Abstract: A method for calibrating a phase nonlinearity of a digital-to-time converter is provided. The method includes generating, based on a control word, a reference signal using a phase-locked loop. A frequency of the reference signal is equal to a frequency of an output signal of the digital-to-time converter. Further, the method includes measuring a temporal order of a transition of the output signal from a first signal level to a second signal level, and a transition of the reference signal from the first signal level to the second signal level. The method additionally includes adjusting a first entry of a look-up table based on the measured temporal order.

Abstract: A method for calibrating a phase nonlinearity of a digital-to-time converter is provided. The method includes generating, based on a control word, a reference signal using a phase-locked loop. A frequency of the reference signal is equal to a frequency of an output signal of the digital-to-time converter. Further, the method includes measuring a temporal order of a transition of the output signal from a first signal level to a second signal level, and a transition of the reference signal from the first signal level to the second signal level. The method additionally includes adjusting a first entry of a look-up table based on the measured temporal order.

Abstract: A phase interpolator is provided. The phase interpolator includes a plurality of first interpolation cells each configured to supply a first current to a common node of the phase interpolator. Further, the phase interpolator includes a plurality of second interpolation cells each configured to supply a second current to the common node. The second current is lower than the first current, wherein a sum of the plurality of second currents supplied to the common node by the plurality of second interpolation cells is substantially equal to the first current.

Abstract: An apparatus for interpolating between a first and a second signal is provided. The apparatus includes a plurality of interpolation cells coupled to a common node of the apparatus. Further, the apparatus includes a control circuit configured to supply, based on a control word, respective selection signals to each of the plurality of interpolation cells. At least one of the plurality of interpolation cells is configured to couple the common node to a first potential if the first signal and the second signal are both at a first signal level, couple the common node to a second potential, which is different from the first potential, if the first signal and the second signal are both at a second signal level, which is different from the first signal level, and to decouple the common node from at least one of the first potential and the second potential if the first signal and the second signal are at different signal levels.

Abstract: An apparatus for generating a radio frequency signal based on a symbol within a constellation diagram is provided. The constellation diagram is spanned by a first axis representing an in-phase component and an orthogonal second axis representing a quadrature component. The apparatus includes a processing unit configured to select a segment of a plurality of segments of the constellation diagram containing the symbol. The segment is delimited by a third axis and a fourth axis each crossing the origin of the constellation diagram and spanning an opening angle of the segment of less than about 90°. The processing unit is further configured to calculate a first coordinate of the symbol with respect to the third axis, and a second coordinate of the symbol with respect to the fourth axis. The apparatus further includes a plurality of digital-to-analog converter cells configured to generate the radio frequency signal using the first coordinate and the second coordinate.

Abstract: An apparatus for interpolating between a first and a second signal is provided. The apparatus includes a plurality of interpolation cells coupled to a common node of the apparatus. Further, the apparatus includes a control circuit configured to supply, based on a control word, respective selection signals to each of the plurality of interpolation cells. At least one of the plurality of interpolation cells is configured to couple the common node to a first potential if the first signal and the second signal are both at a first signal level, couple the common node to a second potential, which is different from the first potential, if the first signal and the second signal are both at a second signal level, which is different from the first signal level, and to decouple the common node from at least one of the first potential and the second potential if the first signal and the second signal are at different signal levels.

Abstract: Some embodiments include apparatus and methods using a first digital-to-time converter (DTC) circuit to receive an input clock signal and generate a first clock signal based on the input clock signal, a second DTC circuit to receive the input clock signal and generate a second clock signal based on the input clock signal, and an output circuit to receive the first and second clock signals to generate an output clock signal based on the first and second clock signals.

Abstract: An apparatus for interpolating between a first signal edge and a second signal edge is provided. The apparatus includes a plurality of interpolation cells coupled to a common node. At least one of the plurality of interpolation cells is configured to supply, based on a control word, the first signal edge and/or the second signal edge to the common node. Further, the apparatus includes a control circuit configured to activate all of the plurality interpolation cells in a first mode of operation, and to deactivate part of the plurality of interpolation cells in a second mode of operation.

Abstract: An apparatus for generating a radio frequency signal based on a symbol within a constellation diagram is provided. The constellation diagram is spanned by a first axis representing an in-phase component and an orthogonal second axis representing a quadrature component. The apparatus includes a processing unit configured to select a segment of a plurality of segments of the constellation diagram containing the symbol. The segment is delimited by a third axis and a fourth axis each crossing the origin of the constellation diagram and spanning an opening angle of the segment of less than about 90°. The processing unit is further configured to calculate a first coordinate of the symbol with respect to the third axis, and a second coordinate of the symbol with respect to the fourth axis. The apparatus further includes a plurality of digital-to-analog converter cells configured to generate the radio frequency signal using the first coordinate and the second coordinate.

Abstract: Some embodiments include apparatus and methods using a first digital-to-time converter (DTC) circuit to receive an input clock signal and generate a first clock signal based on the input clock signal, a second DTC circuit to receive the input clock signal and generate a second clock signal based on the input clock signal, and an output circuit to receive the first and second clock signals to generate an output clock signal based on the first and second clock signals.

Abstract: A phase interpolator is provided. The phase interpolator includes a plurality of first interpolation cells each configured to supply a first current to a common node of the phase interpolator. Further, the phase interpolator includes a plurality of second interpolation cells each configured to supply a second current to the common node. The second current is lower than the first current, wherein a sum of the plurality of second currents supplied to the common node by the plurality of second interpolation cells is substantially equal to the first current.

Abstract: An apparatus for interpolating between a first signal edge and a second signal edge is provided. The apparatus includes a plurality of interpolation cells coupled to a common node. At least one of the plurality of interpolation cells is configured to supply, based on a control word, the first signal edge and/or the second signal edge to the common node. Further, the apparatus includes a control circuit configured to activate all of the plurality interpolation cells in a first mode of operation, and to deactivate part of the plurality of interpolation cells in a second mode of operation.

Abstract: Some embodiments include apparatus and methods using a first digital-to-time converter (DTC) circuit to receive an input clock signal and generate a first clock signal based on the input clock signal, a second DTC circuit to receive the input clock signal and generate a second clock signal based on the input clock signal, and an output circuit to receive the first and second clock signals to generate an output clock signal based on the first and second clock signals.

Abstract: Described herein are technologies related to an implementation of a digital-to-time converter (DTC) circuitry that utilizes a first interpolation and a second and finer interpolation to increase interpolation ranges. The DTC circuitry generates a fine-phase modulated signal generating at least two correlated signals, and generating coarse and fine interpolations of the correlated signals.

Abstract: An apparatus comprises a radio frequency (RF) transceiver circuit; a phase modulator that comprises digital-to-time converter (DTC) circuitry configured to convert a digital value to a specified signal phase of a signal transmitted by the RF transceiver circuit; low drop out regulator (LDO) circuitry operatively coupled to the DTC circuitry, wherein a bias current of the LDO circuitry is adjustable; and logic circuitry operatively coupled to the LDO circuitry and DTC circuitry, wherein the logic circuitry is configured to set the adjustable bias current of the LDO circuitry according to a digital value input to the DTC circuitry.

Abstract: Described herein are technologies related to an implementation of a digital-to-time converter (DTC) circuitry that utilizes a first interpolation and a second and finer interpolation to increase interpolation ranges. The DTC circuitry generates a fine-phase modulated signal generating at least two correlated signals, and generating coarse and fine interpolations of the correlated signals.

Abstract: This application discusses, among other things, an interpolator architecture for digital-to-time converters (DTCs). In an example, an interpolator can include interpolation cells and retention cells configured provide an interpolated output based on at least two offset clock signals. In certain examples, an example interpolator can provide contention free control of the interpolator output with improved noise immunity.

Abstract: This application discusses, among other things, an interpolator architecture for digital-to-time converters (DTCs). In an example, an interpolator can include interpolation cells and retention cells configured provide an interpolated output based on at least two offset clock signals. In certain examples, an example interpolator can provide contention free control of the interpolator output with improved noise immunity.