Abstract: A phase shifter includes a first transistor and a second transistor. The first transistor includes a first gate terminal configured to receive a first voltage. The first transistor is configured to adjust at least a resistance or a first capacitance of the phase shifter responsive to the first voltage. The second transistor is coupled to the first transistor. The second transistor includes a second gate terminal configured to receive a second voltage. The second transistor is configured to adjust a second capacitance of the phase shifter responsive to the second voltage. The second gate terminal includes a first polysilicon portion and a second polysilicon portion extending in a first direction. The first polysilicon portion and the second polysilicon portion are positioned along opposite edges of an active region of the first transistor and the second transistor.

Abstract: A method for manufacturing a semiconductor device including an upper-channel implant transistor is provided. The method includes forming one or more fins extending in a first direction over a substrate. The one or more fins include a first region along the first direction and second regions on both sides of the first region along the first direction. A dopant is shallowly implanted in an upper portion of the first region of the fins but not in the second regions and not in a lower portion of the first region of the fins. A gate structure extending in a second direction perpendicular to the first direction is formed overlying the first region of the fins, and source/drains are formed overlying the second regions of the fins, thereby forming an upper-channel implant transistor.

Abstract: A voltage-controlled oscillator (VCO) includes a power supply source, a voltage source, a reference voltage node, first and second transistors, each including a source terminal coupled to the reference voltage node, and first through fourth conductive structures. The first conductive structure includes a first terminal coupled to the power supply source, a first extending portion coupled between the first terminal and a drain terminal of the first transistor, and a second extending portion coupled between the first terminal and a drain terminal of the second transistor, and the second conductive structure includes a second terminal coupled to the voltage source, a third extending portion coupled in series with the third conductive structure between the second terminal and a gate of the first transistor, and a fourth extending portion coupled in series with the fourth conductive structure between the second terminal and a gate of the second transistor.

Abstract: A power amplifier structure includes at least one power amplifier circuit. The power amplifier circuit includes a transistor of a first type connected in series with a transistor of a second type connected between the same voltage supply. In a non-limiting nonexclusive example, an n-type transistor is connected in series with a p-type transistor connected between Vdd. The power amplifier structure can include two amplifier circuits configured in a differential amplifier structure. The differential amplifier structure includes two amplifier circuits operably connected in parallel between the same voltage supply.

Abstract: A semiconductor device includes a substrate including a well region of a first conductive type; a first gate electrode on the substrate; a second gate electrode on the substrate; a first doped region embedded within the well region and is of the first conductive type, a second doped region embedded within the well region and is of the first conductive type, and a third doped region embedded within the well region and is of the first conductive type; and a first interconnection structure electrically connecting the first gate electrode and the second gate electrode. The first doped region and the second doped region are on opposite sides of the first gate electrode.

Abstract: An integrated circuit includes a first substrate having a first substrate material, and the first substrate includes a first circuit. A second substrate has a second substrate material different than the first substrate material, and the second substrate includes a second circuit. A conductive interconnect electrically connects the first circuit and the second circuit.

Abstract: A low noise amplifier (LNA) includes a pair of n-type transistors, each configured to provide a first transconductance; a pair of p-type transistors, each configured to provide a second transconductance; a first pair of coupling capacitors, cross-coupled between the pair of n-type transistors, and configured to provide a first boosting coefficient to the first transconductance; and a second pair of coupling capacitors, cross-coupled between the pair of p-type transistors, and configured to provide a second boosting coefficient to the second transconductance, wherein the LNA is configured to use a boosted effective transconductance based on the first and second boosting coefficients, and the first and second transconductances to amplify an input signal.

Abstract: A semiconductor device includes a substrate, a first metal-oxide-semiconductor device and a at least one first resistor. The substrate includes a non-doped region. The first metal-oxide-semiconductor device extends into the substrate. The first metal-oxide-semiconductor device is adjacent to the non-doped region. The at least one first resistor is disposed right above the non-doped region and arranged in a first row aligned with the first metal-oxide-semiconductor device in a first direction.

Abstract: A device including a substrate, a front-end module circuit situated over the substrate and configured to provide radio frequency communications, and a wafer-level chip-scale package circuit situated over the front-end module circuit and connected to the front-end module circuit and configured to provide passive components for radio frequency communications.

Abstract: A power amplifier structure includes at least one power amplifier circuit. The power amplifier circuit includes a transistor of a first type connected in series with a transistor of a second type connected between the same voltage supply. In a non-limiting nonexclusive example, an n-type transistor is connected in series with a p-type transistor connected between Vdd. The power amplifier structure can include two amplifier circuits configured in a differential amplifier structure. The differential amplifier structure includes two amplifier circuits operably connected in parallel between the same voltage supply.

Abstract: A semiconductor structure includes a circuit with a redistribution layer (RDL) formed over the circuit. The redistribution layer comprises a plurality of metal layers. An inductor is formed in a topmost metal layer, and the circuit is located directly under the inductor. An under bump metallization (UBM) layer formed on the topmost metal layer and a conductive connector formed on the UBM layer.

Abstract: A semiconductor device is provided. The semiconductor device includes a substrate, a transistor, at least one isolation and at least one non-doped region. The substrate includes a lower portion. The transistor is disposed on the lower portion. The at least one isolation is adjacent to the transistor, and disposed on the lower portion. The at least one non-doped region is disposed between and adjacent to the isolation and the lower portion.

Abstract: A band-pass filter (BPF) includes first and second windings. The first winding includes first and second terminals, a first outer extending portion extending from the first terminal, a second outer extending portion extending from the second terminal, and a first conductive structure configured to electrically connect the first and second outer extending portions to each other at a location opposite the first and second terminals. The second winding includes third and fourth terminals positioned between the first and second terminals, and a second conductive structure electrically connected to the third and fourth terminals and extending between the first conductive structure and each of the first and second outer extending portions.

Abstract: A semiconductor device includes a substrate, a first metal-oxide-semiconductor device and a at least one first resistor. The substrate includes a non-doped region. The first metal-oxide-semiconductor device extends into the substrate. The first metal-oxide-semiconductor device is adjacent to the non-doped region. The at least one first resistor is disposed right above the non-doped region and arranged in a first row aligned with the first metal-oxide-semiconductor device in a first direction.

Abstract: A semiconductor device is disclosed. The semiconductor device includes a substrate, a transistor, at least one isolation and at least one non-doped region. The substrate includes a lower portion. The transistor is disposed on the lower portion. The at least one isolation is adjacent to the transistor, and disposed on the lower portion. The at least one non-doped region is disposed between and adjacent to the isolation and the lower portion.

Abstract: An IC includes a device-under-test (DUT) configured to receive a first AC signal at a first node and output a second AC signal at a second node, the second AC signal being based on the first AC signal, and first and second detection circuits. Each of the first and second detection circuits includes a first gain stage coupled to a corresponding one of the first or second nodes through a first capacitive device, a second gain stage in a cascade arrangement with the first gain stage, and a low-pass filter configured to generate a DC signal based on an output signal of the second gain stage.

Abstract: A testing system includes: a dividing circuit configured to receive a testing signal and provide a plurality of input signals according to the testing signal; and a plurality of integrated power-amplifiers coupled to the dividing circuit, each of the plurality of integrated power-amplifiers being configured to be tested by receiving a respective input signal of the plurality of input signals and generating a respective output signal for a predetermined testing time.

Abstract: Disclosed is an amplifying circuit and method. In one embodiment, an amplifying circuit, includes: a common-gate (CG) amplifier, wherein the CG amplifier comprises a first transistor, wherein source terminal and body terminal of the first transistor is coupled together through a first resistor.

Abstract: An integrated circuit includes an inductor that includes a first set of conductors in at least a first metal layer, and a guard ring enclosing the inductor. The guard ring includes a first conductor extending in a first direction, a second conductor extending in a second direction, and a first set of staggered conductors coupled to a first end of the first conductor and a first end of the second conductor. The first set of staggered conductors includes a second set of conductors in a second metal layer, a third set of conductors in a third metal layer and a first set of vias coupling the second set of conductors with the third set of conductors. The third metal layer is above the second metal layer. All metal lines in the second metal layer that are part of the guard ring extend in the first direction.

Abstract: A testing system includes: a dividing circuit configured to receive a testing signal and provide a plurality of input signals according to the testing signal; and a plurality of power-amplifier chips coupled to the dividing circuit, each of the plurality of power-amplifier chips being configured to be tested by receiving a respective input signal of the plurality of input signals and generating a respective output signal for a predetermined testing time.