Abstract: An accessory device suitable for use with an electronic device is disclosed. The electronic device may include an audio assembly designed to generate acoustical energy. The audio assembly may use certain components of the accessory device to generate the acoustical energy. For example, the accessory device may include a shell, or rigid body, that provides structural support for the accessory device. The accessory device may also include a flexible layer, such as silicone, disposed over the shell. The audio assembly may use part of the shell and acoustically drive that part of the shell to generate the acoustical energy. Further, the audio assembly may use part of the flexible layer as a “surround” to allow part of the shell to move relative to other parts. The electronic device may electrically couple with the accessory device, thereby providing a means for providing an audio signal.

Abstract: An accessory device suitable for use with an electronic device is disclosed. The electronic device may include an audio assembly designed to generate acoustical energy. The audio assembly may use certain components of the accessory device to generate the acoustical energy. For example, the accessory device may include a shell, or rigid body, that provides structural support for the accessory device. The accessory device may also include a flexible layer, such as silicone, disposed over the shell. The audio assembly may use part of the shell and acoustically drive that part of the shell to generate the acoustical energy. Further, the audio assembly may use part of the flexible layer as a “surround” to allow part of the shell to move relative to other parts. The electronic device may electrically couple with the accessory device, thereby providing a means for providing an audio signal.

Abstract: A removable case may receive an electronic device. A male connector in the case may mate with a female connector in the device. A battery in the case may supply power to the device through the male connector. The electronic device may have an antenna. The case may have a supplemental antenna that compensates for variations in performance in the antenna when the device is received within the case. The supplemental antenna may be a parasitic antenna resonating element that is formed from metal traces on a flexible printed circuit. The flexible printed circuit, a metal trim structure, and a plastic support structure may form portions of a connector support structure in the case.

Abstract: An accessory device for an electronic device is disclosed. The accessory device may include a unitary body having a first region, a second region, and a hinge positioned between the first region and the second region. When a force is applied to the first region, the first region may bend or pivot at the hinge. When bent, the first region allows the electronic device to slide into or out of the accessory device. Further, the electronic device may slide into or out of the accessory device in a straight or linear manner. Also, the accessory device may further include a power supply designed to supply electrical current to a battery of the electronic device. The accessory device may further include a connector that electrically connects the power supply with the electronic device. The sliding motion of the electronic device prevents the connector from damage by bending.

Abstract: An accessory device is disclosed. The accessory device may include a light guide assembly that directs light from a light source (or sources) through an opening of the accessory device, and in particular, in a base portion of the accessory device. The light guide assembly may be disposed in a compartment of the accessory device and include a light guide body as well as a light guide insert disposed in an opening of the light guide body. To form the opening, a single cutting operation may cut through the base portion and the light guide body so that the respective openings of the base portion and the light guide body are aligned. The light guide body may be designed to receive the light from the light source and direct or focus the light toward the light guide insert. The light guide insert may refract, scatter, and/or diffuse the light.

Abstract: A method for connecting or terminating wires to a printed circuit is disclosed. The method includes applying layers, such as a first layer and a second layer, to the printed circuit. The first layer is applied over several active components on the printed circuit, and provides a sealant against ingress of contaminants in the active components. The second layer is a rigid layer applied over the first layer. When the printed circuit is placed in a fixture, a metallic element, such as a thermode or hot bar, presses against the wires to hold the wires against several terminals on the printed circuit. The metallic element is heated to melt solder between the wires and the terminals. The second layer is configured to resist compressive forces from the metallic element and the fixture, such that the printed circuit and the active components are not damaged during the connection process.

Abstract: A removable case may receive an electronic device. A male connector in the case may mate with a female connector in the device. A battery in the case may supply power to the device through the male connector. The electronic device may have an antenna. The case may have a supplemental antenna that compensates for variations in performance in the antenna when the device is received within the case. The supplemental antenna may be a parasitic antenna resonating element that is formed from metal traces on a flexible printed circuit. The flexible printed circuit, a metal trim structure, and a plastic support structure may form portions of a connector support structure in the case.

Abstract: A case for an electronic device is disclosed. The case includes a body defining an interior volume configured to receive the electronic device therein. The body includes a user input region formed from a deformable material having an electrical resistance that decreases in response to a touch force on the deformable material, and an electrode pair in contact with the deformable material and configured to be operatively coupled to a sensing circuit configured to detect a change to the electrical resistance of the deformable material due to the touch force. The body also includes a connector configured to operatively couple the electrode pair to the electronic device.

Abstract: An accessory device for an electronic device is disclosed. The accessory device may include a unitary body having a first region, a second region, and a hinge positioned between the first region and the second region. When a force is applied to the first region, the first region may bend or pivot at the hinge. When bent, the first region allows the electronic device to slide into or out of the accessory device. Further, the electronic device may slide into or out of the accessory device in a straight or linear manner. Also, the accessory device may further include a power supply designed to supply electrical current to a battery of the electronic device. The accessory device may further include a connector that electrically connects the power supply with the electronic device. The sliding motion of the electronic device prevents the connector from damage by bending.

Abstract: An electronic device has structures such as substrates and internal housing structures. The substrates may be rigid substrates such as rigid printed circuit boards and flexible substrates such as flexible printed circuits, flexible touch sensor substrates, and flexible display substrates. Carbon nanotubes may be patterned to form carbon nanotube signal paths on the substrates. The signal paths may resist cracking when bent. A flexible structure such as a flexible printed circuit may have carbon nanotube signal paths interposed between polymer layers. Openings in a polymer layer may expose metal solder pads on the carbon nanotube signal paths. A stiffener may be provided under the metal solder pads. Polymer materials in the flexible structure may be molded to form bends. Bends may be formed along edges of a touch sensor or display or may be formed in a flexible printed circuit.

Abstract: An inductive coupling assembly for an electronic device is disclosed. The system may include an electronic device having an enclosure, and an internal inductive charging assembly positioned within the enclosure. The internal inductive charging assembly may include a receive inductive coil positioned within the enclosure. The system may also include a charger in electrical communication with the internal inductive charging assembly of the electronic device. The charger may include a transmit inductive coil aligned with the receive inductive coil. The transmit inductive coil may be configured to be in electrical communication with the receive inductive coil. Additionally, the system can include an inductive coupling assembly positioned between the electronic device and the charger.

Abstract: An electronic device has structures such as substrates and internal housing structures. The substrates may be rigid substrates such as rigid printed circuit boards and flexible substrates such as flexible printed circuits, flexible touch sensor substrates, and flexible display substrates. Carbon nanotubes may be patterned to form carbon nanotube signal paths on the substrates. The signal paths may resist cracking when bent. A flexible structure such as a flexible printed circuit may have carbon nanotube signal paths interposed between polymer layers. Openings in a polymer layer may expose metal solder pads on the carbon nanotube signal paths. A stiffener may be provided under the metal solder pads. Polymer materials in the flexible structure may be molded to form bends. Bends may be formed along edges of a touch sensor or display or may be formed in a flexible printed circuit.

Abstract: A method for connecting or terminating wires to a printed circuit is disclosed. The method includes applying layers, such as a first layer and a second layer, to the printed circuit. The first layer is applied over several active components on the printed circuit, and provides a sealant against ingress of contaminants in the active components. The second layer is a rigid layer applied over the first layer. When the printed circuit is placed in a fixture, a metallic element, such as a thermode or hot bar, presses against the wires to hold the wires against several terminals on the printed circuit. The metallic element is heated to melt solder between the wires and the terminals. The second layer is configured to resist compressive forces from the metallic element and the fixture, such that the printed circuit and the active components are not damaged during the connection process.

Abstract: Cable structures with multi-material extruded strain reliefs and systems and methods for making the same are provided. In some embodiments, a cable structure may include at least two materials simultaneously extruded through a die and about a conductor. A relationship between the two materials may be changed during the simultaneous extrusion for varying the stiffness of the cable structure, which may thereby provide a strain relief region to the cable structure. One of the two materials may be stiffer than another of the two materials, and the ratio of the amount or thickness of one of the two materials with respect to the amount or thickness of the other of the two materials may be varied during the extrusion process to vary the stiffness of the cable structure along its length for providing the strain relief region.