A DAC, for use in an iADC, is configured for converting a multi-bit word to an analog feedback signal. The DAC comprises a MMS logic block. It further comprises a plurality of output elements configured to generate respective analog portions based on a selection vector and a signal combiner for combining the analog portions to the analog feedback signal. In the MMS logic block switching blocks are arranged cascaded. Each switching block receives at least a portion of the multi-bit word, splits the portion into two sub-portions and forwards them to one subsequent switching block or to one output element. A weight factor is adjusted by multiplying it with the difference of the two sub-portions. A weight accumulator accumulates successive adjusted weight factors, wherein the way of splitting the portion of a further multi-bit word is determined based on the sign of the weight accumulator.

A DAC, for use in an iADC, is configured for converting a multi-bit word to an analog feedback signal. The DAC comprises a MMS logic block. It further comprises a plurality of output elements configured to generate respective analog portions based on a selection vector and a signal combiner for combining the analog portions to the analog feedback signal. In the MMS logic block switching blocks are arranged cascaded. Each switching block receives at least a portion of the multi-bit word, splits the portion into two sub-portions and forwards them to one subsequent switching block or to one output element. A weight factor is adjusted by multiplying it with the difference of the two sub-portions. A weight accumulator accumulates successive adjusted weight factors, wherein the way of splitting the portion of a further multi-bit word is determined based on the sign of the weight accumulator.

An implantable pulse generator (IPG) is disclosed having an improved ability to steer anodic and cathodic currents between the IPG's electrodes. Each electrode node has at least one PDAC/NDAC pair to source/sink or sink/source a stimulation current to an associated electrode node. Each PDAC and NDAC receives a current with a magnitude indicative of a total anodic and cathodic current, and data indicative of a percentage of that total that each PDAC and NDAC will produce in the patient's tissue at any given time, which activates a number of branches in each PDAC or NDAC. Each PDAC and NDAC may also receive one or more resolution control signals specifying an increment by which the stimulation current may be adjusted at each electrode. The current received by each PDAC and NDAC is generated by a master DAC, and is preferably distributed to the PDACs and NDACs by distribution circuitry.

Methods, devices, and systems for processing information are disclosed. An example device may comprise a metastructure comprising a plurality of physical features configured to transform an analog signal according to a kernel of an integral equation. The device may comprise one or more waveguides coupled to the metastructure and configured to recursively supply a transformed analog output signal of the metastructure to an input of the metastructure to iteratively cause one or more transformed analog signals output from the metastructure to converge to an analog signal representing a solution to the integral equation.

Methods, devices, and systems for processing information are disclosed. An example device may comprise a metastructure comprising a plurality of physical features configured to transform an analog signal according to a kernel of an integral equation. The device may comprise one or more waveguides coupled to the metastructure and configured to recursively supply a transformed analog output signal of the metastructure to an input of the metastructure to iteratively cause one or more transformed analog signals output from the metastructure to converge to an analog signal representing a solution to the integral equation.

A kickback current is suppressed so as not to generate a deviation in a signal that outputs a comparison result.

A comparator includes a first input terminal and a second input terminal to which a first differential input signal pair is input, a third input terminal and a fourth input terminal to which a second differential input signal pair is input, a first comparison circuit that outputs a signal corresponding to a difference signal of the first differential input signal pair generated by connecting the first input terminal to a positive side and connecting the second input terminal to a negative side and a difference signal of the second differential input signal pair generated by connecting the third input terminal to a positive side and connecting the fourth input terminal to a negative side, and a second comparison circuit that outputs a signal corresponding to a difference signal of the first differential input signal pair generated by connecting the first input terminal to a negative side and connecting the second input terminal to a positive side, and a difference signal of the second differential input signal pair generated by connecting the third input terminal to a positive side and connecting the fourth input terminal to a negative side.

A kickback current is suppressed so as not to generate a deviation in a signal that outputs a comparison result.

A comparator includes a first input terminal and a second input terminal to which a first differential input signal pair is input, a third input terminal and a fourth input terminal to which a second differential input signal pair is input, a first comparison circuit that outputs a signal corresponding to a difference signal of the first differential input signal pair generated by connecting the first input terminal to a positive side and connecting the second input terminal to a negative side and a difference signal of the second differential input signal pair generated by connecting the third input terminal to a positive side and connecting the fourth input terminal to a negative side, and a second comparison circuit that outputs a signal corresponding to a difference signal of the first differential input signal pair generated by connecting the first input terminal to a negative side and connecting the second input terminal to a positive side, and a difference signal of the second differential input signal pair generated by connecting the third input terminal to a positive side and connecting the fourth input terminal to a negative side.

A system, method, and computer-readable medium are disclosed for performing a control transfer operation. The control transfer operation includes: using a Bluetooth compatible phase based ranging to detect proximity between a first device and a second device, the first device executing a first application, the first application having an associated first application context; detecting a change in proximity between the first device and the second device via the phase based ranging; providing a notification to a user on the second device when the change in proximity is detected, the notification querying the user regarding whether to transfer operation of the first application from the first device to the second device; and, automatically providing the first application context to the second device based upon the querying.

A phase rotator receives control signals and thermometer coded signals that specifies the phase of an output signal. The phase rotator may be used, for example, by a clock and data recovery (CDR) circuit to continually rotate the phase of a clock to compensate for phase/frequency mismatches between received data and the clock. The control signals determine the phase quadrant (i.e., 0°-90°, 90°-180°, etc.) of the output signal. The thermometer coded signals determine the phase of the output signal within a quadrant by steering a set of bias currents between two or more nodes. The set of bias currents are selected to reduce the non-linearity between the thermometer coded value and the phase of the output signal.

The disclosure belongs to the field of integrated circuits, and is used for reducing an area overhead and a power consumption of a pipelined analog-to-digital converter. Each stage of the pipelined analog-to-digital converter according to the disclosure comprises an analogue-to-digital converter, a digital-to-analog converter, a subtractor and an amplifier. According to the disclosure, an amplification time of the pipelined ADC is used for extra quantization, and a number of bits of each ADC is reduced on the premise of not increasing a number of stages of the pipelined ADC, so that a scale of each circuit is greatly reduced, and the power consumption and the area overhead are reduced.