A first input terminal is connected to a point of connection of a drain terminal of a first transistor and a gate terminal of a fourth transistor. A second input terminal is connected to a point of connection of a drain terminal of a third transistor and a gate terminal of a second transistor. One of first through fourth output terminals to is connected to a source terminal of each of the first through fourth transistors to. A gate terminal of the first transistor and a drain terminal of the second transistor are connected, and a gate terminal of the third transistor and a drain terminal of the fourth transistor are connected.

A first input terminal is connected to a point of connection of a drain terminal of a first transistor and a gate terminal of a fourth transistor. A second input terminal is connected to a point of connection of a drain terminal of a third transistor and a gate terminal of a second transistor. One of first through fourth output terminals to is connected to a source terminal of each of the first through fourth transistors to. A gate terminal of the first transistor and a drain terminal of the second transistor are connected, and a gate terminal of the third transistor and a drain terminal of the fourth transistor are connected.

Microwave ablation systems and methods use a cable assembly including a signal divider device that enables use of multiple microwave antennas through a single channel of a microwave generator. The cable assembly includes a microwave transmission line, a signal divider device having multiple ports coupled to an end portion of the microwave transmission line, an electrical line, and a monitoring circuit coupled to an end portion of the electrical line. The monitoring circuit is configured to acquire information regarding multiple devices coupled to multiple respective ports of the signal divider device and convert the information regarding multiple devices to single channel information. The single channel information is inserted in a communication packet and transmitted to the microwave generator via the electrical line. The signal divider device includes a temperature sensor, which the monitoring circuit monitors to ensure that the temperature of the signal divider device circuitry remains within temperature limits.

Microwave ablation systems and methods use a cable assembly including a signal divider device that enables use of multiple microwave antennas through a single channel of a microwave generator. The cable assembly includes a microwave transmission line, a signal divider device having multiple ports coupled to an end portion of the microwave transmission line, an electrical line, and a monitoring circuit coupled to an end portion of the electrical line. The monitoring circuit is configured to acquire information regarding multiple devices coupled to multiple respective ports of the signal divider device and convert the information regarding multiple devices to single channel information. The single channel information is inserted in a communication packet and transmitted to the microwave generator via the electrical line. The signal divider device includes a temperature sensor, which the monitoring circuit monitors to ensure that the temperature of the signal divider device circuitry remains within temperature limits.

An apparatus is disclosed for phase-shifting signals. In example implementations, the apparatus includes a phase shifter. The phase shifter includes a first port, a second port, a vector modulator coupled to the first port, and a signal phase generator. The signal phase generator includes multiple amplifiers coupled between the vector modulator and the second port. The signal phase generator also includes multiple capacitors that couple the multiple amplifiers together to form a loop. Each respective capacitor of the multiple capacitors is coupled between a respective pair of consecutive amplifiers of the multiple amplifiers to form the loop.

An apparatus is disclosed for phase-shifting signals. In example implementations, the apparatus includes a phase shifter. The phase shifter includes a first port, a second port, a vector modulator coupled to the first port, and a signal phase generator. The signal phase generator includes multiple amplifiers coupled between the vector modulator and the second port. The signal phase generator also includes multiple capacitors that couple the multiple amplifiers together to form a loop. Each respective capacitor of the multiple capacitors is coupled between a respective pair of consecutive amplifiers of the multiple amplifiers to form the loop.

An in-phase/quadrature (I/Q) clock generator is described. The I/Q clock generated includes a poly-phase filter configured to generate a four-phase quadrature clock signal in response to a two-phase quadrature clock signal generated in response to a single-ended input clock signal. The I/Q clock generated also includes a phase interpolator configured to generate an output four-phase quadrature clock signal from the four-phase quadrature clock signal. The I/Q clock generated further includes a poly-phase filter tune circuit coupled to an output of the phase interpolator. The poly-phase filter tune circuit is configured to generate a control voltage for the poly-phase filter to tune the four-phase quadrature clock signal from the poly-phase filter.

The present disclosure relates to a phase shifter including an input port configured to receive a radio frequency (RF) signal; a first output port, a second output port, a third output port, and a fourth output port each configured to output a respective phase-shifted sub-component of the RF signal; a first conductive trace that extends in a first direction, the first conductive trace coupled to the first output port and the second output port; a second conductive trace that extends in the first direction, the second conductive trace coupled to the third output port and the fourth output port; and a first wiper configured to couple the input port to the first conductive trace and the second conductive trace, wherein the first wiper is configured to be slidable in the first direction with respect to the first conductive trace and the second conductive trace

The present disclosure relates to a phase shifter including an input port configured to receive a radio frequency (RF) signal; a first output port, a second output port, a third output port, and a fourth output port each configured to output a respective phase-shifted sub-component of the RF signal; a first conductive trace that extends in a first direction, the first conductive trace coupled to the first output port and the second output port; a second conductive trace that extends in the first direction, the second conductive trace coupled to the third output port and the fourth output port; and a first wiper configured to couple the input port to the first conductive trace and the second conductive trace, wherein the first wiper is configured to be slidable in the first direction with respect to the first conductive trace and the second conductive trace

Described herein are systems and methods that allow for correcting a residual frequency offset in the GHz frequency range by using low-complexity analog circuit implementations of a broad-band frequency detector that comprises two analog polyphase filters in a dual configuration. Each filter comprises an RC network of cross-coupled capacitors that facilitate filters with opposite passbands and opposite stop-bands. In various embodiments, the outputs of the two filters are combined to obtain power metrics that when subtracted from each other, deliver a measure of the imbalance between the positive and negative halves of a frequency spectrum. Since the measure is substantially proportional to a frequency offset within a linear range spanning 5 GHz or more, the polyphase filters may be used in a broad-band frequency detector that, based on the measure, adjusts the frequency offset.