Abstract: Frequency synthesizer circuitry employs a delay line. A reference clock signal propagates through successive stages of the delay line, and the currents drawn by output buffers of all of the stages are added at a common node. The common node current is converted to a voltage, which is AC-coupled to an output buffer ring oscillator of the frequency synthesizer. The output buffer ring oscillator includes a plurality of inverters connected in a series. A feedback connection including a resistor is provided from an output node of the last inverter to an input node of the first inverter.

Abstract: A system and method for frequency pushing/pulling compensation in phase-locked loops including a method for cancelling frequency push/pull in an oscillator of a transmitter. The method includes computing an error signal from a signal of a phase locked loop, wherein the error signal includes an aggressor signal. Transfer characteristics are computed for the aggressor signal. A transmitted signal is filtered using the transfer characteristics to produce a correction term. The correction term is applied to a frequency control word being provided to the oscillator.

Abstract: Transmission of information between user equipment (UE) and base stations in a wireless network occurs using a stream of periodic data. A modem in the UE operates synchronized to a first clock source to produce the stream of periodic data at a chip rate. Transceiver circuitry is synchronized to a variable clock source to receive the stream of data from the first circuitry at a rate according to the variable clock source. A fixed phase relationship is maintained between the variable clock source and the first clock source while the data period is uniform by adjusting the variable clock in response to detected phase errors. Occasionally, one period of the periodic data is changed by a defined amount. The fixed phase relationship is restored over a number of periods in a gradual manner by changing the frequency of the variable clock by an amount. By restoring the phase relationship gradually, quality degradation of the transmitted signal is reduced.

Abstract: A digital loop circuit—i.e., a phase-locked loop (“PLL”) or delay-locked loop (“DLL”)—having a simplified digital loop filter, is particularly well-suited for a programmable logic device (“PLD”). The loop filter may be a memory (e.g., a shift register) which counts the early/late or up/down signals from a phase detector or phase-frequency detector (“error detector”) and outputs a signal when the count exceeds a threshold. Separate integral and proportional paths of the loop may include chained shift registers, with each outputting a signal only when the previous shift register overflows into it. A digital error detector may respond nonlinearly, with outputs of different bit widths, to different amounts of phase or frequency error.

Abstract: A system and method for frequency pushing/pulling compensation in phase-locked loops including a method for cancelling frequency push/pull in an oscillator of a transmitter. The method includes computing an error signal from a signal of a phase locked loop, wherein the error signal includes an aggressor signal. Transfer characteristics are computed for the aggressor signal. A transmitted signal is filtered using the transfer characteristics to produce a correction term. The correction term is applied to a frequency control word being provided to the oscillator.

Abstract: A novel and useful apparatus for and method of reducing phase and amplitude modulation bandwidth in polar transmitters. The bandwidth reduction mechanism of the present invention effectively reduces the phase modulation bandwidth of the polar modulation performed in the transmitter by modifying the zero-crossing trajectories in the IQ domain. This significantly reduces the phase modulation bandwidth while still meeting the output spectrum and error vector magnitude (EVM) requirements of the particular modern wideband wireless standard, such as 3G WCDMA, etc. The mechanism detects a zero crossing or a near zero crossing within a predetermined threshold of the origin and an offset vector is generated that when added to the input TX IQ data, shifts the trajectory to avoid the origin thus reducing the resultant polar modulation amplitude and phase bandwidth.

Abstract: Variable capacitance circuitry includes a fine tuning bank and a medium tuning bank. The fine tuning bank includes a plurality of varactors of progressively increasing size (e.g., width). Only one of these varactors is turned on at any one time. The medium tuning bank includes a plurality of similarly sized varactor circuits. These are turned on selectively in thermometer fashion (e.g., more are turned on (or off) as more (or less) overall capacitance is needed). The medium tuning bank increment is matched to the fine tuning bank range, so that when the fine tuning bank reaches an end of its range, another medium increment can be added or subtracted while the fine tuning bank is reset to the other end of its range. A uniform progression of small, incremental, capacitance changes is therefore provided over the relatively wide tuning range of the medium bank.

Abstract: A new all digital PLL (ADPLL) circuit and architecture and the corresponding method of implementation are provided. The ADPLL processes an integer and a fractional part of the phase signal separately, and achieves power reduction by disabling circuitry along the integer processing path of the circuit when the ADPLL loop is in a locked state. The integer processing path is automatically enabled when the loop is not in lock. Additional power savings is achieved by running the ADPLL on the lower-frequency master system clock, which also has the effect of reducing spur levels on the signals.