Abstract: A method for increasing performance of a voltage-buck switched-mode voltage regulator includes generating a first pulse-width modulation signal based on a clock signal, decreasing a frequency of the clock signal to form a modified clock signal, passing the modified clock signal to a digital modulation circuit as a regulated clock signal; and generating a second pulse-width modulation signal based on the regulated clock signal using the digital modulation circuit. The first pulse-width modulation signal includes a period T1 and an off duration D2 corresponding to a first duty cycle. The off duration D2 is an intrinsic pulse-width modulation signal generation latency. The second pulse-width modulation signal includes a period T2 and the off duration D2. The decreased frequency of the modified clock signal causes T2 to be greater than T1 such that a second duty cycle of the second pulse-width modulation signal is increased relative to the first duty cycle.

Abstract: In an embodiment, A device includes an operational amplifier and a feedback loop. The feedback loop is coupled between a first input of the operational amplifier and an output of the operational amplifier. The feedback loop is controllable according to a saturation of the operational amplifier. In one example, the device is incorporated in a microcontroller.

Abstract: A method for increasing performance of a voltage-buck switched-mode voltage regulator includes generating a first pulse-width modulation signal based on a clock signal, decreasing a frequency of the clock signal to form a modified clock signal, passing the modified clock signal to a digital modulation circuit as a regulated clock signal; and generating a second pulse-width modulation signal based on the regulated clock signal using the digital modulation circuit. The first pulse-width modulation signal includes a period T1 and an off duration D2 corresponding to a first duty cycle. The off duration D2 is an intrinsic pulse-width modulation signal generation latency. The second pulse-width modulation signal includes a period T2 and the off duration D2. The decreased frequency of the modified clock signal causes T2 to be greater than T1 such that a second duty cycle of the second pulse-width modulation signal is increased relative to the first duty cycle.

Abstract: A method can be used for regulating a pulse-width modulation signal that is driving a voltage-buck switched-mode voltage regulator. The method includes comparing an input voltage of the switched-mode voltage regulator with a threshold voltage. The frequency of the pulse-width modulation signal is decreased when the input voltage is lower than the threshold voltage. The frequency is not decreased when the input voltage is not lower than the threshold voltage.

Abstract: A method includes switching a switching circuit of the switched-mode power supply in a synchronous mode by turning on and off switches of the switching circuit in synchrony with a clock signal, wherein the switching circuit is coupled to an inductive element, and wherein the synchronous mode comprises a charging phase and a discharging phase; switching the switching circuit in an asynchronous mode by turning on and off switches of the switching circuit without being synchronized with the clock signal, wherein the asynchronous mode comprises a charging phase and a discharging phase; charging the inductive element during the charging phase of the synchronous mode; discharging the inductive element during the discharging phase of the synchronous mode; charging the inductive element during the charging phase of the asynchronous mode; and discharging the inductive element during the discharging phase of the asynchronous mode.

Abstract: A method includes switching a switching circuit of the switched-mode power supply in a synchronous mode by turning on and off switches of the switching circuit in synchrony with a clock signal, wherein the switching circuit is coupled to an inductive element, and wherein the synchronous mode comprises a charging phase and a discharging phase; switching the switching circuit in an asynchronous mode by turning on and off switches of the switching circuit without being synchronized with the clock signal, wherein the asynchronous mode comprises a charging phase and a discharging phase; charging the inductive element during the charging phase of the synchronous mode; discharging the inductive element during the discharging phase of the synchronous mode; charging the inductive element during the charging phase of the asynchronous mode; and discharging the inductive element during the discharging phase of the asynchronous mode.

Abstract: A method includes switching a switching circuit of the switched-mode power supply in a synchronous mode by turning on and off switches of the switching circuit in synchrony with a clock signal, wherein the switching circuit is coupled to an inductive element, and wherein the synchronous mode comprises a charging phase and a discharging phase; switching the switching circuit in an asynchronous mode by turning on and off switches of the switching circuit without being synchronized with the clock signal, wherein the asynchronous mode comprises a charging phase and a discharging phase; charging the inductive element during the charging phase of the synchronous mode; discharging the inductive element during the discharging phase of the synchronous mode; charging the inductive element during the charging phase of the asynchronous mode; and discharging the inductive element during the discharging phase of the asynchronous mode.

Abstract: In an embodiment, A device includes an operational amplifier and a feedback loop. The feedback loop is coupled between a first input of the operational amplifier and an output of the operational amplifier. The feedback loop is controllable according to a saturation of the operational amplifier. In one example, the device is incorporated in a microcontroller.

Abstract: A method can be used for regulating a pulse-width modulation signal that is driving a voltage-buck switched-mode voltage regulator. The method includes comparing an input voltage of the switched-mode voltage regulator with a threshold voltage. The frequency of the pulse-width modulation signal is decreased when the input voltage is lower than the threshold voltage. The frequency is not decreased when the input voltage is not lower than the threshold voltage.

Abstract: A method includes switching a switching circuit of the switched-mode power supply in a synchronous mode by turning on and off switches of the switching circuit in synchrony with a clock signal, wherein the switching circuit is coupled to an inductive element, and wherein the synchronous mode comprises a charging phase and a discharging phase; switching the switching circuit in an asynchronous mode by turning on and off switches of the switching circuit without being synchronized with the clock signal, wherein the asynchronous mode comprises a charging phase and a discharging phase; charging the inductive element during the charging phase of the synchronous mode; discharging the inductive element during the discharging phase of the synchronous mode; charging the inductive element during the charging phase of the asynchronous mode; and discharging the inductive element during the discharging phase of the asynchronous mode.

Abstract: There is disclosed a driver circuit for a power amplifier of class D type having a segmented architecture with at least one current branch which can be powered down in a low power mode of operation of the circuit. The branch comprising a switch with a cascode MOS transistor, the circuit further comprises a bias circuitry adapted for dynamically generating a dynamic bias control signal so as to cause the cascode MOS transistor of the switch to be ‘Off’ in the low power mode.

Abstract: An audio amplification circuit comprises an amplifier having an input and an output, as well as an audio output to which a load can be connected. It additionally comprises a first driver stage having an input and an output which is not coupled to the audio output, and a second driver stage having an input and an output which is coupled to the audio output. The output from the amplifier is selectively coupled to the input of the first driver stage in a first phase of operation and then selectively to the input of the second driver stage in a second phase of operation following the first phase of operation.

Abstract: An audio amplification circuit is provided having an amplifier that receives an input signal, an output, and a digital control input for receiving a control value in a number n of bits; a comparator having a first input that receives the amplifier's output signal image, a second input that receives a reference potential, and an output; and a thermometer counter having a selection input coupled to the comparator output, and an output delivering an n-bit digital value to the amplifier control input. The amplifier comprises a differential input stage having a first and a second differential branch, each traversed by a bias current, the current in the first branch being modifiable by n basic current sources which each deliver either a current identical for all current sources, or no current, as a function of one respective bit of the digital control value received at the control input.

Abstract: There is disclosed a driver circuit for a power amplifier of class D type having a segmented architecture with at least one current branch which can be powered down in a low power mode of operation of the circuit. The branch comprising a switch with a cascode MOS transistor, the circuit further comprises a bias circuitry adapted for dynamically generating a dynamic bias control signal so as to cause the cascode MOS transistor of the switch to be ‘Off’ in the low power mode.

Abstract: An audio amplification circuit is provided having an amplifier that receives an input signal, an output, and a digital control input for receiving a control value in a number n of bits; a comparator having a first input that receives the amplifier's output signal image, a second input that receives a reference potential, and an output; and a thermometer counter having a selection input coupled to the comparator output, and an output delivering an n-bit digital value to the amplifier control input. The amplifier comprises a differential input stage having a first and a second differential branch, each traversed by a bias current, the current in the first branch being modifiable by n basic current sources which each deliver either a current identical for all current sources, or no current, as a function of one respective bit of the digital control value received at the control input.

Abstract: An audio amplification circuit comprises an amplifier having an input and an output, as well as an audio output to which a load can be connected. It additionally comprises a first driver stage having an input and an output which is not coupled to the audio output, and a second driver stage having an input and an output which is coupled to the audio output. The output from the amplifier is selectively coupled to the input of the first driver stage in a first phase of operation and then selectively to the input of the second driver stage in a second phase of operation following the first phase of operation.