There is provided an analog-to-digital converter circuit including: a first converter circuit generating a first digital code by performing analog-to-digital conversion on the basis of an input voltage; a second converter circuit generating a second digital code by performing, on the basis of the input voltage and the first digital code, analog-to-digital conversion over a voltage range wider than that. of a least significant. bit of the first converter circuit; an error detector detecting a conversion error of the analog-to-digital conversion on the basis of the first and second digital codes, thereby generating error data indicating a bit having a conversion error and the kind of the conversion error; and a calibration circuit estimating an error factor on the basis of the first and second digital codes and the error data, and performing calibration of a circuit relevant to the estimated error factor on the basis of an estimation result.

Apparatuses, methods, and systems for an antenna assembly, are disclosed. One apparatus includes a multiple layer printed circuit board (PCB), a dielectric plate, and antenna elements. The PCB includes antenna excitation feed elements, wherein the antenna excitation feed elements are located on a layer of the PCB. A second surface of the dielectric plate is affixed to a first surface of PCB forming gaps adjacent each of the antenna excitation feed elements, wherein a dielectric constant of the dielectric plate, a thickness of the dielectric plate, and a thickness of the gaps are selected based on an operating frequency of wireless signals communicated through the antenna assembly, and based on RF (radio frequency) characteristics of the PCB. Each of the antenna elements are affixed to a first surface of the dielectric plate.

Disclosed herein are some examples of analog-to-digital converters (ADCs) that can perform auto-zeroing with amplifying a signal for improvement of a signal-to-noise ratio. The ADCs may produce a first digital code to represent an analog input signal and a second digital code based on a residue from the first digital code, and may combine the first digital code and the second digital code to produce a digital output code to represent the analog input signal. The ADC may utilize a first observation and a second observation of an analog residue value representing the residue to produce the second digital code.

Disclosed herein are some examples of analog-to-digital converters (ADCs) that can perform auto-zeroing with amplifying a signal for improvement of a signal-to-noise ratio. The ADCs may produce a first digital code to represent an analog input signal and a second digital code based on a residue from the first digital code, and may combine the first digital code and the second digital code to produce a digital output code to represent the analog input signal. The ADC may utilize a first observation and a second observation of an analog residue value representing the residue to produce the second digital code.

An energy-efficient capacitance-to-digital converter (CDC) is provided that utilizes a capacitance-domain successive approximation (SAR) technique. Unlike SAR analog-to-digital converters (ADCs), analysis shows that for SAR CDCs, the comparator offset voltage will result in signal-dependent and parasitic-dependent conversion errors, which necessitates an op-amp-based implementation. The inverter-based SAR CDC contemplated herein provides robust, energy-efficient, and fast operation. The inverter-based SAR CDC may include a hybrid coarse-fine programmable capacitor array. The design of example embodiments is insensitive to analog references, and thus achieves very low temperature sensitivity without the need for calibration. Moreover, this design achieves improved energy efficiency.

An energy-efficient capacitance-to-digital converter (CDC) is provided that utilizes a capacitance-domain successive approximation (SAR) technique. Unlike SAR analog-to-digital converters (ADCs), analysis shows that for SAR CDCs, the comparator offset voltage will result in signal-dependent and parasitic-dependent conversion errors, which necessitates an op-amp-based implementation. The inverter-based SAR CDC contemplated herein provides robust, energy-efficient, and fast operation. The inverter-based SAR CDC may include a hybrid coarse-fine programmable capacitor array. The design of example embodiments is insensitive to analog references, and thus achieves very low temperature sensitivity without the need for calibration. Moreover, this design achieves improved energy efficiency.

Systems and methods for an asynchronous successive approximation register analog-to-digital converter (SAR ADC) with word completion algorithm may include a SAR ADC comprising a plurality of switched capacitors, a comparator, a metastability detector including a timer having a tunable time interval, and a successive approximation register. The SAR ADC may sample input signals at inputs of the switched capacitors and compare signals at outputs of the switched capacitors. The SAR ADC may also determine, based on a value of a tunable time interval, whether to set a metastability flag for a first bit to be evaluated and update the value of the tunable time interval based on whether the metastability flag was set.

Systems and methods for an asynchronous successive approximation register analog-to-digital converter (SAR ADC) with word completion algorithm may include a SAR ADC comprising a plurality of switched capacitors, a comparator, a metastability detector including a timer having a tunable time interval, and a successive approximation register. The SAR ADC may sample input signals at inputs of the switched capacitors and compare signals at outputs of the switched capacitors. The SAR ADC may also determine, based on a value of a tunable time interval, whether to set a metastability flag for a first bit to be evaluated and update the value of the tunable time interval based on whether the metastability flag was set.

A slope analog-to-digital converter, ADC, for converting an analog input signal to a digital representation, said slope ADC comprising: a comparator configured to compare two input signals, wherein a sampled value of the analog input signal and a slope signal are used in forming the two input signals; a memory element, which is configured to receive a trigger signal based on the comparator identifying a change in which of the two input signals is higher, and a counter signal, wherein a value of the counter signal when the trigger signal is received provides the digital representation of the sampled value of the analog input signal; wherein the slope signal and the counter signal have a nonlinear relationship, wherein the nonlinear relationship is adapted to improve linearity of a transfer function of the slope ADC for converting the analog input signal to the digital representation.

A slope analog-to-digital converter, ADC, for converting an analog input signal to a digital representation, said slope ADC comprising: a comparator configured to compare two input signals, wherein a sampled value of the analog input signal and a slope signal are used in forming the two input signals; a memory element, which is configured to receive a trigger signal based on the comparator identifying a change in which of the two input signals is higher, and a counter signal, wherein a value of the counter signal when the trigger signal is received provides the digital representation of the sampled value of the analog input signal; wherein the slope signal and the counter signal have a nonlinear relationship, wherein the nonlinear relationship is adapted to improve linearity of a transfer function of the slope ADC for converting the analog input signal to the digital representation.