A subsystem configured to implement an analog to digital converter that includes a high speed comparator with an embedded reference voltage level that functions as a calibrated threshold. A calibration element applies power to a reference voltage system. The calibration element then selects a differential analog voltage and applies the differential analog voltage to the inputs of the comparator. A digitally coded signal then configures an array of switches that connect complements of integrated resistors to each input of the comparator so that the switching point of the comparator occurs coincident with the applied differential analog reference voltage, nulling out the effect of the applied differential analog voltage and comparator errors. The calibration element then removes power from the reference voltage system. As a result, the comparator is configured with an embedded threshold that equals the differential analog reference voltage.

A digital to analog conversion, DAC, device for converting digital signals to analog signals comprises a RF output for outputting the analog signals, a thermometer segment comprising a first number of data slices and a second number calibration slices, and a calibration controller, which electrically disconnects one of the data slices from the RF output and at the same time connects one of the calibration slices to the RF output as replacement slice for the respective data slice and performs a calibration of the disconnected data slice.

An analog-to-digital converter, configured to convert an input signal into an n bits digital output signal, includes a capacitor module, a control signal generation unit, a comparator, and a register. The capacitor module is configured to receive the input signal at a sampling phase in a normal mode, and to generate a first sampling signal and a second sampling signal according to the input signal in a conversion phase. The control signal generation unit is configured to adjust the first sampling signal or the second sampling signal in the conversion phase. In the normal mode, the comparator is configured to compare the first sampling signal and the second sampling signal in the conversion phase to generate n comparison signals. The register is configured to store the n comparison signals as the digital output signal, and output the digital output signal in the normal mode.

The present invention pertains to a high-speed successive approximation analog-to-digital converter of two bits per circle, includes three switches, two capacitor arrays, three comparators, an encoding circuit, a first switch array corresponding to the first capacitor array, a second switch array corresponding to the second capacitor array, a shifting register and a digital correction unit. The analog-to-digital converter, featuring doubled speed, realizes a successive approximation process without any fault when a high-bit large capacitor is unsettled. Thus no redundancy bit capacitor is required to compensate for unsettled pre-stage large capacitor. By using the encoding circuit, a thermometer code is converted into a binary code effectively, and inherent errors of comparators are reduced by the randomization of three comparators.

A comparator configured to calibrate an offset according to a control signal, including an input circuit configured to receive a first input signal and a second input signal, and to generate a first internal signal corresponding to the first input signal and a second internal signal corresponding to the second input signal; a differential amplification circuit configured to consume a supply current flowing from a positive voltage node having a positive supply voltage to a negative voltage node having a negative supply voltage, and to generate an output signal by amplifying a difference between the first internal signal and the second internal signal; and a current valve configured to adjust at least a portion of the supply current based on the control signal.

A method for removing low frequency offset components from a digital data stream includes receiving, at an input of an analog-to-digital converter (ADC), an analog input signal from one or more analog front end components. The analog input signal has an associated low frequency offset due, at least in part, to the analog front end components. The method also includes generating, at an output of the ADC, a digital data stream representative of the analog input signal. The digital data stream having an associated low frequency offset due, at least in part, to the analog front end components and the ADC. One or more low pass finite impulse response (FIR) filters are applied to the digital data stream to detect the low frequency offset components in the digital data stream, and generate a filtered output signal with only the low frequency offset components present. A corrected digital data stream without the low frequency offset components is generated in response thereto, for example, by taking the difference of the filtered output signal from the digital data stream.

A receiver having an analog to digital converter with adjustable reference voltages that are calibrated to account for process variations. The receiver comprises an analog to digital converter. The analog to digital converter includes a reference generator to generate a set of N reference voltages. The reference generator adjusts voltage levels of the set of N reference voltages based on one or more control signals. A plurality of comparators compare an input signal to the set of N reference voltages. A calibration circuit generates the one or more control signals for adjusting the voltage levels of the N reference voltages based on outputs of the comparators.

Example embodiments relate to time-interleaved analog-to-digital converters and conversion methods thereof. One embodiment includes a slope analog-to-digital converter. The slope analog-to-digital converter includes a sample and hold stage configured to sample an analog input signal at a sampling frequency. The slope analog-to-digital converter also includes a comparator downstream to the sample and hold stage configured to compare the analog input signal to a slope signal. Further, the slope analog-to-digital converter includes a digital logic configured to receive a counter value corresponding to a voltage level of the slope signal and to sample the counter value based upon the comparison, thereby generating a digital representation of the analog input signal based upon the comparison. The slope signal is asynchronous to the sampling frequency.

A system and method for driving a solid-state image pickup device including a pixel array unit including unit pixels. Each unit pixel includes a photoelectric converter, column signal lines and a number of analog-digital converting units. The unit pixels are selectively controlled in units of rows. Analog signals output from the unit pixels in a row selected by the selective control though the column signal lines are converted to digital signals via the analog-digital converting units. The digital signals are added among a number of unit pixels via the analog-digital converting units. The added digital signals from the analog-digital converting units are read. Each unit pixel in the pixel array unit is selectively controlled in units of arbitrary rows, the analog-distal converting units being operable to performing the converting in a (a) normal-frame-rate mode and a (b) high-frame-rate mode in response to control signals.

A time-interleaved analog to digital converter (TI-ADC) includes a first sub-ADC configured to sample and convert an input analog signal to generate a first digital signal and a second sub-ADC configured to sample and convert said input analog signal to generate a second digital signal. Sampling by the second sub-ADC occurs with a time skew mismatch. A multiplexor interleaves the first and second digital signals to generate a third digital signal. A time skew mismatch error determination circuit processes the first and second digital signals to generate a time error corresponding to the time skew mismatch. A slope value of said third digital signal is determined and multiplied by the time error to generate a signal error. The signal error is summed with the third digital signal to generate a digital output signal which eliminates the error due to the time skew mismatch. This correction is performed in real time.