Techniques are provided for phase-locked loop (PLL) configuration, based on a calibrated lookup table (LUT). A methodology implementing the techniques according to an embodiment includes selecting one of a number of voltage controlled oscillators (VCOs) of the PLL, and selecting a tuning parameter to control the VCO. The method further includes testing the PLL, using multiple loop divider values, to determine a minimum and maximum value that define the lower and upper bounds of a range of loop divider values for which the PLL achieves a locked state while using the selected VCO and tuning parameter. The method further includes storing PLL configuration parameters to an entry in the configuration LUT, the PLL configuration parameters to include an identification of the selected VCO, the selected tuning parameter, the minimum loop divider value, and the maximum loop divider value. The method iterates using additional combinations of selected VCOs and tuning parameters.

To speed up output clock alignment in a digital phase locked loop wherein a controlled oscillator generates synthesizer pulses that are divided to produce output pulses at a predetermined normal spacing and time location, and wherein during an alignment procedure the output pulses are moved in time in response to a delay value obtained by comparing a phase of the output pulses with a phase applied to the controlled oscillator averaged over a number of synthesizer pulses in a feedback circuit to align said output pulses with a reference clock taking into account hardware delay, a group of the output pulses is advanced during the alignment procedure to reduce the spacing between them. After determining the delay value averaged over the group of output pulses subsequent output pulses are restored to their normal spacing and time locations.

In some embodiments, a phase-locked loop (PLL) system comprises a phase-frequency detector (PFD) configured to compare a phase-frequency reference signal and a feedback signal, a charge pump (CP) electrically coupled to the PFD and configured to produce a first tuning signal based on an output of the PFD, multiple integrator cells electrically coupled to the CP and configured to output multiple second tuning signals based on a voltage of the first tuning signal relative to a voltage reference signal, and a voltage-controlled oscillator (VCO) electrically coupled to the CP and to the multiple integrator cells and configured to adjust a capacitance value of the VCO based on the multiple second tuning signals. The capacitance value and the first tuning signal affect a frequency of the feedback signal.

An apparatus comprises a digitally controlled circuit having a variable capacitance and a controller configured to adjust a magnitude of the variable capacitance of the digitally controlled circuit. The digitally controlled circuit comprises a plurality of gain elements, the plurality of gain elements comprising one or more positive voltage-to-frequency gain elements and one or more negative voltage-to-frequency gain elements. The controller is configured to adjust the magnitude of the capacitance by adjusting the gain provided by respective ones of the gain elements in an alternating sequence of the positive voltage-to-frequency gain elements and the negative voltage-to-frequency gain elements.

A biased impedance circuit, an impedance adjustment circuit, and an associated signal generator are provided. The biased impedance circuit is coupled to a summation node and applies a biased impedance to the summation node. A periodic input signal is received at the summation node. The biased impedance circuit includes a switching circuit for receiving an output window signal, wherein a period of the output window signal is shorter than a period of the periodic input signal. The switching circuit includes a low impedance path and a high impedance path. The low impedance sets the biased impedance to a first impedance when the output window signal is at a first voltage level. The high impedance path sets the biased impedance to a second impedance when the output window signal is at a second voltage level. The first impedance is less than the second impedance.

A flash analog-to-digital converter (ADC) receives an input control signal and performs coarse tuning of a frequency of an output signal, produced between first and second nodes having an inductance coupled therebetween. The flash ADC quantizes an operating frequency range for the output signal produced between the first and second nodes as M.Math.f, where M is an integer from 0 to N1, where N is a number of intervals into which a frequency range for the output signal is divided, and where f is a resulting frequency step produced by the quantizing. The value of M is generated based upon the input control signal and a word controlling switches of a plurality of switched capacitance circuits associated with the first and second nodes to close ones of those switches associated with the control word to coarsely tune the frequency of the output signal.

A method of generating an output signal includes determining a sampling period N according to a number of most significant bits (MSBs) of a divider number control signal. The method also includes determining a first logic value of a control signal by a comparing circuit based on the sampling period N, and generating a coarse tuning signal by a code generating circuit based on a phase difference signal and the control signal. When an M-th least significant bit (LSB) of the number of MSBs of the divider number control signal equals a second logic value, the sampling period N is set based on the M-th LSB of the number of MSBs of the divider number control signal.

An element includes a coupling line in which a first conductor layer, a dielectric layer, and a second conductor layer are stacked in this order, and which is connected to the second conductor layer in order to mutually synchronize a plurality of antennas at a frequency of a terahertz wave; and a bias line connecting a power supply for supplying a bias signal to a semiconductor layer and the second conductor layer. A wiring layer in which the coupling line is formed and a wiring layer in which the bias line is formed are different layers. The bias line is disposed in a layer between the first conductor layer and the second conductor layer.

A time-to-digital converter (TDC) circuit generates a digital output indicating a time, known as a phase difference, from a phase of the generated signal to a corresponding phase of a reference signal. The digital output is used by the digitally controlled oscillator (DCO) to correct for the phase/frequency difference to synchronize the generated signal with the reference signal. In an aspect, an adaptive TDC circuit generates a first digital indication in a coarse mode when the offset time is above a threshold and generates a second digital indication in a fine mode when the offset time is below the threshold. The first digital indication and the second digital indication each comprise a same number of bits, and the first digital indication is normalized to the second digital indication for the digital output of the adaptive TDC circuit. A fractional bit may be employed to compensate for a quantization error.

In some embodiments, a phase-locked loop (PLL) system comprises a phase-frequency detector (PFD) configured to compare a phase-frequency reference signal and a feedback signal, a charge pump (CP) electrically coupled to the PFD and configured to produce a first tuning signal based on an output of the PFD, multiple integrator cells electrically coupled to the CP and configured to output multiple second tuning signals based on a voltage of the first tuning signal relative to a voltage reference signal, and a voltage-controlled oscillator (VCO) electrically coupled to the CP and to the multiple integrator cells and configured to adjust a capacitance value of the VCO based on the multiple second tuning signals. The capacitance value and the first tuning signal affect a frequency of the feedback signal.