A sensor assembly comprising a holder body and a housed semiconductor sensor element situated on the holder body for rotational speed measurement and/or position measurement, a cured enveloping material that covers the housed semiconductor sensor element completely being situated on the holder body. It is provided that the housed semiconductor sensor element is glued onto a mounting surface of the holder body using an adhesive that differs from the enveloping material, and that the adhesive is situated in a receiving space between the mounting surface and a bottom side of the housed semiconductor sensor element that is facing the mounting surface.

A sensor assembly comprising a holder body and a housed semiconductor sensor element situated on the holder body for rotational speed measurement and/or position measurement, a cured enveloping material that covers the housed semiconductor sensor element completely being situated on the holder body. It is provided that the housed semiconductor sensor element is glued onto a mounting surface of the holder body using an adhesive that differs from the enveloping material, and that the adhesive is situated in a receiving space between the mounting surface and a bottom side of the housed semiconductor sensor element that is facing the mounting surface.

A reel assembly for an agricultural header includes a reel arm configured to couple to a frame of the agricultural header and configured to support a reel of the reel assembly. The reel assembly further includes a device mounting assembly movably coupled to the reel arm and configured to support a device that is configured to monitor a terrain feature. The device mounting assembly is configured to move between an extended position and a retracted position relative to the frame to move the device between a first position corresponding to the extended position of the device mounting assembly and a second position corresponding to the retracted position of the device mounting assembly. The device mounting assembly is configured to enable the device to monitor the terrain feature at the first position and the second position.

A reel assembly for an agricultural header including a reel arm configured to rotatably couple to a frame of the agricultural header and configured to support a reel of the reel assembly. The reel assembly further includes a device mounting assembly coupled to the reel arm and configured to support a device that is configured to monitor a terrain feature. The device mounting assembly is configured to maintain an orientation between the device and a ground on which the agricultural header is positioned as the reel arm rotates relative to the frame of the agricultural header.

A mobile sensory platform includes a propulsion system configured to move the platform within a growing area, a vertically-extending support, and sensors in or on the support. Different sensors are positioned at different heights along the support. The sensors are configured to capture data associated with plants in the growing area. The platform also includes a communication interface configured to support two-way wireless communication, a power supply, and a control system configured to control movement of the platform and operation of the sensors. The sensors include microclimate sensors configured to sense microclimates around individual ones of the plants and stereo imaging sensors configured to capture images of the plants. The sensors are configured to non-invasively capture multi-dimensional data points for the individual ones of the plants. At least some of the multi-dimensional data points are associated with a 3D structure of a canopy of the individual ones of the plants.

A mobile sensory platform includes a propulsion system configured to move the platform within a growing area, a vertically-extending support, and sensors in or on the support. Different sensors are positioned at different heights along the support. The sensors are configured to capture data associated with plants in the growing area. The platform also includes a communication interface configured to support two-way wireless communication, a power supply, and a control system configured to control movement of the platform and operation of the sensors. The sensors include microclimate sensors configured to sense microclimates around individual ones of the plants and stereo imaging sensors configured to capture images of the plants. The sensors are configured to non-invasively capture multi-dimensional data points for the individual ones of the plants. At least some of the multi-dimensional data points are associated with a 3D structure of a canopy of the individual ones of the plants.

A positioning device (10) for pivoting at least one relevant component (20) for a motor vehicle headlight about a first and a second axis (X, Y), comprising a holding element (100) for a relevant component (20), said holding element comprising a first sliding surface (110), which is designed as part of a spherical surface, a support frame (200), which comprises a second sliding surface (210), which is designed as part of a spherical surface, the holding element (100) being supported in the support frame (200) by means of a bearing apparatus such that the first sliding surface (110) of the holding element (100) can be displaced along the second sliding surface (210) of the support frame (200) about the first and second axis (X, Y), an adjusting apparatus (300), which has a positioning component (301) and a first moving apparatus (310) and a second moving apparatus (320), which are each arranged on the positioning component (301), which is mechanically connected to the holding element (100) by means of a connecting element (400), wherein the connecting element (400) passes through the support frame (200) via an opening (220), wherein the connecting element (400) is designed to transmit a movement of the positioning component (301) to the holding element (100), and wherein the connecting element is designed as a screw means, wherein the positioning component can be brought into a released state and a fastened state, wherein the positioning component can be displaced when in the released state, and the positioning component (301) can be clamped immovably against the support frame when in the fastened state by tightening the screw means.

A stand for receiving a portable test and measurement instrument includes a base plate, a first portion extending orthogonally from the generally flat base, the first portion including one or more holes spaced in a pattern through which one or more fasteners may attach the test and measurement instrument to the stand, and a second portion adjacent to and extending at an angle from the first portion, the second portion including one or more holes spaced in a pattern through which one or more fasteners may attach the test and measurement instrument to the stand.

A stand for receiving a portable test and measurement instrument includes a base plate, a first portion extending orthogonally from the generally flat base, the first portion including one or more holes spaced in a pattern through which one or more fasteners may attach the test and measurement instrument to the stand, and a second portion adjacent to and extending at an angle from the first portion, the second portion including one or more holes spaced in a pattern through which one or more fasteners may attach the test and measurement instrument to the stand.

Various designs for a stand for a laser projection device including feet capable of being used in indoor and outdoor environments and the leg retention devices to lock legs of the stand together are shown. In one example, the stand includes feet with a rotatable spike structure that can be implanted in soft environments outdoors and hidden to protect indoor flooring. In another example the stand includes a leg retention device including a clip to clamp or hold the legs of the stand together in a closed position. In another example, a leg retention device including detents are used to hold the legs of the stand together in a closed position.