A touch sensor, a touch detection device and a detection method, and a touch control apparatus are provided. The touch sensor comprises a first electrode layer, a rigid insulating layer, a second electrode layer, a compressible layer, and a third electrode layer disposed successively The compressible layer may change the distance between the second electrode layer and the third electrode layer when subjected to a touch pressure. The second electrode layer and the third electrode layer may form a capacitor structure, and the capacitance value of the capacitor structure may vary with the distance between the second electrode layer and the third electrode layer. The pressure information of a user's touch operation can be calculated from the change of the capacitance value.

Embodiments of the present disclosure provide a force detection apparatus and method, a touch device and an electronic terminal. The apparatus includes: a first detection capacitor, and a second detection capacitor configured to perform differential processing for a capacitance of the first detection capacitor to cancel an interference signal; wherein the first detection capacitor includes a force detection electrode, and the second detection capacitor includes a reference detection electrode, the force detection electrode and the reference detection electrode being arranged within a surface, such that the first detection capacitor and the second detection capacitor are simultaneously coupled to the interference signal causing interference to force detection, and differential processing is performed for capacitances of the first detection capacitor and the second detection capacitor. In this way, the interference signal, for example, which caused by a display device, is canceled, and sensitivity of force detection is enhanced while temperature drift is inhibited.

A controlling device has a moveable touch sensitive panel positioned above a plurality of switches. When the controlling device senses an activation of at least one of the plurality of switches when caused by a movement of the touch sensitive panel resulting from an input at an input location upon the touch sensitive surface, the controlling device responds by transmitting a signal to an appliance wherein the signal is reflective of the input location upon the touch sensitive surface.

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 flexible touch panel is provided. Both reduction in thickness and high sensitivity of a touch panel are achieved. The touch panel includes a first flexible substrate, a first insulating layer over the first substrate, a transistor and a light-emitting element over the first insulating layer, a color filter over the light-emitting element, a pair of sensor electrodes over the color filter, a second insulating layer over the sensor electrodes, a second flexible substrate over the second insulating layer, and a protective layer over the second substrate. A first bonding layer is between the light-emitting element and the color filter. The thickness of the first substrate and the second substrate is each 1 μm to 200 μm inclusive. The first bonding layer includes a region with a thickness of 50 nm to 10 μm inclusive.

A touch sensor is disclosed. The touch sensor includes a touch panel including a plurality of sensing nodes in columns and rows and sensing lines connected to the sensing nodes, a touch sensing unit configured to provide a driving signal to at least one of sensing lines to charge at least one of the sensing nodes during a first time period and discharge voltages on the sensing nodes during a second period, and a charge sharer or equalizer configured to short-circuit the sensing lines during the second time period.

A sensor comprises conductive elements arranged and connected for proximity sensing. The conductive elements are formed of an ionically conductive polymer. The sensor may also include conductive elements arranged and connected for touch sensing. The conductive elements may be connected to an alternating-current (AC) source. Another sensor comprises one or more conductive elements arranged and connected for touch sensing by detecting resistivity changes in the one or more conductive elements. A flexible and transparent sensor is also provided, which comprises a layer of a piezoelectric polymer and conductive elements in contact with the layer for transmitting an electric signal generated by compression of the layer. Methods and processes for using such sensors are also provided.

The present disclosure relates to a touch sensor and a method for sensing a touch using the same, the touch sensor including a substrate, a first sensor and a plurality of second sensors provided on the substrate and configured to sense a location and a force of a touch, wherein the first sensor is disposed in a central area of one surface of the substrate, the plurality of second sensors are arranged to surround the first sensor, and a width of the plurality of second sensors increases as a distance from the central area increases.

An apparatus includes a force sensor circuit and a controller. The force sensor circuit includes first, second, third, and fourth electrodes disposed on a substrate. The first and second electrodes extend through first and second cells of a row of cells. The third and fourth electrodes extend through third and fourth cells of a column of cells. The first electrode occupies more area in the first cell than in the second cell. The second electrode occupies more area in the second cell than in the first cell. The third electrode occupies more area in the third cell than in the fourth cell. The fourth electrode occupies more area in the fourth cell than in the third cell. The controller detects a force and a position of the force based on signals communicated by the force sensor circuit.

An electronic device configured to provide localized haptic feedback to a user on one or more regions or sections of a surface of the electronic device. A support structure is positioned below the surface, and one or more haptic actuators are coupled to the support structure. In some examples, the support structure is shaped or configured to amplify a response to a haptic actuator. When a haptic actuator is actuated, the support structure deflects, which causes the surface to bend or deflect at a location that substantially corresponds to the location of the activated haptic actuator. In some examples, prior to providing haptic feedback, at least one haptic actuator is electrically pre-stressed to place the haptic actuator(s) in a pre-stressed state. When haptic feedback is to be provided, at least one haptic actuator transitions from the pre-stressed state to a haptic output state to produce one or more deflections in the surface. In other examples, a haptic structure incorporates a piezoelectric element that is shaped to reduce the overall cost of the haptic structure while still providing high actuation performance.