A resonator device includes first and second resonators and an integrated circuit device. The integrated circuit device includes a first oscillation circuit configured to oscillate the first resonator, a second oscillation circuit configured to oscillate the second resonator, and a processing circuit configured to perform processing by using frequency difference information or frequency comparison information between a first clock signal generated by oscillating the first resonator and a second clock signal generated by oscillating the second resonator. The first resonator is supported on the integrated circuit device by a first support portion. The second resonator is supported on the integrated circuit device by a second support portion.

Provided is an AD converter that is capable of converting a wideband noise signal of several GHz or more into a digital signal and that can be used even when an installation space and power supply are severely limited. The AD converter includes: a comparator (10) configured to compare an input voltage of an analog signal to a determination voltage; an adjustment unit (12) configured to shift at least one of the input voltage of the analog signal or the determination voltage; an encoder (11) configured to output time-series data of one bit based on a result of the comparison obtained by the comparator; a processing unit (13) configured to calculate a frequency of appearance of an output code included in the time-series data; and a control unit (14) configured to cause the adjustment unit to operate so that a result of the calculation obtained by the processing unit becomes a predetermined value.

Aspects of a method and system for a successive approximation analog-to-digital converter with dynamic search algorithms are provided. In some embodiments, a successive approximation analog-to-digital converter includes a digital-to-analog converter, a comparator, and a search and decode logice modules which cooperate to generate a digital output code representative of the analog input voltage based on a dynamic search algorithm. The dynamic search algorithms may alter a sequence of reference voltages used to successively approximate the analog input voltage based on one or more characteristics of the analog input voltage.

Aspects of a method and system for a successive approximation analog-to-digital converter with dynamic search algorithms are provided. In some embodiments, a successive approximation analog-to-digital converter includes a digital-to-analog converter, a comparator, and a search and decode logice modules which cooperate to generate a digital output code representative of the analog input voltage based on a dynamic search algorithm. The dynamic search algorithms may alter a sequence of reference voltages used to successively approximate the analog input voltage based on one or more characteristics of the analog input voltage.

Systems, methods, and circuitries for converting an analog voltage to a digital signal are provided. In one example a method to convert an analog voltage into a binary sequence that represents the voltage includes two modes. In the first mode, in each cycle, values for a next two or more of consecutive most significant bits (MSBs) in the sequence are determined using M comparators, wherein M is equal to or greater than 3. In a second mode, in each cycle, M redundant comparison results are determined using the M comparators. A value for the LSB is determined based on the M redundant values. At an end of conversion, the sequence of N bit values is generated based on the MSBs and the LSB.

Some embodiments include apparatuses and methods using capacitor circuitry to sample a value of an input signal; comparators to compare the value of the input signal with a range of voltage values and provide comparison results; successive approximation register (SAR) logic circuitry to generate first bits and second bits based on the comparison results; and circuitry to calculate an average value of a value of the second bits and a value of bits of a portion of the first bits, and to generate output bits representing the value of the input signal, the output bits including bits generated based on the average value.

Aspects of a method and system for a successive approximation analog-to-digital converter with dynamic search algorithms are provided. In some embodiments, a successive approximation analog-to-digital converter includes a digital-to-analog converter, a comparator, and a search and decode logic modules which cooperate to generate a digital output code representative of the analog input voltage based on a dynamic search algorithm. The dynamic search algorithms may alter a sequence of reference voltages used to successively approximate the analog input voltage based on one or more characteristics of the analog input voltage.

Aspects of a method and system for a successive approximation analog-to-digital converter with dynamic search algorithms are provided. In some embodiments, a successive approximation analog-to-digital converter includes a digital-to-analog converter, a comparator, and a search and decode logic modules which cooperate to generate a digital output code representative of the analog input voltage based on a dynamic search algorithm. The dynamic search algorithms may alter a sequence of reference voltages used to successively approximate the analog input voltage based on one or more characteristics of the analog input voltage.

Some embodiments include apparatuses and methods using capacitor circuitry to sample a value of an input signal; comparators to compare the value of the input signal with a range of voltage values and provide comparison results; successive approximation register (SAR) logic circuitry to generate first bits and second bits based on the comparison results; and circuitry to calculate an average value of a value of the second bits and a value of bits of a portion of the first bits, and to generate output bits representing the value of the input signal, the output bits including bits generated based on the average value.

A method and apparatus for determining a difference between signal edges in two signals includes a multiple stage converter where each stage determines which of the two signals has an earlier signal edge, outputs a value corresponding to that determination, and then applies a delay to the earlier signal that is equal to half of the delay applied by the next previous stage. The stages examine smaller and smaller intervals to the sought-after signal edge. Each stage includes a plurality of logic elements. If all logic elements in the stage output the same signal, the edge position is clear. If some of the logic elements in the stage vote differently than others in the state due to differences in setup time for the different elements, the edge location has been found within the sensing band of the stage.