A light ranging system including a shaft having a longitudinal axis; a light ranging device configured to rotate about the longitudinal axis of the shaft, the light ranging device including a light source configured to transmit light pulses to objects in a surrounding environment, and detector circuitry configured to detect reflected portions of the light pulses that are reflected from the objects in the surrounding environment and to compute ranging data based on the reflected portion of the light pulses; a base subsystem that does not rotate about the shaft; and an optical communications subsystem configured to provide an optical communications channel between the base subsystem and the light ranging device, the optical communications subsystem including one or more turret optical communication components connected to the detector circuitry and one or more base optical communication components connected to the base subsystem.

An electronic component has a support member, an SAW element which is mounted on the support member with a space S therebetween and which has a facing surface which faces the support member, and a resin portion which covers the SAW element and which is provided so as to seal the space S. The SAW element has a piezoelectric substrate, an IDT provided on the facing surface of the piezoelectric board, an wiring (an outer wiring) which is provided on the facing surface of the piezoelectric board and extends from the IDT toward the periphery side of the piezoelectric board, and a dam member which is adjacent to a lateral edge portion of the wiring and which is provided locally relative to the circumferential direction which surrounds the IDT.

A press-fit mounting peg (2) is described for retaining a component such as a stepped-motor on a circuit board (21). The mounting peg (2) is securable in a mounted position by a first axial displacement of a locking pin (17) along a pin channel (16) of the press-fit mounting peg (2) in a first axial direction along a longitudinal axis of the press-fit mounting peg (2) from a first axial position to a second axial position. The pin channel (16) comprises at least one pin displacement stop (13, 20) for stopping a second axial displacement of the locking pin (17) out of the second axial position.

A power conversion device comprises: a power conversion circuit that converts a supplied electric power; a current detection circuit that detects a current; a control circuit that controls an operation of the power conversion circuit; and a multilayer substrate that is provided with the power conversion circuit, the current detection circuit, and the control circuit. The multilayer substrate includes a printed wiring, and the printed wiring includes a transmission pattern that transmits a detection signal detected by the current detection circuit to the control circuit. An on-off fluctuation unit of the power conversion circuit fluctuates. The whole of the transmission pattern is disposed at a position different from the on-off fluctuation unit in a direction perpendicular to a plate surface of the multilayer substrate.

An electronic module includes a first supporting element, a second supporting element, and a plurality of components arranged on the first supporting element and the second supporting element. The first supporting element and the second supporting element are electrically conductively connected, and the second supporting element forms an intermediate chamber in which the first supporting element is arranged.

An electronic module (1) includes a first electronic submodule (2) and at least one further electronic submodule (3, 4). The first electronic submodule (2) and the at least one further electronic submodule (3, 4) are electrically conductively connected to each other with an electrical conductor (5, 6), which is reversibly deformable, at least in sections. The first electronic submodule (2), the at least one further electronic submodule (3, 4), and the electrical conductor (5, 6) are encased in a fluid-tight manner with a casing (15), which is reversibly deformable, at least in sections. An actuator device includes at least one mechanical module and the electronic module (1). A method for manufacturing such an actuator device is also provided.

An apparatus for an electronic power steering system includes a printed circuit board and a first sensor. The printed circuit board comprising: a first surface and a second surface opposite the first surface; a first processor section extending in a first direction on the first surface; a second processor section extending in a second direction opposite the first direction on the second surface; and a void disposed between the first surface and the second surface, the first processor section and the second processor section being separated by the void.

The present invention relates to a sensing device, a method of use of a sensing device and a method of manufacture of a sensing device. Embodiments are generally configured as sensor arrays for detecting a pressure change within an infusion line to pre-empt or detect line occlusions in the administration of medical infusions. Generally, embodiments comprise a support component having a support surface for mounting thereon one or more electrically connected switches, a length of expandable tubing for passing a fluid therethrough and are secured to the support surface and in physical contact with the electrically connected switches. The one or more electrically connected switches forms a sensor array adapted to sense expansion of the expandable tubing indicative of pressure changes resulting from line occlusions.

Disclosed is a robot including a variable length unit coupled to one section of at least one arm unit, wherein the variable length unit may include a motor, a first cam having at least one slit having a specific inclination in one area thereof, and a second cam, at least a portion of which is disposed in an interior of the first cam, and having at least one first boss that passes through the at least one slit of the first cam, wherein the first cam may be rotated through driving of the motor, the second cam may be linearly moved while the at least one first boss is guided by the at least one slit in correspondence to rotation of the first cam, and a length of the at least one arm unit may vary in correspondence to linear motion of the second cam.

An electronic apparatus includes a wiring board. The wiring board includes a wiring and a through-hole and is provided by dividing a multi-board providing board into the wiring board. The electronic apparatus further includes a circuit component having a surface mounting structure, mounted to the wiring board, and electrically connected to the wiring. A side wall of the wiring board has a cut portion that is provided when cutting and dividing the multi-board providing board. In the wiring board, the through-hole is formed adjacent to the cut portion without arranging the circuit component between the cut portion and the through-hole.