Abstract: A diplexer circuit is provided. The diplexer circuit, which includes a pair of hybrid couplers and a filter circuit, can be configured to support dual-connect (DC) communications on a pair of signal bands separated by a narrower transition band (e.g., ?200 MHz). In examples discussed herein, one of the signal bands is associated with a narrower fractional bandwidth (e.g., <13%) than the other signal band. In this regard, the filter circuit can be opportunistically configured to operate based on the narrower fractional bandwidth. By configuring the filter circuit to operate based on the narrower fractional bandwidth, it is possible to eliminate the need for supporting the wider fractional bandwidth in the diplexer circuit. As a result, it may be possible to implement the diplexer circuit using conventional filters to support DC communications on signal bands associated with a wider fractional bandwidth(s) and separated by a narrower transition band.

Abstract: A power amplifier apparatus supporting reverse intermodulation product (rIMD) cancellation is provided. The power amplifier apparatus includes an amplifier circuit configured to amplify and output a radio frequency (RF) signal for transmission via an antenna port. The antenna port may receive a reverse interference signal, which may interfere with the RF signal to create a rIMD(s) that can fall within an RF receive band(s). A reverse coupling circuit is provided in the power amplifier apparatus to generate an interference cancellation signal based on the reverse interference signal. The amplifier circuit is configured to amplify the interference cancellation signal and the RF signal to create an intermodulation product(s) to suppress the rIMD(s) to a determined threshold. By suppressing the rIMD(s) in the power amplifier apparatus, it is possible to support concurrent transmissions and receptions in a number of RF spectrums while in compliance with stringent regulatory spurious emissions (SEM) requirements.

Abstract: Embodiments of radio frequency (RF) filtering circuitry are disclosed. In one embodiment, the RF filtering circuitry includes a first port, a second port, a first RF filter path, and a second RF filter path. The first RF filter path is connected between the first port and the second port and includes at least a pair of weakly coupled resonators. The weakly coupled resonators are configured such that a first transfer response between the first port and the second port defines a first passband. The second RF filter path is coupled to the first RF filter path and is configured such that the first transfer response between the first port and the second port defines a stopband adjacent to the first passband without substantially increasing ripple variation of the first passband defined by the first transfer response.

Abstract: Embodiments of the disclosure relate to a low noise amplifier (LNA) circuit. The LNA circuit includes an LNA configured to amplify a radio frequency (RF) input signal to generate an RF output signal. The LNA may be inherently nonlinear and, as a result, can create a harmonic distortion(s), such as second harmonic distortion (HD2), and/or an intermodulation distortion(s), such as second order intermodulation distortion (IMD2), in the RF output signal. In exemplary aspects discussed herein, a distortion amplifier(s) is provided in the LNA circuit to generate a distortion signal(s) to suppress the harmonic distortion(s) and/or the intermodulation distortion(s) in the RF output signal.

Abstract: RF circuitry, which includes a first acoustic RF resonator (ARFR) and a first compensating ARFR, is disclosed. A first inductive element is coupled between the first compensating ARFR and a first end of the first ARFR. A second inductive element is coupled between the first compensating ARFR and a second end of the first ARFR. The first compensating ARFR, the first inductive element, and the second inductive element at least partially compensate for a parallel capacitance of the first ARFR.

Abstract: RF circuitry, which includes a first acoustic RF resonator (ARFR) and a first compensating ARFR, is disclosed. A first inductive element is coupled between the first compensating ARFR and a first end of the first ARFR. A second inductive element is coupled between the first compensating ARFR and a second end of the first ARFR. The first compensating ARFR, the first inductive element, and the second inductive element at least partially compensate for a parallel capacitance of the first ARFR.

Abstract: A multi radio access technology (RAT) circuit is provided. The multi RAT power management circuit can concurrently support multiple different RATs using a single power management integrated circuit and a single power amplifier. The multi RAT power management circuit receives a first digital signal modulated based on a first RAT and a second digital signal modulated based on a second RAT. Control circuitry generates a composite output signal, which includes the first digital signal and the second digital signal and corresponds to a time-variant composite signal envelope derived from a respective peak envelope of the first and the second digital signals. The control circuitry generates a voltage control signal having a time-variant target voltage envelope tracking the time-variant composite signal envelope of the composite output signal. As such, the multi RAT power management circuit can concurrently support the multiple different RATs without increasing size, costs, complexity, and/or power consumption.

Abstract: Embodiments of the disclosure relate to a low noise amplifier (LNA) circuit. The LNA circuit includes an LNA configured to amplify a radio frequency (RF) input signal to generate an RF output signal. The LNA may be inherently nonlinear and, as a result, can create a harmonic distortion(s), such as second harmonic distortion (HD2), and/or an intermodulation distortion(s), such as second order intermodulation distortion (IMD2), in the RF output signal. In exemplary aspects discussed herein, a distortion amplifier(s) is provided in the LNA circuit to generate a distortion signal(s) to suppress the harmonic distortion(s) and/or the intermodulation distortion(s) in the RF output signal.

Abstract: Embodiments of radio frequency (RF) filtering circuitry are disclosed. In one embodiment, the RF filtering circuitry includes a first port, a second port, a first RF filter path, and a second RF filter path. The first RF filter path is connected between the first port and the second port and includes at least a pair of weakly coupled resonators. The weakly coupled resonators are configured such that a first transfer response between the first port and the second port defines a first passband. The second RF filter path is coupled to the first RF filter path and is configured such that the first transfer response between the first port and the second port defines a stopband adjacent to the first passband without substantially increasing ripple variation of the first passband defined by the first transfer response.

Abstract: Alternating Current (AC)-coupled switch and metal capacitor structures for nanometer or low metal layer count processes are provided. According to one aspect of the present disclosure, a switch and capacitor structure comprises a substrate comprising a device region with a Field Effect Transistor (FET) formed therein, the FET having a source terminal comprising a structure in a first metal layer and a drain terminal comprising a structure in the first metal layer, and a capacitor comprising a first plate and a second plate, the first plate comprising a structure in a second metal layer, the second metal layer being above the first metal layer, the structure of the first plate being electrically connected to the structure of the drain terminal, and the second plate comprising a structure in the second metal layer, the structure of the first plate spaced from the structure of the second plate.

Abstract: RF circuitry, which includes a first acoustic RF resonator (ARFR) and a first compensating ARFR, is disclosed. A first inductive element is coupled between the first compensating ARFR and a first end of the first ARFR. A second inductive element is coupled between the first compensating ARFR and a second end of the first ARFR. The first compensating ARFR, the first inductive element, and the second inductive element at least partially compensate for a parallel capacitance of the first ARFR.

Abstract: Embodiments of radio frequency (RF) filtering circuitry are disclosed. In one embodiment, the RF filtering circuitry includes a common port, a second port, a third port, a first RF filter path, and a second RF filter path. The first RF filter path is connected between the common port and the second port and comprises a first pair of resonators and a first acoustic wave resonator. One of the first pair of resonators also includes a second acoustic wave resonator. The second RF filter path is connected between the common port and the third port. The second RF filter path includes a second pair of resonators. The first and second acoustic wave resonators of the first RF filter path increase roll-off greatly with respect to just an LC filter, and thereby allow for an increase out-of-band rejection at high frequency ranges.

Abstract: A radio frequency switch having a first node, a second node, and a plurality of switch cells that are coupled in series between the first node and the second node is disclosed. Each of the plurality of switch cells includes a field-effect transistor having a drain terminal, a source terminal, a FET gate terminal, and a body terminal and an off-state linearization network. The off-state linearization network includes varactors coupled to the drain terminal and the source terminal of the field-effect transistor.

Abstract: RF circuitry, which includes a first acoustic RF resonator (ARFR) and a first compensating ARFR, is disclosed. A first inductive element is coupled between the first compensating ARFR and a first end of the first ARFR. A second inductive element is coupled between the first compensating ARFR and a second end of the first ARFR. The first compensating ARFR, the first inductive element, and the second inductive element at least partially compensate for a parallel capacitance of the first ARFR.

Abstract: A multi radio access technology (RAT) circuit is provided. The multi RAT power management circuit can concurrently support multiple different RATs using a single power management integrated circuit and a single power amplifier. The multi RAT power management circuit receives a first digital signal modulated based on a first RAT and a second digital signal modulated based on a second RAT. Control circuitry generates a composite output signal, which includes the first digital signal and the second digital signal and corresponds to a time-variant composite signal envelope derived from a respective peak envelope of the first and the second digital signals. The control circuitry generates a voltage control signal having a time-variant target voltage envelope tracking the time-variant composite signal envelope of the composite output signal. As such, the multi RAT power management circuit can concurrently support the multiple different RATs without increasing size, costs, complexity, and/or power consumption.

Abstract: LNA circuitry includes an input node, and output node, a primary amplifier stage, a first ancillary amplifier stage, and an input gain selection switch. The primary amplifier stage is configured to provide a first gain response between a primary amplifier stage input node and a primary amplifier stage output node, wherein the primary amplifier stage input node is coupled to the input node and the primary amplifier stage output node is coupled to the output node. The first ancillary amplifier stage is configured to provide a second gain response between a first ancillary amplifier stage input node and a first ancillary amplifier stage output node, wherein the first ancillary amplifier stage output node is coupled to the primary amplifier stage output node. The input gain selection switch is coupled between the input node and the first ancillary amplifier stage input node.

Abstract: Embodiments of the disclosure include a multi-band radio frequency (RF) front-end circuit. When a first antenna transmits an RF transmit signal in an RF transmit band, a second antenna may receive the RF transmit signal as an interference signal. The multi-band RF front-end circuit includes multiple receive filters for receiving an RF receive signal in multiple RF receive bands. A selected receive filter among the multiple receive filters is opportunistically reconfigured to help suppress the interference signal. Specifically, a bandpass bandwidth of the selected receive filter is expanded to include at least a portion of the RF spectrum of the interference signal. By doing so, it is possible to shunt the interference signal to a ground through the selected receive filter. As a result, it is possible to reduce an adverse impact of the interference signal to improve RF performance of the multi-band RF front-end circuit.

Abstract: An amplifier having improved linearity is disclosed. The amplifier includes a main transistor having a first current input terminal, a first current output terminal, and a first control terminal coupled to an RF input terminal that receives a signal voltage. A cascode transistor has a second current input terminal coupled to an RF output terminal for outputting an amplified signal. The cascode transistor has a second control terminal, and a second current output terminal coupled to the first current input terminal. Linearization circuitry has a bias output terminal coupled to the second control terminal. The linearization circuitry is configured to generate a bias signal at the bias output terminal to maintain a quiescent point of the main transistor for a given load coupled to the RF output terminal such that output conductance of the main transistor decreases nonlinearly with increasing main voltage and increases nonlinearly with decreasing main voltage.

Abstract: Radio frequency (RF) filtering circuitry includes a number of filtering elements and switching circuitry configured to rearrange the filtering elements between a common node, a first input/output node, a second input/output node, and a third input/output node such that the RF filtering circuitry is capable of supporting carrier aggregation between RF signals within a first RF frequency band and RF signals within a second RF frequency band, as well as between RF signals within a first portion of the second RF frequency band and a second portion of the second RF frequency band.

Abstract: Embodiments of the disclosure relate to a frequency selective low noise amplifier (LNA) circuit, which includes a transconductive LNA(s). In one aspect, filter circuitry is provided in a degeneration path of a transconductive LNA(s) to pass in-band frequencies and reject out-of-band frequencies by generating low impedance and high impedance at the in-band frequencies and the out-of-band frequencies, respectively. However, having the filter circuitry in the degeneration path may cause instability in the transconductive LNA. As such, a feedback path is coupled between an input node of the transconductive LNA(s) and the degeneration path to provide a feedback to improve stability of the transconductive LNA(s). In addition, the feedback can help improve impedance match in the frequency selective LNA circuit. As a result, the transconductive LNA(s) is able to achieve improved noise figure (NF) (e.g., below 1.5 dB), return loss, linearity, and stability, without compromising LNA gain.