Abstract: A method of controlling a trajectory of a perpendicular magnetization switching of a ferromagnetic layer using spin-orbit torques in the absence of any external magnetic field includes: injecting a charge current Je through a heavy-metal thin film disposed adjacent to a ferromagnetic layer to produce spin torques which drive a magnetization M out of an equilibrium state towards an in-plane of a nanomagnet; turning the charge current Je off after te seconds, where an effective field experienced by the magnetization of the ferromagnetic layer Heff is significantly dominated by and in-plane anisotropy Hkx, and where M passes a hard axis by precessing around the Heff; and passing the hard axis, where Heff is dominated by a perpendicular-to-the-plane anisotropy Hkz, and where M is pulled towards the new equilibrium state by precessing and damping around Heff, completing a magnetization switching.

Abstract: An adaptive current mirror circuit for current shaping with temperature is disclosed. The adaptive current mirror includes a current generator circuit configured to receive and input current and generate an output current using the input current and an overdrive voltage. The adaptive current mirror further includes a compensation circuit configured to adjust a value of the overdrive voltage based on temperature.

Abstract: Embodiments of the invention provide self-regulating heater cables having improved heat transfer efficiency as well as improved reliability and endurance. The heater cable assembly includes an outer sheath that surrounds a core. The outer sheath includes a conductive ground layer disposed between an inner jacket and outer jacket. The core includes first and second bus wires configured to carry electrical power and a self-regulating resistive heating element that extends along a path to electrically connect the first and second bus wires and convert electric current into thermal energy. The path can be defined by an electrically insulating material disposed in the core and/or the inner jacket.

Abstract: A method of controlling a trajectory of a perpendicular magnetization switching of a ferromagnetic layer using spin-orbit torques in the absence of any external magnetic field includes: injecting a charge current Je through a heavy-metal thin film disposed adjacent to a ferromagnetic layer to produce spin torques which drive a magnetization M out of an equilibrium state towards an in-plane of a nanomagnet; turning the charge current Je off after te seconds, where an effective field experienced by the magnetization of the ferromagnetic layer Heff is significantly dominated by and in-plane anisotropy Hkx, and where M passes a hard axis by precessing around the Heff; and passing the hard axis, where Heff is dominated by a perpendicular-to-the-plane anisotropy Hkz, and where M is pulled towards the new equilibrium state by precessing and damping around Heff, completing a magnetization switching.

Abstract: An adaptive current mirror circuit for current shaping with temperature is disclosed. The adaptive current mirror includes a current generator circuit configured to receive and input current and generate an output current using the input current and an overdrive voltage. The adaptive current mirror further includes a compensation circuit configured to adjust a value of the overdrive voltage based on temperature.

Abstract: A heater cable produces a substantially level voltage across its cross-section, providing a uniform and controllable thermal output along its length. The heater cable includes at least one center bus wire extending axially along a central axis of the heater cable, and at least one radial bus wire extending axially through the heating cable and positioned adjacent to the center bus wire. The heater cable further includes a thermally and electrically conductive interstitial material disposed around the at least one center bus wire and the at least one radial bus wire, and a jacket disposed about the interstitial material, the at least one center bus wire, and the at least one radial bus wire.

Abstract: A control system and methods for a digital circuit breaker are provided. The system comprises a digital circuit breaker, an electric trace heater electrically connected to the digital circuit breaker, a temperature sensor, and a controller device in communication with the digital circuit breaker and the electric trace heater. The controller device includes a processor in communication with the temperature sensor, and the processor is configured to receive a temperature value from the temperature sensor, construct a time-current curve for the digital circuit breaker based on the temperature value, and transmit data representative of the time-current curve to the digital circuit breaker.

Abstract: A method of controlling a trajectory of a perpendicular magnetization switching of a ferromagnetic layer using spin-orbit torques in the absence of any external magnetic field includes: injecting a charge current Je through a heavy-metal thin film disposed adjacent to a ferromagnetic layer to produce spin torques which drive a magnetization M out of an equilibrium state towards an in-plane of a nanomagnet; turning the charge current Je off after te seconds, where an effective field experienced by the magnetization of the ferromagnetic layer Heff is significantly dominated by and in-plane anisotropy Hkx, and where M passes a hard axis by precessing around the Heff; and passing the hard axis, where Heff is dominated by a perpendicular-to-the-plane anisotropy Hkz, and where M is pulled towards the new equilibrium state by precessing and damping around Heff, completing a magnetization switching.

Abstract: A base element for switching a magnetization state of a nanomagnet includes a heavy-metal nanostrip having a surface. A ferromagnetic nanomagnet is disposed adjacent to the surface. The ferromagnetic nanomagnet includes a shape having a long axis and a short axis. The ferromagnetic nanomagnet has both a perpendicular-to-the-plane anisotropy Hkz and an in-plane anisotropy Hkx and the ferromagnetic nanomagnet has a first magnetization equilibrium state and a second magnetization equilibrium state. The first magnetization equilibrium state or the second magnetization equilibrium state is settable by a flow of electrical charge through the heavy-metal nanostrip. A direction of flow of the electrical charge through the heavy-metal nanostrip includes an angle ? with respect to the short axis of the nanomagnet.

Abstract: A self-regulating heater cable includes a PTC core formed of positive temperature coefficient material and disposed in electrical contact with at least two bus wires. The PTC core may encapsulate the bus wires and space the bus wires apart a predetermined distance via a connecting portion of the PTC core. The connecting portion has a tapered profile, and is thinner at the ends approximate the bus wires and thicker in a portion between the ends, which portion may be toward or at the center of the connecting portion. The thicknesses of the ends and the thicker portion are selected to produce a ratio that is within a range at which the heater cable produces heat at its outer surface with a substantially uniform profile, and primary heat generation of the heater cable has not shifted from the center of the connecting portion to the ends of the connecting portion.

Abstract: A base element for switching a magnetization state of a nanomagnet includes a heavy-metal nanostrip having a surface. A ferromagnetic nanomagnet is disposed adjacent to the surface. The ferromagnetic nanomagnet includes a shape having a long axis and a short axis. The ferromagnetic nanomagnet has both a perpendicular-to-the-plane anisotropy Hkz and an in-plane anisotropy Hkx and the ferromagnetic nanomagnet has a first magnetization equilibrium state and a second magnetization equilibrium state. The first magnetization equilibrium state or the second magnetization equilibrium state is settable by a flow of electrical charge through the heavy-metal nanostrip. A direction of flow of the electrical charge through the heavy-metal nanostrip includes an angle ? with respect to the short axis of the nanomagnet.

Abstract: A magnetoresistive dynamic random access memory (MDRAM) cell is described. A hybrid memory cell includes a first transistor having a first source/drain electrode coupled to a charge storage node and a gate of a second transistor. A first transistor second source/drain electrode is coupled to a dynamic bit-line, and a gate of the first transistor coupled to a dynamic bit word-line. A resistive memory element is coupled between a select line and the second transistor first source/drain electrode. A third transistor includes a third transistor first source/drain electrode which is coupled to a second source/drain electrode of the second transistor. A third transistor second source/drain electrode is coupled to a nonvolatile bit-line. A gate of the third transistor is coupled to a nonvolatile bit word-line. A memory array of hybrid memory cells and a hybrid memory cell method is also described.

Abstract: A base element for switching a magnetization state of a nanomagnet includes a heavy-metal strip having a surface. A ferromagnetic nanomagnet is disposed adjacent to the surface. The ferromagnetic nanomagnet has a first magnetization equilibrium state and a second magnetization equilibrium state. The first magnetization equilibrium state or the second magnetization equilibrium state is settable in an absence of an external magnetic field by a flow of electrical charge through the heavy-metal strip. A method for switching a magnetization state of a nanomagnet is also described.

Abstract: A self-regulating heater cable includes a PTC core formed of positive temperature coefficient material and disposed in electrical contact with at least two bus wires. The PTC core may encapsulate the bus wires and space the bus wires apart a predetermined distance via a connecting portion of the PTC core. The connecting portion has a tapered profile, and is thinner at the ends approximate the bus wires and thicker in a portion between the ends, which portion may be toward or at the center of the connecting portion. The thicknesses of the ends and the thicker portion are selected to produce a ratio that is within a range at which the heater cable produces heat at its outer surface with a substantially uniform profile, and primary heat generation of the heater cable has not shifted from the center of the connecting portion to the ends of the connecting portion.

Abstract: A self-regulating electric heater cable includes a monolithic heater core of PTC material encapsulating a pair of bus wires, and a conductive layer disposed on an outer surface of the heater core such that the conductive layer levels the voltage generated at the outer surface of the heater core when an electric current is passed through the bus wires. The conductive layer draws the current evenly through lobes of PTC material encapsulating the bus wires. The conductive layer may be a coating, such as a conductive ink or paint, or may be an extruded or wrapped material applied to the heater core. Standard heater cable layers are applied over the conductive layer, including an electrically insulating layer that contacts a portion of the conductive layer and also may be separated, at points, from the conductive layer by one or more air gaps.

Abstract: An integrated logic device includes a channel having an interconnect section and a pair of spin-orbit segments connected to the interconnect section at either end of the interconnect section. A P structure includes a P magnet disposed on a surface of a spin-orbit segment. A tunneling barrier is disposed between the P magnet and a Rp magnetic reference layer. A Q structure includes a Q magnet disposed on a surface of the other spin-orbit segment. A tunneling barrier is disposed between the Q magnet and a Rq magnetic reference layer. A method of integrated logic spin-orbit perpendicular-anisotropy (SOPE) gate device operation is also described.

Abstract: A self-regulating heater cable includes a PTC core formed of positive temperature coefficient material and disposed in electrical contact with at least two bus wires. The PTC core may encapsulate the bus wires and space the bus wires apart a predetermined distance via a connecting portion of the PTC core. The connecting portion has a tapered profile, and is thinner at the ends approximate the bus wires and thicker in a portion between the ends, which portion may be toward or at the center of the connecting portion. The thicknesses of the ends and the thicker portion are selected to produce a ratio that is within a range at which the heater cable produces heat at its outer surface with a substantially uniform profile, and primary heat generation of the heater cable has not shifted from the center of the connecting portion to the ends of the connecting portion.

Abstract: A heater cable produces a substantially level voltage across its cross-section, providing a uniform and controllable thermal output along its length. The heater cable includes at least one center bus wire extending axially along a central axis of the heater cable, and at least one radial bus wire extending axially through the heating cable and positioned adjacent to the center bus wire. The heater cable further includes a thermally and electrically conductive interstitial material disposed around the at least one center bus wire and the at least one radial bus wire, and a jacket disposed about the interstitial material, the at least one center bus wire, and the at least one radial bus wire.

Abstract: Presented is a method and apparatus for solving. The method includes receiving, by a resistive memory array, a first data, the resistive memory array comprising a plurality of cells, wherein the receiving comprises setting a plurality of resistances on the plurality of cells, wherein each of the plurality of resistances are based on the first data. The method further includes receiving, by the resistive memory array, a second data, wherein the receiving comprises applying at least one of a current and a voltage based on the second data on the plurality of cells. The method still further includes determining, by the resistive memory array, an initial unknown value, the initial value based on the first data and the second data.

Abstract: An electric heating cable is provided with dual heaters, including first and second heating cables encased in at least one polymer jacket. The first heating cable generates thermal energy to heat an object in contact with the exterior surface of the dual-heater cable, and the second heating cable is positioned to pre-heat the first heating cable in order to reduce or eliminate inrush current in the first heating cable when the first heating cable is energized. The first heating cable can be a self-regulating heating cable, and can have a core of positive temperature coefficient (PTC) material encapsulating two bus wires. The second heating cable can be a constant-wattage heating cable disposed between the bus wires; the PTC material can form a channel in which the second heating cable is disposed. Control circuitry energizes the second heating cable for a pre-heating time before energizing the first heating cable.