Abstract: An electronic device may be provided with an organic light-emitting diode display with minimized border regions. The border regions may be minimized by providing the display with bent edge portions having neutral plane adjustment features that facilitate bending of the bent edge portions while minimizing damage to the bent edge portions. The neutral plane adjustment features may include a modified backfilm layer of the display in which portions of the backfilm layer are removed in a bend region. A display device may include a substrate, a display panel on the substrate having display pixels, and peripheral circuitry proximate the display panel and configured to drive the display pixels. A portion of the periphery of the substrate may be bent substantially orthogonal to the display panel to reduce an apparent surface area of the display device. The bent portion may include an electrode for communication with the peripheral circuitry.

Abstract: Delamination of a laminated multilayer stack is provided by generating a layer-specific energy distribution in the stack during delamination. A localized energy transferrer can generate localized heating, cooling heating, cooling, or other form of energy absorption or transmission, in a bonding layer of a multilayer stack. Localized energy transfer can include thermal energy transfer, such as heating and/or cooling, acoustic energy transfer, such as applying ultrasonic energy, electromagnetic energy transfer, such as applying laser light, directed microwaves, etc. Localized energy transfer can generate a layer-specific energy distribution that can weaken the bonding layer while reducing damage to other layers of the stack.

Abstract: The described embodiments relate generally to electronic devices and more particularly to methods for forming mechanical and electrical connections between components within an electronic device. In one embodiment, an interconnect component such as a flex cable is attached to a substrate such as a printed circuit board. A plurality of apertures can be created in the interconnect component, passing through bonding pads located on one end of the interconnect component. The interconnect component can then be aligned with bonding pads on the substrate with the bonding pads on the interconnect component facing away from the substrate. A conductive compound can be injected into the apertures through the interconnect component, forming a mechanical and electrical connection between the bonding pads. In some embodiments, an adhesive layer can be used to further strengthen the bond between the interconnect component and the substrate.

Abstract: Conductive contacts can be disposed on multiple substrates or on different surfaces of a single substrate. Conductive material is disposed over at least a portion of the two conductive contacts to electrically connect the contacts. The conductive material may be disposed over at least one surface between the conductive contacts. One or more conductive borders can be formed on a surface of a conductive layer. The conductive border or borders can improve signal transmission across the surface of the conductive layer.

Abstract: A lamination system (110) may be provided for attaching together display layers (45,46) for an electronic device display. The system may include one or more pressure-sensing lamination stages (124, 126) for temporarily mounting the display layers during lamination operations. A pressure-sensing lamination stage (124) may include one or more pressure sensors (130) configured to sense pressures that are applied to the display layers during lamination operations. The pressure-sensing lamination stages may include a fixed mounting stage (126) and a movable mounting stage (124). The movable mounting stage may be moved so that a first set of display layers is pressed against a second set of display layers to attach the first and second sets of display layers. The pressure with which the first set of display layers (45;46) is pressed against the second set of display layers may be adjusted based on pressure data gathered using the pressure sensors (130).

Abstract: An assembly system may be provided for attaching together display layers for an electronic device display. The system may include substrate cleaning equipment that includes one or more pressure-sensing cleaning rollers (124) for removing debris from the display layers during assembly operations. A pressure-sensing cleaning roller (124) may include a cylindrical roller member having a tacky surface and one or more pressure sensors (136) configured to sense pressures that are applied to the display layers during cleaning operations. The position and orientation of the cleaning rollers (124) may be adjusted before or during cleaning operations based on pressure data gathered using the pressure sensors. The pressure sensors (136) may be attached to the tacky surface of the cylindrical roller member, attached to an edge of the roller member, embedded within the roller member, or attached to other equipment that moves with the roller member.

Abstract: An electronic device may have display layers and other structures. A layer of liquid adhesive may be patterned onto a structure. The liquid adhesive may be pre-cured to increase the viscosity of the liquid adhesive and to partially shrink the liquid adhesive. The structure to which the liquid adhesive has been applied may be laminated to another structure. During lamination, the pre-cured liquid adhesive may be compressed between the structures that are being laminated. The adhesive may then be fully cured to bond the structures together. The thickening of the liquid adhesive during pre-curing helps control the spread of the adhesive. The shrinking of the liquid adhesive helps prevent stresses from developing that could lead to visible stress-induced artifacts following curing.

Abstract: Methods and devices for using liquid optically clear adhesives (LOCAs) are described. A method for detecting uncured LOCA between a first substrate and a second substrate is described. In addition, an improved method for curing a laminated stack up having LOCA between a first substrate and a second substrate is described. The method includes a pre-curing method involving variable exposure of the LOCA. In addition, an improved light emitting diode (LED) unit assembly for exposing a laminated stack up to ultraviolet (UV) light during a pre-curing process is described. A method for testing the LED unit assembly prior to a pre-curing process is described.

Abstract: Flexible circuits for routing signals of a device, such as a touch sensor panel of a touch sensitive device, are provided. The flexible circuit can include a first set of traces for routing a first set of lines and a second set of traces for routing a second set of lines. The first set of traces can couple together the ends of at least a portion of the first set of lines. Additionally, the first set of traces can be non-intersecting or non-overlapping with the second set of traces. The flexible circuit can have a T-shape configuration and can be incorporated within a touch sensitive device, display device, printed circuit board, or the like. The flexible circuit can be placed over another flexible circuit, and can extend onto the device.

Abstract: Improved techniques are disclosed for fabrication of touch panels using thin sheet glass, coupling external circuitry, and securely holding the touch panel within a portable electronic device. The thin sheet glass may be chemically strengthened and laser scribed.

Abstract: Flexible circuits for routing signals of a device, such as a touch sensor panel of a touch sensitive device, are provided. The flexible circuit can include a first set of traces for routing a first set of lines and a second set of traces for routing a second set of lines. The first set of traces can couple together the ends of at least a portion of the first set of lines. Additionally, the first set of traces can be non-intersecting or non-overlapping with the second set of traces. The flexible circuit can have a T-shape configuration and can be incorporated within a touch sensitive device, display device, printed circuit board, or the like. The flexible circuit can be placed over another flexible circuit, and can extend onto the device.

Abstract: An electronic device display may have a color filter layer and a thin film transistor layer. A layer of liquid crystal material may be interposed between the color filter layer and the thin film transistor layer. A layer of polarizer may be laminated onto the surface of the color filter layer. Laser trimming may ensure that the edges of the polarizer are even with the edges of the color filter layer. The thin film transistor layer may have an array of thin film transistors that control pixels of the liquid crystal material in the display. Driver circuitry may be used to control the array. The driver circuitry may be encapsulated in a planarized encapsulant on the thin film transistor layer or may be mounted to the underside of the color filter layer. Conductive structures may connect driver circuitry on the color filter layer to the thin film transistor layer.

Abstract: Methods for controlling deformation of laminated display assemblies are described. The laminated display assemblies can include flexible layers. In some embodiments, the flexible layers are sensor layers. Methods involving the use of a thermal press and ultra violet (UV) curing procedure are described. In one embodiment, a thermal press method can be performed by placing a laminated display assembly including the flexible substrate, an ink layer, an adhesive, and a cover on a temperature controlled fixture. A mechanical press can apply pressure to the top of the laminated display assembly. The mechanical press can remove any planar deformity of the flexible layer and can redistribute portions of the adhesive. Following the mechanical pressing, the laminated display assembly can be exposed to UV light to cure the adhesive and thereby fix in place the planar state of the laminated display assembly.

Abstract: A flexible circuit with multiple independent mounting points can be mounted (soldered) to substrates by independently (and concurrently) positioning mounting points in x, y, and theta (angular rotation) with vacuum chucks. In one embodiment the vacuum chucks can be guided by computer aided vision to locate and match fiducials on the flex circuit with fiducials on the substrate. In one embodiment, hot bars can be used in a subsequent bonding operation to secure an adhesive coupling between the flexible circuits and the substrate.

Abstract: An electronic device display may have a color filter layer and a thin film transistor layer. A layer of liquid crystal material may be interposed between the color filter layer and the thin film transistor layer. A layer of polarizer may be laminated onto the surface of the color filter layer. Laser trimming may ensure that the edges of the polarizer are even with the edges of the color filter layer. The thin film transistor layer may have an array of thin film transistors that control pixels of the liquid crystal material in the display. Driver circuitry may be used to control the array. The driver circuitry may be encapsulated in a planarized encapsulant on the thin film transistor layer or may be mounted to the underside of the color filter layer. Conductive structures may connect driver circuitry on the color filter layer to the thin film transistor layer.

Abstract: An electronic device may have a touch screen display or other input-output device that includes transparent conductive electrodes. The transparent conductive electrodes may be formed from a material that has a relatively high index of refraction such as indium tin oxide. Surrounding layers of the touch screen display such as a touch sensor substrate and an underlying display layer may have lower index of refraction values. To prevent abrupt index-of-refraction discontinuities that lead to unwanted reflections and visible artifacts on the display, the transparent conductive electrodes may be embedded within a dielectric layer. The dielectric layer may have a graded index of refraction. The graded index of refraction may be varied continuously or in a stepwise fashion by adjusting the composition of materials that are incorporated into the dielectric layer as a function of position within the layer.

Abstract: An electronic device display may have a color filter layer and a thin film transistor layer. A layer of liquid crystal material may be interposed between the color filter layer and the thin film transistor layer. A layer of polarizer may be laminated onto the surface of the color filter layer. Laser trimming may ensure that the edges of the polarizer are even with the edges of the color filter layer. The thin film transistor layer may have an array of thin film transistors that control pixels of the liquid crystal material in the display. Driver circuitry may be used to control the array. The driver circuitry may be encapsulated in a planarized encapsulant on the thin film transistor layer or may be mounted to the underside of the color filter layer. Conductive structures may connect driver circuitry on the color filter layer to the thin film transistor layer.

Abstract: A system for controlling a boundary of spreading liquid adhesive on a surface is disclosed. The system includes one or more ultra-violet (UV) sources configurable to emit UV light onto the liquid adhesive; and a control circuit coupled to the one or more UV sources and configured to control the one or more UV sources to selectively apply the UV light at selected locations on the liquid adhesive to cure the adhesive and prevent its further spread at those locations.

Abstract: The described embodiments relate generally to electronic devices and more particularly to methods for forming mechanical and electrical connections between components within an electronic device. In one embodiment, an interconnect component such as a flex cable is attached to a substrate such as a printed circuit board. A plurality of apertures can be created in the interconnect component, passing through bonding pads located on one end of the interconnect component. The interconnect component can then be aligned with bonding pads on the substrate with the bonding pads on the interconnect component facing away from the substrate. A conductive compound can be injected into the apertures through the interconnect component, forming a mechanical and electrical connection between the bonding pads. In some embodiments, an adhesive layer can be used to further strengthen the bond between the interconnect component and the substrate.

Abstract: A method of laminating a surface of a flexible material to a surface of a rigid, curved material. The method includes pressing an area of the surface of the flexible material into the surface of the rigid, curved material with a holder to create a contact area while the flexible material is conformed to the holder, which has a curvature greater than a curvature of the rigid, curved material surface; and changing the contact area between the surface of the flexible material and the surface of the rigid, curved material while maintaining pressure on the contact area until the surface of the flexible material and the surface of the rigid curved material are laminated.