An electronic device and a method of operating the same are provided. The electronic device includes a touch screen, and at least one processor configured to determine, as any one of a first touch type or a second touch type, a type of a user input inputted on the touch screen, output a user interface (UI) corresponding to the first touch type based on the type of inputted touch being determined as the first touch type, correct the determined type as the second touch type based on an error being determined to be present in determining the type of inputted touch as the first touch type, and output a UI corresponding to the second touch type.

According to some embodiments, a processor reads a force from a touch control. Hysteretic behavior is provided through at least three different actuation states and at least four different force threshold values, allowing user-friendly control of disparate actions through one touch interface with applications in volume control, photography, and user authentication. Other possibilities are shown and discussed.

An input device is described which comprises a touch-sensitive surface and a force sensor, wherein the force sensor is adapted to detect a force applied to the touch-sensitive surface. The input device further comprises a vibration sensor and a control unit, wherein the control unit is coupled with the force sensor, the touch-sensitive surface and the vibration sensor. The control unit is adapted to validate a force detected by the force sensor as an input in dependence on a touch of the touch-sensitive surface and in dependence on a vibration detected by the vibration sensor. There is further described a motor vehicle which comprises such an input device. A method of detecting an input at an input device is further described.

An electronic device may include touch input components and associated haptic output components. The control circuitry may provide haptic output in response to touch input on the touch input components and may send wireless signals to the external electronic device based on the touch input. The haptic output components may provide local and global haptic output. Local haptic output may be used to guide a user to the location of the electronic device or to provide a button click sensation to the user in response to touch input. Global haptic output may be used to notify the user that the electronic device is aligned towards the external electronic device and is ready to receive user input to control or communicate with the external electronic device. Control circuitry may switch a haptic output component into an inactive mode to inform the user that a touch input component is inactive.

A touch panel is configured to be disposed on a display panel. The touch panel includes a substrate layer, a first metal layer, an insulating layer covering the first metal layer, a second metal layer, and a protection layer disposed on the second metal layer. The first metal layer includes a plurality of pressure sensors and metal bridges. Each of the pressure sensors includes a pressure sensing electrode. The second metal layer is disposed on the insulating layer and includes a plurality of touch sensors. Each of the touch sensors includes a plurality of first electrodes and second electrodes spaced apart and electrically connected to each other through the metal bridges. The pressure sensing electrode is disposed below the first electrodes and the second electrodes and is electrically connected to a processing chip.

Systems and methods for enabling quick access to media options are provided. A display of a plurality of icons is generated, wherein each of the plurality of icons represents a different one of a plurality of applications. A user input is detected that identifies a first of the plurality of icons associated with a first of the plurality of applications. In response to determining that the user input corresponds to a quick access operation, first and second media asset identifiers and corresponding media options are retrieved from each of second and third applications. A menu that includes the retrieved first and second media asset identifiers is generated for display with the plurality of icons.

Some embodiments include a ferroelectric transistor having an active region which includes a first source/drain region, a second source/drain region vertically offset from the first source/drain region, and a channel region between the first and second source/drain regions. A first conductive gate is operatively adjacent to the channel region of the active region. Insulative material is between the first conductive gate and the channel region. A second conductive gate is adjacent to the first conductive gate. Ferroelectric material is between the first and second conductive gates. Some embodiments include integrated memory. Some embodiments include methods of forming integrated assemblies.

Embodiments of this application disclose a gesture interaction method, applied to a terminal configured with a curved screen, where the curved screen includes a main screen region and a side screen region. The method in the embodiments of this application includes: obtaining, by the terminal, a touch operation input from the side screen region; detecting, by the terminal, a pressing force of the touch operation; and performing, by the terminal, a first function corresponding to the touch operation if the pressing force is greater than a preset threshold.

An electronic device, in response to detecting a touch input on a touch-sensitive surface, determines an intensity of the touch input. In accordance with the intensity of the touch input on the touch-sensitive surface and one or more preselected intensity thresholds, the device determines an intensity stage of the touch input and one or more intensity-based progress values of the touch input, based on an intensity range associated with the determined intensity stage. The device sends touch information to a first software application stored by the electronic device, including the one or more intensity-based progress values of the touch input and information identifying the intensity stage of the touch input, and processes the touch input based on the one or more intensity-based progress values of the touch input and the intensity stage of the touch input.

A capacitive gap force sensor includes a first electrode, a second electrode spaced apart from the first electrode, a first layer of dielectric material positioned between the first electrode and the second electrode, and a second layer of conductive material positioned between the first layer and the second electrode. The first layer has a first compression resistance less than a second compression resistance of the second layer. An effective capacitive sensing gap is defined between the first electrode and the second layer. The first layer is configured to compress or deform and alter the effective capacitive sensing gap when a force is received at the first electrode or the second electrode.