Methods and devices for digitizing an analog repetitive signal using waveform averaging are described. An example method includes generating a time-varying dither signal, receiving the analog repetitive signal comprising multiple instances of a waveform, wherein each waveform has a waveform duration, wherein an average of the time-varying dither signal over multiple waveform durations is substantially zero, and wherein the time-varying dither signal varies over each waveform duration, generating a timing alignment, combining each waveform with the corresponding portion of the time-varying dither signal over each waveform duration to produce an analog output signal, converting the analog output signal to a digital output signal, and producing, based on the timing alignment, a digital averaged signal based on averaging the multiple instances of the waveform in the analog output signal, wherein the timing alignment is used to align the multiple instances of the waveform in the analog output signal.

A data processing system can include a first IC including one or more A/D converters that receive analog inputs from one or more sensors and generate corresponding digital data, a second IC including one or more processing elements that operate on the digital data, and communication circuitry, coupled between the one or more A/D converters and processing elements, that includes a packetizer on the first IC that receives samples and sample data from the one or more A/D converters and assembles each sample and corresponding sample data into a packet, a primary physical interface on the first IC that communicates the packet to a secondary physical interface on the second IC, and a de-packetizer that on the second IC that receives the packet, de-packetizes it, and delivers the sample and sample data to the one or more processing elements.

A method, apparatus, and energy metering system obtains mains samples of a mains power line signal, performs non-white noise (NWN) filtering of the mains power line signal, obtains adjustable clock source samples of an adjustable clock signal of an adjustable clock oscillator, determines a difference based on the mains samples and the adjustable clock source samples, adjusts an adjustable clock source frequency of the adjustable clock oscillator based on the difference, and applies the adjustable clock source frequency to an analog to digital converter (ADC) to determine a conversion rate of the ADC.

A method executable by a low voltage drive circuit (LVDC) includes receiving an analog receive signal, converting the analog receive signal into analog inbound data, converting the analog inbound data into digital inbound data, filtering the digital inbound data to produce filtered digital data, sampling and holding an n-bit digital value of the filtered digital data to produce an n-bit sampled digital data value, adjusting formatting of the n-bit sampled digital data value to produce a formatted digital value, and generating a packet of received digital data from a plurality of formatted digital values.

N (n is a natural number) power converters operate in accordance with a drive signal to generate a power to be supplied to a load. Multi-redundant A/D converters convert an analog detection value from the power converters into digital values. First and second controllers operate in parallel and each generate a drive signal of the power converters using the digital values from the A/D converters. A system selector selects one controller in accordance with an abnormality detection result of the first and second controllers. Each of n output selectors receives the drive signals from both of the first and second controllers and outputs the drive signal from the one controller selected by the system selector to the power converters.

A control device according to an embodiment includes a driving unit that supplies, to a control target, a current or a voltage on which an Alternating-Current (AC) component is superimposed, an Analog-to-Digital (AD) converter, and an AD conversion controller. The AD conversion controller causes, in an AC cycle of the AC component, the AD converter to execute a first AD conversion in synchronization with a starting timing of the AC cycle, and then to execute second and subsequent AD conversions at predetermined time intervals in response to a trigger by an internal timer of the AD converter.

A method and apparatus for processing a periodic analog signal using a composite ADC including a time interleaved set of sub-ADCs, to produce a replica signal representative of the analog signal, wherein the replica signal is characterized by suppression of additive noise on the periodic analog signal, and correction of sub-ADC-caused distortions. Streams of samples from the respective sub-ADCs are accumulated separately for respective positions in signal periods of the periodic analog signal to provide sub-replicas. Fourier transforms of the replicas are determined for the different sub-ADCs, and those Fourier transforms are averaged to obtain a mean Fourier transform. Frequency responses of the sub-ADCs are corrected by dividing the mean Fourier transform by the respective sub-ADC frequency responses. An averaged replica of the signal period is obtained by determining an inverse Fourier transform of the corrected mean Fourier transform.

The present invention provides a receiver including an ADC, an echo-cancellation circuit and a control circuit. In the operations of the receiver, the ADC uses a clock signal to perform an analog-to-digital converting operation on an analog input signal to generate digital input signal, the echo-cancellation circuit refers to a plurality of tap coefficients to perform an echo-cancellation operation on the digital input signal to generate an output signal, and the control circuit is configured to control a phase of the clock signal inputted into the ADC. In addition, when the phase of the clock signal is adjusted, the control circuit calculates a plurality of updated tap coefficients according to the plurality of tap coefficients used by the echo-cancellation circuit in a previous time, for use of the echo-cancellation circuit.

An electrical circuit includes a signal processing chain and a controller. The signal processing chain includes an integrator configured to integrate an input signal over an integration time. The controller is connected to a signal output of the signal processing chain to receive and evaluate an output signal of the signal processing chain. The controller is further configured to adapt the integration time based on the output signal.

A method executable by a low voltage drive circuit (LVDC) includes receiving an analog receive signal, converting the analog receive signal into analog inbound data, converting the analog inbound data into digital inbound data, filtering the digital inbound data to produce filtered digital data, sampling and holding an n-bit digital value of the filtered digital data to produce an n-bit sampled digital data value, adjusting formatting of the n-bit sampled digital data value to produce a formatted digital value, and generating a packet of received digital data from a plurality of formatted digital values.