Abstract: Display assemblies for supporting displays on stands or support arms have mount portions to removably attach to the displays using magnetic assemblies and latches. The magnetic assemblies and latches can improve user experience and allow the display to be installed on a support arm from the viewing side of the display and without having to see or reach behind the display. Magnetic structures can center a mount portion of the support arm and a recess of the display and can attract them to each other. Laterally-extending latches can ensure the display is not inadvertently removed. Locking mechanisms can prevent the display from being rotated to a portrait orientation when sufficient space around the display and the necessary user intent is not provided.

Abstract: Display assemblies for supporting displays on stands or support arms have mount portions to removably attach to the displays using magnetic assemblies and latches. The magnetic assemblies and latches can improve user experience and allow the display to be installed on a support arm from the viewing side of the display and without having to see or reach behind the display. Magnetic structures can center a mount portion of the support arm and a recess of the display and can attract them to each other. Laterally-extending latches can ensure the display is not inadvertently removed. Locking mechanisms can prevent the display from being rotated to a portrait orientation when sufficient space around the display and the necessary user intent is not provided.

Abstract: Display assemblies for supporting displays on stands or support arms have mount portions to removably attach to the displays using magnetic assemblies and latches. The magnetic assemblies and latches can improve user experience and allow the display to be installed on a support arm from the viewing side of the display and without having to see or reach behind the display. Magnetic structures can center a mount portion of the support arm and a recess of the display and can attract them to each other. Laterally-extending latches can ensure the display is not inadvertently removed. Locking mechanisms can prevent the display from being rotated to a portrait orientation when sufficient space around the display and the necessary user intent is not provided.

Abstract: A aesthetically appealing mounting system for an electronic device capable of forming a semi-conductive path for electro-static discharge. The mounting system can include an electrically conductive layer covered by a cosmetic anodized layer with multiple micro-perforations formed through the anodized layer exposing a small portion of the electrically conductive layer. The micro-perforations can be formed by laser-etching the cosmetic anodized layer to provide a grounding path while the micro-perforations remain visually undetectable. A semi-conductive wear layer can be configured to couple with the anodized layer. In some embodiments, the semi-conductive wear layer is in a recess on an electronic device. In some embodiments, the semi-conductive wear layer is comprised of a conformal conductive rubber.

Abstract: A aesthetically appealing mounting system for an electronic device capable of forming a semi-conductive path for electro-static discharge. The mounting system can include an electrically conductive layer covered by a cosmetic anodized layer with multiple micro-perforations formed through the anodized layer exposing a small portion of the electrically conductive layer. The micro-perforations can be formed by laser-etching the cosmetic anodized layer to provide a grounding path while the micro-perforations remain visually undetectable. A semi-conductive wear layer can be configured to couple with the anodized layer. In some embodiments, the semi-conductive wear layer is in a recess on an electronic device. In some embodiments, the semi-conductive wear layer is comprised of a conformal conductive rubber.

Abstract: Display assemblies for supporting displays on stands or support arms have mount portions to removably attach to the displays using magnetic assemblies and latches. The magnetic assemblies and latches can improve user experience and allow the display to be installed on a support arm from the viewing side of the display and without having to see or reach behind the display. Magnetic structures can center a mount portion of the support arm and a recess of the display and can attract them to each other. Laterally-extending latches can ensure the display is not inadvertently removed. Locking mechanisms can prevent the display from being rotated to a portrait orientation when sufficient space around the display and the necessary user intent is not provided.

Abstract: An electronic device may be provided with a microphone in a microphone port. A shield may cover a microelectromechanical systems microphone device on a microphone substrate. An opening in the microphone substrate may form a sound port for the microphone. The microphone port may be formed by perforations in the microphone substrate or other layers such as a flexible printed circuit layer, a sheet metal layer, a layer of adhesive, a flexible polymer carrier layer in an adhesive tape, or an electronic device housing. The perforations may be sufficiently small to help resist the intrusions of foreign material such as liquid and dirt into the sound port of the microphone. Larger openings may be formed in other structures such as an electronic device housing. The larger openings may serve as sound passageways for the microphone port while being sufficiently large to resist clogging.

Abstract: Electronic devices may be provided with conductive structures such as displays and conductive housing walls. Conductive gaskets may be used to form electrical paths between opposing conductive structures in an electronic device. During device assembly, a conductive gasket may be compressed between opposing conductive structures. The conductive gasket may be formed from a conductive gasket wall structure. The conductive gasket wall structure may surround and at least partly enclose an air-filled cavity. Conductive gasket wall structures may be formed from conductive fabric, dielectric sheets coated with metal, or other conductive wall materials. The interior of a conductive gasket may be hollow and completely devoid of supporting structures or may contain internal structures for biasing the conductive gasket wall outwards. Planar gaskets and gaskets with other cross sections may be provided.

Abstract: An electronic device may be provided with a microphone in a microphone port. A shield may cover a microelectromechanical systems microphone device on a microphone substrate. An opening in the microphone substrate may form a sound port for the microphone. The microphone port may be formed by perforations in the microphone substrate or other layers such as a flexible printed circuit layer, a sheet metal layer, a layer of adhesive, a flexible polymer carrier layer in an adhesive tape, or an electronic device housing. The perforations may be sufficiently small to help resist the intrusions of foreign material such as liquid and dirt into the sound port of the microphone. Larger openings may be formed in other structures such as an electronic device housing. The larger openings may serve as sound passageways for the microphone port while being sufficiently large to resist clogging.

Abstract: A flexible printed circuit may be laminated to a metal stiffener. The stiffener may be bent to hold the flexible printed circuit in a desired position. Openings may be formed in the stiffener. Metal traces on the flexible printed circuit may be accessed through the openings. Test points in the metal traces may be accessed through the openings or components may be mounted to the metal traces on the flexible printed circuit through the openings. The stiffener may have bends. The bends may be used to shape the stiffener and flexible printed circuit to form an enclosure. The openings in the stiffener may overlap the bends or may be located away from the bends. Flexible printed circuits mounted on bent stiffeners may be used to form elongated tubes with planar sides.

Abstract: A flexible printed circuit may be laminated to a metal stiffener. The stiffener may be bent to hold the flexible printed circuit in a desired position. Openings may be formed in the stiffener. Metal traces on the flexible printed circuit may be accessed through the openings. Test points in the metal traces may be accessed through the openings or components may be mounted to the metal traces on the flexible printed circuit through the openings. The stiffener may have bends. The bends may be used to shape the stiffener and flexible printed circuit to form an enclosure. The openings in the stiffener may overlap the bends or may be located away from the bends. Flexible printed circuits mounted on bent stiffeners may be used to form elongated tubes with planar sides.

Abstract: Electronic devices may be provided with conductive structures such as displays and conductive housing walls. Conductive gaskets may be used to form electrical paths between opposing conductive structures in an electronic device. During device assembly, a conductive gasket may be compressed between opposing conductive structures. The conductive gasket may be formed from a conductive gasket wall structure. The conductive gasket wall structure may surround and at least partly enclose an air-filled cavity. Conductive gasket wall structures may be formed from conductive fabric, dielectric sheets coated with metal, or other conductive wall materials. The interior of a conductive gasket may be hollow and completely devoid of supporting structures or may contain internal structures for biasing the conductive gasket wall outwards. Planar gaskets and gaskets with other cross sections may be provided.

Abstract: Electronic devices may be provided with conductive structures such as displays and conductive housing walls. Conductive gaskets may be used to form electrical paths between opposing conductive structures in an electronic device. The conductive gaskets may be formed from conductive sheets of material such as conductive fabric sheets. The conductive fabric or other conductive sheets may form conductive gasket wall structures that extend around air-filled cavities in the conductive gaskets. A conductive gasket may have an elongated shape such as a tubular shape that is characterized by a longitudinal axis. The longitudinal axis may follow a straight path or a curved path. To facilitate bending of a hollow conductive gasket to follow a curved path, the wall structures of the gasket may be provided with openings. Cables may be held in place using flaps of gasket wall material and may run through interior portions of a hollow gasket.