Abstract: A process of forming integrated electronic device having a semiconductor body includes: forming a first electrode region having a first type of conductivity; forming a second electrode region having a second type of conductivity, which forms a junction with the first electrode region; and forming a nanostructured semiconductor region, which extends in one of the first and second electrode regions.

Abstract: An integrated magnetoresistive device includes a substrate of semiconductor material that is covered, on a first surface, by an insulating layer. A magnetoresistor of ferromagnetic material extends within the insulating layer and defines a sensitivity plane of the sensor. A concentrator of ferromagnetic material includes at least one arm that extends in a transversal direction to the sensitivity plane and is vertically offset from the magnetoresistor. The concentrator concentrates deflects magnetic flux lines perpendicular to the sensitivity plane so as to generate magnetic-field components directed in a parallel direction to the sensitivity plane.

Abstract: An integrated electronic device having a semiconductor body including: a first electrode region having a first type of conductivity; and a second electrode region having a second type of conductivity, which forms a junction with the first electrode region. The integrated electronic device further includes a nanostructured semiconductor region, which extends in one of the first and second electrode regions.

Abstract: An integrated magnetoresistive device includes a substrate of semiconductor material that is covered, on a first surface, by an insulating layer. A magnetoresistor of ferromagnetic material extends within the insulating layer and defines a sensitivity plane of the sensor. A concentrator of ferromagnetic material includes at least one arm that extends in a transversal direction to the sensitivity plane and is vertically offset from the magnetoresistor. The concentrator concentrates deflects magnetic flux lines perpendicular to the sensitivity plane so as to generate magnetic-field components directed in a parallel direction to the sensitivity plane.

Abstract: A supercapacitor including: a shell; a chamber in the shell; a first electrode and a second electrode on respective walls of the chamber; and a separator arranged between the first electrode and the second electrode through the chamber. The separator includes a first perforated membrane and a second perforated membrane, which is movable with respect to the first membrane between a first position, in which the first membrane and the second membrane are separate and a second position, in which the first membrane and the second membrane are in contact and coupled for rendering the separator impermeable.

Abstract: An integrated AMR magnetoresistive sensor has a magnetoresistor, a set/reset coil and a shielding region arranged on top of each other. The set/reset coil is positioned between the magnetoresistor and the shielding region. The magnetoresistor is formed by a magnetoresistive strip of an elongated shape having a length in a first direction parallel to the preferential magnetization direction and a width in a second direction perpendicular to the first direction. The set/reset coil has at least one stretch extending transversely to the magnetoresistive strip. The shielding region is a ferromagnetic material and has a width in the second direction greater than the width of the magnetoresistive strip so as to attenuate the external magnetic field traversing the magnetoresistive strip and increase the sensitivity scale of the magnetoresistive sensor.

Abstract: A light-emitting device may include a semiconductor body having a first conductivity type, with a front side and a back side. The light-emitting device may also include a porous-silicon region which extends in the semiconductor body at the front side, and a cathode region in direct lateral contact with the porous-silicon region. The light-emitting device may further include a barrier region of electrically insulating material, which extends in direct contact with the cathode region at the bottom side of the cathode region so that, in use, an electric current flows in the semiconductor body through lateral portions of the cathode region.

Abstract: A light-emitting device may include a semiconductor body having a first conductivity type, with a front side and a back side. The light-emitting device may also include a porous-silicon region which extends in the semiconductor body at the front side, and a cathode region in direct lateral contact with the porous-silicon region. The light-emitting device may further include a barrier region of electrically insulating material, which extends in direct contact with the cathode region at the bottom side of the cathode region so that, in use, an electric current flows in the semiconductor body through lateral portions of the cathode region.

Abstract: A method to determine the injection pattern in the intake stroke of the combustion cycle of the cylinders of a direct-injection internal combustion engine, which includes determining the overall quantity of fuel to be injected for each combustion cycle of each cylinder during the intake stroke; determining the maximum quantity of fuel to be injected for each partial injection as a function of the value of the start of injection angle, of the speed and of the load of the internal combustion engine; and determining the number of partial injections and the objective quantity to be injected for each partial injection as a function of the quantity of fuel to be injected for each combustion cycle of each cylinder during the intake stroke and of the maximum quantity of fuel to be injected for each partial injection.

Abstract: An integrated electronic device having a semiconductor body including: a first electrode region having a first type of conductivity; and a second electrode region having a second type of conductivity, which forms a junction with the first electrode region. The integrated electronic device further includes a nanostructured semiconductor region, which extends in one of the first and second electrode regions.

Abstract: An acoustic device includes a micro-machined acoustic transducer element, an acoustically attenuating region, and an acoustic matching region arranged between the acoustic transducer element and the acoustically attenuating region. The acoustic transducer element is formed in a first substrate housing a cavity delimiting a membrane. A second substrate of semiconductor material integrating an electronic circuit is arranged between the acoustic transducer element and the acoustically attenuating region. The acoustic matching region has a first interface with the second substrate and a second interface with the acoustically attenuating region. The acoustic matching region has an impedance matched to the impedance of the second substrate in proximity of the first interface, and an impedance matched to the acoustically attenuating region in proximity of the second interface.

Abstract: A method to determine the injection pattern in the compression stroke of the combustion cycle of the cylinders of a direct-injection internal combustion engine, comprising the steps of determining the initial quantity of fuel and an objective quantity of fuel to be injected for each partial injection of a maximum number of partial injections; determining an effective quantity of fuel to be injected for each partial injection as a function of the respective initial quantity of fuel and of the respective objective quantity of fuel; and determining an objective pattern of partial injections to be performed in the compression stroke as a function of the value of the end of injection angle and of the effective quantity of fuel to be injected for each partial injection of a maximum number of partial injections to be performed in the compression stroke.

Abstract: A magnetic field sensor formed by a Hall cell having a first, second, third and fourth conduction nodes electrically coupled together by resistive paths. Flowing between the first and second conduction nodes is a control current. In the presence of a magnetic field, a difference of potential due to the Hall effect is generated between the third and fourth conduction nodes. An operational amplifier has an inverting input terminal coupled to the fourth conduction node, a non-inverting input terminal biased at the voltage at the third conduction node, and an output terminal coupled in feedback mode to the inverting input by a feedback resistor. The current generated in feedback through the feedback resistor generates a voltage indicating unbalancing, due to the Hall effect, between the third and fourth conductive nodes, and consequently indicates the intensity of the magnetic field that acts upon the Hall cell.

Abstract: A supercapacitor including: a shell; a chamber in the shell; a first electrode and a second electrode on respective walls of the chamber; and a separator arranged between the first electrode and the second electrode through the chamber. The separator includes a first perforated membrane and a second perforated membrane, which is movable with respect to the first membrane between a first position, in which the first membrane and the second membrane are separate and a second position, in which the first membrane and the second membrane are in contact and coupled for rendering the separator impermeable.

Abstract: A light-emitting device may include a semiconductor body having a first conductivity type, with a front side and a back side. The light-emitting device may also include a porous-silicon region which extends in the semiconductor body at the front side, and a cathode region in direct lateral contact with the porous-silicon region. The light-emitting device may further include a barrier region of electrically insulating material, which extends in direct contact with the cathode region at the bottom side of the cathode region so that, in use, an electric current flows in the semiconductor body through lateral portions of the cathode region.

Abstract: An integrated AMR magnetoresistive sensor has a magnetoresistor, a set/reset coil and a shielding region arranged on top of each other. The set/reset coil is positioned between the magnetoresistor and the shielding region. The magnetoresistor is formed by a magnetoresistive strip of an elongated shape having a length in a first direction parallel to the preferential magnetization direction and a width in a second direction perpendicular to the first direction. The set/reset coil has at least one stretch extending transversely to the magnetoresistive strip. The shielding region is a ferromagnetic material and has a width in the second direction greater than the width of the magnetoresistive strip so as to attenuate the external magnetic field traversing the magnetoresistive strip and increase the sensitivity scale of the magnetoresistive sensor.

Abstract: An integrated magnetoresistive device, where a substrate of semiconductor material is covered, on a first surface, by an insulating layer. A magnetoresistor of ferromagnetic material extends in the insulating layer and defines a sensitivity plane of the sensor. A concentrator of ferromagnetic material including at least one arm, extending in a transversal direction to the sensitivity plane and vertically offset to the magnetoresistor. In this way, magnetic flux lines directed perpendicularly to the sensitivity plane are concentrated and deflected so as to generate magnetic-field components directed in a parallel direction to the sensitivity plane.

Abstract: An integrated magnetoresistive device includes a substrate of semiconductor material that is covered, on a first surface, by an insulating layer. A magnetoresistor of ferromagnetic material extends within the insulating layer and defines a sensitivity plane of the sensor. A concentrator of ferromagnetic material includes at least one arm that extends in a transversal direction to the sensitivity plane and is vertically offset from the magnetoresistor. The concentrator concentrates deflects magnetic flux lines perpendicular to the sensitivity plane so as to generate magnetic-field components directed in a parallel direction to the sensitivity plane.

Abstract: A method to determine the injection pattern in the compression stroke of the combustion cycle of the cylinders of a direct-injection internal combustion engine, comprising the steps of determining the initial quantity of fuel and an objective quantity of fuel to be injected for each partial injection of a maximum number of partial injections; determining an effective quantity of fuel to be injected for each partial injection as a function of the respective initial quantity of fuel and of the respective objective quantity of fuel; and determining an objective pattern of partial injections to be performed in the compression stroke as a function of the value of the end of injection angle and of the effective quantity of fuel to be injected for each partial injection of a maximum number of partial injections to be performed in the compression stroke.

Abstract: A method to determine the injection pattern in the intake stroke of the combustion cycle of the cylinders of a direct-injection internal combustion engine, which includes determining the overall quantity of fuel to be injected for each combustion cycle of each cylinder during the intake stroke; determining the maximum quantity of fuel to be injected for each partial injection as a function of the value of the start of injection angle, of the speed and of the load of the internal combustion engine; and determining the number of partial injections and the objective quantity to be injected for each partial injection as a function of the quantity of fuel to be injected for each combustion cycle of each cylinder during the intake stroke and of the maximum quantity of fuel to be injected for each partial injection.