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: A radio frequency switch having an N number of switch cells coupled in series is disclosed. Each of the switch cells includes a field-effect transistor (FET), wherein a source of switch cell 1 is coupled to a first port, a drain of switch cell N is coupled to a second port, and a drain of switch cell X is coupled to a source of switch cell X+1 for switch cell 1 through switch cell N. A first diode stack has a first anode coupled to the body of switch cell X and a first cathode coupled to a drain of switch cell X+1 for switch cell 1 through switch cell N?1, and a second diode stack has a second anode coupled to the body of switch cell X and a second cathode coupled to the source of switch cell X?1 for switch cell 2 through switch cell N.

Abstract: A power amplifier system having a power amplifier with a signal input and a signal output and bias circuitry is disclosed. The bias circuitry includes a bandgap reference circuit coupled between a reference node and a fixed voltage node. A bias generator has a bias input coupled to the reference node and a bias output coupled to the signal input. Also included is a first digital-to-analog converter having a first converter output coupled to the reference node, a first voltage input, and a first digital input, wherein the first digital-to-analog converter is configured to adjust a reference voltage at the reference node in response to a first digital setting received at the first digital input. The first digital setting correlates with an indication of temperature of the power amplifier.

Abstract: A power amplifier system is disclosed that includes a power amplifier having a first signal input, a first signal output, second signal input, and a second signal output. The power amplifier system further includes cross-coupled bias circuitry having a first transistor with a first collector coupled to the first signal input, a first base coupled to the second signal input, and a first emitter coupled to a fixed voltage node, a second transistor with a second collector coupled to the second signal input, a second base coupled to the first signal input, and a second emitter coupled to the fixed voltage node.

Abstract: Radio frequency (RF) amplifier circuitry includes an input node, an output node, an amplifier, and bootstrap circuitry. The amplifier includes a control node coupled to the input node, a first amplifier node coupled to the output node, and a second amplifier node coupled to a fixed potential. The amplifier is configured to receive an input signal having a first frequency at the control node and change an impedance between the first amplifier node and the second amplifier node based on the input signal. The bootstrap circuitry is coupled between the control node and the second amplifier node. The bootstrap circuitry is configured to provide a low impedance path between the control node and the second amplifier node for signals having a second frequency that is equal to about twice the first frequency and provide a high impedance path for signals having a frequency outside the second frequency.

Abstract: The present disclosure relates to a microelectronics package with vertically stacked flip-chip dies, and a process for making the same. The disclosed microelectronics package includes a module board, a first thinned flip-chip die with a through-die via, a second flip-chip die with a package contact at the bottom, and a mold compound. Herein, a top portion of the through-die via is exposed at top of the first thinned flip-chip die. The first thinned flip-chip die and the mold compound reside over the module substrate. The mold compound surrounds the first thinned flip-chip die and extends above the first thinned flip-chip die to define an opening. The second flip-chip die, which has a smaller plane size than the first thinned flip-chip die, resides within the opening and is stacked with the first thinned flip-chip die by coupling the package contact to the exposed top portion of the through-die via.

Abstract: Embodiments of electronic devices, such as integrated circuit (IC) packages are disclosed. In one embodiment, an electronic device includes a first substrate and a second substrate. The first substrate has a first substrate body and a first inductor portion integrated into the first substrate body. Additionally, the second substrate comprises a second substrate body and a second inductor portion integrated into the second substrate body. The second substrate is mounted on the first substrate such that such that the second inductor portion is positioned over the first inductor portion and such that the second inductor portion is electrically connected to the first inductor portion so that the first inductor portion and the second inductor portion form a three dimensional (3D) inductor. By using two substrates, the 3D inductor can be increased in height while still allowing the substrates to be miniaturized and standardized for an IC package.

Abstract: Radio frequency (RF) amplifier circuitry includes an input node, an output node, an amplifier, and bootstrap circuitry. The amplifier includes a control node coupled to the input node, a first amplifier node coupled to the output node, and a second amplifier node coupled to a fixed potential. The amplifier is configured to receive an input signal having a first frequency at the control node and change an impedance between the first amplifier node and the second amplifier node based on the input signal. The bootstrap circuitry is coupled between the control node and the second amplifier node. The bootstrap circuitry is configured to provide a low impedance path between the control node and the second amplifier node for signals having a second frequency that is equal to about twice the first frequency and provide a high impedance path for signals having a frequency outside the second frequency.

Abstract: The present disclosure relates to an air-cavity module having a thinned semiconductor die and a mold compound. The thinned semiconductor die includes a back-end-of-line (BEOL) layer, an epitaxial layer over the BEOL layer, and a buried oxide (BOX) layer with discrete holes over the epitaxial layer. The epitaxial layer includes an air-cavity, a first device section, and a second device section. Herein, the air-cavity is in between the first device section and the second device section and directly in connection with each discrete hole in the BOX layer. The mold compound resides directly over at least a portion of the BOX layer, within which the discrete holes are located. The mold compound does not enter into the air-cavity through the discrete holes.

Abstract: The present disclosure relates to a microelectronics package with a self-aligned stacked-die assembly and a process for making the same. The disclosed microelectronics package includes a module substrate, a first die with a first coupling component, a second die with a second coupling component, and a first mold compound. The first die is attached to the module substrate. The first mold compound resides over the module substrate, surrounds the first die, and extends above an upper surface of the first die to define a first opening. Herein, the first mold compound provides vertical walls of the first opening, which are aligned with edges of the first die in X-direction and Y-direction. The second die is stacked with the first die and in the first opening, such that the second coupling component is mirrored to the first coupling component.

Abstract: An apparatus with a body layer disposed over a substrate is disclosed. The body layer has first and second diffusion areas with a first current collection area between the two. A plurality of first drain/source (D/S) diffusions spaced parallel with one another resides within the first diffusion area. A plurality of first channel regions resides within the first diffusion area such that each of the plurality of first channel regions resides between an adjacent pair of the plurality of the first D/S diffusions. A plurality of second D/S diffusions resides within the second diffusion area and are spaced parallel with one another. A plurality of second channel regions reside within the second diffusion area such that each of the plurality of second channel regions resides between an adjacent pair of the plurality of the second D/S diffusions. A first current collection diffusion resides within the first current collection area.

Abstract: A power amplifier system having a power amplifier with a signal input and a signal output, bias circuitry coupled to the signal input, and a radio frequency (RF) peak detector having an input coupled to the signal output is disclosed. The RF peak detector is configured to generate a peak voltage signal. Temperature-compensated overvoltage protection circuitry coupled between an output of the RF peak detector and a control input of the bias circuitry is configured to respond to the peak voltage signal crossing over a predetermined peak voltage threshold and to provide an overvoltage protection control signal to cause the bias circuitry to adjust biasing for the power amplifier to reduce an overvoltage condition at the RF peak detector input.

Abstract: A power amplifier system is disclosed that includes a power amplifier having a first signal input, a first signal output, second signal input, and a second signal output. The power amplifier system further includes cross-coupled bias circuitry having a first transistor with a first collector coupled to the first signal input, a first base coupled to the second signal input, and a first emitter coupled to a fixed voltage node, a second transistor with a second collector coupled to the second signal input, a second base coupled to the first signal input, and a second emitter coupled to the fixed voltage node.

Abstract: A broadband power amplifier circuit is provided. The broadband power amplifier circuit includes an amplifier circuit configured to amplify a radio frequency (RF) signal to an output power based on a bias voltage and a supply voltage. Given that the output power of the RF signal may rise and fall from time to time, the broadband power amplifier circuit is configured to opportunistically increase or decrease the bias voltage in a defined future time (e.g., a future time slot or a future symbol duration) based on the output power in the defined future time. When necessary, the broadband power amplifier may be further configured to adjust the supply voltage and/or attenuate the RF signal based on the output power. As such, it may be possible to maintain class-A operation mode for the amplifier circuit. As a result, the amplifier circuit may maintain linearity and avoid memory effect with improved efficiency.

Abstract: A stacked field-effect transistor (FET) switch is disclosed. The stacked FET switch has a first FET device stack that is operable in an on-state and in an off-state and is made up of a first plurality of FET devices coupled in series between a first port and a second port, wherein the first FET device stack has a conductance that decreases with increasing voltage between the first port and the second port. The stacked FET switch also includes a second FET device stack that is operable in the on-state and in the off-state and is made up of a second plurality of FET devices coupled in series between the first port and the second port, wherein the second FET device stack has a conductance that increases with increasing voltage between the first port and the second port.

Abstract: A radio frequency (RF) front-end apparatus is provided. In examples discussed herein, the RF front-end apparatus can be configured to communicate RF signals in millimeter wave (mmWave) RF frequencies (e.g., ?12 GHz). The RF front-end apparatus includes an RF front-end circuit and an antenna element. The RF front-end circuit includes a transmit path and a receive path for transmitting and receiving RF signals, respectively. The antenna element includes an input port(s) and an output port(s) that are coupled to the transmit path and the receive path, respectively. The antenna element can be configured to enable impedance matching between the input port(s) and the transmit path, as well as between the output port(s) and the receive path. As a result, it may be possible to reduce insertion losses in the RF front-end circuit, thus helping to improve performance of the RF front-end apparatus, particularly in support of mmWave communications.

Abstract: The present disclosure relates to a microelectronics package with a self-aligned stacked-die assembly and a process for making the same. The disclosed microelectronics package includes a module substrate, a first die with a first coupling component, a second die with a second coupling component, and a first mold compound. The first die is attached to the module substrate. The first mold compound resides over the module substrate, surrounds the first die, and extends above an upper surface of the first die to define a first opening. Herein, the first mold compound provides vertical walls of the first opening, which are aligned with edges of the first die in X-direction and Y-direction. The second die is stacked with the first die and in the first opening, such that the second coupling component is mirrored to the first coupling component.

Abstract: A power amplifier system is disclosed that includes a power amplifier having a first signal input, a first signal output, second signal input, and a second signal output. The power amplifier system further includes cross-coupled bias circuitry having a first transistor with a first collector coupled to the first signal input, a first base coupled to the second signal input, and a first emitter coupled to a fixed voltage node, a second transistor with a second collector coupled to the second signal input, a second base coupled to the first signal input, and a second emitter coupled to the fixed voltage node.

Abstract: A radio frequency switch having an N number of switch cells coupled in series is disclosed. Each of the switch cells includes a field-effect transistor (FET), wherein a source of switch cell 1 is coupled to a first port, a drain of switch cell N is coupled to a second port, and a drain of switch cell X is coupled to a source of switch cell X+1 for switch cell 1 through switch cell N. A first diode stack has a first anode coupled to the body of switch cell X and a first cathode coupled to a drain of switch cell X+1 for switch cell 1 through switch cell N?1, and a second diode stack has a second anode coupled to the body of switch cell X and a second cathode coupled to the source of switch cell X?1 for switch cell 2 through switch cell N.

Abstract: The present disclosure relates to a semiconductor package with reduced parasitic coupling effects, and a process for making the same. The disclosed semiconductor package includes a thinned flip-chip die and a first mold compound component with a dielectric constant no more than 7. The thinned flip-chip die includes a back-end-of-line (BEOL) layer with an upper surface that includes a first surface portion and a second surface portion surrounding the first surface portion, a device layer over the upper surface of the BEOL layer, and a buried oxide (BOX) layer over the device layer. The BEOL layer includes a first passive device and a second passive device, which are underlying the first surface portion and not underlying the second surface portion. Herein, the first mold compound component extends through the BOX layer and the device layer to the first surface portion.