Patents by Inventor Mirko Scholz
Mirko Scholz has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 11967639Abstract: In accordance with an embodiment, a semiconductor device includes: an n-doped region disposed over an insulating layer; a p-doped region disposed over the insulating layer adjacent to the n-doped region, where an interface between the n-doped region and the p-doped region form a first diode junction; a plurality of segmented p-type anode regions disposed over the insulating layer, each of the plurality of segmented p-type anode regions being surrounded by the n-doped region, where a doping concentration of the plurality of segmented p-type anode regions is greater than a doping concentration of the p-doped region; and a plurality of segmented n-type cathode regions disposed over the insulating layer. Each of the plurality of segmented n-type cathode regions are surrounded by the p-doped region, where a doping concentration of the plurality of segmented n-type cathode regions is greater than a doping concentration of the n-doped region.Type: GrantFiled: January 26, 2022Date of Patent: April 23, 2024Assignee: Infineon Technologies AGInventors: Gernot Langguth, Anton Boehm, Christian Cornelius Russ, Mirko Scholz
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Publication number: 20240072040Abstract: An RF switch device includes transistors coupled in series forming an RF conductive current path; a first resistive bias network forming a DC conductive bias path between gate nodes of the plurality of transistors; and a first ESD bias component coupled between the RF conductive current path and the first resistive bias network, wherein the first ESD bias component provides a DC conductive path between the RF conductive current path of the RF switch device and the first resistive bias network during an ESD event.Type: ApplicationFiled: August 23, 2022Publication date: February 29, 2024Inventors: Valentyn Solomko, Semen Syroiezhin, Mirko Scholz
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Publication number: 20230238454Abstract: In accordance with an embodiment, a semiconductor device includes: an n-doped region disposed over an insulating layer; a p-doped region disposed over the insulating layer adjacent to the n-doped region, where an interface between the n-doped region and the p-doped region form a first diode junction; a plurality of segmented p-type anode regions disposed over the insulating layer, each of the plurality of segmented p-type anode regions being surrounded by the n-doped region, where a doping concentration of the plurality of segmented p-type anode regions is greater than a doping concentration of the p-doped region; and a plurality of segmented n-type cathode regions disposed over the insulating layer. Each of the plurality of segmented n-type cathode regions are surrounded by the p-doped region, where a doping concentration of the plurality of segmented n-type cathode regions is greater than a doping concentration of the n-doped region.Type: ApplicationFiled: January 26, 2022Publication date: July 27, 2023Inventors: Gernot Langguth, Anton Boehm, Christian Cornelius Russ, Mirko Scholz
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Patent number: 10424579Abstract: A semiconductor device for electric discharge protection is disclosed. In one aspect, the semiconductor device includes a substrate having a p-type doping. The semiconductor device includes a first well and a second well having an n-type doping and arranged spaced apart within a surface layer of the substrate, and a third well having a p-type doping and arranged in the surface layer of the substrate between the first well and the second well. The semiconductor device further includes an emitter region and a base contact region having a p-type doping and arranged within a surface layer of the first well, and a collector region having a p-type doping. The collector region is arranged at least partly within a surface layer of the third well and such that it overlaps both of the first well and the second well. An integrated circuit including a semiconductor device is also provided.Type: GrantFiled: December 28, 2017Date of Patent: September 24, 2019Assignee: IMEC vzwInventors: Mirko Scholz, Shih-Hung Chen
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Publication number: 20190206855Abstract: A semiconductor device for electric discharge protection is disclosed. In one aspect, the semiconductor device includes a substrate having a p-type doping. The semiconductor device includes a first well and a second well having an n-type doping and arranged spaced apart within a surface layer of the substrate, and a third well having a p-type doping and arranged in the surface layer of the substrate between the first well and the second well. The semiconductor device further includes an emitter region and a base contact region having a p-type doping and arranged within a surface layer of the first well, and a collector region having a p-type doping. The collector region is arranged at least partly within a surface layer of the third well and such that it overlaps both of the first well and the second well. An integrated circuit including a semiconductor device is also provided.Type: ApplicationFiled: December 28, 2017Publication date: July 4, 2019Inventors: Mirko Scholz, Shih-Hung Chen
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Patent number: 9847336Abstract: The disclosed technology relates to semiconductors, and more particularly to a junction field effect transistor (JFET). In one aspect, a method of fabricating a JFET includes forming a well of a first dopant type in a substrate, wherein the well is isolated from the substrate by an isolation region of a second dopant type. The method additionally includes implanting a dopant of the second dopant type at a surface of the well to form a source, a drain and a channel of the JFET, and implanting a dopant of the first dopant type at the surface of the well to form a gate of the JFET. The method additionally includes, prior to implanting the dopant of the first type and the dopant of the second type, forming a pre-metal dielectric (PMD) layer on the well and forming contact openings in the PMD layer above the source, the drain and the gate. The PMD layer has a thickness such that the channel is formed by implanting the dopant of the first type and the dopant of the second type through the PMD layer.Type: GrantFiled: August 24, 2016Date of Patent: December 19, 2017Assignee: IMEC vzwInventors: Geert Hellings, Geert Van der Plas, Mirko Scholz
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Publication number: 20170062431Abstract: The disclosed technology relates to semiconductors, and more particularly to a junction field effect transistor (JFET). In one aspect, a method of fabricating a JFET includes forming a well of a first dopant type in a substrate, wherein the well is isolated from the substrate by an isolation region of a second dopant type. The method additionally includes implanting a dopant of the second dopant type at a surface of the well to form a source, a drain and a channel of the JFET, and implanting a dopant of the first dopant type at the surface of the well to form a gate of the JFET. The method additionally includes, prior to implanting the dopant of the first type and the dopant of the second type, forming a pre-metal dielectric (PMD) layer on the well and forming contact openings in the PMD layer above the source, the drain and the gate. The PMD layer has a thickness such that the channel is formed by implanting the dopant of the first type and the dopant of the second type through the PMD layer.Type: ApplicationFiled: August 24, 2016Publication date: March 2, 2017Inventors: Geert Hellings, Geert Van der Plas, Mirko Scholz
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Patent number: 9263401Abstract: The disclosed technology relates to a semiconductor device comprising a diode junction between two semiconductor regions of different doping types. In one aspect, the diode comprises a junction formed between an upper portion of an active area and a remainder of the active area, where the active area is defined in a substrate between two field dielectric regions. The upper portion is a portion of the active area that has a width smaller than a width of the active area itself. In another aspect, the semiconductor device is an electrostatic discharge protection device (ESD) comprising such a diode. In addition, the active area has a doping profile that exhibits a maximum value at the surface of the active area, and changes to a minimum value at a first depth, where the first depth can be greater in value than half of a depth of the upper portion.Type: GrantFiled: October 29, 2013Date of Patent: February 16, 2016Assignee: IMECInventors: Geert Hellings, Mirko Scholz, Dimitri Linten
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Publication number: 20140124894Abstract: The disclosed technology relates to a semiconductor device comprising a diode junction between two semiconductor regions of different doping types. In one aspect, the diode comprises a junction formed between an upper portion of an active area and a remainder of the active area, where the active area is defined in a substrate between two field dielectric regions. The upper portion is a portion of the active area that has a width smaller than a width of the active area itself. In another aspect, the semiconductor device is an electrostatic discharge protection device (ESD) comprising such a diode. In addition, the active area has a doping profile that exhibits a maximum value at the surface of the active area, and changes to a minimum value at a first depth, where the first depth can be greater in value than half of a depth of the upper portion.Type: ApplicationFiled: October 29, 2013Publication date: May 8, 2014Applicant: IMECInventors: Geert Hellings, Mirko Scholz, Dimitri Linten
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Patent number: 7821272Abstract: The present disclosure relates to a method for calibrating transient behaviour of an electrostatic discharge (ESD) test system. The system includes an ESD pulse generator and probe needles for applying a predetermined pulse on a device under test. The probe needles are connected to the ESD pulse generator via conductors. The test system includes measurement equipment for detecting transient behaviour of the device under test by simultaneously capturing voltage and current waveforms the device as a result of the pulse. The method includes the steps of: (a) applying the ESD test system on a first known system with a first known impedance, (b) applying the ESD test system on a second known system with a known second impedance, and (c) determining calibration data for the transient behaviour the ESD test system on the basis of captured voltage and current waveforms, taking into account said known first and second impedances.Type: GrantFiled: March 19, 2008Date of Patent: October 26, 2010Assignee: IMECInventors: Mirko Scholz, David Eric Tremouilles, Steven Thijs, Dimitri Linten
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Publication number: 20090027063Abstract: The present disclosure relates to a method for calibrating transient behaviour of an electrostatic discharge (ESD) test system. The system includes an ESD pulse generator and probe needles for applying a predetermined pulse on a device under test. The probe needles are connected to the ESD pulse generator via conductors. The test system includes measurement equipment for detecting transient behaviour of the device under test by simultaneously capturing voltage and current waveforms the device as a result of the pulse. The method comprises the steps of: (a) applying the ESD test system on a first known system with a first known impedance, (b) applying the ESD test system on a second known system with a known second impedance, and (c) determining calibration data for the transient behaviour the ESD test system on the basis of captured voltage and current waveforms, taking into account said known first and second impedances.Type: ApplicationFiled: March 19, 2008Publication date: January 29, 2009Applicants: INTERUNIVERSITAIR MICROELEKTRONICA CENTRUM (IMEC), HANWA ELECTRONICS IND. CO., LTD.Inventors: Mirko Scholz, David Eric Tremouilles, Steven Thijs, Dimitri Linten