Abstract: A removable antenna is provided for an electronic device such as a laptop computer. An antenna resonating element is mounted within the antenna. Magnetic coupling structures are used to magnetically attach the antenna to the electronic device. The magnetic coupling structures couple the antenna resonating element to circuitry in the electronic device. The electronic device may have an antenna receptacle that holds the antenna in a stowed position and allows the antenna to extend to an extended position. A user may extend the antenna by sliding the antenna or by rotating the antenna to its extended position. The coupling structures may allow the antenna to break away from the electronic device without damage.

Abstract: Key antennas are provided for an electronic device such as a laptop computer. The electronic device may have radio-frequency transceivers that transmit and receive signals using the key antennas. An antenna resonating element may be mounted beneath a keycap of each key antenna. The antenna resonating element may be spirally wrapped and integrated into the keycap. The key antenna may function as an antenna and may also function as an input key for an electronic device. A flexible communications path may pass through a hole in a conductive housing of the electronic device and may be used to couple the antenna resonating element to the radio-frequency transceiver. The antenna resonating element may be coupled to the radio-frequency transceiver by a weak spring. The weak spring may form a portion of the antenna resonating element.

Abstract: A removable antenna and a resilient antenna are provided for an electronic device such as a laptop computer. An antenna resonating element is mounted within the antenna. Flexible coupling structures are used to physically and removably attach the antenna to the electronic device. The flexible coupling structures couple the antenna resonating element to circuitry in the electronic device. The coupling structures may allow the antenna to break away from the electronic device without causing damage. A user may extend the antenna by rotating the removable antenna to its extended position. The electronic device may have an antenna receptacle that holds the resilient antenna in a stowed position and that allows the resilient antenna to flex to an extended position. A user may extend the resilient antenna by removing the resilient antenna from the antenna receptacle and flexing the antenna into its extended position.

Abstract: Electronic devices may be provided with sensors for determining the presence and position of extendable and removable antennas. The antennas may extend by rotating about an axis, by reciprocating along their length, or by flexing from a retracted position to an extended position. The electronic device may determine when a removable antenna is attached or detached using signals from the sensors. The electronic device may determine the extent to which an antenna has been extended using signals from the sensors. The electronic device may control the operation of a radio-frequency transceiver that is coupled to the antenna based on signals from the sensors. The electronic device may turn the transceiver off when the antenna is retracted or removed. When the antenna is partially extended, the electronic device may place the transceiver in a low-power mode or place a dual-band transceiver into a single-band mode.

Abstract: A disk drive media access system opens a media access door to the interior of a disk drive sufficiently for ejection of disk media from the disk drive but insufficiently for manually engaging and removing disk media that is operationally positioned within the disk drive. The disk media is kept substantially laterally stationary during the opening of the media access door. The disk media is moved sufficiently for manually engaging the disk media for removing the disk media from the disk drive.

Abstract: Connector receptacles having a reduced height or z-dimension that are capable of accepting standard sized connector inserts. One example provides a connector having a reduction in the amount of height consumed by the deflection of a number of fingers. Specifically, the amount of deflection is reduced by eliminating one or more of these fingers on one or both sides of the connector receptacle. Instead of fingers, bumps may be used. These bumps fit into the connector insert cutouts or slots when the connector insert is fully inserted in the connector receptacle. Another example uses a rail, which may be referred to as speed rail. This speed rail can be formed along the seam of connector receptacle. The speed rail can run either a portion or the entire depth of the connector receptacle.

Abstract: A movable I/O port and housing therefore. The I/O port housing may be hinged to pivot between an open and closed position. The pivot point may be a low- or zero-friction pivot. The I/O port housing may include an opening mechanism to facilitate pivoting the port between the open and closed positions, and/or vice versa. For example, the opening mechanism may take the form of paired magnets of opposing polarities.

Abstract: A touchpad assembly for use in an electronic device is provided. The touchpad assembly may include a touchpad frame operative to be placed within an opening in an electronic device frame. The touchpad assembly may include a support plate for supporting a touchpad, and a bracket for receiving a pick button. The support plate and bracket may be manufactured into a same component to increase the rigidity of the touchpad assembly. The pick button may include a varying height to prevent the pick button from deflecting and to make the pick button travel for providing a selection instruction uniform. The pick button may be coupled to the frame using any suitable approach, including using springs connected the ends of the pick button to the frame. The frame may also include pads to muffle the sound of the pick button when it returns to its initial position after having been pressed.

Abstract: An electronic device is disclosed. The electronic device includes a first subassembly having a first housing component. The first housing component has an opening. The electronic device also includes a second subassembly having a second housing component. The second housing component cooperates with the first housing component to enclose components of an electronic device. The at least one internal component is also movable relative to the second subassembly so as to properly align with the opening. The at least one internal component is additionally magnetically attracted towards the first housing component near the opening.

Abstract: Wall portions, such as wall portions of electronic device housing components, are provided with one or more foot assemblies. A foot assembly can be formed by creating an internal cavity in an internal surface of the wall portion, an external cavity in an external surface of the wall portion, and a hollow passageway extending through the wall portion and between the cavities. The foot assembly can be completed by inserting a foot at least partially through the external cavity and hollow passageway and into the internal cavity, such that an external portion of the foot is at least partially contained within and contacting the surfaces of the external cavity, and such that an internal portion of the foot is at least partially contained within the internal cavity. A portion of the foot may be deformable to at least partially conform to the surfaces defining the internal cavity.

Abstract: A multi-layered cable consisting of three or more conductive layers separated by layers of dielectric and/or adhesive material. The bottom layer and the top layer may act as return path for the transmitted signals and as a shield to prevent interference between these and external electrical signals. Located between the bottom layer and the top layer, the middle layer may transmit desired signals through the flexible cable. The material selection and specifics of each of the layers should be selected so as to achieve a balance in which the desired electrical impedance and mechanical flexibility requirements are met. The cable may also include one or more vias connecting the bottom layer to the top layer, providing shielding all the way around the flex cable. An additional conductive sock may be used to improve shielding effectiveness of the top and bottom layer and to connect to I/O connector shells and the system Faraday cage.

Abstract: An access system for a portable device provides a portable computer having a bottom surface. The portable computer is accessed through an active user interface on the bottom surface of the portable computer.

Abstract: An input device is disclosed. The input device includes a movable touch pad capable of detecting an object in close proximity thereto so as to generate a first control signal. The input device also includes a movement indicator capable of detecting the movements of the movable touch pad so as to generate one or more distinct second control signals. The control signals being used to perform actions in an electronic device operatively coupled to the input device.

Abstract: An antenna-carrying assembly for facilitating wireless communication using an electronic device is disclosed. The antenna-carrying assembly may include a body and one or more antenna elements carried by the body. The antenna-carrying assembly may also include a first attraction element carried by the body. The first attraction element is configured to magnetically couple the antenna-carrying assembly with a track and to slide along the track. At least one of the first attraction element and the track includes one or more magnetic elements.

Abstract: A magnetic latch mechanism for latching a first electronic assembly to a second electronic assembly. The magnetic latch mechanism includes a Halbach array captured by the first electronic assembly. The Halbach array is configured to provide a first magnetic flux in a first direction. The magnetic latch mechanism further includes an attraction plate captured by the second electronic assembly. The attraction plate is configured to be coupled with the first magnetic flux when the first electronic assembly is in a closed position with respect to the second electronic assembly such that there is mutual attraction between the attraction plate and the Halbach array in the closed position.

Abstract: A magnetic latch mechanism for latching a first electronic assembly to a second electronic assembly. The magnetic latch mechanism includes a Halbach array captured by the first electronic assembly. The Halbach array is configured to provide a first magnetic flux in a first direction. The magnetic latch mechanism further includes an attraction plate captured by the second electronic assembly. The attraction plate is configured to be coupled with the first magnetic flux when the first electronic assembly is in a closed position with respect to the second electronic assembly such that there is mutual attraction between the attraction plate and the Halbach array in the closed position.

Abstract: A hinge is disclosed. The hinge can include an axle, a first member coupled to the axle, and a second member coupled to the axle and configured to rotate relative to the first member and around the axle. The hinge can further include a stop mechanism configured to stop the second member from rotating, relative to the first member, in a first direction and beyond a first range when the stop mechanism is in a first position and the second member is in the first range. The stop mechanism can be further configured to allow the second member to rotate, relative to the first member, in the first direction, beyond the first range, and into a second range when the stop mechanism is in a second position and the second member is in the first range.

Abstract: A latch mechanism for removably securing a module in a bay of an electronic device. The latch mechanism includes a first wireform configured to move along a first wall of the bay to latch a first side of the module and a tang configured to move substantially perpendicularly to a second side of the module to latch the second side of the module. The latch mechanism includes a control member operatively connected with the first wireform and the tang to actuate the first wireform and the tang simultaneously in response to user input such that when the module is inserted into the bay, the first wireform and the tang simultaneously latch the first side of the module and the second side of the module.

Abstract: Methods and systems for insertion of a memory module into a computer system are provided. The method includes removing an access door of the computer system to make a connector accessible, the access door having a size substantially smaller than a footprint of the memory module, and linearly inserting the memory module into the connector.