Abstract: A packaged device has a die of semiconductor material bonded to a support. An electromagnetic shielding structure surrounds the die and is formed by a grid structure of conductive material extending into the support and an electromagnetic shield, coupled together. A packaging mass embeds both the die and the electromagnetic shield. The electromagnetic shield is formed by a plurality of metal ribbon sections overlying the die and embedded in the packaging mass. Each metal ribbon section has a thickness-to-width ratio between approximately 1:2 and approximately 1:50.

Abstract: A tensile stress measurement device is to be attached to an object to be measured. The tensile stress measurement device may include an IC having a semiconductor substrate and tensile stress detection circuitry, the semiconductor substrate having opposing first and second attachment areas. The tensile stress measurement device may include a first attachment plate coupled to the first attachment area and extending outwardly to be attached to the object to be measured, and a second attachment plate coupled to the second attachment area and extending outwardly to be attached to the object to be measured. The tensile stress detection circuitry may be configured to detect a tensile stress imparted on the first and second attachment plates when attached to the object to be measured.

Abstract: A semiconductor device includes: one or more semiconductor dice, a die pad supporting the semiconductor die or dice, a package molded onto the semiconductor die or dice supported by said die pad, wherein the die pad is exposed at the surface of the package, and the exposed die pad with an etched pattern therein to form at least one electrical contact land in the die pad.

Abstract: A package for a device to be inserted into a solid structure may include a building material that includes particles of one of micrometric and sub-micrometric dimensions. The device may include an integrated detection module having at least one integrated sensor and the package arranged to coat at least one portion of the device including the integrated detection module. A method aspect includes a method of manufacturing the device. A system aspect is for monitoring parameters in a solid structure that includes the device.

Abstract: In order to manufacture a packaged device, a die having a sensitive region is bonded to a support, and a packaging mass of moldable material is molded on the support so as to surround the die. During molding of the packaging mass, a chamber is formed, which faces the sensitive region and is connected to the outside environment. To this end, a sacrificial mass of material that may evaporate/sublimate is dispensed on the sensitive region; the packaging mass is molded on the sacrificial mass; a through hole is formed in the packaging mass to extend as far as the sacrificial mass; the sacrificial mass is evaporated/sublimated through the hole.

Abstract: An electronic component includes one or more circuits having electrical connections coupled therewith. The electrical connections include a lead frame as well as electrical wires coupling the circuit or circuits to respective portions of the lead frame. The electrical wires may be formed as one piece with the respective portion of the lead frame without joints therebetween, e.g., by 3D printing.

Abstract: A packaged device has a die of semiconductor material bonded to a support. An electromagnetic shielding structure surrounds the die and is formed by a grid structure of conductive material extending into the support and an electromagnetic shield, coupled together. A packaging mass embeds both the die and the electromagnetic shield. The electromagnetic shield is formed by a plurality of metal ribbon sections overlying the die and embedded in the packaging mass. Each metal ribbon section has a thickness-to-width ratio between approximately 1:2 and approximately 1:50.

Abstract: A tensile stress measurement device is to be attached to an object to be measured. The tensile stress measurement device may include an IC having a semiconductor substrate and tensile stress detection circuitry, the semiconductor substrate having opposing first and second attachment areas. The tensile stress measurement device may include a first attachment plate coupled to the first attachment area and extending outwardly to be attached to the object to be measured, and a second attachment plate coupled to the second attachment area and extending outwardly to be attached to the object to be measured. The tensile stress detection circuitry may be configured to detect a tensile stress imparted on the first and second attachment plates when attached to the object to be measured.

Abstract: In order to manufacture a packaged device, a die having a sensitive region is bonded to a support, and a packaging mass of moldable material is molded on the support so as to surround the die. During molding of the packaging mass, a chamber is formed, which faces the sensitive region and is connected to the outside environment. To this end, a sacrificial mass of material that may evaporate/sublimate is dispensed on the sensitive region; the packaging mass is molded on the sacrificial mass; a through hole is formed in the packaging mass to extend as far as the sacrificial mass; the sacrificial mass is evaporated/sublimated through the hole.

Abstract: A substrate for mounting a semiconductor device includes an insulating layer having first and second opposed surfaces defining a thickness. First and second electrically conductive lands are included in the insulating layer. The first electrically conductive lands extend through the whole thickness of the insulating layer and are exposed on both the first and second opposed surfaces. The second electrically conductive lands have a thickness less than the thickness of the insulating layer and are exposed only at the first surface. Electrically conductive lines at the first surface of the insulating layer couple certain ones of the first electrically conductive lands with certain ones of the second electrically conductive lands. The semiconductor device is mounted to the first surface of the insulating layer. Wire bonding may be used to electrically coupling the semiconductor device to certain ones of the first and second lands.

Abstract: An embodiment for manufacturing electronic devices is proposed. The embodiment includes the following phases: a) forming a plurality of chips in a semiconductor material wafer including a main surface; each chip includes respective integrated electronic components and respective contact pads facing the main surface; said contact pads are electrically coupled to the integrated electronic components; b) attaching at least one conductive ribbon to at least one contact pad of each chip; c) covering the main surface of the semiconductor material wafer and the at least one conductive ribbon with a layer of plastic material; d) lapping an exposed surface of the layer of plastic material to remove a portion of the plastic material layer at least to uncover portions of the at least one conductive ribbon, and e) sectioning the semiconductor material wafer to separate the chips.

Abstract: A method is for making a semiconductor device having an IC die on a substrate with electric contact formations for the IC die and the substrate. The method may include printing ink including electrically conductive nanoparticles, onto the electric contact formations.

Abstract: An electronic component includes one or more circuits having electrical connections coupled therewith. The electrical connections include a lead frame as well as electrical wires coupling the circuit or circuits to respective portions of the lead frame. The electrical wires may be formed as one piece with the respective portion of the lead frame without joints therebetween, e.g., by 3D printing.

Abstract: The integrated electronic device is for detecting a local parameter related to a force observed in a given direction, within a solid structure. The device includes at least one sensor configured to detect the above-mentioned local parameter at least in the given direction through piezo-resistive effect. At least one damping element, integrated in the device, is arranged within a frame-shaped region that is disposed around the at least one sensor and belongs to a substantially planar region comprising a plane passing through the sensor and perpendicular to the given direction. Such at least one damping element is configured to damp forces acting in the planar region and substantially perpendicular to the given direction.

Abstract: A pressure sensing device may include a body configured to distribute a load applied between first and second parts positioned one against the other, and a pressure sensor carried by the body. The pressure sensor may include a support body, and an IC die mounted with the support body and defining a cavity. The IC die may include pressure sensing circuitry responsive to bending associated with the cavity, and an IC interface coupled to the pressure sensing circuitry.

Abstract: A tensile stress measurement device is to be attached to an object to be measured. The tensile stress measurement device may include an IC having a semiconductor substrate and tensile stress detection circuitry, the semiconductor substrate having opposing first and second attachment areas. The tensile stress measurement device may include a first attachment plate coupled to the first attachment area and extending outwardly to be attached to the object to be measured, and a second attachment plate coupled to the second attachment area and extending outwardly to be attached to the object to be measured. The tensile stress detection circuitry may be configured to detect a tensile stress imparted on the first and second attachment plates when attached to the object to be measured.

Abstract: An IC may include a semiconductor substrate having circuitry formed in the substrate, an interconnect layer above the semiconductor substrate and having an antenna coupled to the circuitry, and a seal ring around a periphery of the interconnect layer. The IC may include an electrically insulating trench extending vertically into the semiconductor substrate and extending laterally across the semiconductor substrate from adjacent one side to adjacent another side.

Abstract: An embodiment for manufacturing electronic devices is proposed. The embodiment includes the following phases: a) forming a plurality of chips in a semiconductor material wafer including a main surface; each chip includes respective integrated electronic components and respective contact pads facing the main surface; said contact pads are electrically coupled to the integrated electronic components; b) attaching at least one conductive ribbon to at least one contact pad of each chip; c) covering the main surface of the semiconductor material wafer and the at least one conductive ribbon with a layer of plastic material; d) lapping an exposed surface of the layer of plastic material to remove a portion of the plastic material layer at least to uncover portions of the at least one conductive ribbon, and e) sectioning the semiconductor material wafer to separate the chips.

Abstract: A semiconductor structure includes at least a semiconductor body, a delimiting structure delimiting a cup-shaped recess in the body and a conductive region in the recess. The conductive region is made of a low-melting-temperature material, having a melting temperature lower than that of the materials forming the delimiting structure.

Abstract: A packaged semiconductor device includes a communication pad formed in a side surface, which is operatively coupled to a communication circuit so as to enable the establishing of a wireless communication channel to an adjacently positioned packaged semiconductor device. The communication pad may be formed upon cutting a block including the packaged semiconductor device and an appropriately positioned and dimensioned conductor.