Abstract: A vehicle component includes a polymeric material, a first filler, and a second filler. The polymeric material can be present at a concentration of at least about 35% by weight of the vehicle component. The first filler can be a carbon-containing filler dispersed within the polymeric material. The carbon-containing filler can be present at a concentration of at least about 20% by weight of the vehicle component. The second filler includes a substrate and carbon nanotubes. The carbon nanotubes extend from a surface of the substrate.

Abstract: A vehicle component includes a polymeric material, a first filler, and a second filler. The polymeric material can be present at a concentration of at least about 35% by weight of the vehicle component. The first filler can be a carbon-containing filler dispersed within the polymeric material. The carbon-containing filler can be present at a concentration of at least about 20% by weight of the vehicle component. The second filler includes a substrate and carbon nanotubes. The carbon nanotubes extend from a surface of the substrate.

Abstract: A vehicle component includes a polymeric material, a first filler, and a second filler. The polymeric material can be present at a concentration of at least about 35% by weight of the vehicle component. The first filler can be a carbon-containing filler dispersed within the polymeric material. The carbon-containing filler can be present at a concentration of at least about 20% by weight of the vehicle component. The second filler includes a substrate and carbon nanotubes. The carbon nanotubes extend from a surface of the substrate.

Abstract: A method of forming a cross-car beam is provided. A composite is melted to form a viscous polymer. The polymer is injected into a mold. Pressurized fluid is injected into the mold to evacuate a portion of the viscous polymer from the mold and to form a channel therethrough. The remaining viscous polymer is cooled within the mold to form a cross-car beam.

Abstract: A method of forming a cross-car beam is provided. A composite is melted to form a viscous polymer. The polymer is injected into a mold. Pressurized fluid is injected into the mold to evacuate a portion of the viscous polymer from the mold and to form a channel therethrough. The remaining viscous polymer is cooled within the mold to form a cross-car beam.

Abstract: A method of forming a cross-car beam is provided. A composite is melted to form a viscous polymer. The polymer is injected into a mold. Pressurized fluid is injected into the mold to evacuate a portion of the viscous polymer from the mold and to form a channel therethrough. The remaining viscous polymer is cooled within the mold to form a cross-car beam.

Abstract: A blockage detection system and methods for use in a radar sensor such as a side object detection (SOD) sensor in an automotive radar system are described. The blockage detection system and method operate in systems including two or more radar sensors having overlapping field-of-views (FOVs). The blockage detection system includes a storage in a first radar sensor having stored therein a tracked object list including detections/tracks for one or more targets made by a second radar sensor and a processor for adjusting an overlap zone associated with the first radar sensor based upon an estimated mounting angle of the first radar sensor.

Abstract: An assembly includes a display screen, a bracket for receiving and holding the display screen, a deformable mounting feature and a frangible mounting feature. The deformable mounting feature is adapted to absorb initial energy in the event of an impact to the display screen. The frangible mounting feature is adapted to further dissipate energy to the extent that the impact energy exceeds the ability of the deformable mounting feature to absorb it.

Abstract: An assembly includes a display screen, a bracket for receiving and holding the display screen, a deformable mounting feature and a frangible mounting feature. The deformable mounting feature is adapted to absorb initial energy in the event of an impact to the display screen. The frangible mounting feature is adapted to further dissipate energy to the extent that the impact energy exceeds the ability of the deformable mounting feature to absorb it.

Abstract: A cross-car beam is provided herein. The cross-car beam includes a composite elongated panel extending across a vehicle. A bracket is operably coupled with an elongated panel. An attachment feature and a cowl attachment structure are each integrally formed with the bracket and are disposed at opposing end portions of the bracket.

Abstract: A method of forming a cross-car beam is provided. A composite is melted to form a viscous polymer. The polymer is injected into a mold. Pressurized fluid is injected into the mold to evacuate a portion of the viscous polymer from the mold and to form a channel therethrough. The remaining viscous polymer is cooled within the mold to form a cross-car beam.

Abstract: A cross-car beam is provided herein. The cross-car beam includes a composite elongated panel extending across a vehicle. A bracket is operably coupled with an elongated panel. An attachment feature and a cowl attachment structure are each integrally formed with the bracket and are disposed at opposing end portions of the bracket.

Abstract: A blockage detection system and methods for use in a radar sensor such as a side object detection (SOD) sensor in an automotive radar system are described. The blockage detection system and method operate in systems including two or more radar sensors having overlapping field-of-views (FOVs). The blockage detection system includes a storage in a first radar sensor having stored therein a tracked object list including detections/tracks for one or more targets made by a second radar sensor and a processor for adjusting an overlap zone associated with the first radar sensor based upon an estimated mounting angle of the first radar sensor.

Abstract: The invention provides a compact, high-frequency, transmit and receive millimeter-wave radar sensor device, system, and method of use. The sensor can operate at a variety of distances, speeds, and resolutions depending on the hardware components selected in a given implementation. The hardware and software architecture is generic and can be tailored to required applications.

Abstract: In some aspects, the disclosure is directed methods and systems for establishing a wideband radar system for imaging. A receiver of a radar imaging system may receive a set of phase measurements for each of a plurality of frequency bands, each of the plurality of frequency bands established by up-converting or down-converting a base frequency band. A phase adjuster of the radar imaging system may identify, from each region of overlap between consecutive frequency bands of the plurality of frequency bands, a phase difference between corresponding sets of the phase measurements. The phase adjuster may adjust one or more sets of the phase measurements based on the identified phase differences to generate an image across the plurality of frequency bands.

Abstract: The invention provides a compact, high-frequency, transmit and receive millimeter-wave radar sensor device, system, and method of use. The sensor can operate at a variety of distances, speeds, and resolutions depending on the hardware components selected in a given implementation. The hardware and software architecture is generic and can be tailored to required applications.

Abstract: A cross car beam for a vehicle having a molded base, a molded steering column structure attached to the forward side of the driver's side of the molded base, and a molded driver side structure attached to the rearward side of the driver's side of the molded base. One of the molded base, the molded steering column structure, and the molded driver side structure is composed of a polymer or a blend of polymers reinforced with fibers to provide strength. An optional tensile member such as a steel tube is attached to the molded base. The tensile member is composed of a metal or a reinforced polymerized material. One of the molded base, the molded steering column structure, and the molded driver side structure may include a class A surface. Alternatively or in addition a class A part may be attached to one of these structures.

Abstract: A cross car beam for a vehicle having a molded base, a molded steering column structure attached to the forward side of the driver's side of the molded base, and a molded driver side structure attached to the rearward side of the driver's side of the molded base. One of the molded base, the molded steering column structure, and the molded driver side structure is composed of a polymers or blends of polymers reinforced with fibers to provide strength. An optional tensile member such as a steel tube is attached to the molded base. The tensile member is composed of a metal or a reinforced polymerized material. One of the molded base, the molded steering column structure, and the molded driver side structure may include a class A surface. Alternatively or in addition a class A part may be attached to one of these structures.