An analog-to-digital converter comprising a plurality of sampling cells. At least one of the plurality of sampling cells comprises a capacitive element coupled to a cell output of the at least one of the plurality of sampling cells, wherein a cell output signal is provided at the cell output. The at least one of the plurality of sampling cells further comprises a first cell input for receiving an input signal to be digitized, and a second cell input for receiving a calibration signal. Additionally, the at least one of the plurality of sampling cells comprises a first switch circuit capable of selectively coupling the first cell input to the capacitive element based on a clock signal, and a second switch circuit capable of selectively coupling the second cell input to the capacitive element, wherein a size of the second switch circuit is smaller than a size of the first switch circuit.

An analog-to-digital converter of one embodiment in the present disclosure may comprise a first conversion unit generating an internal clock signal, generating a first digital code and a residual signal by converting an input signal in a successive approximation register (SAR) method in response to the internal clock signal and generating a flash clock signal in response to an external clock signal, a second conversion unit generating a second digital code by converting the residual signal in a flash method in response to the flash clock signal, and an output circuit generating an output digital signal in response to the first digital code and the second digital code.

It is an object of the present technology to provide an image sensor capable of reducing crosstalk in an AD conversion unit. The image sensor includes: capacitors in an even-numbered column region; and a capacitor in an odd-numbered column region disposed facing the capacitors in the even-numbered column region with different areas.

An analog-to-digital converter includes a switch circuit, a first capacitor array, a second capacitor array and a comparator. A method of operating the analog-to-digital converter includes switching a swap signal to a first level in a first sampling period for the switch circuit to couple the first capacitor array to a first input terminal of the comparator and a first signal source, and couple the second capacitor array to a second input terminal of the comparator and a second signal source, and switching the swap signal to a second level in a second sampling period for the switch circuit to couple the first capacitor array to the second input terminal of the comparator and the second signal source, and couple the second capacitor array to the first input terminal of the comparator and the first signal source.

A method of operating an analog-to-digital converter includes in a first conversion period, a comparator generating a first comparison result, a first selection circuit switching a voltage output to a first capacitor of a set of larger capacitor of a first capacitor array, and a second selection circuit switching a voltage output to a second capacitor of a set of larger capacitor of a second capacitor array, and in a second conversion period after the first conversion period, the comparator generating a second comparison result different from the first comparison result, the first selection circuit switching back the voltage output to a first capacitor portion of the first capacitor of the set of larger capacitor of the first capacitor array, and the second selection circuit switching back the voltage output to a first capacitor portion of the second capacitor of the set of larger capacitor of the second capacitor array.

Numerous embodiments of analog neural memory arrays are disclosed. In one embodiment, an analog neural memory system comprises an array of non-volatile memory cells, wherein the cells are arranged in rows and columns, the columns arranged in physically adjacent pairs of columns, wherein within each adjacent pair one column in the adjacent pair comprises cells storing W+ values and one column in the adjacent pair comprises cells storing W− values, wherein adjacent cells in the adjacent pair store a differential weight, W, according to the formula W=(W+)−(W−). In another embodiment, an analog neural memory system comprises a first array of non-volatile memory cells storing W+ values and a second array storing W− values.

A dual-loop analog to digital converter (ADC) includes an asynchronous inner loop including first and second comparators and a state machine, where outputs of the first and second comparators are coupled to inputs of the state machine, and where outputs of the state machine are cross-coupled to enable ports of the first and second comparators. The ADC includes a synchronous outer loop including a successive approximation register (SAR), a digital to analog converter (DAC), and the first and second comparators, where the outputs of the first and second comparators are coupled to inputs of the SAR, an N-bit output of the SAR is coupled to an N-bit input of the DAC, and a differential output of the DAC is coupled to inputs of the first and second comparators, where a state of the state machine is independent of the state of the SAR.

Herein disclosed is an example analog-to-digital converter (ADC) and methods that may be performed by the ADC. The ADC may derive a first code that approximates a combination of an analog input value of the ADC and a dither value for the ADC sampled on a capacitor array. The ADC may further derive a second code to represent a residue of the combination with respect to the first code applied to the capacitor array. The ADC may combine the numerical value of the first code and the numerical value of the second code to produce a combined code applied to the capacitor array for deriving a digital output code. Combining the numerical value of the first code and the numerical value of the second code in the digital domain can provide for greater analog-to-digital (A/D) conversion linearity.

A method of operating an analog-to-digital converter includes in a first sampling stage, switching a swap signal to a first level for a first selection circuit to reset a first capacitor array according to a first voltage configuration and for a second selection circuit to reset a second capacitor array according to the first voltage configuration, and in a second sampling stage, switching the swap signal to a second level for the first selection circuit to reset the first capacitor array according to the second voltage configuration and for the second selection circuit to reset the second capacitor array according to the second voltage configuration. A control logic circuit is used to switch the swap signal between the first level and the second level in a uniform order in a plurality of sampling stages.

An analog-to-digital converter is provided. An analog-to-digital converter includes a comparator including a first input node receiving an output of a plurality of first unit capacitors and a second input node receiving an output of a plurality of second unit capacitors, a control logic configured to output first and second control signals on the basis of an output signal of the comparator, and a reference voltage adjustment circuit configured to adjust an output voltage provided to the comparator on the basis of the first and second control signals. The reference voltage adjustment circuit comprises a first pull-up circuit configured to apply a first reference voltage to each of the plurality of first unit capacitors and a first pull-down circuit configured to apply a second reference voltage to each of the plurality of second unit capacitors, based on v.