Abstract: A battery cell includes a first electrode, a second electrode, and a heat conducting member that is in thermal communication with the first electrode and the second electrode. The heat conducting member includes a thermally insulating portion and a thermally conducting portion that includes an individual thermal conductivity morphology.

Abstract: Methods, systems, and device for wirelessly charging a device. The inductive charging system includes a power source for providing an electrical charge that is wirelessly transferred or emitted to charge a first device. The inductive charging system includes a configurable grid that is configured to form a first inductive loop and multiple switches. Each switch is configured to open and close to electrically connect different portions of the configurable grid. The inductive charging system includes a processor connected to the multiple switches. The processor is configured to operate the multiple switches to open and close the portions of the configurable grid to form the first inductive loop that wirelessly transfers the electrical charge to the first device.

Abstract: Methods, systems, and devices for an external vehicle charging system. The external vehicle charging system includes a first set of inductive coils. The first set of inductive coils include a first inductive coil and a second inductive coil and are configured to provide an alternating magnetic field to one or more inductive loops of a vehicle. The external vehicle charging system includes a sensor configured to detect a position of the one or more inductive loops and a processor. The processor is configured to determine a first threshold distance between the first inductive coil and the second inductive coil to reduce or eliminate interference. The processor is configured to activate the first inductive coil and the second inductive coil so that the first inductive coil and the second inductive coil align with the one or more inductive loops based on the detected position and the first threshold distance.

Abstract: A method for fabricating a thermal composite includes pouring a mixture including a plurality of magnetically susceptible particles and a thermosetting polymer into a mold, placing the mold containing the mixture in a chamber including a plurality of magnet arrays, and heating the mold containing the mixture in the chamber for a time and at a temperature sufficient to cure the thermosetting polymer. At least one of the plurality of magnet arrays includes a Halbach array.

Abstract: Embodiments described herein generally relate to an assembly including a manifold structure. The manifold structure includes a fluid inlet and a fluid outlet. The fluid inlet is for receiving a cooling fluid into the manifold structure and the fluid outlet is for removing the cooling fluid from the manifold structure. The manifold structure also includes a first cooling surface and an opposite second cooling surface. The first cooling surface includes a cooling chip inlet opening fluidly coupled to a cooling chip outlet opening. The fluid inlet is fluidly coupled to the cooling chip inlet opening. The second cooling surface includes a cavity. A first integrated fluid channel fluidly couples the cooling chip outlet opening to the cavity and a second integrated fluid channel fluidly couples the cavity to the fluid outlet. A cooling chip includes a plurality of microchannels, which fluidly couple the cooling chip to the first cooling surface.

Abstract: A system includes a photophoretic display device including a trap light source and an illumination light source, an image converter including a light signal propagation director and a light signal sensor, and a control unit. The trap light source is configured to trap a scattering particle and the illumination light source is configured to illuminate the scattering particle that the trap light source is configured to trap such that the photophoretic display device generates a volumetric image. The light signal propagation director is configured to direct a visual signal of the volumetric image to the light signal sensor. The light signal sensor is configured to sense the visual signal and to generate a planar image signal based on the visual signal.

Abstract: A multilayer composite bonding material with a plurality of thermal stress compensation layers is provided. The plurality of thermal stress compensation layers include a metal core layer, a pair of particle layers extending across the metal core layer such that the metal core layer is sandwiched between the pair of particle layers, and a pair of metal outer layers extending across the pair of particle layers such that the pair of particle layers are sandwiched between the pair of metal outer layers. A pair of low melting point (LMP) bonding layers extend across the pair of metal outer layers. The metal core layer, the pair of particle layers, and the pair of metal outer layers each have a melting point above a transient liquid phase (TLP) sintering temperature, and the pair of LMP bonding layers each have a melting point below the TLP sintering temperature.

Abstract: A multi-layer cooling structure comprising a first substrate layer comprising an array of cooling channels, a second substrate layer comprising a nozzle structure that includes one or more nozzles, an outlet, and an outlet manifold, a third substrate layer comprising an inlet manifold and an inlet, and one or more TSVs disposed through the first substrate layer, second substrate layer, and third substrate layer. At least one of the one or more TSVs is metallized. The first substrate layer and the second substrate layer are directly bonded, and the second substrate layer and the third substrate layer are directly bonded.

Abstract: A system includes a photophoretic display device including a trap light source and an illumination light source, an image converter including a light signal propagation director and a light signal sensor, and a control unit. The trap light source is configured to trap a scattering particle and the illumination light source is configured to illuminate the scattering particle that the trap light source is configured to trap such that the photophoretic display device generates a volumetric image. The light signal propagation director is configured to direct a visual signal of the volumetric image to the light signal sensor. The light signal sensor is configured to sense the visual signal and to generate a planar image signal based on the visual signal.

Abstract: A system for optically cloaking an object includes a photophoretic optical trap display including a trap light source and an illumination light source; and a visual sensor at a first visual sensor location. The visual sensor captures an image of a scene, the trap light source is configured to generate a trap beam to control one or more of a position and an orientation of a scattering particle, and the illumination light source is configured to generate an illumination beam to illuminate the scattering particle to generate a reproduction image based on the image of the scene captured by the visual sensor.

Abstract: Systems and methods for modifying an infrared signature of a vehicle are provided. A method may include producing an aerosol cloud proximate the vehicle. The method may further include determining one or more characteristics of the aerosol cloud. The method may also include determining a projection plane within the aerosol cloud based on the aerosol cloud characteristics for projecting a representation of the object. The method may additionally include providing heat at particles in the projection plane of the aerosol cloud to generate the object representation.

Abstract: A battery cell includes a first electrode, a second electrode, and a heat conducting member that is in thermal communication with the first electrode and the second electrode.

Abstract: Embodiments described herein disclose a vapor chamber including a thermally-conductive evaporator wall, a thermally-conductive condenser wall and a volume therebetween defining a vapor core for transporting a vapor of a working fluid from the evaporator wall to the condenser wall. The outer surfaces of the evaporator wall and the condenser wall are configured to be in thermal contact with a plurality of heat sources and a heat sink respectively. The vapor chamber further includes a porous wick structure for holding and pumping the working fluid towards the plurality of heat sources. The wick structure comprises an evaporator-feeding wick having an inner surface in thermal contact with an inner surface of the evaporator wall. The evaporator-feeding wick comprises a first region having a higher permeability than at least a second region to form a permeability gradient, such that the working fluid has a uniform flow to the plurality of heat sources.

Abstract: A system for displaying data inside of a vehicle includes a main body including a substrate forming a display surface and defining a vehicle interior. The system also includes a plurality of lenticular lenses located on the display surface. The system also includes an eye tracker designed to detect a location of eyes of a person relative to the display surface. The system also includes a light source designed to generate light to produce an image via the plurality of lenticular lenses. The system also includes an electronic control unit (ECU) coupled to the eye tracker and the light source and designed to determine the location of the eyes relative to the display surface and to control the light source to center the image based on the location of the eyes relative to the display surface.

Abstract: A method includes collecting, via processing circuitry, a first set of multi-load data from a power control unit of a vehicle and usage data at a first servicing of the vehicle, computing, via the processing circuitry, a Mahalanobis Distance (MD) using the first set of multi-load data, defining, via the processing circuitry, a healthy state and an anomaly threshold based on the MD, correlating, via the processing circuitry, the first set of usage data to the anomaly threshold; generating, via the processing circuitry, a usage based servicing schedule for a vehicle; collecting, via the processing circuitry, a next set of multi-load data and usage data at a next servicing of the vehicle; updating, via the processing circuitry, the MD, a servicing schedule and evaluating the performance of the vehicle; determining, via the processing circuitry, whether the MD crosses the anomaly threshold; and transmitting, via a network, a servicing alert.

Abstract: A multi-layer cooling structure comprising a first substrate layer comprising an array of cooling channels, a second substrate layer comprising a nozzle structure that includes one or more nozzles, an outlet, and an outlet manifold, a third substrate layer comprising an inlet manifold and an inlet, and one or more TSVs disposed through the first substrate layer, second substrate layer, and third substrate layer. At least one of the one or more TSVs is metallized. The first substrate layer and the second substrate layer are directly bonded, and the second substrate layer and the third substrate layer are directly bonded.

Abstract: An electronics assembly includes a first cooling chip made of a semiconductor material, and at least one subassembly mounted on the first cooling chip. The first cooling chip includes at least one metallization layer on a portion of a first surface of the first cooling chip, at least one inlet through a second surface of the first cooling chip, wherein the second surface is opposite to the first surface, at least one outlet through the second surface of the first cooling chip, and one or more micro-channels extending between and fluidly coupled to the at least one inlet and the at least one outlet. The at least one subassembly includes one or more photonic cores positioned to receive light from a light source, wherein the one or more photonic cores comprise a wide band gap semiconductor material.

Abstract: Systems and methods for projecting images from a vehicle onto a dynamic projection surface within an aerosol are provided. A method may include performing an initial scan of the aerosol to determine a projection surface within the aerosol based upon an aerosol density map. The method may further include projecting an image onto the projection surface within the aerosol. The method may also include performing an updated scan to update the projection surface based on changing depth and changing distance of the projection surface relative to the scanning device over time. The method may additionally include modifying the image being projected based upon a change to the projection surface due to one or more of a motion of the vehicle and a change in the aerosol.

Abstract: Methods, systems, and devices for inductively charging a vehicle. The inductive charging system includes multiple inductive coils for receiving a wireless transferred power. The inductive charging system includes a power electronics circuit that converts the wireless transferred power to a DC current and one or more power storage devices for storing the electrical energy by charging the one or more power storage devices using the DC current. The inductive charging system includes one or more motors configured to move the vehicle using the electrical energy. The inductive charging system includes an electronic control unit that is configured to control at least one of an amount of the electrical energy that is stored in each of the one or more power storage devices or an amount of the electrical energy that is distributed to the one or more motors to move the vehicle.

Abstract: A system for displaying data inside of a vehicle includes a main body including a substrate forming a display surface and defining a vehicle interior. The system also includes a plurality of lenticular lenses located on the display surface. The system also includes an eye tracker designed to detect a location of eyes of a person relative to the display surface. The system also includes a light source designed to generate light to produce an image via the plurality of lenticular lenses. The system also includes an electronic control unit (ECU) coupled to the eye tracker and the light source and designed to determine the location of the eyes relative to the display surface and to control the light source to center the image based on the location of the eyes relative to the display surface.