Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: Connector receptacles that may help maintain registration or alignment between a printed circuit board, a connector receptacle, and an opening in a device enclosure. One example may provide a connector receptacle having a housing including a passage. A pin may be placed in the passage such that a first portion extends away from a front of the housing and a rear portion extends away from a rear of the housing. The front portion may be arranged to fit in a cavity or opening in an inside surface of a device enclosure, while the rear portion may be arranged to fit in a cavity or opening in a top surface of a printed circuit board.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: A display housing for a portable computing device that utilizes a plastic cover bonded to an internal metal frame is described. To account for thermal cycling issues and in particular to prevent bond slippage, multiple types of adhesives are employed to join the metal frame and the plastic cover. In particular, a very high bond (VHB) adhesive material is used in certain areas to bond the metal inner frame to the plastic cover and a liquid adhesive is used in other areas. The plastic cover can be translucent to light. A method of coating the plastic cover to block light, such as from a backlight used for the display, is described.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: Connector receptacles that may help maintain registration or alignment between a printed circuit board, a connector receptacle, and an opening in a device enclosure. One example may provide a connector receptacle having a housing including a passage. A pin may be placed in the passage such that a first portion extends away from a front of the housing and a rear portion extends away from a rear of the housing. The front portion may be arranged to fit in a cavity or opening in an inside surface of a device enclosure, while the rear portion may be arranged to fit in a cavity or opening in a top surface of a printed circuit board.

Abstract: Structures, methods, and apparatus that provide connector receptacles that have a reduced tendency to scratch and otherwise mar connector inserts, have an aesthetically-pleasing appearance, have an improved tactile response when inserts are inserted, or are very thin or have a low profile. Various examples reduce scratches and wear by utilizing domes, cylinders, balls, or other structures as finger contacts in a connector receptacle. Another example provides aesthetically-pleasing connector receptacle enclosures by forming receptacle enclosures using the same type of material, or material having the same or similar color or texture, as is used for enclosing the electronic device that includes the receptacle. Another example provides an aesthetically-pleasing receptacle enclosure by forming receptacle enclosures that are, in part or in whole, contiguous or formed with the housing. Another example provides a super-thin connector receptacle by removing fingers and portions of a shell along one or more sides.

Abstract: Structures, methods, and apparatus that provide connector receptacles that have a reduced tendency to scratch and otherwise mar connector inserts, have an aesthetically-pleasing appearance, have an improved tactile response when inserts are inserted, or are very thin or have a low profile. Various examples reduce scratches and wear by utilizing domes, cylinders, balls, or other structures as finger contacts in a connector receptacle. Another example provides aesthetically-pleasing connector receptacle enclosures by forming receptacle enclosures using the same type of material, or material having the same or similar color or texture, as is used for enclosing the electronic device that includes the receptacle. Another example provides an aesthetically-pleasing receptacle enclosure by forming receptacle enclosures that are, in part or in whole, contiguous or formed with the housing. Another example provides a super-thin connector receptacle by removing fingers and portions of a shell along one or more sides.

Abstract: Connectors that may be incorporated and used in electronic devices in a reliable manner. One example may provide a connector that may receive a memory card, such as a Secure Digital, SmartMedia, Compact Flash, or other type of memory card. One example may provide a connector that may connect to other electronic circuits and components in an electronic device in a reliable manner. Another may provide a connector that may reliably form a connection for electromagnetic interference protection during device assembly. Another may provide a connector that may be resistant to damage from debris or other particulate matter that may enter the connector. Another example may provide a connector that has a back that is reinforced to prevent damage caused by the insertion of a card with excessive force. Another may provide a connector having a raised portion arranged to fit in an opening in a printed circuit board.

Abstract: A display housing for a portable computing device that utilizes a plastic cover bonded to an internal metal frame is described. To account for thermal cycling issues and in particular to prevent bond slippage, multiple types of adhesives are employed to join the metal frame and the plastic cover. In particular, a very high bond (VHB) adhesive material is used in certain areas to bond the metal inner frame to the plastic cover and a liquid adhesive is used in other areas. The plastic cover can be translucent to light. A method of coating the plastic cover to block light, such as from a backlight used for the display, is described.

Abstract: Structures, methods, and apparatus that provide connector receptacles that have a reduced tendency to scratch and otherwise mar connector inserts, have an aesthetically-pleasing appearance, have an improved tactile response when inserts are inserted, or are very thin or have a low profile. Various examples reduce scratches and wear by utilizing domes, cylinders, balls, or other structures as finger contacts in a connector receptacle. Another example provides aesthetically-pleasing connector receptacle enclosures by forming receptacle enclosures using the same type of material, or material having the same or similar color or texture, as is used for enclosing the electronic device that includes the receptacle. Another example provides an aesthetically-pleasing receptacle enclosure by forming receptacle enclosures that are, in part or in whole, contiguous or formed with the housing. Another example provides a super-thin connector receptacle by removing fingers and portions of a shell along one or more sides.

Abstract: A display housing for a portable computing device that utilizes a plastic cover bonded to an internal metal frame is described. To account for thermal cycling issues and in particular to prevent bond slippage, multiple types of adhesives are employed to join the metal frame and the plastic cover. In particular, a very high bond (VHB) adhesive material is used in certain areas to bond the metal inner frame to the plastic cover and a liquid adhesive is used in other areas. The plastic cover can be translucent to light. A method of coating the plastic cover to block light, such as from a backlight used for the display, is described.

Abstract: A display housing for a portable computing device that utilizes a plastic cover bonded to an internal metal frame is described. To account for thermal cycling issues and in particular to prevent bond slippage, multiple types of adhesives are employed to join the metal frame and the plastic cover. In particular, a very high bond (VHB) adhesive material is used in certain areas to bond the metal inner frame to the plastic cover and a liquid adhesive is used in other areas. The plastic cover can be translucent to light. A method of coating the plastic cover to block light, such as from a backlight used for the display, is described.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a clutch barrel. The clutch barrel encloses a connector assembly, the connector assembly providing support for a lid. The clutch barrel is configured such that a junction formed by the clutch barrel and a top layer of the lid is not visible to a user when the computer housing is on a horizontal surface.

Abstract: Connectors that may be incorporated and used in electronic devices in a reliable manner. One example may provide a connector that may receive a memory card, such as a Secure Digital, SmartMedia, Compact Flash, or other type of memory card. One example may provide a connector that may connect to other electronic circuits and components in an electronic device in a reliable manner. Another may provide a connector that may reliably form a connection for electromagnetic interference protection during device assembly. Another may provide a connector that may be resistant to damage from debris or other particulate matter that may enter the connector. Another example may provide a connector that has a back that is reinforced to prevent damage caused by the insertion of a card with excessive force. Another may provide a connector having a raised portion arranged to fit in an opening in a printed circuit board.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: A multipart computer housing is described. The multipart computer housing includes at least a structural support layer and a body. The body includes at least an outer layer formed of lightweight flexible material and an inner layer attached to the outer layer. The inner layer is connected to the support layer forming a load path between the inner layer and the structural support layer. A load applied to the multipart computer housing is transferred by way of the load path to the support layer without substantially affecting the outer layer.

Abstract: Structures, methods, and apparatus that provide connector receptacles that have a reduced tendency to scratch and otherwise mar connector inserts, have an aesthetically-pleasing appearance, have an improved tactile response when inserts are inserted, or are very thin or have a low profile. Various examples reduce scratches and wear by utilizing domes, cylinders, balls, or other structures as finger contacts in a connector receptacle. Another example provides aesthetically-pleasing connector receptacle enclosures by forming receptacle enclosures using the same type of material, or material having the same or similar color or texture, as is used for enclosing the electronic device that includes the receptacle. Another example provides an aesthetically-pleasing receptacle enclosure by forming receptacle enclosures that are, in part or in whole, contiguous or formed with the housing. Another example provides a super-thin connector receptacle by removing fingers and portions of a shell along one or more sides.