An analog-to-digital conversion apparatus is provided. The analog-to-digital conversion apparatus includes an integrated circuit (IC) configured to generate a first interrupt request; and an analog-to-digital converter included in an integrated circuit, wherein the analog-to-digital converter is configured to receive a plurality of analog values from a plurality of channels, and convert at least a portion of the received analog values that correspond to at least a portion of channels of the plurality of channels, that are selected based on the first interrupt request into at least a portion of digital values.

An ADC circuit (50) is disclosed. It comprises a global input configured to receive an input voltage (V.sub.in) and a plurality of converter circuits (105.sub.1-105.sub.N). Each converter circuit (105.sub.j) comprises a comparator circuit (70.sub.j) having a first input connected to the global input, a second input, and an output configured to output a one-bit output signal of the comparator circuit (70.sub.j). Furthermore, each converter circuit (105.sub.j) comprises a one-bit current-output DAC (110.sub.j) having an input directly controlled from the output of the comparator circuit (70.sub.j) and an output connected to the second input of the comparator circuit (70.sub.j). The second inputs of all comparator circuits are interconnected. The ADC circuit (50) further comprises a digital output circuit (130) configured to generate an output signal z[n] of the ADC circuit (50) in response to the one-bit output signals of the comparator circuits (70.sub.j).

A delta-sigma modulator may include a loop filter, a quantizer, an input gain element having a programmable input gain and coupled between an input of the delta-sigma modulator and an input of the loop filter, a feedforward gain element having a programmable feedforward gain and coupled between the input of the delta-sigma modulator and an output of the loop filter, and a quantizer gain element having a quantizer gain and coupled between the output of the loop filter and an input of the quantizer. The programmable input gain is controlled in order to control a variable gain of the delta-sigma modulator. The programmable feedforward gain is controlled to be equal to the ratio of the programmable input gain and the quantizer gain such that the delta-sigma modulator has a fixed phase response.

A method comprising activating an internal switch within a packaged electronic device to connect to a reference ground of an internal voltage source to a first input of an analog front end, receiving an external ground potential voltage at a first package pin of the packaged electronic device, generating a zero detector output signal for the packaged electronic device at a second package pin, activating the internal switch to connect the first input of the analog front end to the internal voltage source, receiving a second voltage level at the first package pin that generates a second output signal that matches the zero detector output signal, and receiving trim instructions to trim an internal voltage generated by the internal voltage source to a voltage level that is closer to a target voltage level.

The present description concerns a converter comprising: a circuit (C1) supplying a first pulse (P1) determined by an interval between an active edge of a first signal (S1) and an active edge of a second signal (S2); a circuit (INT) which, at each first pulse (P1), integrates the first pulse (P1), a second pulse (P2) starting after the first pulse (P1) in synchronism with a clock signal (clk), and a third pulse (P3) starting after the third pulse (P3) in synchronism with the clock signal (clk); a circuit (C3) sampling over one bit (OUT1) an output signal (RES1) of the integrator circuit (INT) at the beginning of each third pulse (P3); and two circuits (C2, C4) generating, for each first pulse (P1), respectively the corresponding second pulse and the third corresponding pulse based on the first bit (OUT1).

An oscillator provides a plurality of clock signals, including a first clock signal having a first frequency and a first period, wherein each clock signal has the first frequency and is phase shifted from the first clock signal by an integer times a predetermined fractional amount of the first period. A multiphase frequency divider receives the plurality of clock signals and provides a divided clock output, and includes an integer frequency divider which provides the divided clock output based on a modified clock input and a clock selector which provides a current clock as the modified clock input during a first portion of the divided clock output and a next clock as the modified clock input during a subsequent portion of the divided clock output. The next clock is selected from the plurality of clock signals based on a selected fractional phase shift amount indicated by a sigma-delta modulator.

An apparatus is provided which substantially removes a perturbation signal from a pulse density modulated signal representing a combination of a signal to be measured and a perturbation applied to the signal to be measured. The removal of the perturbation is done by subtracting a correcting signal from the pulse density modulated signal. This approach introduces very little delay as it can be implemented by simple logic gates. It also provided enhanced immunity from the effects of bit errors.

A power supply monitor includes a delta-sigma modulator including an input receiving a binary number and an output providing a pulse-density modulated signal, the delta-sigma modulator operable to scale the pulse-density modulated signal based on the binary number. A fast droop detector circuit includes a level shifter providing the modulated signal referenced to a clean supply voltage. A lowpass filter is coupled between the level shifter and a comparator. The comparator produces a droop detection signal at said output responsive to a monitored supply voltage dropping below a predetermined level relative to the filtered signal.

Described herein is an apparatus and method for enhancing the dynamic range of an analog-to-digital converter (ADC). In one embodiment of the present approach, an analog input signal is amplified in a programmable gain amplifier (PGA) before the ADC receives the signal, so that the gain applied to an input signal, and gain (or attenuation) later applied in order to balance the overall gain of the circuit, occurs only in either the analog domain; in the prior art, gain occurs partly in each domain. The ADC gain is then adjusted to compensate for gain of the PGA and balance the overall gain of the circuit. In another embodiment, the ADC gain is adjusted, and gain of a digital gain element that receives the signal from the ADC is adjusted to compensate for the ADC gain and balance the overall gain of the circuit, eliminating the need for a PGA.

A power supply monitor includes a delta-sigma modulator including an input receiving a binary number and an output providing a pulse-density modulated signal, the delta-sigma modulator operable to scale the pulse-density modulated signal based on the binary number. A fast droop detector circuit includes a level shifter providing the modulated signal referenced to a clean supply voltage. A lowpass filter is coupled between the level shifter and a comparator. The comparator produces a droop detection signal at said output responsive to a monitored supply voltage dropping below a predetermined level relative to the filtered signal.