There is provided a touch force sensor including a first drive electrode, a second drive electrode and a receiving electrode. The first drive electrode is used to form a first capacitance with the receiving electrode. The second drive electrode is used to form a second capacitance with the receiving electrode. The receiving electrode shields the first drive electrode such that when a conductor approaches the receiving electrode, only the second capacitance is changed but the first capacitance is not changed. The first capacitance is changed only when the conductor gives a force upon the receiving electrode.

A touch panel include a cover member, a drive electrode, a pressure detecting electrode, and a position detecting electrode. The pressure detecting electrode and the position detecting electrode are alternately arranged in a first direction. The pressure detecting electrode includes a plurality of pressure detecting sections, arranged side by side in a second direction orthogonal to the first direction, that each independently detect a pressure. The position detecting electrode includes a plurality of position detecting sections, arranged side by side in the second direction, that each independently detect a touched position. The area of a pressure detecting section is larger than the area of a position detecting section.

Disclosed is a touch input device including: a touch sensor including a plurality of electrodes; a drive unit configured to apply a driving signal to at least some of the plurality of electrodes of the touch sensor; a touch signal detection unit configured to detect a touch-position-related signal related to a touch position of an object inputted to the touch surface from at least some of the plurality of electrodes of the touch sensor; and an LGM disturbance signal detection unit configured to detect an LGM-disturbance-signal-related signal related to an LGM disturbance signal generated from the touch surface from at least some of the plurality of electrodes of the touch sensor.

A pressure calibration method, applicable to a touch panel which sequentially comprises a first electrode layer, an elastic dielectric layer and a second electrode layer, the first electrode layer includes multiple first electrodes in parallel to a first axis, the second electrode layer includes multiple second electrodes in parallel to a second axis, the pressure calibration method comprising: retrieving a depression event according to mutual capacitance sensing between the first electrodes and the second electrodes; finding a corresponding calibration area according to coordinate of the depression event; and calculating a calibrated pressure value according to a pressure sensing value of the depression event and a pressure calibration function of the corresponding calibration area.

According to various embodiments, disclosed is an electronic device comprising at least one sensor, a display comprising a touch panel, at least one pressure sensor disposed in the upper or lower layer of the touch panel such that pressure applied to at least a part of a region of the display can be sensed, and at least one processor, the at least one processor configured to: sense whether the electronic device is in a submerged state by using the at least one sensor or the display, receive a user input with respect to the at least a part of a region of the display while the electronic device is sensed to be in the submerged state, acquire the pressure and the position of the user input by using the at least one pressure sensor, and process the user input on the basis of the acquired pressure and the acquired position.

A haptic device for an electronic device includes an actuation member formed from a shape-memory alloy (SMA) material that changes shape (e.g., expands or contracts) in response to an applied electrical current. In some cases, the haptic devices described herein also include a restoration mechanism that restores the actuation member to its original shape or to a similar shape. The change in the shape of the actuation member and the restoration of the shape of the actuation member may produce a haptic output at the electronic device.

A system and method for sharing and manipulating digital content allows users an intuitive mechanism with which to interact with touchscreen devices. A provided device with short-range wireless connectivity can interact with a mobile device by providing physical contact points that can be moved or adjusted to interact with displayed content. A series of the physical contact points distributed about the perimeter of the provided device allows an application to collect data regarding the position and orientation of the provided device placed upon the screen of the mobile device. A second set of physical contact points, also made of conductive material, contains at least one individual contact point that functions as a capacitive ‘button’ when the user touches it. Upon placement of the provided device on the capacitive screen of a mobile device, real-time tracking of the changing touch patterns can provide a more intuitive interface for handling digital content.

A method executable by a touch screen processing module of a touch screen includes detecting, via one or more drive-sense circuits of the touch screen, one or more changes in electrical characteristics of one or more electrodes of the touch screen, determining an interface area of the touch screen based on location of the one or more electrodes, associating the interface area with a passive pen, and interpreting the one or more changes in the electrical characteristics as one or more impedance values. When the one or more impedance values is in a first range, the method further includes interpreting the one or more impedance values as a touch. When the one or more impedance values is in a second range, the method further includes interpreting the one or more impedance values as a pressure measurement.

A device with touch sensing. The device includes a first sensor configured to detect a touch and to provide a first sensing signal, a second sensor configured to detect another touch and to provide a second sensing signal, a threshold generator configured to set a first threshold by a reflecting of an amount of change of the second sensing signal to an initial threshold, and a sensor circuit configured to generate a first differential signal based on the first sensing signal, and to determine a first touch based on a consideration of the first threshold with respect to a first signal generated based on the first differential signal and the first sensing signal.

A touch sensor detector system and method incorporating an interpolated sensor array is disclosed. The system and method utilize a touch sensor array (TSA) configured to detect proximity/contact/pressure (PCP) via a variable impedance array (VIA) electrically coupling interlinked impedance columns (IIC) coupled to an array column driver (ACD), and interlinked impedance rows (IIR) coupled to an array row sensor (ARS). The ACD is configured to select the IIC based on a column switching register (CSR) and electrically drive the IIC using a column driving source (CDS). The VIA conveys current from the driven IIC to the IIC sensed by the ARS. The ARS selects the IIR within the TSA and electrically senses the IIR state based on a row switching register (RSR). Interpolation of ARS sensed current/voltage allows accurate detection of TSA PCP and/or spatial location.