A MEMS board assembly, a LiDAR system including the same, and a method for making the same are disclosed. The exemplary MEMS board assembly includes a MEMS board having a plurality of through holes and a mount having a plurality of threaded holes. The MEMS board assembly further includes a plurality of spring-loaded posts each formed by fitting a spring into a respective post. The plurality of spring-loaded posts are fitted into the plurality of threaded holes of the mount. The MEMS board assembly also includes a plurality of screws fitting the MEMS board to the mount by reaching into the plurality of threaded holes of the mount through the plurality of through holes in the MEMS board and the plurality of spring-loaded posts. The MEMS board touches the plurality of spring-loaded posts at the plurality of through holes in the MEMS board corresponding to the plurality of threaded holes of the mount respectively.

An information handling system may include a battery, a circuit board, an enclosure, and a control circuit. The circuit board may include at least one electric component, a first electrically conductive pad, and a second electrically conductive pad in proximity to the first electrically conductive pad. The enclosure may be configured to house components of the information handling system including the battery and the circuit board, and the enclosure may include a first member, a second member configured to be mechanically coupled to the first member, and a mechanical component comprising conductive material and configured to electrically short the first electrically conductive pad to the second electrically conductive pad when the first member is mechanically coupled to the second member, and cause electrical isolation of the first electrically conductive pad from the second electrically conductive pad when the first member is mechanically decoupled from the second member. The control circuit may be configured to, when the first electrically conductive pad is shorted to the second electrically conductive pad, cause the at least one electrical component to be electrically coupled to the battery and when the first electrically conductive pad is electrically isolated from the second electrically conductive pad, cause the at least one electrical component to be electrically decoupled from the battery.

The present disclosure relates to a spacer configured to space a first member apart from a second member, and the spacer includes a support component and a spacer component. The support component has a body, which has a support surface for the first member to be put on, and the support component further has a first hook element separated from the support surface by a first distance and a second hook element separated from the support surface by a second distance greater than the first distance. The spacer component is used to be placed between the first member and the second member and to space the first member apart from the second member, and the spacer component can be snap-fitted with the first hook element or the second hook element relational to the thickness of the first member. The present disclosure further relates to a connection system including the spacer for a base station antenna. The spacer is advantageous in cost, compact in structure, and easy to install.

Provided are a flexible flat cable and a method of producing the same. The flexible flat cable includes a plate-shaped first insulation portion comprising an insulating material; a first ground, a second ground, and a third ground disposed at predetermined intervals on the first insulation portion; at least one first signal transmission line positioned between the first ground and the second ground and disposed on the first insulation portion; at least one second signal transmission line positioned between the second ground and the third ground and disposed on the first insulation portion; a first second insulation portion disposed on at least a portion of the first ground and at least a portion of the at least one first signal transmission line and the second ground; a second second insulation portion disposed on at least a portion of the second ground and at least a portion of the at least one second signal transmission line, and the third ground; a conductive adhesive layer configured to enclose the first insulation portion, the first second insulation portion, and the second second insulation portion; and a shielding portion comprising a shielding material adhered to an outside of the conductive adhesive layer. Therefore, by improving shielding efficiency of a plurality of signal transmission lines, while having good electromagnetic interference and crosstalk characteristics, a plurality of signals can be simultaneously transmitted.

A wearable device (100) includes a body (1) and a detection electrode (21). The body (1) includes an electrocardiosignal collection circuit (11), and an inner electrode (12) and an outer electrode (13) that are electrically connected to the electrocardiosignal collection circuit (11). The inner electrode (12) is configured to collect an electric potential signal of a first wearing position (200), and the outer electrode (13) is configured to collect an electric potential signal of a non-wearing position (300). The detection electrode (21) can move relative to the body (1), and the detection electrode (21) is configured to electrically connect to the electrocardiosignal collection circuit (11) and collect an electric potential signal of a second wearing position (400). The non-wearing position (300) and the second wearing position (400) are different from the first wearing position (200). The wearable device (100) can measure electrocardiosignal data in time.

A screw boss assembly, including: a plastic substrate, including: a bottom surface including a first channel; an indented surface; a sidewall surface connecting the bottom surface and the indented surface, the sidewall surface including second channels, each of the second channels connected to the first channel; a metal insert, including: a first contacting member; second contacting member; connecting members connecting the first contacting member to the second contacting member; wherein the metal insert is coupled with the plastic substrate such that the first contacting member is positioned within the first channel and the connecting members are positioned within respective second channels.

A power module for operating an electric vehicle drive, comprising power switches for generating an output current based on an input current; control electronics for controlling the power switches including a first region, to which a first electric potential is applied, and a second region, to which a second electric potential is applied, wherein the second electric potential is higher than the first electric potential; a heatsink for discharging heat generated by the power switches and the control electronics; a shielding layer for electrically shielding the control electronics placed between the heatsink and the control electronics, such that the control electronics lies on the shielding layer, and the shielding layer lies on the heatsink; wherein the shielding layer is designed to connect the heatsink thermally and electrically to the first region, and thermally to the second region, and electrically insulate it therefrom.

A signal transmission circuit includes: a circuit board stored in a housing; a connector which is mounted on the circuit board and includes a first signal terminal and a first ground terminal; and an integrated circuit which is mounted on the circuit board and includes a second signal terminal and a second ground terminal. The first signal terminal and the second signal terminal are connected to each other by a signal wiring arranged on the circuit board. The first around terminal and the second ground terminal are connected to each other by a ground wiring arranged in a predetermined range including a portion immediately above or immediately below the signal wiring in the circuit board. At least a part of the ground wiring immediately above or immediately below the signal wiring has a high impedance structure formed to be wider than the signal wiring and narrower than a combined width of the first signal terminal and the first ground terminal.

Low-profile fasteners with springs that are either integrated with the fastener or are a physically separate component can provide a more evenly distributed load to a heat transfer device, such as a vapor chamber or a heat pipe. The low-profile fasteners do not increase the height of the base of a mobile computing device as the spring and the portion of the fastener that extends past the spring fit within a recess or cavity of the heat transfer device. The spring can be a diaphragm spring, a wave spring, or another suitable spring. The use of low-profile fasteners with springs to fasten a heat transfer device to a mainboard may allow for designs with a smaller mainboard area, which can leave room for a larger thermal management solution (which can increase cooling capacity) and allow for a greater thermal design power for the system.

Provided are a flexible flat cable and a method of producing the same. The flexible flat cable includes a plate-shaped first insulation portion comprising an insulating material; a first ground, a second ground, and a third ground disposed at predetermined intervals on the first insulation portion; at least one first signal transmission line positioned between the first ground and the second ground and disposed on the first insulation portion; at least one second signal transmission line positioned between the second ground and the third ground and disposed on the first insulation portion; a first second insulation portion disposed on at least a portion of the first ground and at least a portion of the at least one first signal transmission line and the second ground; a second insulation portion disposed on at least a portion of the second ground and at least a portion of the at least one second signal transmission line, and the third ground; a conductive adhesive layer configured to enclose the first insulation portion, the first second insulation portion, and the second insulation portion; and a shielding portion comprising a shielding material adhered to an outside of the conductive adhesive layer. Therefore, by improving shielding efficiency of a plurality of signal transmission lines, while having good electromagnetic interference and crosstalk characteristics, a plurality of signals can be simultaneously transmitted.