Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

A stripline radio-frequency (RF) connection interface is provided and includes first and second printed circuit boards (PCBs). The first PCB includes a first trace, ground planes at opposite sides of the first trace, dielectric material interposed between the first trace and the ground planes and a first end. The first end is formed as a first rabbet at which the first trace is exposed. The second PCB includes a second trace, ground planes at opposite sides of the second trace, dielectric material interposed between the second trace and the ground planes and a second end. The second end is formed as a second rabbet, which is substantially identical to the first rabbet, at which the second trace is exposed. The first and second ends are mated in a shiplap joint to electrically couple the first and second traces.

Various implementations include force elements for electronic devices. In some aspects, a force element includes: an outer ring surrounding a central axis and having a first diameter; an inner ring surrounding the central axis and having a second diameter that is smaller than the first diameter; an outer wall connecting a radially inner portion of the outer ring with a radially outer portion of the inner ring; an inner wall extending from a radially inner portion of the inner ring and located radially inboard of the outer wall; and a central platform extending from the inner wall around the central axis.

Heat transfer devices and systems for thermally coupling electrical components to a heatsink can comprise one or more all-metal heat transfer device(s) thermally coupling at least one electrical component to a heatsink. A heat transfer device can comprise a metal cup attached to a metal heatsink, and a metal piston and a compliant device disposed in the cup. The piston is forcible to a secured first position, upon reflowing solder, while compressing the compliant device. Upon reflowing solder again, the compliant device causes the piston to bias and attach to the electrical component to provide an all-metal thermal path and absorb assembly tolerances to avoid using thermal gap fillers. A method is provided for thermally coupling a heatsink to a plurality of electrical components via a plurality of all-metal, expandable heat transfer devices.

A lens driving device is provided, including a base, a holder, a first driving mechanism disposed on the first side of the base, a second driving mechanism disposed on the second side of the base opposite the first side, and a conductive member disposed on the base. The holder is configured to sustain a lens. The first driving mechanism is configured to force the holder to move along the optical axis of the lens. The second driving mechanism includes a circuit board assembly and a shape memory alloy (SMA) wire assembly configured to force the base to move in the plane perpendicular to the optical axis. The conductive member and the circuit board assembly are connected at an electrical connection point, and the SMA wire assembly is closer to the light-incident end of the lens with respect to the electrical connection point.

A circuit structure includes a signal substrate having a signal trace formed thereon and a microstrip substrate disposed above the signal substrate that includes a microstrip trace formed thereon and a hole passing through it. The circuit structure also includes a conductor passing through and substantially filling the hole passing through the microstrip substrate and electrically contacting the signal trace on the signal substrate and a flat wire connector electrically connecting the microstrip trace to a first end of the conductor, the flat wire connector being arranged such that a gap is formed between the flat wire connector and a top surface of the microstrip substrate.

A lens driving device is provided, including a base, a holder, a first driving mechanism disposed on the first side of the base, a second driving mechanism disposed on the second side of the base opposite the first side, and a conductive member disposed on the base. The holder is configured to sustain a lens. The first driving mechanism is configured to force the holder to move along the optical axis of the lens. The second driving mechanism includes a circuit board assembly and a shape memory alloy (SMA) wire assembly configured to force the base to move in the plane perpendicular to the optical axis. The conductive member and the circuit board assembly are connected at an electrical connection point, and the SMA wire assembly is closer to the light-incident end of the lens with respect to the electrical connection point.

Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

Tamper-respondent assemblies and fabrication methods are provided which incorporate enclosure-to-circuit board protection. The tamper-respondent assemblies include a circuit board, and an enclosure mounted to the circuit board along an enclosure-to-board interface. The enclosure facilitates enclosing at least one electronic component coupled to the circuit board within a secure volume. A tamper-respondent electronic circuit structure facilitates defining the secure volume, and includes one or more tamper-detect circuits including at least one conductive trace disposed, at least in part, within the enclosure-to-board interface. The conductive trace(s) includes stress rise regions to facilitate tamper-detection at the enclosure-to-board interface. An adhesive is provided to secure the enclosure to the circuit board. The adhesive contacts, at least in part, the conductive trace(s) of the tamper-detect circuit(s) at the enclosure-to-board interface, including at the stress rise regions of the conductive trace(s).

A power converter includes a housing including a convex radiator that radiates heat from a heater element and protrudes toward a board, in which the board and the heater element are arranged, and an urging member that is arranged between the board and a bottom surface of the housing and urges the heater element toward a first side surface of the convex radiator of the housing.