Abstract: An apparatus, comprising: a substrate; a coupling capacitor that is formed over the substrate; and an isolator that is formed between the substrate and the coupling capacitor, the isolator including: (a) an MP-well layer, (b) a first well layer, (c) an epi tub layer that is nested in the MP-well layer and the first well layer, and (d) a second well layer that is nested in the epi tub layer.

Abstract: An electronic device having first and second terminals includes an electrical overstress (EOS) protection circuitry configured to detect an EOS event at one or both of the first and second terminals. The electronic device includes a power clamp coupled to the EOS protection circuitry and configured to clamp a voltage between the first terminal and the second terminal to a clamp voltage. The EOS protection circuitry can adjust the clamp voltage when an EOS event is detected.

Abstract: In one aspect, an integrated circuit includes a first conductive layer and a magnetoresistance element (MRE) disposed over and coupled to the first layer through first vias. The MRE is magnetized to produce a first magnetic orientation. The first layer is disposed over and coupled to a second conductive layer in the circuit through second vias. The circuit also includes a metal filler disposed proximate to the MRE. The metal filler is positioned over and coupled to the second layer through third vias. The circuit also includes a thermal dissipation path resulting from a physical input applied to the first MRE. The thermal dissipation path extends through the first through third vias, the first and second layers, an integrated circuit interconnection, and the metal filler.

Abstract: In one aspect an electronic device includes a substrate having one of a p-type doping or an n-type doping, a first well in the substrate, a second well in the substrate, a third well in the substrate between the first and second wells, a first terminal connected to the first well, a second terminal connected to the second well, an electrostatic discharge (ESD) clamp connected to the first and second terminals and a transient voltage source connected to the third well. A doping type of the first, second and third wells is the other one of the p-type or n-type doping. The ESD clamp is configured to clamp the first and second wells at a clamp voltage during an ESD event and the transient voltage source is configured to provide a voltage during the ESD event that is less than the clamp voltage.

Abstract: Methods and apparatus for a sensor with a main coil to direct a magnetic field at a rotating target for inducing eddy currents in an end of the target and a sensing element to detect a magnetic field reflected from the target, wherein the target end comprises a conductive surface. The reflected magnetic field can be processed to determine an angular position of the target.

Abstract: In one aspect an electronic device includes a substrate having one of a p-type doping or an n-type doping, a first well in the substrate, a second well in the substrate, a third well in the substrate between the first and second wells, a first terminal connected to the first well, a second terminal connected to the second well, an electrostatic discharge (ESD) clamp connected to the first and second terminals and a transient voltage source connected to the third well. A doping type of the first, second and third wells is the other one of the p-type or n-type doping. The ESD clamp is configured to clamp the first and second wells at a clamp voltage during an ESD event and the transient voltage source is configured to provide a voltage during the ESD event that is less than the clamp voltage.

Abstract: A magnetoresistance structure includes a base that includes a conductive layer and a first active element on and in direct contact with the conductive layer. The magnetoresistance structure also includes a pillar structure connected to the base. The pillar structure includes a first hard mask, a capping material, a second active element and a tunnel layer. The magnetoresistance structure also further includes an etching barrier deposited on the pillar and the base; a second hard mask deposited on the etching barrier; and a capping barrier deposited on the second hard mask and covering side walls of the base.

Abstract: A metal-oxide semiconductor (MOS) transistor structure is provided herein having one or more horizontal and/or one or more vertical MOS transistor structures formed around trench and liner isolation regions. The trench region serves as a gate electrode, while the liner is formed around the sidewalls of trench region and serves as a gate dielectric of a parasitic MOS within the transistor structure. The MOS transistor structure includes various doped regions formed around one or more portions of the trench and liner regions. The doped regions can have one or more different doping types such that in response to a voltage applied to the trench region, a channel region is formed in at least one of the doped regions and provides a current path within the MOS transistor between different doped regions.

Abstract: An apparatus including a magnetoresistance element having conductive contacts disposed between the magnetoresistance element and a semiconductor substrate.

Abstract: Methods for fabricating an integrated circuit having a plurality of gate dielectrics. The methods are provided to include: forming one or more isolation trenches and a first active region and a second active region in a substrate; depositing hard mask material on the substrate; removing a first portion of the hard mask material over the first active region; forming a first oxide layer having a first thickness over the first active region; removing a second portion of the hard mask material over the second active region; and forming a second oxide layer having a second thickness over the first and second active regions such that a thickness of oxide formed over the first active region comprises a sum of the thickness of the first oxide layer and the second oxide layer, and a thickness of oxide formed over the second active region comprises the second thickness.

Abstract: A manufacturing method results in a magnetoresistance element having conductive contacts disposed between the magnetoresistance element and a semiconductor substrate.

Abstract: Methods for fabricating an integrated circuit having a plurality of gate dielectrics. The methods are provided to include: forming one or more isolation trenches and a first active region and a second active region in a substrate; depositing hard mask material on the substrate; removing a first portion of the hard mask material over the first active region; forming a first oxide layer having a first thickness over the first active region; removing a second portion of the hard mask material over the second active region; and forming a second oxide layer having a second thickness over the first and second active regions such that a thickness of oxide formed over the first active region comprises a sum of the thickness of the first oxide layer and the second oxide layer, and a thickness of oxide formed over the second active region comprises the second thickness.

Abstract: A manufacturing method results in a magnetoresistance element having conductive contacts disposed between the magnetoresistance element and a semiconductor substrate.

Abstract: An electronic circuit includes a driver circuit having an output terminal that can be coupled to a load to drive the load. A control circuit is coupled to the driver circuit for controlling the driver circuit. A transistor is coupled in series between the driver circuit and the output terminal. The transistor has a first terminal coupled to the driver circuit and a second terminal coupled to the output terminal. A biasing circuit is coupled to a gate terminal of the transistor and configured to provide a constant voltage to the gate terminal to bias the transistor to a conducting state to reduce the susceptibility of the electronic circuit to electromagnetic interference. The biasing circuit includes a voltage regulator, a Zener diode, and a capacitor. The Zener diode and capacitor are coupled to the gate terminal and a reference terminal.

Abstract: A magnetoresistance structure includes a base that includes a conductive layer and a first active element on and in direct contact with the conductive layer. The magnetoresistance structure also includes a pillar structure connected to the base. The pillar structure includes a first hard mask, a capping material, a second active element and a tunnel layer. The magnetoresistance structure also further includes an etching barrier deposited on the pillar and the base; a second hard mask deposited on the etching barrier; and a capping barrier deposited on the second hard mask and covering side walls of the base.

Abstract: Methods and apparatus for a signal isolator having a dielectric interposer supporting first and second die each having a magnetic field sensing element. A first signal path extends from the first die to the second die and a second signal path extends from the second die to the first die. In embodiments, the first signal path is located in the interposer and includes a first coil to generate a magnetic field and the second signal path is located in the interposer and includes a second coil to generate a magnetic filed. The first coil is located in relation to the second magnetic field sensing element of the second die and the second coil is located in relation to the first magnetic field sensing element of the first die.

Abstract: An apparatus includes a first terminal, a second terminal, and a conduction path circuit coupled between the first and second terminals. The conduction path circuit includes an input terminal to receive an enable signal which, when activated, allows the conduction path circuit to conduct electrical current between the first and second terminal. A control circuit coupled to the input terminal of the conduction path circuit is configured to selectively activate the enable signal.

Abstract: An electronic device having first and second terminals includes an electrical overstress (EOS) protection circuitry configured to detect an EOS event at one or both of the first and second terminals. The electronic device includes a power clamp coupled to the EOS protection circuitry and configured to clamp a voltage between the first terminal and the second terminal to a clamp voltage. The EOS protection circuitry can adjust the clamp voltage when an EOS event is detected.

Abstract: A method includes depositing on a substrate a magnetoresistance stack, depositing a first hard mask on the magnetoresistance stack, depositing a first photoresist on the first hard mask, patterning the first photoresist to expose portions of the first hard mask, and etching the exposed portions of the first hard mask to expose a portion of the magnetoresistance stack. The method further includes stripping the first photoresist, etching the exposed portions of the magnetoresistance stack and the first hard mask to form a first intermediate structure having a base and a pillar structure, depositing an etch barrier on the first intermediate structure, and depositing a second hard mask on the etch barrier. A second photoresist is deposited on the second hard mask.

Abstract: A method includes depositing on a substrate a magnetoresistance stack, depositing a first hard mask on the magnetoresistance stack, depositing a first photoresist on the first hard mask, patterning the first photoresist to expose portions of the first hard mask, and etching the exposed portions of the first hard mask to expose a portion of the magnetoresistance stack. The method further includes stripping the first photoresist, etching the exposed portions of the magnetoresistance stack and the first hard mask to form a first intermediate structure having a base and a pillar structure, depositing an etch barrier on the first intermediate structure, and depositing a second hard mask on the etch barrier. A second photoresist is deposited on the second hard mask.