Abstract: A switched capacitance circuit including: a switched capacitance section, capable of receiving as input a signal and carrying out a sampling of said signal, the section comprising at least one group of capacitors each of which has a terminal connected to a common node; at least an operational stage including at least an input terminal connected to said common node, the operational stage providing a current to said common node for charging said group of capacitors during a sampling time interval of said signal. The circuit further includes an auxiliary circuit connected to said common node and capable of being activated/deactivated by an enabling signal for injecting a further current into said common node and increasing the current provided to said common node during at least one time interval equal to a fraction of said sampling interval.

Abstract: The circuit comprises a first ring oscillator comprising an odd number of inverting elements, a delay element and an output terminal; the delay element responds to a pulse at its input with a predetermined time delay with respect to a predetermined edge of the input pulse and substantially without time delay with respect to the other edge of the input pulse. With a view to avoiding start-up transients and generating pulses with a duty cycle that can be easily modified, the circuit comprises a second ring oscillator, having an output terminal connected to the output terminal of the first oscillator, and a bistable logic circuit having an output terminal connected to the common output of the first and the second oscillator. At least one of the inverting elements of the first oscillator and at least one of the inverting elements of the second oscillator form part of the bistable logic circuit.

Abstract: The described analog-digital converter comprises quantization means having an input for receiving an analog quantity to be converted, a register having an output for providing a digital quantity corresponding to the analog quantity, a timing pulse generator and logic means connected to the quantization means, the register and the timing pulse generator and capable of responding to a conversion request signal by activating the quantization means in such a manner as to make them carry out predetermined operations timed by the timing pulses and load into the register the digital quantity to be provided at the output.

Abstract: A time delay logic comprises a first stage with an inverter, a capacitor connected to the input terminal of the inverter, a constant current generator and an electronic switch controlled by an input pulse. The capacitor begins to charge at a predetermined edge of the input pulse and brings the input terminal of the inverter from a first voltage (ground) to the switching threshold voltage of the inverter, so that on the output terminal of the inverter there is obtained a pulse having an edge that, as referred to the predetermined edge of the input pulse, has a delay time that depends on the inverter threshold. The circuit comprises a second stage, coupled with the first, that is a dual circuit of the circuit of the first stage and has an inverter equal to the one of the first stage.

Abstract: The circuit comprises a differential amplifier with two inputs and two outputs and a common mode regulation circuit. Between a regulation terminal of the amplifier and the outputs there are connected first and second capacitors and first and second capacitive elements that by controlled switches are connected in parallel with, respectively, the first and second capacitors or alternately between first and second reference voltage terminals. The common mode output voltage is not exactly fixed at the beginning of the design, but is determined by attributing appropriate values to the first and second capacitive elements; more particularly, their capacitances C3 and C4 are chosen in such a way as to satisfy the following equality: Vcmn=Vrefl+[(Vrefp?Vrefm)/2]*(C4?C3)/(C3+C4), where Vcmn is the desired common mode output voltage, Vrefp and Vrefm are the differential output voltages and Vrefl is the voltage of the second reference terminal.

Abstract: A digital system comprises a digital data processing unit, at least one output buffer connected to the processing unit to generate output signals in response to digital signals arriving from the processing unit and at least one user unit connect as output buffer load. With a view to assuring that the switching current of the output buffer can be set to different values, the output buffer comprises means for fixing the switching current to a value that is substantially constant and independent of the load and means for selectively setting the value of the switching current and the processing unit comprises means for storing a predetermined parameter; said means are connected to the selective setting means for setting the values of the switching current as functions of the predetermined parameter.

Abstract: An A/D converter having capacitors of a first array of sampling capacitors weighted in binary code connected between a first common circuit node and an input terminal to be charged to an input voltage with respect to a ground of a signal to be converted, and in accordance with SAR technique are then selectively connected with two differential reference terminals, and at the same time capacitors of a second array equal to the first and all connected to a second node are selectively connected to ground and the lower differential voltage terminal. The two nodes are connected to the respective inputs of a comparator. A logic unit controls the connections of the capacitors of the two arrays in accordance with a predetermined timing program and as a function of the output of the comparator.

Abstract: A digital-to-analog converter includes a first section (MSB) that converts the more significant bits of a digital code into a first voltage (Vin) of a multiplicity of discrete voltages that are integral multiples of a predetermined first voltage step (&Dgr;V1). A second section (LSB) of the converter converts the less significant bits of the digital code into a current. The current is transformed into a second voltage of a multiplicity of discrete voltages that are integral multiples of a second voltage step (&Dgr;V2) equal to ½L of the product of the first voltage step (&Dgr;V1) multiplied by a predetermined coefficient, where L is the number of the less significant bits of the digital code to be converted. A summer generates an output voltage (Vout) that is the sum of the second voltage and the product of the first voltage multiplied by the predetermined coefficient. With a view to obtaining a low consumption, the summer has a resistive feedback circuit including a voltage divider (R3, R4).

Abstract: An A/D converter having capacitors of a first array of sampling capacitors weighted in binary code connected between a first common circuit node and an input terminal to be charged to an input voltage with respect to a ground of a signal to be converted, and in accordance with SAR technique are then selectively connected with two differential reference terminals, and at the same time capacitors of a second array equal to the first and all connected to a second node are selectively connected to ground and the lower differential voltage terminal. The two nodes are connected to the respective inputs of a comparator. A logic unit controls the connections of the capacitors of the two arrays in accordance with a predetermined timing program and as a function of the output of the comparators.

Abstract: The circuit comprises a differential amplifier (10) with two inputs and two outputs and a common mode regulation circuit. Between a regulation terminal (INCM) of the amplifier and the outputs there are connected a first (C1p) and a second (1m) capacitor and first (C3) and second (C4) capacitive means that by means of controlled switches (SW9-SW12) can be alternatively and simultaneousy connected in parallel with, respectively, the first ((C1p) and the second (C1m) capacitor or between a first (VB) and a second (Vref1) reference voltage terminal.

Abstract: A method of operating an SAR-type analog-to-digital converter to match the dynamic range of an input voltage signal to be converted with the full scale range of the converter, the converter including at least one array of binary weighted capacitors. The method includes the step of obtaining a digital gain code that represents the ratio between the full scale range and the dynamic range of the voltage signal to be converted, applying the voltage signal to be converted to the capacitor array so as to charge with the voltage signal to be converted only those array capacitors having the same binary weights as the bits of the gain code that have a selected binary value, and selectively coupling the capacitors of the array to one of a first and second predetermined reference voltage terminals according to an SAR technique, to obtain an output digital code corresponding to the input voltage signal.

Abstract: A digital system comprises a digital data processing unit, at least one output buffer connected to the processing unit to generate output signals in response to digital signals arriving from the processing unit and at least one user unit connect as output buffer load. With a view to assuring that the switching current of the output buffer can be set to different values, the output buffer comprises means for fixing the switching current to a value that is substantially constant and independent of the load and means for selectively setting the value of the switching current and the processing unit comprises means for storing a predetermined parameter; said means are connected to the selective setting means for setting the values of the switching current as functions of the predetermined parameter.

Abstract: An analog to digital converter includes first and second converter segments having respective first and second arrays of binary weighted capacitors. Each capacitor of the first segment has a first electrode connected to a first common node and a second electrode connected through respective switches to one of a first reference voltage terminal and an input terminal. Each capacitor of the second segment has a first electrode connected to a second common node and a second electrode connected through respective switches to one of the first reference voltage terminal and the input terminal. The converter includes a coupling capacitor connected between the first and second common nodes and capacitance means connected between the first common node and a reference voltage terminal.

Abstract: A method of operating an SAR-type analog-to-digital converter to match the dynamic range of an input voltage signal to be converted with the full scale range of the converter, the converter including at least one array of binary weighted capacitors. The method includes the step of obtaining a digital gain code that represents the ratio between the full scale range and the dynamic range of the voltage signal to be converted, applying the voltage signal to be converted to the capacitor array so as to charge with the voltage signal to be converted only those array capacitors having the same binary weights as the bits of the gain code that have a selected binary value, and selectively coupling the capacitors of the array to one of a first and second predetermined reference voltage terminals according to an SAR technique, to obtain an output digital code corresponding to the input voltage signal.

Abstract: A switched capacitor digital to analog converter includes first and second converter segments having respective first and second arrays of binary weighted capacitors. Each capacitor of the first segment has a first electrode connected to a first common node and a second electrode connected through respective switches to one of first and second reference voltage terminals. Each capacitor of the second segment has a first electrode connected to a second common node and a second electrode connected through respective switches to one of the first and second reference voltage terminals. The converter includes a coupling capacitor connected between the first and second common nodes and capacitance means connected between the first common node and a reference voltage terminal.

Abstract: A switched capacitor digital-to-analog converter includes a first voltage generator for providing first and second reference voltages, a second voltage generator for providing third and fourth reference voltages selected to match predetermined design values of the first and second reference voltages, and an array of binary weighted capacitors. Each capacitor has a first electrode connected to a common circuit node, which is connected to a converter output terminal and a second electrode selectively connected, through an associated first switching circuit, to either one of the first and second reference voltages or, through an associated second switching circuit, to either one of the third and fourth reference voltages.

Abstract: A switched capacitor digital to analog converter includes first and second converter segments having respective first and second arrays of binary weighted capacitors. Each capacitor of the first segment has a first electrode connected to a first common node and a second electrode connected through respective switches to one of first and second reference voltage terminals. Each capacitor of the second segment has a first electrode connected to a second common node and a second electrode connected through respective switches to one of the first and second reference voltage terminals. The converter includes a coupling capacitor connected between the first and second common nodes and capacitance means connected between the first common node and a reference voltage terminal.

Abstract: An area-efficient reconstruction filter removes undesirable sample images produced by current-driven digital-to-analog converters. The reconstruction filter includes: an input node for receiving the input current signal; an operational amplifier having first and second inputs and an output at which the output voltage signal is produced; a first resistor coupled between the output of the operational amplifier and the input node; a second resistor coupled to the first input of the operational amplifier; and a third resistor coupled between the input node and the second resistor. The reconstruction filter may also include a fourth resistor coupled between the input node and a reference voltage.

Abstract: A set of sampling capacitors weighted according to a binary code is charged through a first capacitive unit, whose capacitance is equal to the sum of the capacitances of the set, at a voltage Vcm−Vin/2. The conversion is carried out by an SAR process by a comparator and a logic unit which operates the switches associated with the capacitors. The final position of the switches is loaded into a register which supplies the digital output signal. To prevent any disturbances in the power supply and reference potential sources from affecting the accuracy of the conversion, two further capacitive units are provided, with the same capacitance as the first capacitive unit. These make it possible to prevent all the disturbances at the input of the comparator in common mode and therefore without any effect on the output.

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.