In some examples, a device comprises a first driver coupled to a first node, the first node to couple to a first load external to the device. The device comprises a second driver coupled to a second node, the second node coupled to a second load internal to the device. The device comprises a comparison circuit having an inverting input coupled to the first node and a non-inverting input coupled to the second node. Sizes of the second driver and the second load are configured proportionately to sizes of the first driver and the first load, respectively.

The present disclosure includes a frequency divider circuit that includes a superharmonically injection-locked ring oscillator, injection circuitry, and various switches. The input can include a collection of signal components at different phases that are all at the same, but changeable, frequency. The divider's division ratio can be changed during the divider's operation by, for example, utilizing one or more switches to change: the number of stages in the ring oscillator, and/or which stage(s) of the ring oscillator are injected into by which input signal components.

The present disclosure includes a frequency divider circuit that includes a superharmonically injection-locked ring oscillator, injection circuitry, and various switches. The input can include a collection of signal components at different phases that are all at the same, but changeable, frequency. The divider's division ratio can be changed during the divider's operation by, for example, utilizing one or more switches to change: the number of stages in the ring oscillator, and/or which stage(s) of the ring oscillator are injected into by which input signal components.

Phase-locked loop circuitry to generate an output signal, the phase-locked loop circuitry comprising oscillator circuitry, switched resistor loop filter, coupled to the input of the oscillator circuitry (which, in one embodiment, includes a voltage-controlled oscillator), including a switched resistor network including at least one resistor and at least one capacitor, wherein an effective resistance of the switched resistor network is responsive to and increases as a function of one or more pulsing properties of a control signal (wherein pulse width and frequency (or period) are pulsing properties of the control signal), phase detector circuitry, having an output which is coupled to the switched resistor loop filter, to generate the control signal (which may be periodic or non-periodic). The phase-locked loop circuitry may also include frequency detection circuitry to provide a lock condition of the phase-locked loop circuitry.

Phase-locked loop circuitry to generate an output signal, the phase-locked loop circuitry comprising oscillator circuitry, switched resistor loop filter, coupled to the input of the oscillator circuitry (which, in one embodiment, includes a voltage-controlled oscillator), including a switched resistor network including at least one resistor and at least one capacitor, wherein an effective resistance of the switched resistor network is responsive to and increases as a function of one or more pulsing properties of a control signal (wherein pulse width and frequency (or period) are pulsing properties of the control signal), phase detector circuitry, having an output which is coupled to the switched resistor loop filter, to generate the control signal (which may be periodic or non-periodic). The phase-locked loop circuitry may also include frequency detection circuitry to provide a lock condition of the phase-locked loop circuitry.

Disclosed herein are devices and methods to reduce unwanted CIMS emission in a wireless communication device, such that the transmit (TX) power level applied in a RU can be increased without exceeding a regulatory emission requirement. In some aspects, unwanted emission may be reduced by shifting or changing local oscillator (LO) frequencies during TX operation. Some embodiments are directed to a fast-locking PLL with adjustable bandwidth that can be controlled to increase the PLL bandwidth during the RX to TX transition to provide a fast locking to a new LO frequency. Some aspects are directed to configuring an LO frequency shift amount for different RUs when multiple RUs are allocated within a frequency band.

The application provides a calibration method, a calibration device and a multi-phase clock circuit. The method includes: gating each of multi-phase clock signals as a first primary clock signal and gating a corresponding clock signal as a first auxiliary clock signal according to a first preset rule; gating each of the multi-phase clock signals as a second primary clock signal and gating a corresponding clock signal as a second auxiliary clock signal according to a second preset rule; obtaining a time difference between each primary clock signal and its corresponding auxiliary clock signal under the first preset rule and the second preset rule; determining a delay adjustment amount of each primary clock signal according to the time difference, and obtaining a phase error between the multi-phase clock signals according to the delay adjustment amount; and obtaining a calibration amount of the multi-phase clock signals according to the phase error.

The application provides a calibration method, a calibration device and a multi-phase clock circuit. The method includes: gating each of multi-phase clock signals as a first primary clock signal and gating a corresponding clock signal as a first auxiliary clock signal according to a first preset rule; gating each of the multi-phase clock signals as a second primary clock signal and gating a corresponding clock signal as a second auxiliary clock signal according to a second preset rule; obtaining a time difference between each primary clock signal and its corresponding auxiliary clock signal under the first preset rule and the second preset rule; determining a delay adjustment amount of each primary clock signal according to the time difference, and obtaining a phase error between the multi-phase clock signals according to the delay adjustment amount; and obtaining a calibration amount of the multi-phase clock signals according to the phase error.

An apparatus is described and includes a current integrating phase interpolator core having a programmable bias current; an AC-coupled inverter circuit coupled to an output of the current integrating phase interpolator core for receiving a signal comprising a periodic sawtooth waveform therefrom; a digital-to-analog (D/A) converter for setting an input common mode voltage of the AC-coupled inverter circuit; a duty cycle measurement (DCM) circuit for measuring a duty cycle distortion (DCD) of a rectangular wave clock signal output from the AC-coupled inverter circuit; and a circuit for computing a difference in the DCD of the rectangular wave clock signal when the input common mode voltage of the AC-coupled inverter circuit is set to a high voltage and when the input common mode voltage of the AC-coupled inverter circuit is set to a low voltage.

An apparatus is described and includes a current integrating phase interpolator core having a programmable bias current; an AC-coupled inverter circuit coupled to an output of the current integrating phase interpolator core for receiving a signal comprising a periodic sawtooth waveform therefrom; a digital-to-analog (D/A) converter for setting an input common mode voltage of the AC-coupled inverter circuit; a duty cycle measurement (DCM) circuit for measuring a duty cycle distortion (DCD) of a rectangular wave clock signal output from the AC-coupled inverter circuit; and a circuit for computing a difference in the DCD of the rectangular wave clock signal when the input common mode voltage of the AC-coupled inverter circuit is set to a high voltage and when the input common mode voltage of the AC-coupled inverter circuit is set to a low voltage.