A receiver device includes an I-Q mixer circuit configured to provide an I-phase signal and a Q-phase signal. The receiver device also includes a first analog-to-digital converter (ADC) circuit configured to digitize the I-phase signal. The receiver device also includes a second ADC circuit configured to digitize the Q-phase signal. The receiver device also includes a 25% duty cycle clock generator configured to provide 25% duty cycle clock signals to the I-Q mixer. The 25% duty cycle clock generator includes a divider circuit with an inverter ring arrangement.

In certain aspects, an apparatus includes a plurality of phase generators configured to generate a first plurality of local oscillator (LO) phase signals, wherein the plurality of phase generators includes a first set of phase generators and a second set of phase generators. The apparatus also includes a duty cycle generator coupled to the plurality of phase generators, wherein the duty cycle generator is configured to receive the first plurality of LO phase signals and to generate a second plurality of LO phase signals by converting a duty cycle of each of the first plurality of LO phase signals. The first set of phase generators is located adjacent to a first side of the duty cycle generator and the second set of phase generators is located adjacent to a second side of the duty cycle generator, the second side being opposite the first side.

A receiver device includes an I-Q mixer circuit configured to provide an I-phase signal and a Q-phase signal. The receiver device also includes a first analog-to-digital converter (ADC) circuit configured to digitize the I-phase signal. The receiver device also includes a second ADC circuit configured to digitize the Q-phase signal. The receiver device also includes a 25% duty cycle clock generator configured to provide 25% duty cycle clock signals to the I-Q mixer. The 25% duty cycle clock generator includes a divider circuit with an inverter ring arrangement.

An apparatus is configured to receive a two-phase input clock and output a four-phase output clock. The apparatus includes a circuit configured in a ring topology comprising a first switch controlled by a first phase of the input clock, a first inverting amplifier, a second switch controlled by a second phase of the input clock, a second inverting amplifier, a third switch controlled by the first phase of the input clock, a third inverting amplifier, a fourth switch controlled by the second phase of the input clock, and a fourth inverting amplifier, wherein the first inverting amplifier and the third inverting amplifier share a first regenerative load that is reset upon the first phase of the input clock, and the second inverting amplifier and the fourth inverting amplifier share a second regenerative load that is reset upon the second phase of the input clock.

A duty cycle conversion circuit portion comprises N inverters, wherein N is an integer greater than two. The duty cycle conversion circuit is arranged to receive N input signals each having a duty cycle between 1/N and 2/N. Each of the N input signals is applied to a respective input terminal of one of the N inverters such that each inverter receives a different input signal. Each of the N input signals is applied to a respective power terminal of one of the N inverters such that each inverter is powered by a different input signal. Each inverter receives different input signal at its respective input terminal to the input signal applied to its respective power terminal.

Techniques are described herein for phase modulation and interpolation that support high phase modulation resolution with high linearity. Embodiments receive a digital signal that uses a sequence of K-bit digital codes to encode a sequence of instantaneous phases for phase-modulating a local oscillator signal. A fractional divider divides a reference clock into N divided clock signals at equally spaced phase intervals and selects a pair of such signals based on first designated bits of the digital code. A fractional divider-calibrated delay line generates M delayed clock signals at equally spaced phase intervals between the selected pair of divided clock signals, and selects a pair of the delayed clock signals based on second designated bits of the digital code. A digital controlled edge interpolator generates a delayed local oscillator output signal by interpolating between the selected pair of delayed clock signals based on third designated bits of the digital code.

A phase correction circuit includes a plurality of signal paths configured to transmit multi-phase signals. The phase correction circuit further includes a loop circuit coupled to the plurality of signal paths, the loop circuit configured to correct phase skew among the multi-phase signals by averaging the phases of two signals which are obtained by synthesizing a signal of each of the signal paths with another signal of a signal path different from the corresponding signal path.

Apparatuses are provided for a quadra-phase clock signal generator. An example apparatus includes a first delay circuit configured to receive a first input clock signal generating a first delayed clock signal. A first phase mixer is provided communicatively coupled to the first delay circuit and configured to receive the first delayed clock signal at a first input and a second input clock signal at a second input. The first phase mixer may then generate a first output clock signal at a first output node responsive, at least in part, to mixing of the first delayed clock signal and the second input clock signal.

One embodiment includes a clock distribution system. The system includes a first resonator spine that propagates a first clock signal and a second resonator spine that propagates a second clock signal that is out-of-phase relative to the first clock signal. The system also includes at least one resonator rib each conductively coupled to at least one of the first and second resonator spines and being arranged as a standing wave resonator with respect to a respective at least one of the first and second clock signals to inductively provide the respective at least one of the first and second clock signals to an associated circuit via a respective transformer-coupling line. The system further includes an isolation element configured to mitigate at least one of inductive and capacitive coupling between the first and second clock signals.

One embodiment includes a clock distribution system. The system includes at least one resonator spine that propagates a clock signal and at least one resonator rib conductively coupled to the at least one resonator spine and being arranged as a standing wave resonator. At least one of the at least one resonator rib has a thickness that varies along a length of the respective one of the at least one resonator rib. The system also includes at least one transformer-coupling line. Each of the at least one transformer-coupling line can be conductively coupled to an associated circuit and being inductively coupled to the at least one resonator rib to inductively generate a clock current corresponding to the clock signal to provide functions for the associated circuit.