Abstract: A haptically enabled device includes a haptic output device used to control motion. The haptically enabled device determines a desired motion, and then generates a haptic effect on the haptic output device to cause the desired motion.

Abstract: One illustrative system disclosed herein includes a sensor configured to detect a user interaction with a touch surface and transmit a sensor signal including data associated with a pressure of the user interaction. The illustrative system also includes a processor in communication with the sensor, the processor configured to: receive the sensor signal; determine, based on the sensor signal, a pressure level; determine a user interface level based at least in part on the pressure level; perform a function associated with the user interface level and the user interaction; determine a haptic effect based at least in part on the user interface level and the user interaction; generate a haptic signal based at least in part on the haptic effect; and transmit the haptic signal. The illustrative system further includes a haptic output device in configured to receive the haptic signal and output the haptic effect.

Abstract: A system that controls a haptic effect experienced at a trigger is provided. The system receives a haptic effect definition including haptic data. The system further receives trigger data including at least one of: a position of a trigger of a peripheral device; or a range of the trigger of the peripheral device. The system further determines whether a trigger condition is reached based on the received trigger data. The system further sends a haptic instruction and the haptic effect definition to the peripheral device when the trigger condition is reached. The system further causes a haptic output device (or multiple haptic output devices) to produce haptic effects that are based on the haptic effect definition at the peripheral device in response to the haptic instruction.

Abstract: A system that produces a dynamic haptic effect and generates a drive signal that includes a gesture signal and a real or virtual device sensor signal. The haptic effect is modified dynamically based on both the gesture signal and the real or virtual device sensor signal such as from an accelerometer or gyroscope, or by a signal created from processing data such as still images, video or sound. The haptic effect may optionally be modified dynamically by using the gesture signal and the real or virtual device sensor signal and a physical model, or may optionally be applied concurrently to multiple devices which are connected via a communication link. The haptic effect may optionally be encoded into a data file on a first device. The data file is then communicated to a second device and the haptic effect is read from the data file and applied to the second device.

Abstract: A platform including a security system is described. The security system comprises, in one embodiment, a multi-state system having a plurality of modes, available whenever the platform has a source of power. The modes comprise an unarmed mode, in which the security system is not protecting the platform, an armed mode, in which the platform is protected, the armed mode reached from the unarmed mode, after an arming command, and a suspecting mode, in which the platform is suspecting theft, the suspecting mode reached from the armed mode, when a risk behavior is detected.

Abstract: A system provides overlaid haptic effects. The system determines a primary content and a primary haptic effect associated with the primary content. The system also determines a secondary content and a secondary haptic effect associated with the secondary content. Subsequently, the system outputs the secondary content concurrently with the primary content, and also outputs the secondary haptic effect concurrently with the primary haptic effect on at least one haptic output device.

Abstract: A system includes a processor, an audio display, and a haptic peripheral including a haptic output device. The audio display includes a speaker and a headphone connector. The haptic output device is configured to receive a control signal from the processor and output a haptic effect to the haptic peripheral in response to the control signal from the processor. The processor is configured to vary the control signal for the haptic output device depending on an audio output accessory connectivity status of the audio display such that the haptic output device generates and applies a first haptic effect if the audio display is connected to an audio output accessory in order to output audio through the headphone connector and the haptic output device generates and applies a second haptic effect if the audio display is not connected to an audio output accessory in order to output audio through the speaker.

Abstract: Various systems, game controllers, and methods for simulating various objects such as weapons are provided. For example, a game controller may include a trigger, a processor within the body that receives a trigger signal when the trigger is activated by the user. The processor may communicate with a computer running a software program such as a gaming application, and an actuator coupled to the trigger, the actuator configured to output a haptic effect to the trigger in response to receiving a control signal from the processor. The game controller may simulate a gun and generate a recoil effect. In some embodiments, the recoil effect may be generated by impacting a moving mass from a discharge end of the gun to a handle end of the gun. In some embodiments, the recoil effect may be generated by using a body part of a user as a tether.

Abstract: A haptic representation system is provided that generates a haptic effect in response to sensor input. The sensor input is mapped to a haptic signal. The haptic signal is sent to an actuator configured to receive the haptic signal. The actuator utilizes the haptic signal to generate the haptic effect.

Abstract: A system is provided that produces haptic effects. The system receives an audio signal that includes a low-frequency effects audio signal. The system further extracts the low-frequency effects audio signal from the audio signal. The system further converts the low-frequency effects audio signal into a haptic signal by shifting frequencies of the low-frequency effects audio signal to frequencies within a target frequency range of a haptic output device. The system further sends the haptic signal to the haptic output device, where the haptic signal causes the haptic output device to output one or more haptic effects.

Abstract: A processing device may include a first processor executing an operating system including a configurable setting and an isolated execution environment including a second processor communicatively coupled to the first processor, and a secure store coupled to the second processor to store a setting profile containing a copy of the configurable setting, in which the second processor is to, subsequent to establishing a trust relationship between the isolated execution environment and the operating system, synchronize the configurable setting with the setting profile.

Abstract: A system is provided that produces haptic effects. The system receives an audio signal that includes a low-frequency effects audio signal. The system further extracts the low-frequency effects audio signal from the audio signal. The system further converts the low-frequency effects audio signal into a haptic signal by shifting frequencies of the low-frequency effects audio signal to frequencies within a target frequency range of a haptic output device. The system further sends the haptic signal to the haptic output device, where the haptic signal causes the haptic output device to output one or more haptic effects.

Abstract: A haptic representation system is provided that generates a haptic effect in response to sensor input. The sensor input is mapped to a haptic signal. The haptic signal is sent to an actuator configured to receive the haptic signal. The actuator utilizes the haptic signal to generate the haptic effect.

Abstract: Systems and methods are described herein for authenticating a user device that uses a wireless local area network, determining the location of the device, and complying with wireless guidelines based at least in part on the location. The user device may communicate with a location server to determine the user device's location. The user device will determine which wireless guidelines are applicable to that location and configure the wireless system or any device feature to comply with the guidelines. For example, some locations prohibit the operation of wireless devices with a frequency of greater than 5 GHz. If the location of the user device dictates compliance with that guideline, the user device will not transmit wireless signals with a frequency of greater than 5 GHz.

Abstract: A wearable apparatus includes a wearable article that is wearable by a person. The wearable apparatus includes a display, an input portion on a surface of the apparatus, and a haptic actuator. A controller is electrically connected to the input portion and the haptic actuator. The controller is programmed to generate haptic drive signals in response to receiving an input signal from the input portion.

Abstract: One disclosed method includes the steps of determining a context of a user device; determining a notification to be provided by the user device; determining a category of the notification; generating a haptic effect based on the category of the notification; and outputting the haptic effect to the user device. Another disclosed method includes the steps of receiving a selection of a category for a haptic effect, the category one of a plurality of predetermined categories of haptic effects; obtaining a plurality of constraints for the haptic effect based on the selected category; receiving an input indicating a characteristic of the haptic effect; determining whether the characteristic violates any of the plurality of constraints; responsive to determining that the characteristic violates at least one of the plurality of constraints, refusing the input; and otherwise, modifying the haptic effect based on the input.

Abstract: A system provides overlaid haptic effects. The system determines a primary content and a primary haptic effect associated with the primary content. The system also determines a secondary content and a secondary haptic effect associated with the secondary content. Subsequently, the system outputs the secondary content concurrently with the primary content, and also outputs the secondary haptic effect concurrently with the primary haptic effect on at least one haptic output device.

Abstract: Generally, this disclosure provides devices, systems and methods for improved transmit power adaptation for platforms with wireless communication capability. A device may include a memory to store a first transmission (Tx) power level and a Tx power determination module to receive a second Tx power level from a device driver, the second Tx power level provided from a Basic Input/Output System (BIOS) associated with a platform hosting the device. The Tx power determination module may further determine a third Tx power level based on a comparison of the first Tx power level and the second Tx power level. The device may further include a radio frequency (RF) transmission module to transmit a wireless signal at the third Tx power level.

Abstract: A system of the present disclosure may include a sensor configured to detect user interaction with a touch surface and transmit a sensor signal associated with the user interaction; a processor in communication with the sensor, the processor configured to: determine a position of the user interaction based on the sensor signal, determine a feature associated with the position of the user interaction, control a device associated with the feature, modify a display signal based in part on the user interaction, select a haptic effect to generate based at least in part on user interaction and the position, the haptic effect selected to simulate the feature, and transmit a haptic signal to generate the haptic effect, and a haptic output device in communication with the processor and coupled to the touch surface, the haptic output device configured to receive a haptic signal and output a haptic effect.

Abstract: A system that produces a dynamic haptic effect and generates a drive signal that includes a gesture signal and a real or virtual device sensor signal. The haptic effect is modified dynamically based on both the gesture signal and the real or virtual device sensor signal such as from an accelerometer or gyroscope, or by a signal created from processing data such as still images, video or sound. The haptic effect may optionally be modified dynamically by using the gesture signal and the real or virtual device sensor signal and a physical model, or may optionally be applied concurrently to multiple devices which are connected via a communication link. The haptic effect may optionally be encoded into a data file on a first device. The data file is then communicated to a second device and the haptic effect is read from the data file and applied to the second device.