Abstract: It is described a circuit generating a stable reference voltage with respect to temperature, which circuit is connected between first and second voltage references and comprises at least one current generating circuit adapted to inject a reference current into a resistive element connected between a base terminal of a bipolar transistor and an additional voltage reference. The bipolar transistor is connected between the first and second voltage references and to an output terminal of the generator circuit whereat the stable reference voltage with respect to temperature is. The generator circuit further comprises at least another resistive element, feedback connected between the output terminal of the generator circuit and the base terminal of the bipolar transistor to enable injecting additional current, having reverse dependence on temperature from the reference current, into the resistive element.

Abstract: The buffer has an output stage formed by two complementary MOS transistors connected so as to operate in phase opposition between the supply terminals and two driver stages having the input in common. Each driver stage has a first branch comprising a current-generator connected between the gate electrode of the transistor to be driven and a supply terminal and an electronic switch controlled by the input and connected between the same gate electrode and the other supply terminal, and a second branch which comprises, connected in series, a transistor connected as a diode and an electronic switch controlled by the output, and is arranged between the gate electrode of the transistor to be driven and a respective supply terminal. The buffer can control a load with a constant switching current, is simple in structure, and occupies a small area.

Abstract: The boosted switch device comprises an input terminal and an output terminal; a supply line set to a supply potential; a ground line set to a ground potential; a transistor connected between the input and output terminals; a capacitor; and a switch device connecting the capacitor between the supply line and the ground line, when the transistor is off, and between the input terminal and the control terminal of the transistor, when the transistor is on.

Abstract: An area-efficient low-pass, time-invariant, second-order reconstruction filter, particularly for current-driven digital-to-analog converters, including: a first resistor and a first capacitor which are parallel connected; an operational amplifier; a terminal of a second resistor which is connected to the inverting input of the operational amplifier; another terminal of the second resistor which is connected to a common node of the first resistor and the first capacitor; a second capacitor, which is ffeedback-connected between the output of the operational amplifier and the inverting input; and an additional pair of resistors which are arranged so as to provide feedback between the output and the inverting input, a current signal arriving from a digital-to-analog converter arranged upstream of the reconstruction filter being fed to a common node of the additional pair of resistors.

Abstract: A second-order double-sampled &Sgr;&Dgr; analog/digital converter uses two fully differential switched-capacitor integrators coupled in cascade. The first integrator has a fully-floating double-sampled, bilinear switched capacitor input structure. The second integrator has a double-sampled lossless discrete integrator (LDI) switched-capacitor input structure. The converter achieves an excellent SNR with a reduced number of switches for low power consumption.

Abstract: A .SIGMA..DELTA. digital/analog converter includes a signal reconstructing multirate low pass filter realized as a switched capacitor fully differential, double sampled structure. The input stage of the filter employs only two sampling capacitors, switched alternately on the two inputs of the stage. The input stage further includes two delay circuits (z.sup.-1) in the feed line of the bitstream towards one of the two inputs of the multistage SC filter. The zeroes introduced in the transfer function reduce the noise energy in the vicinity of frequencies f.sub.s /2.sup.n, preserving the SNR even with a relatively large mismatch between the capacitors.

Abstract: A fully differential voltage-current converter, comprising a differential operational amplifier which is supplied with a differential voltage to be converted into a current, a first transistor being fedback to a noninverting input of the amplifier, a second transistor being fedback to an inverting input of the amplifier, the second transistor having the opposite polarity with respect to the first transistor, a third transistor and a fourth transistor having mutually opposite polarities being connected between a supply voltage and ground and to the second transistor in order to force a current that flows through the second transistor to be equal to a current that flows through the first transistor, a gate terminal of the first transistor being connected to a gate terminal of the fourth transistor.

Abstract: The circuit of a two-stage fully differential amplifier includes a differential input stage, two output stages and a common mode feedback circuit coupled to the output nodes of the amplifier. The amplifier also includes a non-inverting stage coupled to a respective output node of the differential input stage for driving the respective output stage. Each auxiliary non-inverting stage of the two branches of the fully differential amplifier uses as a biasing current generator, the load device of the branch of the differential input stage to the output of which the non-inverting stage is coupled. The fully differential amplifier permits the use of a null-consumption common mode feedback circuit as normally employed only in a single stage fully differential amplifier.

Abstract: A regulating circuit for the output voltage of a voltage booster, of the type which comprises a first charge transfer capacitor adapted to draw electric charges from the supply terminal and transfer them to the output terminal, through electronic switches controlled by non-overlapped complementary phase signals, and a second charge storage capacitor connected between the output terminal and ground, further comprises an error amplifier which generates, during one of the operational phases, a DC voltage corresponding to the difference between a reference voltage and a divided voltage of the output voltage of the voltage booster; this DC voltage is applied directly to one end of the transfer capacitor.

Abstract: A voltage multiplier includes a first charge transfer capacitor designed to take and transfer electrical charges from the input terminal to the output terminal, a second capacitor for charge storage connected between the output terminal and ground and an output voltage stabilization circuit. The output voltage stabilization circuit includes an integrator designed to generate a continuous voltage corresponding to the difference between a reference voltage and the output voltage of the voltage multiplier. The continuous voltage is applied to one terminal of said charge transfer capacitor so that the potential at the other terminal of the capacitor changes proportionally to the output voltage of the voltage multiplier.

Abstract: Electronic switch for low-voltage supply circuits completed with CMOS technology and comprising a first, a second and a third circuit element (SW1 ,SW2,SW3) consisting each of a pair of complementary transistors. The first and second of said elements (SW1,SW2) are inserted between two connection terminals of the switch (A,B) while the third element SW3 is inserted between a node (C) included between the first and the second element of a voltage reference (VCM). The first and second element are driven to conduction in phases (.phi.1) not overlapping the phases (.phi.2) in which it conducts the third element.

Abstract: An electronic driver circuit for low-impedance loads, being of a type which comprises an input terminal (IN) to which a voltage signal (Vin) is applied for alternate transfer to an output, and a plurality of output terminals (OUTi), each connected to a corresponding electric load (2), further comprises, between the input terminal and the output terminals, a single operational amplifier (3) having multiple output stages (7), one for each output terminal (OUTi). The operational amplifier (3) is of the single-ended or fully differential multistage type and allows each load to be driven alternately by activation of the corresponding output stage (7i).

Abstract: An initialization circuit for memory registers, having a signal input being applied a supply voltage which rises linearly from a null value, and an initializing output connected to an input of a memory register and on which a voltage signal, being equal or proportional to the supply voltage, during the initialization step, and a null voltage signal, upon the supply voltage dropping below a predetermined tripping value, are produced. Additionally, the circuit has, between the input and the output, a first circuit portion connected to the input; a second circuit portion connected after the first and having a first output connected to the initializing output; and a third, inverting circuit portion having an input connected to a second output of the second portion and an output connected to the first portion to hold off that first portion while the supply voltage drops below the threshold voltage.

Abstract: An electronic switch having a reduced body effect includes first and second switch terminals. A first transistor of a first type has a control terminal, a first substrate coupled to a first voltage level, and first and second drive terminals respectively coupled to the first and second switch terminals. A second transistor of a second type has a control terminal, a second substrate, a first drive terminal coupled to the second substrate and to the first switch terminal, and a second drive terminal. A third transistor of the second type has a control terminal, a third substrate, a first drive terminal coupled to the second drive terminal of the second transistor, and a second drive terminal coupled to the third substrate and to the second switch terminal. A fourth transistor of a first type has a control terminal, a fourth substrate, a first drive terminal coupled to the second drive terminal of the second transistor, and a second drive terminal coupled to the fourth substrate and a first voltage level.

Abstract: A voltage multiplier for relatively high output current has its design output voltage stabilized and rendered independent of process spread, temperature, supply voltage and output current level, by a stabilization loop driving the switch that cyclically connects to ground a charge transfer capacitance of the functional voltage multiplier circuit. The feedback loop comprises an integrating stage, stabilized by creating a low-frequency zero in the transfer function for compensating one of two low-frequency poles of the transfer function of the whole circuit.

Abstract: A sampled band-gap voltage reference circuit which has quicker regeneration of the voltage reference signal after degeneration of the voltage reference signal due to additional loading. The voltage reference circuit prevents interference from the circuit source inputs to the operational amplifier by selective switching. The selective switching of the circuit allows the operational amplifier to regenerate the output voltage up to ten times quicker than prior art devices of the same size.

Abstract: The circuit includes a filter to which an analog signal is applied, a quantizer driven by the filter, a sampler at a desired frequency driven by the quantizer and a PCM encoder driven by the sampler. The quantizer generates a quantize signal according to the received analog signal and further generates a difference signal according to the difference between a quantized signal and the analog signal. A feedback circuit feeds back the difference signal from the quantizer to a stage of the filter so that the overall transfer function from the input of the feedback circuit to the output of the filter is equivalent to a low pass filtering.

Abstract: A power CMOS operational amplifier with a differential output, having an intrinsically stable current absorption under rest conditions, comprises two symmetric branches, each comprising a first folded cascode input inverting stage, a level shifting circuit, a second currant mirror type noninverting amplifying stage and a third output inverting stage, constituted by a complementary pair of transistors, connected in a common source configuration between the supply rails and driven by the output of the second noninverting stage and by the output of the level shifting circuit. Frequency compensation is accomplished by means of two capacitors connected between each of the two output terminals of the amplifier and the output of the first inverting stage and a node of the output branch of the noninverting current mirror stage. A single common mode feedback network stabilizes both symmetric branches of the amplifier.

Abstract: The filter comprises at least one completely differential operational amplifier having two inputs and two outputs and at least one pair of feedback circuits connecting said outputs with respective inputs of said amplifier outside of same. The operational amplifier has no common-mode feedback circuit, whose functions are performed by said feedback circuits external to the amplifier.

Abstract: An integrated, low-pass filter of the first order made using the switched capacitors technique utilizes advantageously a single switched capacitor and only two switches in contrast to the filters of the prior art which utilize two switched capacitors and four switches. The filter of the invention requires a smaller integration area and moreover exhibits a greater precision of its DC gain.