The present disclosure generally relates to user interfaces. In some examples, the electronic device transitions between user interfaces for capturing photos based on data received from a first camera and a second camera. In some examples, the electronic device provides enhanced zooming capabilities that result in visual pleasing results for a displayed digital viewfinder and for captured videos. In some examples, the electronic device provides user interfaces for transitioning a digital viewfinder between a first camera with an applied digital zoom to a second camera with no digital zoom. In some examples, the electronic device prepares to capture media at various magnification levels. In some examples, the electronic device enhanced capabilities for navigating through a plurality of values.

Technologies are described for pressure sensors used in display devices. In one embodiment, a reference ground layer and sensing pad can be positioned between a display substrate and a window substrate. Additionally, a compression region can be positioned between the display substrate and the window substrate. The compression region can be compressed so as to change a distance between the reference ground layer and the sensing pad. By placing the compression region between the window substrate and the display substrate, the air gap below the display substrate can be removed. In still another embodiment, the sensing pad is aligned over a frit layer, but it is divided into spaced-apart sub-regions that are serially coupled together. Gaps between the sub-regions are sized such that the laser can adequately penetrate through the sensor pad to melt the frit.

The present disclosure provides a touch screen and a pressure touch detection method thereof. The touch screen comprises a touch panel and a frame surrounding sides of the touch panel, the touch panel comprises a display module and a touch module, at least one pressure sensor is arranged between the touch module and the frame; wherein the pressure sensor comprises a first electrode, a second electrode, and a piezoresistive material layer disposed between the first electrode and the second electrode; the first electrode is located on a same layer and is formed by a same material as a touch electrode of the touch module; the second electrode is formed by a portion of the frame in touch with the piezoresistive material layer and located at the opposite side of the first electrode; both the first electrode and the second electrode are connected with a touch control chip.

A force sensing method, applied to a force sensing system comprising a plurality of force sensors and a touch sensing surface, comprising: (a) determining a first location of a first object on the touch sensing surface; (b) defining a first force sensing region according to the first location; and (c) computing a first system sensing force which the first object causes to the touch sensing surface according to the first location, and according to at least one sensor sensing force of a first part of the force sensors corresponding to the first force sensing region. The present invention also discloses a force sensing system which uses the above-mentioned force sensing method, and an efficient force sensor calibration method. Noises can be reduced and power consumption can be decreased, since only sensor sensing forces of force sensors near the object are used for computing the system sensing force.

A touch panel device includes: a touch panel; an elastic member that supports the touch panel; a plurality of depressing force sensors arranged at installation positions where depression or upward warps of the touch panel occur due to the application of depressing force; and processing circuitry to obtain touch coordinates; to obtain a plurality of detection values corresponding to the sensor signals; and to load a plurality of predetermined depressing force calculation modes from a storage storing a plurality of regions on the operation surface and the plurality of predetermined depressing force calculation modes corresponding to the plurality of regions, to select a depressing force calculation mode for a region corresponding to the touch coordinates from the plurality of depressing force calculation modes, and to calculate the depressing force by using the selected depressing force calculation mode and the plurality of detection values.

Various examples of the present invention relate to a method for controlling a biosensor linked with a display, the method comprising: acquiring an input of a user on the basis of a first region corresponding to the biosensor and a second region which corresponds to a touch sensor and is adjacent to at least a part of the first region; confirming an input shape corresponding to the input of the user; and acquiring, through a control of the biosensor, bio-information corresponding to the input of the user when the confirmed input shape satisfies a predetermined condition. Other embodiments are also possible.

A touch panel according to the embodiment includes a substrate including an effective area and a dummy area surrounding the effective area; a transparent electrode on the substrate; and an outer dummy layer on the dummy area, wherein the outer dummy layer comprises a piezoelectric material.

An electronic device is disclosed that includes a body having an external surface; a processor enclosed within the body; and at least one force sensor disposed on the body and connected to the processor, the force sensor being operable to generate at least one signal indicative of a magnitude of a force applied to the external surface of the body, the processor being configured to receive the at least one signal and to determine a user input by processing the received at least one signal. The device may include at least one touch sensing surface and may be operable to receive a touch applied to the external surface of the body and to generate at least one signal indicative of a location of the received touch on the at least one touch sensing surface.

The disclosure relates to a combined input and output device including a screen for displaying at least one operating element, a touchscreen arranged above screen, for detecting a position of a contact with the operating surface of the touchscreen, and a frame. The screen is arranged under the touchscreen in frame, and, on the frame, a plurality of mini switches are arranged, on which the touchscreen rests.

There is presented a system and method for detecting mobile device fault conditions, including detecting fault conditions by software operating on the mobile device. In one embodiment, the present invention provides for systems and methods for detecting a that a mobile device has a cracked screen, and reporting the status of the screen, working or not, so that appropriate action may be taken by a third party. In one embodiment, the data obtained by testing of the mobile device is encrypted to prevent tampering or spoofing by the user of the mobile device, and is suitably decrypted by the recipient or software running within a server.