Describe is a buffer which comprises: a differential source follower coupled to a first input and a second input; first and second current steering devices coupled to the differential source follower; and a current source coupled to the first and second current steering devices. The buffer provides high supply noise rejection ratio (PSRR) together with high bandwidth.

A current transformer (CT) for the purpose of, for example, current measurement, that uses a power line as a first coil and a second coil for measurement purposes, is further equipped with a third coil. Circuitry connected to the third coil is adapted to measure a signal therefrom. The measured signal from the third coil is compared to a signal measured from the second coil and based on the results, internal CT parameters are determined allowing calibration of actual results to expected results thereby providing an improved accuracy. This is especially desirable when using the CT for measurement of the like of current or phase of the primary coil when measurements are adjusted using the newly determined calibration parameters.

A current transformer (CT) for the purpose of, for example, current measurement, that uses a power line as a first coil and a second coil for measurement purposes, is further equipped with a third coil. Circuitry connected to the third coil is adapted to measure a signal therefrom. The measured signal from the third coil is compared to a signal measured from the second coil and based on the results, internal CT parameters are determined allowing calibration of actual results to expected results thereby providing an improved accuracy. This is especially desirable when using the CT for measurement of the like of current or phase of the primary coil when measurements are adjusted using the newly determined calibration parameters.

A device is provided for time measurement of a clock-based signal comprising a sample stage comprising a switching device that is driven by a control signal and a capacitance (Cs), wherein the sample stage is arranged to transform an analog input signal in an analog output signal, the device further comprising an analog-to-digital converter to convert the analog output signal into a digital output signal, wherein the input signal applied to the sample stage is a reference signal and wherein the clock-based signal is applied to the control signal. Also, an according method is suggested.

In a method of operating an analog-to-digital converter, a gain error and an offset error that are associated with a digital code generated from the analog-to-digital converter are obtained by performing a first analog-to-digital conversion on a first input analog signal. The gain error and the offset error are stored. A calibration digital code is generated by performing a second analog-to-digital conversion on a second input analog signal based on the gain error and the offset error.

A frequency determination device for determining a frequency relationship between a reference signal and a clock signal. Each constituent TDC is configured to provide a digitally represented constituent output signal in response to receiving a constituent reference signal and a constituent clock signal, and the frequency determination device is configured to successively provide respectively delayed versions of the constituent clock signal of a first constituent TDC as respective constituent clock signals to the other constituent TDC:s. The reference signal provider is configured to provide the respective constituent reference. The switching circuitry is configured to provide the reference signal as the constituent clock signal to the first constituent TDC. The determination circuitry is configured to determine a number of consecutively same-valued symbols in a concatenation of the digitally represented constituent output signals of the constituent TDC:s, and to determine the frequency relationship.

A frequency determination device for determining a frequency relationship between a reference signal and a clock signal. Each constituent TDC is configured to provide a digitally represented constituent output signal in response to receiving a constituent reference signal and a constituent clock signal, and the frequency determination device is configured to successively provide respectively delayed versions of the constituent clock signal of a first constituent TDC as respective constituent clock signals to the other constituent TDC:s. The reference signal provider is configured to provide the respective constituent reference. The switching circuitry is configured to provide the reference signal as the constituent clock signal to the first constituent TDC. The determination circuitry is configured to determine a number of consecutively same-valued symbols in a concatenation of the digitally represented constituent output signals of the constituent TDC:s, and to determine the frequency relationship.

An interleaved analog-to-digital conversion (ADC) system may have timing errors in a time domain that is corrected using phase compensation in a phase domain. The ADC system may include sub-ADCs, each receiving a clock signal, which is associated with a representation of a timing skew value, reflecting an undesired timing error. A mixer may have sub-mixers, each receiving a sub-ADC output signal and a compensated numerically controlled oscillator (NCO) value. A combiner may combine the sub-mixer output signals. A decimator may decimate the output of the combiner. Each timing skew value is in a time domain. A compensated NCO value is determined using a respective phase skew value. Each phase skew value is an offset value in phase and is not a value in time. Each phase skew value in a phase domain compensates the respective timing skew value in a time domain. Multiple ADC systems and methods are described.

A system and method for equalization of a linear or non-linear system. The system includes an adder configured to add an analog reference signal and an input signal, a processing system configured to process a sum of the analog reference signal and the input signal, a non-linear equalizer (NLEQ) configured to process an output of the processing system to remove a distortion incurred by the processing system, a calibration circuitry configured to generate a reconstructed reference signal in digital domain based on measurement of the analog reference signal, and generate coefficients for the NLEQ based on the reconstructed reference signal and the output of the processing system, and a subtractor configured to subtract the reconstructed reference signal from an output of the NLEQ. The analog reference signal may be a sinusoid including single or multiple tones of sinusoids. The non-linear system may be an analog-to-digital converter (ADC).

Quantum repeater systems and apparatus for quantum communication. In one aspect, a system includes a quantum signal receiver configured to receive a quantum field signal; a quantum signal converter configured to: sample quantum analog signals from a quantum field signal received by the quantum signal receiver; encode sampled quantum analog signals as corresponding digital quantum information in one or more qudits, comprising applying a hybrid analog-digital encoding operation to each quantum analog signal and a qudit in an initial state; decode digital quantum information stored in the one or more qudits as a recovered quantum field signal, comprising applying a hybrid digital-analog decoding operation to each qudit and a quantum analog register in an initial state; a quantum memory comprising qudits and configured to store digital quantum information encoded by the quantum signal converter; and a quantum signal transmitter configured to transmit the recovered quantum field signal.