A circuit and a method for eliminating a spurious signal are provided. The circuit includes a phase detector, a spurious estimation and regeneration device, and a phase shifter. After an actual clock signal containing a spurious signal is obtained, the contained spurious signal is estimated based on the reference clock signal that does not contain the spurious signal. Reverse adjustment is performed on the actual clock signal based on the estimated spurious signal to eliminate the spurious signal in the actual clock signal, ensuring eliminating the generated spurious signal by performing reverse adjustment, improving the signal transmission quality, thereby solving the problem of reduced signal quality due to that the spurious signal cannot be suppressed in generation according to the conventional technology.

A circuit and a method for eliminating a spurious signal are provided. The circuit includes a phase detector, a spurious estimation and regeneration device, and a phase shifter. After an actual clock signal containing a spurious signal is obtained, the contained spurious signal is estimated based on the reference clock signal that does not contain the spurious signal. Reverse adjustment is performed on the actual clock signal based on the estimated spurious signal to eliminate the spurious signal in the actual clock signal, ensuring eliminating the generated spurious signal by performing reverse adjustment, improving the signal transmission quality, thereby solving the problem of reduced signal quality due to that the spurious signal cannot be suppressed in generation according to the conventional technology.

An aspect relates to a filter or a first gyrator including a first set of cascaded inverters, and a first set of one or more passive devices coupled to the first set of cascaded inverters. Another aspect relates to a method including applying an input signal to an input of a first one of a set of cascaded inverters coupled to a set of one or more passive devices, and receiving an output signal from the set of cascaded inverters, the output signal being a filtered version of the input signal. Still another aspect relates to a transceiver including a filter with a first set of cascaded inverters, and a first set of one or more passive devices coupled to the first set of cascaded inverters; and a mixer coupled to the filter.

A method of manufacturing an electrical system for reducing differential-to-differential far end crosstalk (DDFEXT) includes converting a first S parameter representative of a design of a first electrical system into a differential-only S parameter, generating a second differential-only S parameter configured to add even-mode propagation delay and odd-mode propagation delay of the differential-only S parameter of the electrical system such that a total even-mode propagation delay and odd-mode propagation delay of the differential-only S parameter are substantially equivalent, and reconfiguring a second electrical system from the differential-only S parameter and the second differential-only S parameter.

A method of manufacturing an electrical system for reducing differential-to-differential far end crosstalk (DDFEXT) includes converting a first S parameter representative of a design of a first electrical system into a differential-only S parameter, generating a second differential-only S parameter configured to add even-mode propagation delay and odd-mode propagation delay of the differential-only S parameter of the electrical system such that a total even-mode propagation delay and odd-mode propagation delay of the differential-only S parameter are substantially equivalent, and reconfiguring a second electrical system from the differential-only S parameter and the second differential-only S parameter.

An interface circuit may convert an input electrical signal at an input node in a first power domain having a first ground or reference voltage into an output electrical signal at an output node in a second power domain having a second ground or reference voltage. Notably, a level-shifting circuit in the interface circuit may selectively electrically couple to the input node and the output node. Then, when there is electrical coupling, the level-shifting circuit may perform level shifting between the first power domain and the second power domain. The level shifting may involve: passing, using a first filter, frequencies in the input electrical signal below a first corner frequency; passing, using a second filter in parallel with the first filter, frequencies in the input electrical signal above a second corner frequency; and combining outputs of the first filter and the second filter as the output electrical signal.

An interface circuit may convert an input electrical signal at an input node in a first power domain having a first ground or reference voltage into an output electrical signal at an output node in a second power domain having a second ground or reference voltage. Notably, a level-shifting circuit in the interface circuit may selectively electrically couple to the input node and the output node. Then, when there is electrical coupling, the level-shifting circuit may perform level shifting between the first power domain and the second power domain. The level shifting may involve: passing, using a first filter, frequencies in the input electrical signal below a first corner frequency; passing, using a second filter in parallel with the first filter, frequencies in the input electrical signal above a second corner frequency; and combining outputs of the first filter and the second filter as the output electrical signal.

In described examples of a ramp circuit, a first terminal of a capacitor is coupled to a ramp terminal and a second capacitor terminal is coupled to a return terminal. A charge source has an input terminal coupled to a supply terminal and a charge output terminal. A resistor has a first terminal coupled to the return terminal. A first switch is coupled between the ramp terminal and a second terminal of the resistor. A second switch is coupled between the charge output terminal and the ramp terminal.

In described examples of a ramp circuit, a first terminal of a capacitor is coupled to a ramp terminal and a second capacitor terminal is coupled to a return terminal. A charge source has an input terminal coupled to a supply terminal and a charge output terminal. A resistor has a first terminal coupled to the return terminal. A first switch is coupled between the ramp terminal and a second terminal of the resistor. A second switch is coupled between the charge output terminal and the ramp terminal.

A circuit and a method for eliminating a spurious signal are provided. The circuit includes a phase detector, a spurious estimation and regeneration device, and a phase shifter. After an actual clock signal containing a spurious signal is obtained, the contained spurious signal is estimated based on the reference clock signal that does not contain the spurious signal. Reverse adjustment is performed on the actual clock signal based on the estimated spurious signal to eliminate the spurious signal in the actual clock signal, ensuring eliminating the generated spurious signal by performing reverse adjustment, improving the signal transmission quality, thereby solving the problem of reduced signal quality due to that the spurious signal cannot be suppressed in generation according to the conventional technology.