In one general aspect, a computing device includes a hardware processor, a memory, a first housing portion including a touch screen display, and a second housing portion coupled to the first housing portion by a hinge, where the second housing portion includes a rotatable keyboard.

Providing haptic communications includes attaching to skin of a user a haptic device that produces touch impulses, electronically transmitting a message to the haptic device, converting the message to touch impulses, and providing the touch impulses to the user. Messages may be converted to touch impulses using coding from the Braille system or Morse code. Messages may be converted to touch impulses using Braille coding where the touch impulses are provided by a positional matrix that is part of the device. Messages may be converted to touch impulses using Morse coding where a Morse code dot is provided by a brief touch and where a Morse code dash is provided by a longer touch. The haptic device may be a patch or a sticker attached to the user with a biocompatible adhesive. The haptic device may notify the user of receipt of a new message using special touch symbols.

A structure for housing electronic components. The structure includes a first layer and a second layer. One or more layers may each have a modulus of elasticity of less than 2.41 MPa. One or more layers may be at least partially affixed to form a combined layer. The combined layer may have a combined modulus of elasticity of less than 2300 MPa. The combined layer may be transparent to electromagnetic waves. The combined layer may be not electrically conductive across an entire surface area of the combined layer. The combined layer may be polycarbonate free. An outermost layer may be a textile layer.

A computing device may include one or more dynamically configurable user input devices. In one example, a triggering event, such as, for example, a user input at a user interface of the computing device, may be detected in connection with an application running on the computing device. In response to the detected triggering event, individual elements of the user interface, such as, for example, keys of a keyboard, may be configured, and/or re-configured, to correspond to the input received and/or the application running on the computing device.

The method of a portable device may includes the steps of setting a first mode based on a first folding angle between the first body and the second body and a second folding angle between the first body and the third body, displaying a first application in the first mode, detecting change of the first folding angle and change of the second folding angle in the first mode, detecting the changed first folding angle being equal to or greater than a first threshold angle and the changed second folding angle less than a second threshold angle and if it is detected that a rear side of the second body is in a state of being contacted with a different real object, switching the first mode to a second mode.

A key structure includes a key cap, a bridge assembly, a first supporting part, a second supporting part, an attractable element and a magnet. The bridge assembly includes first and second hinge parts. One end of the first hinge part has a first link bar, and the other end has a first pivot coupling portion and a first shaft having a first connecting portion. One end of the second hinge part has a second link bar, and the other end has a second pivot coupling portion and a second shaft having a second connecting portion coupled to the first connecting portion. When the magnet under a first attractive position, the first end of the attractable element is attracted to the first attractive position. When the magnet under a second attractive position, the second end of the attractable element is attracted to the second attractive position.

A method for providing haptic feedback at a portable electronic device including a touch-sensitive display and a physical keyboard comprising depressible keys and touch sensors for detecting touches thereon, is provided. In response to detecting a first touch on the physical keyboard, which physical keyboard is moveable relative to the touch-sensitive display, between a first position in which the physical keyboard is exposed for use and a second position in which the physical keyboard is not exposed, wherein the first touch is associated with haptic feedback, first haptic feedback is provided to the physical keyboard. In response to detecting a second touch on the touch-sensitive display when the physical keyboard is in the second position in which the physical keyboard is not exposed, wherein the second touch is associated with haptic feedback, second haptic feedback is provided to the touch-sensitive display.

A haptic keyboard based sound system of an information handling system comprising a coversheet to identify a plurality of key locations of a haptic keyboard and a first key having a piezoelectric element for haptic tactile feedback upon key actuation, a support layer, a contact foil placed between the coversheet and support layer, and a haptic feedback and piezo sound controller operatively coupled to the contact foil to receive the mid-frequency portion of an audio signal and the high frequency portion of the audio signal from an audio controller operably connected to the haptic feedback and piezo sound controller, and send a piezo audio signal to the piezoelectric element to cause the piezoelectric element to generate a mid-frequency and high-frequency sound audio according to the received mid-frequency portion of an audio signal and the high frequency portion of the audio signal.

A button assembly for an electronic device is disclosed. The button assembly integrates a biometric sensor below a top surface of the button. The button assembly is positioned relative to a secondary display of an electronic device. The secondary display can be positioned relative to a keyboard, such as above a top row of keys of the keyboard.

A computing device can include a housing including a peripheral housing defining an aperture, the peripheral housing having a constant cross-sectional area. The computing device can also include a display having a first major surface and a second major surface opposing the first major surface, the display disposed within the aperture defined by the peripheral housing and attached to the housing at one or more locations such that the first major surface and the second major surface of the display are substantially unobstructed by any other portion of the computing device.