Abstract: This document describes techniques, apparatuses, and systems utilizing a high-isolation transition design for differential signal ports. A differential input transition structure includes a first layer and a second layer made of a conductive metal and a substrate positioned between the first and second layers. The second layer includes a first section that electrically connects to a single-ended signal contact point and to a first contact point of a differential signal port. The first section includes a first stub based on an input impedance of the single-ended signal contact point and a second stub based on a differential input impedance associated with the differential signal port. The second layer includes a second section that electrically connects to a second contact point of the differential signal port and to the first layer through a via housed in a pad. The second section includes a third stub associated with the differential input impedance.

Abstract: The techniques of this disclosure relate to determining an optical characteristic of a camera. The device includes a housing that receives a test fixture retaining a camera. The housing includes a first segment and a second segment creating a chamber surrounding the camera. The first segment is attached to the test fixture and defines a first orifice located in a side of the first segment. The first orifice directs a flow of a gas out of the chamber. The second segment defines a second orifice located in a first side of the second segment to direct the flow of the gas into the chamber. An aperture is located in a second side of the second segment and positioned opposite the test fixture to define a field of view that includes a camera target. The aperture receives a lens barrel of the camera and enables the determination of the optical characteristic.

Abstract: This document describes techniques, apparatuses, and systems of a metal antenna assembly with integrated features. The described antenna assembly comprises an antenna structure including an antenna body having at least one antenna element formed from a metal alloy while in a thixotropic state. The antenna structure includes a surface having a corrosion inhibitor coating. The antenna assembly further includes an air-waveguide structure. In implementations, the antenna structure is configured to attach to a mounting. The antenna structure includes at least one integrated alignment feature promoting alignment during manufacturing of the antenna assembly. The antenna structure further includes an internal portion in the antenna body defining an integrated heatsink portion and an integrated electromagnetic interference portion within which circuit components can reside.

Abstract: This document describes techniques, apparatuses, and systems utilizing a high-isolation transition design for differential signal ports. A differential input transition structure includes a first layer and a second layer made of a conductive metal and a substrate positioned between the first and second layers. The second layer includes a first section that electrically connects to a single-ended signal contact point and to a first contact point of a differential signal port. The first section includes a first stub based on an input impedance of the single-ended signal contact point and a second stub based on a differential input impedance associated with the differential signal port. The second layer includes a second section that electrically connects to a second contact point of the differential signal port and to the first layer through a via housed in a pad. The second section includes a third stub associated with the differential input impedance.

Abstract: The techniques of this disclosure relate to determining an optical characteristic of a camera. The device includes a housing that receives a test fixture retaining a camera. The housing includes a first segment and a second segment creating a chamber surrounding the camera. The first segment is attached to the test fixture and defines a first orifice located in a side of the first segment. The first orifice directs a flow of a gas out of the chamber. The second segment defines a second orifice located in a first side of the second segment to direct the flow of the gas into the chamber. An aperture is located in a second side of the second segment and positioned opposite the test fixture to define a field of view that includes a camera target. The aperture receives a lens barrel of the camera and enables the determination of the optical characteristic.

Abstract: This document describes techniques, apparatuses, and systems utilizing a high-isolation transition design for differential signal ports. A differential input transition structure includes a first layer and a second layer made of a conductive metal and a substrate positioned between the first and second layers. The second layer includes a first section that electrically connects to a single-ended signal contact point and to a first contact point of a differential signal port. The first section includes a first stub based on an input impedance of the single-ended signal contact point and a second stub based on a differential input impedance associated with the differential signal port. The second layer includes a second section that electrically connects to a second contact point of the differential signal port and to the first layer through a via housed in a pad. The second section includes a third stub associated with the differential input impedance.

Abstract: This document describes techniques, apparatuses, and systems utilizing a high-isolation transition design for differential signal ports. A differential input transition structure includes a first layer and a second layer made of a conductive metal and a substrate positioned between the first and second layers. The second layer includes a first section that electrically connects to a single-ended signal contact point and to a first contact point of a differential signal port. The first section includes a first stub based on an input impedance of the single-ended signal contact point and a second stub based on a differential input impedance associated with the differential signal port. The second layer includes a second section that electrically connects to a second contact point of the differential signal port and to the first layer through a via housed in a pad. The second section includes a third stub associated with the differential input impedance.

Abstract: The techniques of this disclosure relate to determining an optical characteristic of a camera. The device includes a housing that receives a test fixture retaining a camera. The housing includes a first segment and a second segment creating a chamber surrounding the camera. The first segment is attached to the test fixture and defines a first orifice located in a side of the first segment. The first orifice directs a flow of a gas out of the chamber. The second segment defines a second orifice located in a first side of the second segment to direct the flow of the gas into the chamber. An aperture is located in a second side of the second segment and positioned opposite the test fixture to define a field of view that includes a camera target. The aperture receives a lens barrel of the camera and enables the determination of the optical characteristic.

Abstract: An illustrative example detector for use on a vehicle includes a radiation emitter having a near field region that is defined at least in part by a wavelength of radiation emitted by the radiation emitter. A radiation steering device includes a plurality of reflectors, an actuator, and a controller. The reflectors are situated to reflect the radiation emitted by the radiation emitter. The reflectors are in the near field region and have at least one characteristic that limits any phase shift of the reflected radiation. The actuator is configured to adjust an orientation of the reflectors. The controller is configured to determine an orientation of the plurality of reflectors relative to the radiation emitter to steer the emitted radiation reflected from the reflectors in a determined direction. The controller is configured to control the actuator to achieve the determined orientation.

Abstract: An illustrative example detector for use on a vehicle includes a radiation emitter having a near field region that is defined at least in part by a wavelength of radiation emitted by the radiation emitter. A radiation steering device includes a plurality of reflectors, an actuator, and a controller. The reflectors are situated to reflect the radiation emitted by the radiation emitter. The reflectors are in the near field region and have at least one characteristic that limits any phase shift of the reflected radiation. The actuator is configured to adjust an orientation of the reflectors. The controller is configured to determine an orientation of the plurality of reflectors relative to the radiation emitter to steer the emitted radiation reflected from the reflectors in a determined direction. The controller is configured to control the actuator to achieve the determined orientation.

Abstract: An imaging system is configured to refractively shift light from a field of view about a vehicle to an image sensing device. The field of view is directed through a vehicle window characterized as having a substantial rake angle. The imaging system includes a first refractive element configured to be optically coupled with the vehicle window. Light impinging on a first surface of the first refractive element along the field of view axis passes through the first refractive element and exits a second surface along an intermediate axis. The imaging system includes a second refractive element in optical communication with an image sensing device. Light impinging on a third surface of the second refractive element along the intermediate axis passes through the second refractive element and exits a fourth surface along an image sensing device axis, whereby light from the field of view is directed into the image sensing device.

Abstract: A vehicle vision system displays a vehicle pathway image that includes a reticle for visually identifying the in-path portion of the image. A reticle array is disposed between a video camera chip and a lens, and includes a conical or frustro-conical region of substantially un-attenuated light transmissivity surrounded by a region of perceptibly attenuated light transmissivity, such that in-path portions of the displayed image are substantially unchanged and out-of-path portions of the displayed image are perceptibly attenuated. The reticle array may also include a number of reduced transmissivity lines traversing its conical or frustro-conical region to produce a series of receding stadia lines in the in-path portion of the displayed image, enabling the driver to reliably discern the range of displayed objects.