An example force-sensitive electronic device is described herein. The device can include a device body, a touch surface bonded to the device body in a bonded region that is arranged along a peripheral edge of the touch surface, and a plurality of force sensors that are arranged between the device body and the touch surface. Each of the plurality of force sensors can be spaced apart from the bonded region.

A force-sensitive input device for receiving user input. The input device can include a contact (e.g., touch) sensor and a plurality of force sensors. By combining the information from a multi-touch event with information from each of the plurality of force sensors, a contact centroid and a force centroid can be determined. Thereafter, by projecting a vector defining the force applied to the input device onto a vector defined between the contact centroid and an individual contact location, a magnitude of force applied at that contact location can be approximated.

An input device includes a touch plate having a central axis and a top surface with three outer points evenly spaced away from the central axis. A touch sensor is used to detect a user touch on the top surface at the first outer point, and a support mechanism supports the touch plate and is configured to translate the touch plate at the second and third outer points upon application of the user touch and translation of the touch plate at the first outer point. Translation of the three outer points is substantially equal along the central axis.

The operating device for a vehicle is provided with a housing having a front face with a receiving opening being delimited by an opening edge, and having a rear wall, and with an operating element being arranged in the receiving opening at a distance from the opening edge thereof and having an operating surface, said operating element having a front face provided with the operating surface, a rear face, and a delimiting edge region. The operating device further comprises a holding element having a bottom wall and support parts which protrude from the bottom wall and end below the delimiting edge region of the operating element and are mechanically coupled to the operating element in the delimiting edge region. The bottom wall of the holding element has a central region which is spaced from the support parts and within which the bottom wall of the holding element is supported against the rear wall of the housing. A manual actuation of the operating element is detected by multiple actuation sensors which are arranged between the bottom wall of the holding element and the rear wall of the housing within the surrounding region that surrounds the central region of the bottom wall of the holding element and is arranged at a distance from the rear wall of the housing. An evaluation unit receives the signals from the actuation sensors and evaluates said signals for the purpose of detecting a manual actuation of the operating element performed with a predefinable minimum pressing force.

A display device includes: a display unit that displays a screen; a plurality of detection sensors that integrally deform with the display unit and output a signal corresponding to the deformation; and a control unit that converts coordinate data on the display unit based on detection data related to the deformation detected by the plurality of detection sensors. Typically, the control unit, based on detection data from the plurality of detection sensors arranged in a plurality of directions, calculates moving direction of a coordinate point on the display unit, and its moving amount and moving speed, the coordinate point corresponding to arrangement directions of the detection sensors.

A display module, an electronic device, and an electronic device control method relate to the field of display technologies. A pressure sensor is integrated into a layered structure of the display module. The display module includes an active area and an inactive area. The inactive area includes the pressure sensor. The pressure sensor includes one or more pressure sensitive resistors, at least one pressure sensitive resistor is disposed at a same layer as a semiconductor active layer of the active area, and the at least one pressure sensitive resistor is made of a same material as the semiconductor active layer.

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.

The present invention is a method for measuring touching position, touching energy and display device thereof. While touching position is measured, at least two sensors are installed in dispersing form under the sensing panel of touch control equipment. The sensing panel is divided into a plurality of grids. The unit energy distribution vector of the touching signal is compared with the unit energy distribution vector of the benchmark signal of each grid, therefore touching position is obtained. While touching energy is measured, at least one sensor is installed under the sensing panel. The sensing panel is divided into a plurality of grids. Touching position would be obtained by the above method for measuring touching position or other methods. The touching energy could be calculated by comparing the detected touching signal energy with energy of benchmark signal at touching position in corresponding grid. The present invention could reduce the cost, complexity and power consumption of touch control equipment dramatically.

An input device includes a touch plate having a central axis and a top surface with three outer points evenly spaced away from the central axis. A touch sensor is used to detect a user touch on the top surface at the first outer point, and a support mechanism supports the touch plate and is configured to translate the touch plate at the second and third outer points upon application of the user touch and translation of the touch plate at the first outer point. Translation of the three outer points is substantially equal along the central axis.

An example force sensitive touch panel device can include a device body; a touch surface for receiving a touch force; a sensor for sensing touch force that is arranged between the device body and the touch surface; and a membrane configured to mechanically isolate the device body and the touch surface. Additionally, the membrane can apply a preload force to the sensor.