Abstract: A multiple antenna feed assembly including an antenna feed support having a body made of an electrically insulating material and a method of forming the antenna feed assembly. The antenna feed support may have a slot adapted to receive a connector; and a gap formed in the body having a thickness to fit a printed circuit board (PCB). The multiple antenna feed assembly may include a first connector adapted to fit in the slot of the antenna feed support; and a second connector electrically isolated from the first connector. Also provided is an antenna feed support to provide structural support and electrical isolation for the components of a multiple antenna feed assembly as above.

Abstract: The described embodiments relate generally to electronic devices and to three dimensional modules for increasing useable space on a circuit board associated therewith. In some embodiments, the modules can have a cuboid geometry, and can include a number of surfaces having embedded circuit traces configured to interconnect electronic components arranged on various surfaces of the module. One of the surfaces of module can include at least one communication interface configured to interconnect the circuit traces on the module to associated circuit paths on a circuit board to which the module is coupled. In some embodiments the module can be operative as a standoff between the circuit board and another component of the electronic device.

Abstract: This application relates to securing and positioning internal components within a housing of a portable computing device. In one embodiment, a number of insert molded retaining members are utilized to inhibit outward deformation of a sidewall of the housing during a drop event. In another embodiment, a cowling is utilized to retain a number of board-to-board connectors within communication slots on a printed circuit board (PCB). In another embodiment, a C-shaped washer having diametrically opposed protrusions is utilized to adjust an alignment of an internal component.

Abstract: An electronic device may be provided with a touch screen display. The touch screen display may have an array of display pixels that are used to display images for a user. Touch input to the touch screen display may be provided by a user's finger or other external object. A touch sensor in the display may have vertical and horizontal position sensors that are based on distinct touch sensor technologies. The position sensors may be based on strain gauge sensors or other force sensors, capacitive sensors having multiple elongated transparent capacitive electrodes that span the display, acoustic sensors, light-based sensors, and other types of sensors. An opaque masking layer in an inactive area of the display may hide some of the position sensor structures from view such as vertical position sensor structures. The horizontal position sensor structures may have minimal inactive regions along their edges.

Abstract: Electronic devices may be provided that include mechanical and electronic components. Connectors may be used to interconnect printed circuits and devices mounted to printed circuits. Printed circuits may include rigid printed circuit boards and flexible printed circuit boards. Heat sinks and other thermally conductive structures may be used to remove excess component heat. Structures may also be provided in an electronic device to detect moisture. Integrated circuits and other circuitry may be mounted on a printed circuit board under a radio-frequency shielding can.

Abstract: A method of forming a part includes uni-directionally injecting a mold with material to form a molded part, removing the molded part from the mold, and forming at least one cavity in the molded part, the at least one cavity being defined by a machining process separate from a molding process.

Abstract: This application relates to securing and positioning internal components within a housing of a portable computing device. In one embodiment, a number of insert molded retaining members are utilized to inhibit outward deformation of a sidewall of the housing during a drop event. In another embodiment, a cowling is utilized to retain a number of board-to-board connectors within communication slots on a printed circuit board (PCB). In another embodiment, a C-shaped washer having diametrically opposed protrusions is utilized to adjust an alignment of an internal component.

Abstract: An electronic device with seamless protective cover glass is disclosed. In the described embodiments, the cover glass is coupled to the housing such that the cover glass or portions of the cover glass move with respect to the housing. This movement can be used as an interface for receiving user inputs that can be used to provide control signals to the electronic device.

Abstract: The subject matter of the disclosure relates to connectors for antenna feed assemblies and display coupling components of a mobile device. The flexible connectors can be configured with a flexible spring connector component that couples a mobile device antenna to a main logic board of the mobile device within a housing of the mobile device such that the flexible connector can withstand a drop event, while at the same providing for an in-line inductance as part of an antenna-defined design requirement. The display of the mobile device can be coupled to a housing of the mobile device using a pin-screw arrangement that allows the display to controllably shift in the X-direction and the Y-direction, while only being purposefully constrained in the Z-direction (with reference to a 3-dimensional graph having X, Y, and Z axes). This configuration can prevent the display from being pulled out of alignment during a drop event.

Abstract: The subject matter of the disclosure relates to connectors for antenna feed assemblies and display coupling components of a mobile device. The flexible connectors can be configured with a flexible spring connector component that couples a mobile device antenna to a main logic board of the mobile device within a housing of the mobile device such that the flexible connector can withstand a drop event, while at the same providing for an in-line inductance as part of an antenna-defined design requirement. The display of the mobile device can be coupled to a housing of the mobile device using a pin-screw arrangement that allows the display to controllably shift in the X-direction and the Y-direction, while only being purposefully constrained in the Z-direction (with reference to a 3-dimensional graph having X, Y, and Z axes). This configuration can prevent the display from being pulled out of alignment during a drop event.

Abstract: Several embodiments for ejecting a SIM tray from an electronic device are disclosed. In some embodiments, a lever positioned behind the tray can be actuated to eject the tray. In some embodiments, a pivot mechanism can be actuated to eject the tray. In other embodiments, a gear mechanism can be actuated to eject the tray. In other embodiments, a spring element can be actuated to eject the tray. In some embodiments, the electronic device may include a key feature that allows the tray to eject only when a tool is used having a mating key feature with the key feature of the electronic device.

Abstract: An electronic device may have a printed circuit to which electrical components are mounted. The electrical components may include a thermal sensor and a pressure sensor. A through hole in the printed circuit may receive the shaft of a standoff The standoff may be soldered to plated metal on the sides of the through hole. A screw or other fastener may secure the printed circuit to a housing for the electronic device. A ring-shaped metal member may be soldered to the printed circuit. The ring-shaped metal member may form a bumper that surrounds the screw or other fastener and the thermal sensor. The pressure sensor may have a port through which ambient pressure measurements are made. A dust protection cover such as a fabric or other porous layer may cover the port.

Abstract: An electronic device may have a printed circuit to which electrical components are mounted. Electromagnetic shields may be mounted to the printed circuit over the components to suppress interference. A shield may have a metal frame covered with a conductive fabric. The conductive fabric may cover an opening in the top of the frame. An insulating layer may be formed on the lower surface of the conductive fabric to prevent shorts between components on the printed circuit and the conductive fabric. An insulating cap such as an elastomeric polymer cap may also be formed over each component to provide electrical isolation between the components and the conductive fabric. Shields may be formed by coupling shield cans to subscriber identity module shields or other metal structures in a device. Intervening wall structures may be removed to help provide additional shielding volume.

Abstract: The subject matter of the disclosure relates to connectors for antenna feed assemblies and display coupling components of a mobile device. The flexible connectors can be configured with a flexible spring connector component that couples a mobile device antenna to a main logic board of the mobile device within a housing of the mobile device such that the flexible connector can withstand a drop event, while at the same providing for an in-line inductance as part of an antenna-defined design requirement. The display of the mobile device can be coupled to a housing of the mobile device using a pin-screw arrangement that allows the display to controllably shift in the X-direction and the Y-direction, while only being purposefully constrained in the Z-direction (with reference to a 3-dimensional graph having X, Y, and Z axes). This configuration can prevent the display from being pulled out of alignment during a drop event.

Abstract: An electronic device may have electrical components mounted on substrates such as printed circuits. The electrical components may include magnetic components such as inductors. A metal shielding can may be provided with a magnetic shielding layer to shield the magnetic components. The magnetic shielding layer may be formed on an inner surface of the metal shielding can. The magnetic shielding layer may include a ferromagnetic layer that is attached to the inner surface by a layer of adhesive. An insulating coating may be formed on the lower surface of the ferromagnetic layer to prevent shorts. An insulating layer for the lower surface of the ferromagnetic layer may be formed form a layer of polymer that is attached to the ferromagnetic layer with adhesive. The shielding can with magnetic shielding may withstand solder reflow temperatures, allowing the shielding can to be soldered to a printed circuit to shield an electrical component.

Abstract: This application relates to securing and positioning internal components within a housing of a portable computing device. In one embodiment a cowling is utilized to retain a number of board-to-board connectors within communication slots on a printed circuit board (PCB). In another embodiment a number of insert molded retaining members are utilized to prevent outward deformation of sidewalls of the portable computing device during a drop event. In another embodiment, a C-shaped washer having diametrically opposed protrusions is utilized to adjust an alignment of an internal component.

Abstract: This application relates to securing and positioning internal components within a housing of a portable computing device. In one embodiment, a number of insert molded retaining members are utilized to inhibit outward deformation of a sidewall of the housing during a drop event. In another embodiment, a cowling is utilized to retain a number of board-to-board connectors within communication slots on a printed circuit board (PCB). In another embodiment, a C-shaped washer having diametrically opposed protrusions is utilized to adjust an alignment of an internal component.

Abstract: Adjustable antenna structures may be used to compensate for manufacturing variations in electronic device antennas. An electronic device antenna may have an antenna feed and conductive structures such as portions of a peripheral conductive electronic device housing member and other conductive antenna structures. The adjustable antenna structures may have a movable dielectric support. Multiple conductive paths may be formed on the dielectric support. The movable dielectric support may be installed within an electronic device housing so that a selected one of the multiple conductive paths is coupled into use to convey antenna signals. Coupling the selected path into use adjusts the position of an antenna feed terminal for the antenna feed and compensates for manufacturing variations in the conductive antenna structures that could potentially lead to undesired variations in antenna performance.

Abstract: Board-to-board connectors that consume a minimal amount of board area, are simple to assemble, and provide a clear indication that a proper connection has been made. One example may consume minimal area, since only a retention key and slots in boards and connectors are needed. The connector may be simple to assemble since it may be as simple as stacking components, pushing down, and turning a retention key. Further, a first and a first line on a key and a cowling may be aligned after assembly to provide a clear indication that the connector has been properly assembled.