Abstract: A method of operating a Power Line Communications (PLC) network including a plurality of nodes having wirelines extending therebetween for propagating PLC signals between said nodes over said wirelines. The method includes coupling to a set of nodes of the PLC network respective partitioning filters, which can be activated for countering propagation of the PLC signals through the nodes to which said partitioning filters are coupled. The method also includes selectively activating filters chosen from among said partitioning filters, so that said PLC network is partitioned into a plurality of sub-networks with the propagation of PLC signals between the various sub-networks countered by the activated partitioning filters.

Abstract: A method of operating a Power Line Communications (PLC) network including a plurality of nodes having wirelines extending therebetween for propagating PLC signals between said nodes over said wirelines. The method includes coupling to a set of nodes of the PLC network respective partitioning filters, which can be activated for countering propagation of the PLC signals through the nodes to which said partitioning filters are coupled. The method also includes selectively activating filters chosen from among said partitioning filters, so that said PLC network is partitioned into a plurality of sub-networks with the propagation of PLC signals between the various sub-networks countered by the activated partitioning filters.

Abstract: A process manufactures power MOS lateral transistors together with CMOS devices on a semiconductor substrate. The process forms a lateral MOS transistor having a gate electrode on the semiconductor region, a source comprising a first highly doped portion aligned with the gate electrode and a drain comprising a lightly doped portion aligned with the gate electrode and a second highly doped portion included in the lightly doped portion. The process forms on the lightly doped portion, a protective layer of a first material; forms on the lateral MOS transistor, a dielectric layer of a second material selectively etchable with respect to the first material; forms, in the dielectric layer first, second, and third openings; and fills the openings with a conductive layer that forms drain and source contacts electrically connected to the first and second highly doped portions, and one electrical shield substantially aligned with the protective layer.

Abstract: A method for manufacturing a MOS transistor integrated into a chip of semi-conductive material comprising a first and a second active region which extend from the inside of the chip to a surface of the chip. The method comprises the steps of: a) forming a layer of insulating material on the surface of the chip and depositing a layer of conductive material on said insulating layer, b) defining an insulated gate electrode of the transistor, from said superimposed insulating and conductive layers, c) defining, from said superimposed insulating and conductive layers, an additional structure arranged on a first surface portion of the first active region, and d) placing between the insulated gate electrode and the additional structure a dielectric spacer placed on a second surface portion of the first active region.

Abstract: A process manufactures power MOS lateral transistors together with CMOS devices on a semiconductor substrate. The process forms a lateral MOS transistor having a gate electrode on the semiconductor region, a source comprising a first highly doped portion aligned with the gate electrode and a drain comprising a lightly doped portion aligned with the gate electrode and a second highly doped portion included in the lightly doped portion. The process forms on the lightly doped portion, a protective layer of a first material; forms on the lateral MOS transistor, a dielectric layer of a second material selectively etchable with respect to the first material; forms, in the dielectric layer first, second, and third openings; and fills the openings with a conductive layer that forms drain and source contacts electrically connected to the first and second highly doped portions, and one electrical shield substantially aligned with the protective layer.

Abstract: A power amplifier comprising at least a load element and at least an active element inserted, in series to each other, between a first and a second voltage reference is described. Advantageously, according to an embodiment of the invention, the load element comprises a DMOS transistor.

Abstract: A process is disclosed for forming, on a common semiconductor substrate, CMOS transistors and vertical or lateral MOS transistors on at least first and second portions, respectively, of the substrate. A first dielectric layer is formed on the substrate. A first semiconductor material layer is then formed on the first dielectric layer, in the first portion. A stack structure comprising a second dielectric layer, second semiconductor layer, and low-resistance layer is then formed over the substrate. First ports are defined in the second semiconductor layer and the low-resistance layer to provide gate regions of the vertical or lateral MOS transistors. The second semiconductor layer and the low-resistance layer are then removed from the first portion of the substrate by using the second dielectric layer as a screen. Second ports in the second dielectric layer and the second semiconductor layer are then defined to provide gate regions for the CMOS transistors.

Abstract: A method for manufacturing a MOS transistor integrated into a chip of semi-conductive material comprising a first and a second active region which extend from the inside of the chip to a surface of the chip. The method comprises the steps of: a) forming a layer of insulating material on the surface of the chip and depositing a layer of conductive material on said insulating layer, b) defining an insulated gate electrode of the transistor, from said superimposed insulating and conductive layers, c) defining, from said superimposed insulating and conductive layers, an additional structure arranged on a first surface portion of the first active region, and d) placing between the insulated gate electrode and the additional structure a dielectric spacer placed on a second surface portion of the first active region.

Abstract: A metal oxide semiconductor transistor integrated in a wafer of semiconductor material includes a gate structure located on a surface of the wafer and includes a gate oxide layer. The gate oxide layer includes a first portion having a first thickness and a second portion having a second thickness differing from the first thickness.

Abstract: A method for manufacturing a MOS transistor integrated into a chip of semi-conductive material comprising a first and a second active region which extend from the inside of the chip to a surface of the chip. The method comprises the steps of: a) forming a layer of insulating material on the surface of the chip and depositing a layer of conductive material on said insulating layer, b) defining an insulated gate electrode of the transistor, from said superimposed insulating and conductive layers, c) defining, from said superimposed insulating and conductive layers, an additional structure arranged on a first surface portion of the first active region, and d) placing between the insulated gate electrode and the additional structure a dielectric spacer placed on a second surface portion of the first active region.

Abstract: A metal oxide semiconductor transistor integrated in a wafer of semiconductor material includes a gate structure located on a surface of the wafer and includes a gate oxide layer. The gate oxide layer includes a first portion having a first thickness and a second portion having a second thickness differing from the first thickness.

Abstract: A process is disclosed for forming, on a common semiconductor substrate, CMOS transistors and vertical or lateral MOS transistors on at least first and second portions, respectively, of the substrate. A first dielectric layer is formed on the substrate. A first semiconductor material layer is then formed on the first dielectric layer, in the first portion. A stack structure comprising a second dielectric layer, second semiconductor layer, and low-resistance layer is then formed over the substrate. First ports are defined in the second semiconductor layer and the low-resistance layer to provide gate regions of the vertical or lateral MOS transistors. The second semiconductor layer and the low-resistance layer are then removed from the first portion of the substrate by using the second dielectric layer as a screen. Second ports in the second dielectric layer and the second semiconductor layer are then defined to provide gate regions for the CMOS transistors.

Abstract: Electronic circuit integrated in a chip of semiconductor material comprising a first buried channel MOS transistor and a second MOS transistor, of a type complementary to the first transistor, both made in said chip in CMOS technology. Particularly, also the second transistor is of a buried channel type.

Abstract: A power amplifier comprising at least a load element and at least an active element inserted, in series to each other, between a first and a second voltage reference is described. Advantageously, according to an embodiment of the invention, the load element comprises a DMOS transistor.

Abstract: A method for manufacturing a MOS transistor integrated into a chip of semi-conductive material comprising a first and a second active region which extend from the inside of the chip to a surface of the chip. The method comprises the steps of: a) forming a layer of insulating material on the surface of the chip and depositing a layer of conductive material on said insulating layer, b) defining an insulated gate electrode of the transistor, from said superimposed insulating and conductive layers, c) defining, from said superimposed insulating and conductive layers, an additional structure arranged on a first surface portion of the first active region, and d) placing between the insulated gate electrode and the additional structure a dielectric spacer placed on a second surface portion of the first active region.

Abstract: A metal oxide semiconductor transistor integrated in a wafer of semiconductor material includes a gate structure located on a surface of the wafer and includes a gate oxide layer. The gate oxide layer includes a first portion having a first thickness and a second portion having a second thickness differing from the first thickness.

Abstract: An LDMOS structure is formed in a region of a first type of conductivity of a semiconductor substrate and comprises a gate, a drain region and a source region. The source region is formed by a body diffusion of a second type of conductivity within the first region, and a source diffusion of the first type of conductivity is within the body diffusion. An electrical connection diffusion of the second type of conductivity is a limited area of the source region, and extends through the source diffusion and reaches down to the body diffusion. At least one source contact is on the source diffusion and the electrical connection diffusion. The LDMOS structure further comprises a layer of silicide over the whole area of the source region short-circuiting the source diffusion and the electrical connection diffusion. The source contact is formed on the silicide layer.

Abstract: A reduced surface field (RESURF) lateral diffused metal oxide semiconductor (LDMOS) integrated circuit includes a first region having a first conductivity type defined in a semiconductor substrate having a second conductivity type, a body region having the second conductivity type in the first region, and a source region having the first conductivity type formed in the body region. More specifically, the body region may be within a surface portion of the first region that is more heavily doped than the remainder of the of the first region.

Abstract: An LDMOS structure is formed in a region of a first type of conductivity of a semiconductor substrate and comprises a gate, a drain region and a source region. The source region is formed by a body diffusion of a second type of conductivity within the first region, and a source diffusion of the first type of conductivity is within the body diffusion. An electrical connection diffusion of the second type of conductivity is a limited area of the source region, and extends through the source diffusion and reaches down to the body diffusion. At least one source contact is on the source diffusion and the electrical connection diffusion. The LDMOS structure further comprises a layer of silicide over the whole area of the source region short-circuiting the source diffusion and the electrical connection diffusion. The source contact is formed on the silicide layer.