An integrated haptic system may include a digital signal processor and an amplifier communicatively coupled to the digital signal processor and integrated with the digital signal processor into the integrated haptic system. The digital signal processor may be configured to receive a force sensor signal indicative of a force applied to a force sensor and generate a haptic playback signal responsive to the force. The amplifier may be configured to amplify the haptic playback signal and drive a vibrational actuator communicatively coupled to the amplifier with the haptic playback signal as amplified by the amplifier.

A main housing portion of a portable information handing system. The main housing portion includes: a bottom cover portion; and, a top cover portion coupled to the bottom cover portion, the top cover portion comprising a top portion unibody cover, a clear mesh portion, the clear mesh portion performing a touch sensing operation and a top portion bottom cover, the top portion unibody cover and the clear mesh portion being fastened to the top portion bottom cover to provide a unibody top cover portion.

An input sensing device includes sensor pixels initialized in response to a reset signal provided through a reset line, and output a sensing signal to a read-out line in response to a scan signal provided through a scan line. A controller generates at least one start signal and clock signals. A selector selectively provides the at least one start signal and the clock signals to first control lines or second control lines. A reset driver connected to the first control lines, and supplying reset signals to at least some of the reset lines based on the at least one start signal and the clock signals provided through the first control lines. A scan driver is connected to the second control lines, and supplies scan signals to at least some of the scan lines based on the at least one start signal and the clock signals.

A force sensing resistor (FSR) that is constructed with a first substrate made of polyimide disposed underneath a second substrate that is resistive and flexible. A handheld controller for an electronic system may include the FSR having a first substrate made of polyimide. The FSR may be mounted on a planar surface of a structure within the controller body, such as a structure mounted within a handle of the controller body, and/or a structure that is mounted underneath at least one thumb-operated control that is included on a head of the controller body. The FSR may be configured to measure a resistance value that corresponds to an amount of force applied to an outer surface of the handle and/or an amount of force applied to the at least one thumb-operated control.

A method includes obtaining sensor coordinates corresponding to positions on a sensor pointed to by an electronic pen, and values determined based signals received from the electronic pen; mapping, using a first mapping method, a first set of the sensor coordinates to first display screen coordinates; determining that a first one of the values is greater than or equal to a first threshold value; determining that a second one of the values is less than or equal to a second threshold value, after determining that the first one of the values is greater than or equal to the first threshold value; and in response to determining that the second one of the values is less than or equal to the second threshold value, mapping, using a second mapping method, a second set of the sensor coordinates to a second display screen coordinates.

A force sensing device includes: a substrate disposed inside a housing and spaced apart from inner side surfaces of a first force member and a second force member; a first inductor element mounted on a first surface of the substrate and spaced apart from the first force member, the first inductor element having a first inductance, variable at a time of force input pressing the first force member; a second inductor element mounted on the first surface of the substrate and spaced apart from the second force member, the second inductor element having a second inductance, variable at a time of force input; and a support member having one end contacting the first surface of the substrate between the first inductor element and the second inductor element and another end contacting an inner side surface of the housing between the first force member and the second force member.

The present disclosure generally relates to interfaces and techniques for media playback on one or more devices. In accordance with some embodiments, an electronic device includes a display, one or more processors, and memory. The electronic device receives user input and, in response to receiving the user input, displays, on the display, a multi-device interface that includes: one or more indicators associated with a plurality of available playback devices that are connected to the device and available to initiate playback of media from the device, and a media playback status of the plurality of available playback devices.

Methods and apparatuses are provided that address interoperability limitations of current digital pens and touch sensitive devices. In aspects, methods are provided for operating an adaptable digital pen and touch sensitive device to determine the best means for pen state information such as pressure information to be transferred from the pen to the device. A digital pen includes multiple communication interfaces to permit wide compatibility with touch sensitive devices. A communication interface is provided that enables the digital pen to communicate via an active pen protocol with a digitizer of the touch sensitive device while operating in a first mode. Another communication interface is provided as an alternative channel for communicating pen state information to the touch sensitive device while operating in a second mode. Where neither such interface suffices for communicating pen state information to the touch sensitive device, the digital pen may operate in a reflective capacitive mode.

A touch panel device is provided with a display panel, a touch sensor, a panel driving unit, a division range setting unit, and a correction unit. The division range setting unit divides and sets the detection range of the touch sensor into a plurality of ranges. The correction unit corrects an object detection area for detecting a touch operation to an object in a touch sensor for each of a plurality of ranges based on operation position deviation data indicating an operation position deviation between a position where the object is displayed on the display panel and a touch operation position of the touch sensor for each of the plurality of ranges.

A method of recording measurement data for characterizing a response of a given type of device to an applied force, the given type defining devices of that type as comprising a defined arrangement of a surface and N force sensors of the device concerned, where N≥1, each force sensor configured to output a sensor signal, wherein in the defined arrangement the N force sensors are operatively coupled to a defined input region of the surface so as to sense a force applied to that input region, the method comprising: for a specimen device of the given type, performing at least one measurement procedure, each measurement procedure comprising at least one measurement operation, each measurement operation comprising applying a defined force at a corresponding location on the input region of the device concerned and recording measurement data for that device and location based on the sensor signals of the N force sensors of that device. Also disclosed are a related computer-implemented method of generating a characterization definition for devices of the given type, a computer-implemented method of generating a configuration definition for devices of the given type for a given use case defined by a use-case definition, a method of configuring a candidate device of the given type for the given use case, and a method of assessing or calibrating a candidate device of the given type.