Aspect of the present disclosure provide for a circuit. In an example, the circuit comprises a multiplexer having a first input, a second input, a control input, and an output. The circuit further comprises a first register having an input coupled to the output of the multiplexer and an output. The circuit further comprises a second register having an input coupled to the output of the first register and an output. The circuit further comprises a subtractor having a first input coupled to the output of the multiplexer and a second input coupled to the output of the second register. The circuit further comprises a third register having an input coupled to the output of the subtractor and an output coupled to the first input of the multiplexer.

Aspect of the present disclosure provide for a circuit. In an example, the circuit comprises a multiplexer having a first input, a second input, a control input, and an output. The circuit further comprises a first register having an input coupled to the output of the multiplexer and an output. The circuit further comprises a second register having an input coupled to the output of the first register and an output. The circuit further comprises a subtractor having a first input coupled to the output of the multiplexer and a second input coupled to the output of the second register. The circuit further comprises a third register having an input coupled to the output of the subtractor and an output coupled to the first input of the multiplexer.

Configuration information is generated for a configurable mixed-signal system. Analog requirements for operating the configurable mixed-signal system are gathered. A simulation model of a delta-sigma modulator is received. A simulation based on the simulation model of the delta-sigma modulator is performed to obtain parameter settings for the delta-sigma modulator. The obtained parameter settings are used to build at least a portion of a description of the configurable mixed-signal system. The description of the configurable mixed signal system is synchronized to receive configuration information.

Embodiments of multi-mode sigma-delta analog-to-digital converter (ADC) circuits and a microphone circuit are disclosed. In an embodiment, a multi-mode sigma-delta ADC circuit includes a pair of operational transconductance amplifiers (OTAs), a filter connected to the pair of OTAs, a quantizer connected to the filter, a differential digital-to-analog converter (DAC) connected to the quantizer, and a controller configured to switch the multi-mode sigma-delta ADC circuit between a single-ended operational mode, a pseudo differential operational mode, and a full differential operational mode to improve common mode rejection (CMR) performance by controlling the pair of OTAs. An output of a microphone and a differential output of the differential DAC are inputted into input terminals of the pair of OTAs.

A system may include an output stage for driving a load at an output of the output stage, a pulse-width modulation mode path configured to pre-drive the output stage in a first mode of operation, a linear mode path configured to pre-drive the output stage in a second mode of operation and a loop filter coupled at its input to the output of the output stage and coupled at its output to both of the pulse-width modulation mode path and the linear mode path. The pulse-width modulation mode path and the linear mode path may be configured such that a first transfer function between the output of the loop filter and the output of the output stage is substantially equivalent to a second transfer function between the output of the loop filter and the output of the output stage

A communication unit (300, 400, 500) is described that includes at least one antenna (302, 402, 502); a plurality of radio frequency (RF) circuits (304, 310, 404, 410) respectively coupled to at least one antenna (302, 402, 502); at least one sigma-delta modulator (316, 416, 616, 816) comprising a number of stages, each stage comprising at least one signal-feedforward coefficient (603, 604, 605), a filter and a feedback gain element, the at least one sigma-delta modulator (316, 416, 616, 816) coupled to the plurality of RF circuits (304, 310, 404, 410) and configured to perform sigma-delta modulation; and a controller (340, 440, 640, 840) operably coupled to the at least one sigma-delta modulator (316, 416, 616, 816). The at least one sigma-delta modulator (316, 416, 616, 816) comprises an input (315, 415, 602, 801, 802, 902) configured to receive multiple multi-phase input signals and the controller (340, 440, 640, 840) is configured to adjust the at least one signal-feedforward coefficient (603, 604, 605) of the at least one sigma-delta modulator (316, 416, 616, 816) when combining the multiple multi-phase input signals.

Disclosed herein are multi-mode methods and devices for sample generation. An exemplary device for generating an output sample includes an analog-to-digital converter (ADC) for sampling a plurality of input analog signals and producing an ADC output sample. The ADC may include a ADC digital modulator including timing-critical components. A plurality of digital blocks may be coupled to the ADC digital modulator. The exemplary device may include a baseband processor for controlling a plurality of clock inputs. The plurality of clock inputs may drive the ADC digital modulator and the plurality of digital blocks. The baseband processor may be configured to operate in a plurality of modes including a first mode and a second mode. The first mode may include a first mode standby state and a first mode initial operating state. The second mode may include a second mode initial operating state and a second mode standby state.

Techniques for a configurable analog-to-digital converter filter to ameliorate transfer function peaking or frequency response issues are provided. In an example, a front-end circuit of a processing circuit can include a resistor-capacitor filter including at least two capacitors and a switch circuit. The resistor-capacitor filter can couple an input analog signal to the processing circuit. The switch circuit can couple to a first capacitor of the at least two capacitors, and can selectively place a terminal of the first capacitor at a selected one of a plurality of distinct nodes of the resistor-capacitor filter to configure the circuit to address the peaking or frequency response issue.

A X-bit Digital-to-Analog Converter (DAC) circuit includes an effective X/2-bit coarse DAC configured to produce a coarse bitstream (CBS) from a digital input DC.sub.1 using an n.sup.th order Sigma-Delta () modulator, and to provide a coarse current source based on the CBS, wherein X is an even integer and n is an integer; an effective X/2-bit fine DAC configured to produce a fine bitstream (FBS) from a digital input DC.sub.2 using a 1.sup.st order modulator, and to provide a fine current source based on the FBS; and an output configured to form a voltage from the combination of the coarse current source and the fine current source.

The present disclosure a switched-mode power supply using a reconfigurable delta-signal modulator (DSM). The switched-mode power supply comprises, a current sensing unit configured to determine an operation mode on the basis of a result of sensing a current of an output terminal; a compensator configured to output a compensation signal by amplifying a difference value between an output voltage and a reference voltage; a reconfigurable DSM configured to output a digital signal by noise-shaping the compensation signal; a power switch unit switched by the digital signal to output an output voltage; and an attenuator configured to supply a feedback voltage of the output voltage attenuated by a voltage divider to the compensator.