A touch sensing system is configured to determine a state of a paper material indicative of a touch input on the paper material. The actions include receiving one or more values of features representing physical properties of a paper material. The system generates, by a pair of electrodes in a conductive material that is electrically connected with the paper material, an electric field in the conductive material. The paper material is configured to shunt current from the conductive material when the paper material is touched. The system measures the electric field in the conductive material in the conductive material. The system generates an approximation of the electric field in the conductive material. The system determines with a classifier a state of the paper material indicative of a touch input on the paper material.

A capacitive sensor includes: a substrate that is in the form of a sheet; and a sensor electrode that is capacitive and disposed on a frontside of the substrate. The sensor electrode is a conductive fabric made by applying a metal plating on a mesh fabric that is woven of a plurality of warps and a plurality of wefts and that has openings each formed by two adjacent warps among the plurality of warps and two adjacent wefts among the plurality of wefts. An area defined by a maximum outside diameter of a warp or weft is smaller than an area of an opening space of each of the openings.

Left and right earphones are independently wireless such that the left and right earphones are not physically connected when worn by a user. Each earphone comprises a speaker, microphone and a body portion with an SOC. Each SOC comprises a wireless communication circuit and a processor. Each processor comprises a digital signal processor for noise cancellation.

An input device has an operative member on which switches are arranged to receive a pushing force. The input device has a control unit which is configured to store both a first correction coefficient and a second correction coefficient. The first correction coefficient may correct variations in displacement caused by differences in pushing positions on the operative member. The second correction coefficient may correct differences in sensitivity among a plurality of sensors. The control unit is configured to perform: correcting a plurality of displacements by the first correction coefficient and the second correction coefficient; and determining whether presence or absence of a push operation by comparing a summation of corrected values with a predetermined threshold value.

A touch control display substrate, a touch control display panel, and a touch control display device are provided. The touch control display substrate includes a substrate, a plurality of touch control electrode blocks, a plurality of first touch control switches, a plurality of compensation switches, a plurality of first signal lines, and a plurality of compensation signal lines. Each of the compensation signal lines is connected to one of the compensation switches and one of the touch control electrode blocks. Each of the touch control signal blocks is connected to the first touch control switches by the first signal lines, and is connected to the compensation switches by the compensation signal lines.

Systems and methods of printing sensor loops on a sensor mat for use in a steering wheel are disclosed herein. For example, the sensor mat may include a base substrate, one or more printed sensing loops, and an insulating material. The printed sensing loops are made with conductive ink that is disposed upon the base substrate or the insulating layer from a print head and adheres thereto. These sensor mats are versatile with respect to the type of base substrate and insulating materials that may be used, the shape of the sensing loops, and the area each loop may occupy. Shielding loop(s) may also be printed adjacent the sensing loop(s). This configuration allows shielding for the sensing loops as part of the sensing mat, which may reduce the thickness of the steering wheel rim and manufacturing and installation times.

Various embodiments include processing devices and methods for managing multisensor inputs on a mobile computing device. Various embodiments may include receiving multiple inputs from multiple touch sensors, identifying types of user interactions with the touch sensors from the multiple inputs, identifying sensor input data in a multisensor input data structure corresponding with the types of user interactions, and determining whether the multiple inputs combine as a multisensor input in an entry in the multisensor input data structure having the sensor input data related to a multisensor input response. Various embodiments may include detecting a trigger for a multisensor input mode, entering the multisensor input mode in response to detecting the trigger, and enabling processing of an input from a touch sensor.

An audio output device comprises a loudspeaker and, four stem control inputs substantially even spaced on the upper surface of a housing. The stem control inputs are each divided into four segments, each comprising a touch sensor and an illumination unit. Each stem control input is associated with a different stem in an audio track for playback via the loudspeaker. Touching the segments of each stem control input results in the touch being detected and a touch signal being output by the respective segment. In response to a touch signal, the associated illumination unit is togged on/off and a property of the associated stem is varied during playback by loudspeaker.

A vehicle smart garnish is provided. The vehicle smart garnish includes an upper casing formed with a plurality of symbols to which light is emitted, a capacitive touch sensor pad corresponding to at least one of the plurality of symbols and recognizing a touch, a holder casing in which the capacitive touch sensor pad is mounted and coupled from a rear of the upper casing, and a circuit board positioned behind the holder casing and on which a light emitting element emitting light is mounted and configured to detect a touch signal of the capacitive touch sensor pad, wherein the holder casing includes a light guide path for guiding the light emitted from the light emitting element to the plurality of symbols, and a light reflection layer is formed on a partition of the light guide path.

The method for product selection comprises the steps of selecting a product among a plurality of options of different products, said selection being carried out by remotely signaling a label that represents the selected product; checking that no other selection has been detected; checking that the detected selection lasts longer than a predetermined period of time or more than a predetermined electromagnetic field strength; and dispensing the selected product if it has been verified that no other selection has been detected and if it has been verified that the selection lasts longer than said predetermined period of time and less than the predetermined electromagnetic field strength, or canceling the selection of the product if another selection has been detected or the detected selection lasts less than said predetermined period of time or is greater than the predetermined electromagnetic field strength.