Disclosed successive approximation register analog-to-digital converters (SAR ADCs) and conversion methods detect a statistical effect of meta-stability induced errors and limit the level of such errors. One illustrative integrated circuit chip includes: a SAR ADC that employs asynchronous bit cycles to convert a sequence of analog signal samples into a sequence of digital signal samples; and a detector that accelerates the asynchronous bit cycles when a meta-stability error bias exceeds a predetermined threshold. An illustrative analog-to-digital conversion method includes: converting a sequence of analog signal samples to a sequence of digital signal samples using a successive approximation register analog to digital converter (SAR ADC) with asynchronous bit cycles; deriving a meta-stability error bias from the sequence of digital signal samples; and accelerating the asynchronous bit cycles when the meta-stability error bias exceeds a predetermined threshold.

Continuous time pipeline, level-crossing (LC), analog-to-digital converters (ADCs) use a plurality of stages from a first stage to a last stage. Each stage has an array of comparators that are provided with an array of reference voltage levels. Each stage is configured to detect level crossings of increasing fineness compared to the preceding stage such that the accuracy of a digitized representation of an input signal can be increased by adding stages as well as increasing the number of comparators in each stage. The voltage error in the digitized representation of the signal that remains after each stage provides the input to the subsequent stage. The continuous time pipeline LC ADCs are also applied to analog signal processing and software defined radios.

An integrated circuit includes: a magnetic sensor for outputting a magnetic sensor signal indicative of a first current in a conductor; a shunt interface for outputting a shunt signal indicative of a second current across an external shunt resistor; a processing circuit for receiving the magnetic sensor signal and the shunt signal; and a communication interface for providing a signal indicative of a measured current based on one or more of the first current and the second current. The integrated circuit can compare the magnetic sensor signal and the shunt signal and provide an output signal in response to the magnetic sensor signal and the shunt signal.

Successive-approximation-register (SAR) analog-to-digital conversion technique continues to be one of the most popular analog-to-digital conversion techniques, due to their versatility, which allows providing high resolution output or high conversion rates. In addition, SAR analog-to-digital converters (ADC) have a modest circuit complexity that results in low-power dissipation. A SAR ADC is, typically, composed of a single comparator, a bank of capacitors and switches, in addition to, a control digital logic. However, the comparator input capacitance is input-signal dependent, and hence introduces non-linearity to the transfer characteristics of the ADC. A simple technique is devised to significantly reduce this non-linearity, by pre-distorting the sampled-and-held input signal using the same comparator input capacitance.

Described are apparatus and methods for successive approximation register (SAR) analog to digital converter (ADC) (SAR ADC) with factoring and background clock calibration. An apparatus includes a SAR ADC configured to, in response to receiving an enable flag based on detection of an acquisition clock with a first logic state sent by a controller, sample and convert a pair of differential input signals using a sampling clock to obtain a defined number of samples in an acquisition clock cycle and a factoring circuit configured to obtain the defined number of samples from the SAR ADC using a capturing clock based on the sampling clock, factor the defined number of samples, and send a factored samples ready flag to the controller.

A mixed-domain circuit has a differential pair of Digital-to-Time Converters (DTCs), one receiving a reference clock and the other receiving a feedback clock. A Time-to-Digital Converter (TDC) compares outputs from the differential pair of DTCs and generates a digital error value that controls a digital loop filter that controls a Digitally-Controlled Oscillator (DCO) that generates an output clock. A Multi-Modulus Divider (MMD) generates the feedback clock. An accumulated modulation from a delta-sigma modulator is compared to the digital error value by a Least-Mean Square (LMS) correlator to adjust supply voltage or current sources in the pair of DTCs to compensate for errors. A capacitor in each DTC has a charging time adjusted by the accumulated modulation. The DTC can be reduced to a Time-to-Voltage Converter (TVC) and the analog voltages on the capacitors input to an Analog-to-Digital Converter (ADC) to generate the digital error value.

Asynchronous stream generation and processing techniques are described that support implementation of an asynchronous stream mote in which one or more analog sensor signals are used to generate one or more asynchronous streams. On-device operations processing of the one or more asynchronous streams may be performed before transmission of the result(s) to other system components (e.g., peer motes or higher-level system components).

The invention provides a signal processing system, for transferring analog signals from a probe to a remote processing unit. The system comprises a first ASIC at a probe, which is adapted to receive an analog probe signal. The first ASIC comprises an asynchronous sigma-delta modulator, wherein the asynchronous sigma-delta modulator is adapted to: receive the analog probe signal; and output a binary bit-stream. The system further comprises a second ASIC at the remote processing unit, adapted to receive the binary bit-stream. The asynchronous may further include a time gain function circuit, the first ASIC may further comprise a multiplexer, the second ASIC may further comprise a time-to-digital converter. The time to digital converter may be a pipelined time-to-digital converter.

A mixed-domain circuit has a differential pair of Digital-to-Time Converters (DTCs), one receiving a reference clock and the other receiving a feedback clock. A Time-to-Digital Converter (TDC) compares outputs from the differential pair of DTCs and generates a digital error value that controls a digital loop filter that controls a Digitally-Controlled Oscillator (DCO) that generates an output clock. A Multi-Modulus Divider (MMD) generates the feedback clock. An accumulated modulation from a delta-sigma modulator is compared to the digital error value by a Least-Mean Square (LMS) correlator to adjust supply voltage or current sources in the pair of DTCs to compensate for errors. A capacitor in each DTC has a charging time adjusted by the accumulated modulation. The DTC can be reduced to a Time-to-Voltage Converter (TVC) and the analog voltages on the capacitors input to an Analog-to-Digital Converter (ADC) to generate the digital error value.

Single-stage and multiple-stage current-mode Analog-to-Digital converters (iADC)s utilizing apparatuses, circuits, and methods are described in this disclosure. The disclosed iADCs can operate asynchronously and be free from the digital clock noise, which also lowers dynamic power consumption, and reduces circuitry overhead associated with free running clocks. For their pseudo-flash operations, the disclosed iADCs do not require their input current signals to be replicated which saves area, lowers power consumption, and improves accuracy. Moreover, the disclosed methods of multi-staging of iADCs increase their resolutions while keeping current consumption and die size (cost) low. The iADC's asynchronous topology facilitates decoupling analog-computations from digital-computations, which helps reduce glitch, and facilitates gradual degradation (instead of an abrupt drop) of iADC's accuracy with increased input current signal frequency. The iADCs can be arranged with minimal digital circuitry (i.e., be digital-light), thereby saving on die size and dynamic power consumption.