilize accelerator beam loading of the radio frequency field in an accelerator cavity during successive pulses of the beam into the cavity. A digital signal processor enables an adaptive algorithm to generate a feedforward error correcting signal functionally determined by the feedback error obtained by a beam pulse loading the cavity after the previous correcting signal was applied to the cavity. Each cavity feedforward correcting signal is successively stored in the digital processor and modified by the feedback error resulting from its application to generate the next feedforward error correcting signal. A feedforward error correcting signal is generated by the digital processor in advance of the beam pulse to enable a composite correcting signal and the beam pulse to arrive concurrently at the cavity.