Patent application number | Description | Published |
20110075835 | SELF ADAPTING HAPTIC DEVICE - Methods and apparatuses are disclosed that allow an electronic device to autonomously adapt one or more user alerts of the electronic device. For example, some embodiments may include a method for operating a haptic device including driving a haptic device using a control signal, measuring a frequency related to the operation of the haptic device and comparing the measured frequency with a target frequency. A control signal is adjusted based on the comparison to drive the haptic device to the target frequency. | 03-31-2011 |
20110214977 | SNORKEL FOR VENTING A DOME SWITCH - To prevent debris from entering the volume between a dome and contacts of a dome switch, a dome can include a channel providing a remote path through which air can be vented. In particular, the channel can extend from the dome to a location within an electronic device that is known to be or expected to be contaminant free (e.g., a region of the device that does not include any interfaces communicating with the device environment). The channel can be defined from components of the dome switch including, for example, as a channel bound by spacer walls between a flex circuit and a film layer. The channel can include an opening for venting the dome switch. In some embodiments, the dome switch can include a protective film applied over the opening in the channel. The protective film can be selected to allow air to flow through, but to prevent contaminants or particles from reaching the channel opening. | 09-08-2011 |
20110244165 | STRUCTURES FOR CONTAINING LIQUID MATERIALS AND MAINTAINING PART ALIGNMENT DURING ASSEMBLY OPERATIONS - Components may be interconnected using liquid materials such as liquid adhesive and solder. To prevent undesired movement between the components during the assembly process and to prevent the liquid material from flowing into undesired areas, an attachment and dam structure may be provided. The structure may be formed from a substrate such as a flexible polymer film coated with adhesive. When interposed between first and second components, the structure attaches the first and second components and prevents movement between the first and second components. The structure may have one or more edges adjacent to the liquid material to block the liquid material from flowing while the liquid material is in its liquid state. Once the components have been connected, the liquid material can be solidified. | 10-06-2011 |
20110255000 | CAMERA ALIGNMENT AND MOUNTING STRUCTURES - An electronic device may be provided with a housing. A camera module may be mounted within the housing. The housing may have a camera window with which a lens in the camera module is aligned. To rotationally and laterally align the camera module with respect to the camera window and the electronic device housing, an alignment structure may be mounted to the housing in alignment with the camera window and housing. The alignment structure may be formed form a ring-shaped structure with an opening. The alignment structures may have sidewalls that form an alignment groove for the camera module. The camera window may be formed from a circular opening in a layer of opaque material deposited on a transparent housing member such as a planar layer of glass. During the process, a laser tool may be used to trim the opening in the opaque material. | 10-20-2011 |
20120175232 | STRUCTURALLY ENHANCED SWITCH ASSEMBLIES - Slide switch assemblies with structural enhancements are provided for use in electronic devices. Slide switch assemblies in accordance with embodiments the invention can include a button, an engagement member, and switch box. The engagement member couples the button to the switch box and translates any movement of the button to the switch box. The switch box is mounted offset with respect to the button because another component such as, for example, a display screen occupies the space that would have been a better mounting position for the switch box. To compensate for the offset, and the added torsion that is applied to the engagement member during button movement events, the engagement member is structurally enhanced. | 07-12-2012 |
20120176760 | SYSTEMS AND METHODS FOR GROUNDING A MOVABLE COMPONENT - An electronic device can include different components providing different functionality. Some electronic devices can include a proximity sensor for determining when a user's face is near the device. The sensor can include an emitter and a detector that are separated by a foam block to limit cross-talk between the emitter and detector. A sheet can be placed over the foam block to define openings for each of the emitter and detector. Some electronic devices can also include a camera. A glass cover secured to the device enclosure can protect the camera. To improve an adhesive bond between the glass cover and a metal enclosure, an ink layer can be placed between an adhesive and the glass. In addition, the camera or another component may need to be grounded to ensure proper operation. During assembly, however, the position of the camera can shift due to closing an enclosure. A grounding assembly that maintains contact with the camera in its initial and final positions can be provided. | 07-12-2012 |
20120225258 | TRANSPARENT ELECTRONIC DEVICE COMPONENTS WITH OPAQUE EDGE COVERINGS - An electronic device may have components such as button members, display cover glass layers, structures associated with connector ports, and other components. The components may have transparent and opaque structures. The transparent structures may be formed on top of the opaque structures. The transparent structures may have peripheral edges through which light may pass. To help prevent the appearance of the components from becoming degraded by the presence of dirt, at least some of the edge portions of the transparent structures may be covered with an opaque covering material. The opaque covering material may be formed from paint or sidewall structures that are formed as an integral part of the opaque structures. | 09-06-2012 |
20130050950 | SYSTEMS AND METHOD FOR PROVIDING A GRAPHITE LAYER IN AN ELECTRONIC DEVICE - Systems and methods are provided for a sheet of graphite material on an electromagnetic interference shield for enhanced heat transfer. An electronic device component may be enclosed by an EMI shield, which may retain heat generated by the component. To help dissipate heat, a sheet of material selected for its heat transfer properties may be disposed over the EMI shield. A portion of the sheet may be folded over an edge of the EMI shield such that the sheet may cover a top surface of the sheet as well as tabs extending perpendicular to the top surface of the EMI shield. To facilitate the adhesion of the sheet to a smaller surface area of tabs, the sheet may include features forming a discontinuity in regions of the sheet aligned with the edge of the shield to facilitate folding the sheet. The discontinuity can include, for example, one or more holes or windows. | 02-28-2013 |
20130233691 | STRUCTURALLY ENHANCED SWITCH ASSEMBLIES - Slide switch assemblies with structural enhancements are provided for use in electronic devices. Slide switch assemblies in accordance with embodiments the invention can include a button, an engagement member, and switch box. The engagement member couples the button to the switch box and translates any movement of the button to the switch box. The switch box is mounted offset with respect to the button because another component such as, for example, a display screen occupies the space that would have been a better mounting position for the switch box. To compensate for the offset, and the added torsion that is applied to the engagement member during button movement events, the engagement member is structurally enhanced. | 09-12-2013 |
20130300549 | Self Adapting Haptic Device - Methods and apparatuses are disclosed that allow an electronic device to autonomously adapt one or more user alerts of the electronic device. For example, some embodiments may include a method for operating a haptic device including driving a haptic device using a control signal, measuring a frequency related to the operation of the haptic device and comparing the measured frequency with a target frequency. A control signal is adjusted based on the comparison to drive the haptic device to the target frequency. | 11-14-2013 |