Abstract: A digital-to-analog converter (DAC) may include a conversion block providing a first analog value. The DAC may also include an amplification block for receiving the first analog value and providing a second analog value amplified by an amplification factor. The amplification block may include a first input terminal for receiving the first analog value, a second input terminal, and an output terminal for providing the second analog value. The amplification block may also include a first capacitive element and a second capacitive element. The first and second capacitive elements may determine the amplification factor. The amplification block may further include a control unit for recovering a charge at a first terminal of the second capacitive element, and based thereon, the second analog value.

Abstract: A sense structure may include sense amplifiers each having measuring and reference terminals for receiving a measuring and a reference current, respectively, output circuitry for providing an output voltage based upon the measuring and reference currents, and voltage regulating circuitry in cascode configuration for regulating a voltage at the measuring and reference terminals. The regulating circuitry may include measuring and regulating transistors and a reference regulating transistor having a first conduction terminal coupled with the measuring terminal and with the reference terminal, respectively, a second conduction terminal coupled with the output circuitry and a control terminal coupled with a biasing terminal. Biasing circuitry is for providing a biasing voltage to the biasing terminal, and common regulating circuitry is for regulating the biasing voltage. Each sense amplifier may also include local regulating circuitry for regulating the biasing voltage applied to the biasing terminal.

Abstract: An input signal is amplified into an output signal that is to be applied to an electrical load including a capacitive component. An amplifier stage includes a pre-amplifier module to receive a first supply voltage, and an output module to receive a second supply voltage. The pre-amplifier module includes a first gain block to pre-amplify the input signal into a first pre-amplified signal, and a second gain block to pre-amplify the input signal into a second pre-amplified signal. A feedback block feeds back the output signal as a feedback signal. A combination element combines the first pre-amplified signal and the feedback signal into a combined signal. The output module combines the combined signal and the second pre-amplified signal into the output signal.

Abstract: A digital-to-analog converter (DAC) may include a conversion block providing a first analog value. The DAC may also include an amplification block for receiving the first analog value and providing a second analog value amplified by an amplification factor. The amplification block may include a first input terminal for receiving the first analog value, a second input terminal, and an output terminal for providing the second analog value. The amplification block may also include a first capacitive element and a second capacitive element. The first and second capacitive elements may determine the amplification factor. The amplification block may further include a control unit for recovering a charge at a first terminal of the second capacitive element, and based thereon, the second analog value.

Abstract: A phase change non-volatile memory device has a memory array with a plurality of memory cells arranged in rows and columns, a column decoder and a row decoder designed to select columns, and, respectively, rows of the memory array during operations of programming of corresponding memory cells. A control logic, coupled to the column decoder and the row decoder, is designed to execute a sequential programming command, to control the column decoder and row decoder to select one column of the memory array and execute sequential programming operations on a desired block of memory cells belonging to contiguous selected rows of the selected column.

Abstract: A memory device may include memory cells. The method may include receiving a request of reading a selected data word associated with a selected code word stored with an error correction code, and reading a first code word representing a first version of the selected code word by comparing a state of each selected memory cell with a first reference. The method may include verifying the first code word, setting the selected code word according to the first code word in response to a positive verification, reading at least one second code word representing a second version of the selected code word, verifying the second code word, and setting the selected code word according to the second code word in response to a negative verification of the first code word and to a positive verification of the second code word.

Abstract: An electronic switch may include transfer transistor having a first conduction terminal for receiving an input signal, a second conduction terminal, and a control terminal. The transfer transistor may enable/disable a transfer of the input signal from the first conduction terminal to the second conduction terminal according to a control signal. The control signal may take a first value and a second value different from the first value, a difference between the first value and the second value defining, in absolute value, an operative value of the control signal. The electronic switch may further comprise a driving circuit for receiving the input signal and the control signal, and for providing a driving signal equal to the sum between the input signal and the operative value of the control signal to the control terminal of the transfer transistor.

Abstract: A voltage converter device includes a voltage regulator having a supply terminal for receiving a supply voltage and an output terminal for providing a regulated voltage. A voltage multiplier is for receiving the regulated voltage and providing a boosted voltage higher in absolute value than the regulated voltage. The voltage multiplier includes circuitry for providing a clock signal that switches periodically between the regulated voltage and a reference voltage, and a sequence of capacitive stages that alternately accumulate and transfer electric charge according to the clock signal for generating the boosted voltage from the regulated voltage. The voltage regulator includes a power transistor and a regulation transistor each having a first conduction terminal, a second conduction terminal and a control terminal.

Abstract: A decoding system for a phase change non-volatile memory device having a memory array may include a column decoder that selects at least one column of the memory array during programming operations. The decoding system includes a selection circuit that includes selection switches on a number of hierarchical decoding levels for defining a conductive path between at least one column and a driving stage. A biasing circuit may supply biasing signals to the selection switches for defining the first conductive path and bringing the selected column to a programming voltage value. The programming selection circuit may have protection elements between columns and the selection switches. The selection switches and the protection elements may include metal oxide semiconductor (MOS) transistors having an upper threshold voltage level lower than the programming voltage.

Abstract: A voltage regulator has an input terminal for receiving a supply voltage and an output terminal for providing a regulated voltage and a regulated current. Furthermore, the voltage regulator includes a regulator for generating the regulated voltage and the regulated current according to a regulation of the supply voltage. The regulator includes a plurality of regulation branches arranged between the input terminal and the output terminal, each one for providing an output voltage used for obtaining the regulated voltage and for providing an output current contributing to define the regulated current. The regulation branches are partitioned into a plurality of subsets each one including components adapted to operate within a corresponding maximum voltage different from the maximum voltage of the other subsets. In addition, the regulator includes a selector for selectively enabling the regulation branches according to an indicator of the supply voltage.

Abstract: A driving stage for a phase change non-volatile memory device may include an output driving unit, which supplies an output driving current during programming of a memory cell, a driving-control unit, which receives an input current and generates a first control signal for controlling supply of the output driving current in such a way that a value thereof has a desired relation with the input current, and a level-shifter element, which carries out a level shift of a voltage of the first control signal for supplying to the output driving unit a second control signal, having a voltage value that is increased with respect to, and is a function of, the first control signal. A calibration unit may carry out an operation of updating of the value of a shift voltage across the level-shifter element, as the value of the input current varies.

Abstract: A voltage regulator may include an input terminal for receiving an input voltage and an output terminal for providing a respective output voltage, a regulation transistor having a first conduction terminal coupled to the input terminal for receiving the input voltage, a second conduction terminal coupled to the output terminal, and a control terminal coupled to the output of a first operational amplifier. The first operational amplifier may have a non-inverting input terminal for receiving a first reference voltage, and an inverting input terminal coupled to a first terminal of a divider circuit for receiving a second reference voltage.

Abstract: A bandgap voltage reference circuit for generating a bandgap voltage reference. An embodiment comprises a current generator controlled by a first driving voltage for generating a first current depending on the driving voltage, and a first reference circuit element coupled to the controlled current generator for receiving the first current and generating a first reference voltage in response to the first current. The circuit further comprises a second reference circuit element for receiving a second current corresponding to the first current; said second reference circuit element is adapted to generate a second reference voltage in response to the second current. The circuit further comprises an operational amplifier having a first input coupled to the first circuit element and a second input coupled to the second reference circuit element. The circuit also comprises a control circuit comprising first capacitive element and second capacitive element.

Abstract: An electronic device including a set of functional block, and a biasing block for generating a set of bias voltages for the functional blocks. The electronic device further includes a holding block coupled between the biasing block and the functional blocks for providing each bias voltage to at least one corresponding functional block, for each bias voltage the holding block including a capacitive element for storing the bias voltage, and a switch element switchable between an accumulation condition wherein provides the bias voltage from the biasing block to the capacitive element and to the at least one corresponding functional block, and a release condition wherein isolates the capacitive element from the biasing block and provides the bias voltage from the capacitive element to the at least one corresponding functional block, and a control block for alternately switching the switching elements between the accumulation condition and the release condition.

Abstract: A biasing circuit may include an input configured to receive a supply voltage, a value of which is higher than a limit voltage. The biasing circuit may also include a control stage configured to generate first and second control signals with mutually complementary values, equal alternatively to a first value, in a first half-period of a clock signal, or to a second value, in a second half-period of the clock signal. The first and second values may be a function of the supply and limit voltages. The biasing circuit may also include a biasing stage configured to generate a biasing voltage as a function of the values of the first and second control signals. The first and second control signals may control transfer transistors for transferring the supply voltage to respective outputs, while the biasing voltage may be for controlling protection transistors to reduce overvoltages on the transfer transistors.

Abstract: A level-shifter circuit may include a pair of inputs which receive a first and a second low-voltage phase signal having a first voltage dynamic with a first maximum value. The level-shifter circuit may also include a pair of outputs which supply a first high-voltage phase signal and a second high-voltage phase signal, level-shifted with respect to the low-voltage signals and having a second voltage dynamic with a second maximum value, higher than the first maximum value. The level-shifter circuit may further include transfer transistors coupled between one of a first reference terminal and a second reference terminal, which are set at one of a first reference voltage and a second reference voltage, and the first output or second output. Protection elements may be coupled to a respective transfer transistor to protect from overvoltages between at least one of the corresponding conduction terminals and control terminals.

Abstract: The charge pump circuit has a plurality of cascaded charge pump stages, each provided with a first pump capacitor connected to a first internal node and receiving a first high voltage phase signal, and a second pump capacitor connected to a second internal node and receiving a second high voltage phase signal, complementary with respect to the first. A first transfer transistor is coupled between the first internal node and an intermediate node, and a second transfer transistor is coupled between the second internal node and the intermediate node. The first and second high voltage phase signals have a voltage dynamics higher than a maximum voltage sustainable by the first and second transfer transistors. A protection stage is set between the first internal node and second internal node and respectively, the first transfer transistor and second transfer transistor, for protecting the same transfer transistors from overvoltages.

Abstract: A decoding system for a phase change non-volatile memory device having a memory array may include a column decoder that selects at least one column of the memory array during programming operations. The decoding system includes a selection circuit that includes selection switches on a number of hierarchical decoding levels for defining a conductive path between at least one column and a driving stage. A biasing circuit may supply biasing signals to the selection switches for defining the first conductive path and bringing the selected column to a programming voltage value. The programming selection circuit may have protection elements between columns and the selection switches. The selection switches and the protection elements may include metal oxide semiconductor (MOS) transistors having an upper threshold voltage level lower than the programming voltage.

Abstract: A driving stage for a phase change non-volatile memory device may include an output driving unit, which supplies an output driving current during programming of a memory cell, a driving-control unit, which receives an input current and generates a first control signal for controlling supply of the output driving current in such a way that a value thereof has a desired relation with the input current, and a level-shifter element, which carries out a level shift of a voltage of the first control signal for supplying to the output driving unit a second control signal, having a voltage value that is increased with respect to, and is a function of, the first control signal. A calibration unit may carry out an operation of updating of the value of a shift voltage across the level-shifter element, as the value of the input current varies.

Abstract: A driving stage for a phase change non-volatile memory device may have an output driving unit which supplies an output driving current during an operation of programming of at least one memory cell. A driving-control unit receives an input current and generates at output a first control signal that controls supply of the output driving current by the output driving unit in such a way that a value of this current has a desired relation with the input current. A level-shifter element, set between the output of the driving-control unit and a control input of the output driving unit, determines a level shift of the voltage of the first control signal so as to supply to the control input of the output driving unit a second control signal, having a voltage value that is increased with respect to, and is a function of, the first control signal.