Abstract: An electronic device has a self-healing elastomer applied over one or more external electronic connectors. The self-healing elastomer may obscure the electronic connectors from the user as well as provide environmental protection for the connector and the electronic device. Electronic probes may temporarily penetrate the self-healing elastomer to mate with the electronic connector. After removal of the probes the self-healing elastomer may elastically reform and self-heal.

Abstract: An electronic device having a pressure detection system is disclosed. The electronic device may include one or more elements designed to detect pressure exerted on the electronic device. In some embodiments, the electronic device includes a membrane and a detection mechanism, both of which bend in response to a pressure change at the membrane. The membrane may be electrically coupled with a circuit that detects the bending of the membrane and correlates the bending with a pressure change at the membrane. A can may be hermetically sealed with the membrane and surround the circuit to shield the circuit from liquid ingress. In some embodiments, a light transmitter and light receiver are used to detect the bending of the membrane. The light may reflect from the membrane at different angles, based upon a shape of the membrane, and contact the receiving element at different locations, corresponding to pressure change.

Abstract: An electronic device has a concealed external electrical connector that may be activated by a pin of a mating connector. When the pin applies a force to an electrically conductive and flexible region of an exterior housing of an electronic device the electrically conductive region deflects inwards coupling to a contact within the electronic device. A bi-directional communications path is then established from the pin of the connector, through the conductive portion of the housing, to the contact and to circuitry within the housing of the electronic device.

Abstract: A wearable electronic device includes a body, a housing component, a band operable to attach the body to a body part of a user, and a force sensor coupled to the housing component. The force sensor is operable to produce a force signal based on a force exerted between the body part of the user and the housing component. A processing unit of the wearable electronic device receives the force signal from the force sensor and determines the force exerted on the housing component based thereon. The processing unit may use that force to determine a tightness of the band, determine health information for the user, adjust determined force exerted on a cover glass, and/or to perform various other actions.

Abstract: An electronic device includes at least a housing having a force transmissive surface capable of receiving a force, a force sensor configured to sense the force received from the force transmissive surface in accordance with a force path and respond by outputting a signal that indicates a magnitude of the force at a first sensitivity level when the magnitude of the force is less than a threshold level, otherwise, the signal indicates the magnitude of the force in accordance with a second sensitivity level. The electronic device includes a processor in communication with the force sensor that uses the signal to alter an operation of the electronic device. In one embodiment, the electronic device is wearable.

Abstract: An electronic device is disclosed. The electronic device may include a sealing element between a protective cover and a housing of the electronic device. The sealing element may provide a seal between the protective cover and the enclosure, as well as monitor or detect a force to the protective cover. Also, one or more support members may surround the sealing element to provide protection against a material (such as liquid) entering an opening between the protective cover and the enclosure. Alternatively, or in combination, the sealing element may include several openings, each of which may include a restraining element to limit movement of the sealing element. Also, a blocking element may be placed at or near an edge of the enclosure to provide additional reinforcement if the sealing element is laterally displaced. The blocking element may include an operational component of the electronic device, such as an antenna.

Abstract: An electronic device may be provided with a display, trackpad member, or other structure that can shift laterally with respect to another device structure in response to the application of shear force. Shear force may be applied by the fingers of a user. Shear force sensors may be provided in an electronic device to measure the shear force that is applied. The shear force sensors may be capacitive sensors. A capacitive shear force sensor may have capacitive electrodes. In response to application of shear force, the capacitive electrodes may move with respect to each other. Parallel planar electrodes may shift with respect to each other so that the amount of overlap and therefore capacitance between the electrodes changes or the separation distance between parallel planar electrodes may increase or decrease to produce measureable capacitance changes.

Abstract: Transparent structures containing a transparent electrically conductive fluid are used for aesthetically appealing designs and/or improved fatigue performance. Some structures have multiple isolated conductors while others have a single conductive area that may be used as a transparent antenna or a transparent EMI shield. Other embodiments employ fluids that change crystalline structure under an applied voltage such that a structure can change color and/or display a message.

Abstract: Electrical components such as integrated circuits and other components may be mounted on a substrate such as a printed circuit substrate. A molded plastic cap may cover the components and a portion of the printed circuit substrate to form a packaged electrical device. Metal structures such as springs, posts, and other metal members may be insert molded within the plastic cap. A metal layer on the surface of the cap may be patterned to from electromagnetic shielding, signal paths, contact pads, sensor electrodes, antennas, and other structures. Multiple substrates each with a respective set of mounted electrical components may be joined using a flexible printed circuit. The flexible printed circuit may be covered with a rigid cap portion or an elastomeric material or may be left uncovered.

Abstract: An electronic device may include surface mount technology components mounted to a printed circuit board. The surface mount technology components may include electrical components such as resistors, inductors, and capacitors. In order to reduce the size of the electronic device, surface mount technology components may be stacked. A surface mount technology component may be mounted to metal members that electrically connect the surface mount technology component to contact pads on a printed circuit board. A surface mount technology component may be provided with integral standoff portions, and a second surface mount technology component may be mounted to the integral standoff portions. A single surface mount technology component may be used to implement different circuits depending on which face of the surface mount technology component is mounted to the printed circuit board.

Abstract: An electronic device has structures that are assembled using attachment structures. The attachment structures change shape to help join the electronic device structures together. Structures that may be joined together can include electronic device housing structures, display structures, internal device components, electrical components, and other portions of an electronic device. The attachment structures can include heat-activated attachment structures, structures that are activated using other types of applied energy, and structures that change shape due the application of chemicals or other treatments.

Abstract: Transparent structures containing a transparent electrically conductive fluid are used for aesthetically appealing designs and/or improved fatigue performance. Some structures have multiple isolated conductors while others have a single conductive area that may be used as a transparent antenna or a transparent EMI shield. Other embodiments employ fluids that change crystalline structure under an applied voltage such that a structure can change color and/or display a message.

Abstract: An electronic device has structures that are assembled using attachment structures. The attachment structures change shape to help join the electronic device structures together. Structures that may be joined together can include electronic device housing structures, display structures, internal device components, electrical components, and other portions of an electronic device. The attachment structures can include heat-activated attachment structures, structures that are activated using other types of applied energy, and structures that change shape due the application of chemicals or other treatments.

Abstract: Systems and methods for dynamically adjusting the fit of a wearable electronic device are disclosed. In many embodiments, a tensioner associated with a wearable electronic device can control one or more actuators that are mechanically coupled to either the housing or to a band attached to the wearable electronic device. In one example, in response to a signal to increase the tightness of the band, the tensioner can cause the actuator(s) to increase the tension within the band.

Abstract: Capacitive sensor assemblies for electronic devices, and methods of forming capacitive sensor assemblies. The capacitive sensor assembly may include a top component having an intermediate layer formed on the top component, a bottom component positioned opposite the top component, a silicone layer positioned between the top component and the bottom component, and a first electrical trace positioned adjacent the silicone layer.

Abstract: An electronic device has a self-healing elastomer applied over one or more external electronic connectors. The self-healing elastomer may obscure the electronic connectors from the user as well as provide environmental protection for the connector and the electronic device. Electronic probes may temporarily penetrate the self-healing elastomer to mate with the electronic connector. After removal of the probes the self-healing elastomer may elastically reform and self-heal.

Abstract: A force sensor includes compliant material that is configured to stay within a maximum uncompressed dimension in a first direction when compressed in a second direction. The first direction may be perpendicular to the second direction. The compliant material may stay within the maximum uncompressed dimension when compressed by expanding into one or more gaps defined in the compliant material. Such gaps may be defined on an external surface of the compliant material and/or internal to the compliant material. The gaps may be formed using a variety of different processes during or after formation of the compliant material.

Abstract: Board-to-board connectors that may provide durable and reliable connections, may save board space, and may be easy to manufacture. One example may provide board-to-board connectors that provide durable connections by providing a seal between board-to-board plugs and receptacles. The seal may be an O-ring, gasket, or other seal. The seal may protect contacts on the board-to-board connectors from exposure to fluids, such as water or other corrosive fluids. This seal may provide a level of redundancy with one or more seals protecting a device from external fluids, such as a seal at or in the device enclosure.

Abstract: An electronic device has a self-healing elastomer applied over one or more external electronic connectors. The self-healing elastomer may obscure the electronic connectors from the user as well as provide environmental protection for the connector and the electronic device. Electronic probes may temporarily penetrate the self-healing elastomer to mate with the electronic connector. After removal of the probes the self-healing elastomer may elastically reform and self-heal.

Abstract: An auxiliary electronic device attachable to a wearable electronic device. The auxiliary device includes a housing, electronic circuitry within the housing, and an attachment mechanism configured to attach the auxiliary electronic device to the wearable device while the device is being worn by a user. In some embodiments the electronic circuitry includes a power transmitting unit that can wirelessly transmit power to charge a rechargeable battery within the wearable electronic device. In some embodiments the attachment mechanism includes a pair of lugs that extend, from opposite ends of the housing, above the housing towards a center of the auxiliary device and are adapted to fit within corresponding recesses of the wearable electronic device.