Abstract: A method adjusting a user interface experience for a device that includes providing a user interface to retrieve a user input, providing a tactile interface layer that defines a surface and includes a volume of fluid and a displacement device 10 that manipulates the volume of fluid to deform a particular region of the surface into a tactilely distinguishable formation retrieving a user preference between a first type, location, and/or timing and a second embodiment, location, and/or timing through the user interface, and manipulating the volume of fluid to deform a particular region of the surface into a tactilely distinguishable formation of one of the first and second type, location, and/or timing is disclosed.

Abstract: One variation of a dynamic tactile interface includes: a tactile layer including a deformable region and a peripheral region adjacent the deformable region; a substrate coupled to the tactile layer, the substrate defining fluid channel and cooperating with the deformable region to define a variable volume fluidly coupled to the fluid channel; a displacement device coupled to the bladder, displacing fluid into the variable volume to transition the deformable region from the retracted setting to the expanded setting, and displacing fluid out of the variable volume to transition the deformable region from the expanded setting to the retracted setting, the displacement device defining a equilibrium range of fluid pressures within the fluid channel; a reservoir fluidly coupled to the fluid channel and supporting a reserve volume of fluid; and a valve selectively controlling transfer of fluid from the reservoir to the fluid channel.

Abstract: One embodiment of the user interface system comprises: a volume of fluid; a tactile layer; a retaining wall substantially impermeable to the fluid; a permeable layer; a displacement device; and a touch sensor. The tactile layer, with a back surface, defines a second region, operable between: a retracted state, wherein the second region is substantially flush with a first region; and an expanded state, wherein the second region is substantially proud of the first region. The permeable layer, joined to the back surface of the first region, includes a plurality of fluid ports that communicate a portion of the fluid through the permeable layer to the back surface of the second region. The displacement device directs the fluid through the fluid ports to the back surface to transition the second region from the retracted state to the expanded state. The touch sensor detects a user touch on the tactile layer.

Abstract: A dynamic tactile interface includes a tactile layer including an attachment surface, a peripheral region, and a deformable region adjacent the peripheral region, the deformable region operable between a retracted setting and an expanded setting; a substrate coupled to the attachment surface at the peripheral region and defining a fluid conduit and a fluid channel fluidly coupled to the fluid conduit, the fluid conduit adjacent the deformable region; a first magnet coupled to the substrate proximal the deformable region; and a second magnet coupled to the tactile layer at the deformable region and magnetically coupled to the first magnet, the first magnet and the second magnet cooperating to yield a nonlinear displacement of the deformable region in the expanded setting toward the substrate in response to a force applied to the tactile surface at the deformable region.

Abstract: A dynamic tactile interface includes a tactile layer including a peripheral region and a deformable region adjacent the peripheral region, the deformable region operable between an expanded setting and a retracted setting; a substrate coupled to the peripheral region and defining a fluid conduit and a fluid channel fluidly coupled to the fluid conduit, the fluid conduit adjacent the deformable region; and a spring element coupled to the substrate between the tactile layer and the substrate, arranged substantially over the fluid conduit, and operable in a first distended position and a second distended position, the spring element at a local minimum of potential energy in the expanded setting and in the first distended position and at a second potential energy greater than the local minimum of potential energy between the first distended position and the second distended position, the spring element defining a nonlinear displacement response to an input displacing the deformable region in the expanded setting

Abstract: A dynamic tactile interface including a tactile layer including an attachment surface, a peripheral region, and a deformable region adjacent the peripheral region, the deformable region operable between a retracted setting and an expanded setting tactilely distinguishable from the peripheral region; a substrate coupled to the attachment surface at the peripheral region and defining a fluid conduit and a fluid channel fluidly coupled to the fluid conduit, the fluid conduit adjacent the deformable region; a first electromagnetic element coupled to the substrate proximal the deformable region and outputting a first electromagnetic field; and a second electromagnetic element coupled to the tactile layer at the deformable region and outputting a second electromagnetic field, the second electromagnetic element attracted to the first electromagnetic element in a first setting and repelling the first electromagnetic element in a second setting.

Abstract: One variation of a dynamic tactile interface includes a tactile layer defining a peripheral region and a deformable region adjacent the peripheral region; a substrate coupled to the peripheral region, a fluid conduit adjacent the deformable region, a fluid channel fluidly coupled to the fluid conduit, and a via fluidly coupled to the fluid channel and passing through the back surface; a bladder fluidly coupled to the via and the substrate; a structure adjacent a first side of the bladder; and a platen adjacent a second side of the bladder opposite the first side and compressing the bladder against the structure substantially perpendicular the longitudinal axis of the bladder and substantially parallel the substrate to displace fluid from the bladder and into the fluid channel to transition the deformable region from a retracted setting into an expanded setting.

Abstract: A dynamic tactile interface includes a substrate defining a fluid channel, a fluid conduit fluidly coupled to the fluid channel, and an exhaust channel fluidly coupled to the fluid conduit; a tactile layer including a peripheral region coupled to the substrate, a deformable region adjacent the peripheral region and arranged over the fluid conduit, and a tactile surface opposite the substrate; a displacement device displacing fluid into the fluid channel to transition the deformable region from a retracted setting to an expanded setting; a spring element arranged remotely from the deformable region, fluidly coupled to the exhaust channel 116, and buckling from a first position to a second position in response to application of a force on the tactile surface at the deformable region in the expanded setting, the spring element biased toward the exhaust channel in the first position and biased away from the exhaust channel in the second position.

Abstract: The dynamic tactile interface includes: a tactile layer defining a peripheral region and a deformable region adjacent the peripheral region and operable between a retracted setting and an expanded setting; a substrate including an attachment surface and coupled to the peripheral region and defining a fluid conduit adjacent the deformable region and a fluid channel fluidly coupled to the fluid conduit; a border region proximal a periphery of the substrate and defining a cavity configured to receive an instrument, the cavity supporting the instrument in a first configuration and releasing the instrument in a second configuration; and a bladder fluidly coupled to the fluid channel and coupled to the cavity, the instrument compressing a portion of the bladder in the first configuration to displace fluid from the bladder into the fluid channel to transition the deformable region from the retracted setting to the expanded setting.

Abstract: One embodiment of the user interface system comprises: a volume of fluid; a tactile layer; a retaining wall substantially impermeable to the fluid; a permeable layer; a displacement device; and a touch sensor. The tactile layer, with a back surface, defines a second region, operable between: a retracted state, wherein the second region is substantially flush with a first region; and an expanded state, wherein the second region is substantially proud of the first region. The permeable layer, joined to the back surface of the first region, includes a plurality of fluid ports that communicate a portion of the fluid through the permeable layer to the back surface of the second region. The displacement device directs the fluid through the fluid ports to the back surface to transition the second region from the retracted state to the expanded state. The touch sensor detects a user touch on the tactile layer.

Abstract: A dynamic tactile interface including a substrate including an attachment surface, a cavity, and a fluid channel fluidly coupled to the cavity; a pedestal arranged within the cavity, pivotable within the cavity, and including a mating surface and an exterior surface; a tactile layer including a peripheral region coupled to the attachment surface, a deformable region adjacent the peripheral region and arranged over the pedestal, and a tactile surface opposite the substrate; and a displacement device displacing fluid to transition the deformable region from a retracted setting into an expanded setting, the pedestal pivotable within the cavity between a first position and a second position in the retracted setting, the deformable region flush with the peripheral region in the first position and the pedestal partially elevated out of the cavity and the deformable region defining a second formation tactilely distinguishable from the peripheral region in the expanded setting.

Abstract: One variation of the method includes registering interaction with a dynamic tactile interface including a tactile layer and a substrate, the tactile layer defining a tactile surface, a deformable region, and a peripheral region adjacent the deformable region and coupled to the substrate opposite the tactile surface, the method including: detecting an orientation of the device; predicting a location of an upcoming input related to a native application executing on the device; selecting a particular deformable region from a set of deformable regions, the particular deformable region substantially coincident the input location; selectively transitioning the particular deformable region from a retracted setting into an expanded setting, the deformable region substantially flush with the peripheral region in the retracted setting and tactilely distinguishable from the peripheral region in the expanded setting; and detecting an input, corresponding to the upcoming input, on the particular deformable region.

Abstract: A dynamic tactile interface including a substrate including a fluid conduit, a shelf adjacent the fluid conduit, and a fluid channel fluidly coupled to the fluid conduit; a flap including a distal end and a proximal end, the flap extending across the fluid conduit and hinged to the substrate at the proximal end; a tactile layer including a peripheral region and a deformable region adjacent the peripheral region and arranged over the flap, and a tactile surface opposite the substrate; and a displacement device displacing fluid to transition the deformable region from a retracted setting into an expanded setting, the distal end of the flap engaging the shelf in the retracted setting, and the distal end of the flap lifted off of the shelf and the deformable region in the expanded setting.

Abstract: One variation of a dynamic tactile interface for a computing device includes: a tactile layer defining a peripheral region and a deformable region adjacent the peripheral region; a substrate including a transparent base material exhibiting a first optical dispersion characteristic, coupled to the tactile layer at the peripheral region, defining a fluid conduit adjacent the peripheral region and a fluid channel fluidly coupled to the fluid conduit; a volume of transparent fluid contained within the fluid channel and the fluid conduit and exhibiting a second optical dispersion characteristic different from the first optical dispersion characteristic; a volume of particulate contained within the transparent base material of the substrate, biased around the fluid conduit, and exhibiting a third optical dispersion characteristic different from the first optical dispersion characteristic; and a displacement device displacing fluid into the fluid channel to transition the deformable region from a retracted setting i

Abstract: One variation of a system for cooling an integrated circuit within a computing device includes: a substrate arranged within the computing device, extending to an external housing of the computing device, and defining a closed fluid circuit comprising a cavity, a first boustrophedonic fluid channel across a first region of the substrate adjacent the integrated circuit, and second boustrophedonic fluid channel across a second region of the substrate; a volume of fluid within the closed fluid circuit; a displacement device comprising a diaphragm arranged across the cavity and operable between a first position and a second position, the diaphragm distended into the cavity in the first position and distended away from the cavity in the second position; and a power supply powering the displacement device to oscillate the diaphragm between the first position and the second position to pump the volume of fluid through the closed fluid circuit.

Abstract: A user interface system of one embodiment includes a layer defining a surface; a substrate supporting the layer and at least partially defining a cavity; a displacement coupled to the cavity that expands the cavity, thereby deforming a particular region of the surface; and a touch sensor coupled to the substrate and adapted to sense a user touch proximate the particular region of the surface. The layer and the substrate are connected at an attachment point, and the location of the attachment point relative to the layer, substrate, and cavity at least partially defines the shape of the deformed particular region of the surface.

Abstract: One variation of a system for cooling an electrical component within a computing device—including a digital display—includes: an internal heatsink thermally coupled to the integrated circuit and defining a fluid passage including a first end and a second end; a heat exchange layer arranged across a viewing surface of the digital display, including a transparent material, and defining a fluid channel extending across a portion of the digital display, the fluid channel including a fluid inlet coupled to the first end of the fluid passage and a fluid outlet coupled to the second end of the fluid passage; a transparent fluid; and a displacement device configured to circulate the transparent fluid between the internal heatsink and the fluid channel.

Abstract: One variation of a method for remotely sharing touch includes: receiving a location of a touch input on a surface of a first computing device; receiving an image related to the touch input; displaying the image on a display of a second computing device, the second computing device comprising a dynamic tactile layer arranged over the display and defining a set of deformable regions, each deformable region in the set of deformable region configured to expand from a retracted setting into an expanded setting; and transitioning a particular deformable region in the set of deformable regions from the retracted setting into the expanded setting, the particular deformable region defined within the dynamic tactile layer at a position corresponding to the location of the touch input.

Abstract: One embodiment of the user interface system comprises: a volume of fluid; a tactile layer; a retaining wall substantially impermeable to the fluid; a permeable layer; a displacement device; and a touch sensor. The tactile layer, with a back surface, defines a second region, operable between: a retracted state, wherein the second region is substantially flush with a first region; and an expanded state, wherein the second region is substantially proud of the first region. The permeable layer, joined to the back surface of the first region, includes a plurality of fluid ports that communicate a portion of the fluid through the permeable layer to the back surface of the second region. The displacement device directs the fluid through the fluid ports to the back surface to transition the second region from the retracted state to the expanded state. The touch sensor detects a user touch on the tactile layer.

Abstract: A method for actuating a tactile interface layer for a device that defines a surface with a deformable region, comprising the steps of detecting a gesture of the user along the surface of the tactile interface layer that includes a movement of a finger of the user from a first location on the surface to a second location on the surface; interpreting the gesture as a command for the deformable region; and manipulating the deformable region of the surface based on the command.