Abstract: A device includes a patch antenna, which includes a feeding line, and a ground panel over the feeding line. The ground panel has an aperture therein. A low-k dielectric module is over and aligned to the aperture. A patch is over the low-k dielectric module.

Abstract: A method includes placing a device die and a pre-formed dielectric block over a first carrier, encapsulating the device die and the pre-formed dielectric block in an encapsulating material, grinding a top side of the encapsulating material to expose the top side of the pre-formed dielectric block, removing the carrier from the encapsulating material, the pre-formed dielectric block, and the device die to reveal a bottom side of the pre-formed dielectric block, and forming a ground panel, a feeding line, and a patch on the encapsulating material. The ground panel, the feeding line, the patch, and the pre-formed dielectric block form a patch antenna.

Abstract: In a communication system, a communication terminal device transmits and receives RF signals frequently. Subsequent to an antenna of the communication terminal device, the communication terminal device includes a radio frequency switch (also referred to as transmit/receive (T/R) switch) that switches between two states at a high frequency, where one state is for receiving RF signal and other state for transmitting RF signal. In the exemplary embodiments of the disclosure, a complementary metal-oxide-semiconductor (CMOS) switch is provided, where the CMOS switch is deigned to have a high reliability by coupling a body of a transistor of the CMOS switch to a bias voltage through a switch, where the insertion loss and isolation are improved for the operation of the CMOS switch.

Abstract: A wireless transmitter includes a an amplifier; and a switchable transformer, coupled to the amplifier, wherein the amplifier is configured to be coupled to the switchable transformer in first and second configurations, wherein the first configuration causes the amplifier to provide a first output impedance to the switchable transformer, and wherein the second configuration causes the amplifier to provide a second output impedance to the switchable transformer, the first and second output impedances being different from each other.

Abstract: A method includes switching a receiver path network of a front-end module to a first matching mode in a receive mode. The method further includes switching a transmitter path network of the front-end module to a first resonance mode in the receive mode. The method further includes switching the transmitter path network to a second matching mode in a transmit mode. The method further includes switching the receiver path network to a second resonance mode in the transmit mode.

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 method includes (a) switching a receiver path network of a front end module to a first matching mode in a receive mode. The method further includes (b) switching a transmitter path network of the front end module to a first resonance mode in the receive mode. The method further includes (c) switching the transmitter path network to a second matching mode in a transmit mode. The method further includes (d) switching the receiver path network to a second resonance mode in the transmit mode.

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 polygonal inductive device disposed on a first layer on a substrate, the polygonal inductive device including a first line portion; a first conductive line disposed on a second layer on the substrate; a second conductive line disposed on a third layer on the substrate; and a first conductive via arranged to electrically couple the second conductive line to the first conductive line; wherein the first layer is different from the second layer and the third layer, the first conductive line is electrically connected to a reference voltage, and the first conductive line crosses the first line portion viewing from a top of the semiconductor device.

Abstract: An antenna apparatus comprises a semiconductor die in a molding compound layer, a first through via is between a sidewall of the semiconductor die and a sidewall of the molding compound layer and an antenna structure over the molding compound layer, wherein a first portion of the antenna structure is directly over a top surface of the semiconductor die and a second portion of the antenna structure is directly over a top surface of the first through via.

Abstract: A semiconductor device includes: a polygonal inductive device disposed on a first layer on a substrate, the polygonal inductive device including a first line portion; a first conductive line disposed on a second layer on the substrate; a second conductive line disposed on a third layer on the substrate; and a first conductive via arranged to electrically couple the second conductive line to the first conductive line; wherein the first layer is different from the second layer and the third layer, the first conductive line is electrically connected to a reference voltage, and the first conductive line crosses the first line portion viewing from a top of the semiconductor device.

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 antenna apparatus comprises a semiconductor die in a molding compound layer, a first through via is between a sidewall of the semiconductor die and a sidewall of the molding compound layer and an antenna structure over the molding compound layer, wherein a first portion of the antenna structure is directly over a top surface of the semiconductor die and a second portion of the antenna structure is directly over a top surface of the first through via.

Abstract: A method includes (a) switching a receiver path network of a front end module to a first matching mode in a receive mode. The method further includes (b) switching a transmitter path network of the front end module to a first resonance mode in the receive mode. The method further includes (c) switching the transmitter path network to a second matching mode in a transmit mode. The method further includes (d) switching the receiver path network to a second resonance mode in the transmit mode.

Abstract: A wireless transmitter includes a an amplifier; and a switchable transformer, coupled to the amplifier, wherein the amplifier is configured to be coupled to the switchable transformer in first and second configurations, wherein the first configuration causes the amplifier to provide a first output impedance to the switchable transformer, and wherein the second configuration causes the amplifier to provide a second output impedance to the switchable transformer, the first and second output impedances being different from each other.

Abstract: A wireless transmitter includes a an amplifier; and a switchable transformer, coupled to the amplifier, wherein the amplifier is configured to be coupled to the switchable transformer in first and second configurations, wherein the first configuration causes the amplifier to provide a first output impedance to the switchable transformer, and wherein the second configuration causes the amplifier to provide a second output impedance to the switchable transformer, the first and second output impedances being different from each other.

Abstract: A front end module includes a transmitter path network coupled to an antenna and a transmitter, and includes a first selectable matching network. The front end module further includes a receiver path network coupled to the antenna and a receiver. The receiver path network is a second selectable matching network.

Abstract: A device includes a patch antenna, which includes a feeding line, and a ground panel over the feeding line. The ground panel has an aperture therein. A low-k dielectric module is over and aligned to the aperture. A patch is over the low-k dielectric module.

Abstract: A semiconductor device includes: a polygonal inductive device disposed on a first layer on a substrate, the polygonal inductive device including a first line portion; a first conductive line disposed on a second layer on the substrate; a second conductive line disposed on a third layer on the substrate; and a first conductive via arranged to electrically couple the second conductive line to the first conductive line; wherein the first layer is different from the second layer and the third layer, the first conductive line is electrically connected to a reference voltage, and the first conductive line crosses the first line portion viewing from a top of the semiconductor device.

Abstract: An amplifying unit includes a converter and a feedback mechanism. The converter has a supply input coupled to a supply node. The converter further has an input terminal configured to receive an input signal. The converter is configured to amplify the input signal from the input terminal to generate an output signal. The feedback mechanism is coupled to the input terminal of the converter and is configured to cause a constant bias current to flow from the supply node through the converter based on the input signal.