Radio frequency (RF) filters configured to filter undesired signal components (e.g., noise and harmonics) from RF signals are disclosed. In one embodiment, an RF filter includes a first inductor coil having a first winding and a second inductor coil having a second winding and a third winding. The second winding of the second inductor coil is configured to have a first mutual magnetic coupling with the first winding, while the third winding of the second inductor coil is configured to have a second mutual magnetic coupling with the first winding. The second winding is connected to the third winding such that the first mutual magnetic coupling and the second mutual magnetic coupling are in opposition. In this manner, the first inductor coil and the second inductor coil may be provided in a compact arrangement while providing weak mutual magnetic coupling between the first inductor coil and the second inductor coil.

In a portable radio transceiver, a power amplifier system includes a saturation detector that detects power amplifier saturation in response to duty cycle of the amplifier transistor collector voltage waveform. The saturation detection output signal can be used by a power control circuit to back off or reduce the amplification level of the power amplifier to avoid power amplifier control loop saturation.

Apparatus and methods for orienting power amplifiers are disclosed herein. In certain implementations, a method of determining the physical orientation of power amplifiers laid out on a printed circuit board (PCB) is provided. The method includes determining an amount of emissions radiated by a first power amplifier die that is positioned in a first orientation on the PCB. The method further includes determining an amount of emissions radiated by a second power amplifier die that is positioned in a second orientation on the PCB. The method further includes determining a third orientation of the second power amplifier die different than the second orientation, such that when the second power amplifier die is in the third orientation, the amount of emissions radiated by the first power amplifier die and the amount of emissions radiated by the second power amplifier die are distributed in different directions.

A digital power amplifier comprises: an integrated circuit (IC2); an adaption circuit of discrete components connected to first and second transmission output pins of an integrated circuit to adapt the output signal and feed a substantial sinusoidal output current with a transmission resonance frequency to an RFID antenna. IC2 comprises a digital control section with N wave-forming contacts to output a digital wave-forming bit combination of N bits with a clock frequency M-times the transmission resonance frequency; N driver blocks each connected with a first contact to one of the wave-forming contacts and N/2 of them connected with a second contact to the first transmission output pin and the other N/2 of them connected with their second contact to the second transmission output pin. The driver blocks provide increments of the substantial sinusoidal output current to the first and second transmission output pins.

A receiver amplifier and also a receiver equalizer is provided for a three-level signaling system. The receiver amplifier includes a single current source that drives a current into node shared by three transistors arranged in parallel. A trio of input signals corresponds to the three transistors on a one-to-one basis. Each input signal drives the gate of its corresponding transistor. In addition, each transistor produces a corresponding output voltage at a terminal coupled to a resistor. The receiver equalizer includes three transistors and three corresponding equalizing pairs of a resistor and a capacitor. A terminal for the capacitor and for the resistor in each equalizing pair connects to a terminal of the corresponding transistor.

A silicon based (e.g., SiGe, CMOS, or BiCMOS) transmitter includes an algorithm that strategically segment and pre-distort the input signal according to its power; a reconfigurable power amplifier (PA) having a plurality of PA sections, wherein the plurality of PA sections comprise discrete weighted transistor arrays that are digitally turned OFF or ON according to a magnitude of an input signal; an impedance matching network equipped with a common-mode feedback (CMFB) mechanism configured to reduce common-mode glitches at an output of the PA due to ON/OFF manipulations of the PA segments; and a 1:N transformer, which comprises a capacitive matching engine and a power detector, disposed between the impedance matching network and the reconfigurable linear PA.

Techniques for generating a power tracking supply voltage for a circuit (e.g., a power amplifier) are disclosed. The circuit may process multiple transmit signals being sent simultaneously on multiple carriers at different frequencies. In one exemplary design, an apparatus includes a power tracker and a power supply generator. The power tracker determines a power tracking signal based on inphase (I) and quadrature (Q) components of a plurality of transmit signals being sent simultaneously. The power supply generator generates a power supply voltage based on the power tracking signal. The apparatus may further include a power amplifier (PA) that amplifies a modulated radio frequency (RF) signal based on the power supply voltage and provides an output RF signal.

A power amplifier device includes an amplification path implemented within a power amplifier package. The amplification path includes input and output package leads, a transistor die with transistor input and output terminals and a power transistor, and a two-stage input impedance matching circuit electrically coupled between the input package lead and the transistor input terminal. The two-stage input impedance matching circuit has a double T-match topology that includes a first resonator coupled to the first input package lead, and a second resonator coupled between the first resonator and the transistor input terminal. The amplification path also includes an output impedance matching circuit coupled between the transistor output terminal and the first output package lead, and a second output harmonic termination circuit coupled to the first output package lead.

A multi-gain LNA with inductive source degeneration is presented. The inductive source degeneration is provided via a tunable degeneration network that includes an inductor in parallel with one or more switchable shunting networks. Each shunting network includes a shunting capacitor that can selectively be coupled in parallel to the inductor. A capacitance of the shunting capacitor is calculated so that a combined impedance of the inductor and the shunting capacitor at a narrowband frequency of operation is effectively an inductance. The inductance is calculated according to a desired gain of the LNA. According to one aspect, the switchable shunting network includes a resistor in series connection with the shunting capacitor to provide broadband frequency response stability of the tunable degeneration network. According to another aspect, the LNA includes a plurality of selectable branches to further control gain of the LNA.

Apparatus and methods for an inverted Doherty amplifier operating at gigahertz frequencies are described. RF fractional bandwidth and signal bandwidth may be increased over a conventional Doherty amplifier configuration when impedance-matching components and an impedance inverter in an output network of the inverted Doherty amplifier are designed based on characteristics of the main and peaking amplifier and asymmetry factor of the amplifier.