Abstract: A method of rendering a haptic effect on a haptic output device is provided based on an ambient environmental stimulus signal received from a sensor. A notification event based on the stimulus signal is determined. A haptic effect is rendered on a haptic output devices based on the notification event. A system and computer-readable medium are also provided for rendering a haptic effect on a haptic output device based on an ambient environmental stimulus signal.

Abstract: The present disclosure is generally directed to systems and methods for providing haptic effects based on information complementary to multimedia content. For example, one disclosed method includes the steps of receiving multimedia data comprising multimedia content and complementary data, wherein the complementary data describes the multimedia content, determining a haptic effect based at least in part on the complementary data, and outputting the haptic effect while playing the multimedia content.

Abstract: A haptic conversion system is provided that analyzes an audio signal, generates a plurality of haptic signals based on the analysis of the audio signal, and plays the generated plurality of haptic signals through a plurality of actuators to produce one or more haptic effects. The haptic conversion system maps the generated plurality of haptic signals to the plurality of actuators based on one or more audio characteristics of the audio signal. Each generated haptic signal includes one or more haptic parameters, and is played at its mapped actuator to generate the one or more haptic effects.

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: Systems, methods, and computer program products for providing composite haptic effects are disclosed. One disclosed method includes detecting a touch occurring in a touch area when an object contacts a touch surface and selecting a composite haptic effect to generate in response to the touch, the composite haptic effect including at least one surface-based haptic effect and at least one other effect. Based on the selected composite haptic effect, a first haptic signal can be sent to cause an actuator to vary a coefficient of friction of the touch surface and a second actuator can be caused to provide a second haptic output in addition to the variation in the coefficient of friction. The second haptic signal can be sent to a second actuator or the same actuator(s) used to vary the coefficient of friction can generate the second haptic output.

Abstract: A system includes an electronic device that includes a display screen, a cover configured to cover the display screen, a sensor configured to sense an input gesture comprising deformation and/or movement of the cover relative to the electronic device, and a processor configured to determine an action for the electronic device to perform based on the input gesture, to determine a haptic effect to generate based on the input gesture and/or the action for the electronic device to perform, and to initiate the action. The system also includes a haptic output device configured to generate the haptic effect.

Abstract: An apparatus, such as a haptic-enabled device, and a method for providing boost protection logic are presented. The method comprises receiving, by a control circuit of the apparatus, a nonzero drive signal to be used by the haptic actuator to generate a haptic effect. The control circuit causes a first portion of the nonzero drive signal to be applied to the haptic actuator in a boost mode. The control circuit detects a boost duration exceeding a first defined time threshold, such as a boost timeout threshold, or detects an accumulated boost time exceeding the first defined time threshold. In response, the control circuit causes a second portion of the nonzero drive signal to be applied to the haptic actuator in an amplitude-limited mode.

Abstract: A system includes a wearable device configured to be worn by a user. The wearable device includes a flexible mounting, and a haptic output device connected to the flexible mounting. The system includes a signal generator configured to generate a haptic signal and communicate the haptic signal to the haptic output device. The haptic signal includes a short duration control pulse configured to create a small deformation sensation to the user.

Abstract: A method and system for energy savings with silent haptics is presented. A haptically-enabled device includes a processor that executes a haptic track containing haptic instructions. The haptic track is analyzed to determine the presence of a zero-force interval, also known as a silent haptic. The duration of the zero-force interval is determined, and if the duration exceeds a pre-determined threshold, then the system or method enters an energy savings mode. An overhead time associated with the terminating of the energy savings mode is determined. And, the energy savings mode is terminated at the conclusion of the zero-force interval less the overhead time.

Abstract: One illustrative system disclosed herein includes a computing device that comprises a memory and a processor in communication with the memory. The processor generates an interactive user interface and obtains an input parameter and a haptic parameter via the interactive user interface. The processor maps the input parameter to the haptic parameter using a mapping algorithm and designs a dynamic haptic effect based at least in part on mapping the input parameter to the haptic parameter. The processor can then generate a plurality of dynamic haptic effects for a plurality of user devices based at least in part on the designed dynamic haptic effect.

Abstract: One illustrative system disclosed herein includes a computing device that comprises a memory and a processor in communication with the memory. The system also includes an xPC target machine that is capable of achieving sampling rates of at least 100 khz and in communication with the computing device and a user device that includes a sensor and a haptic output device. The processor generates a simulate reality environment and determines a haptic effect based on the simulated reality environment or a sensor signal from the sensor. The processor transmits data about a parameter of the haptic effect or the sensor signal to the xPC target machine, which determines the parameter of the haptic effect and generates, in substantially real time, a haptic signal. The xPC target machine transmits the haptic signal to the haptic output device, which is configured to receive the haptic signal and output the haptic effect.

Abstract: Systems and methods for multi-user shared virtual and augmented reality-based haptics are disclosed. One illustrative method for multi-user shared virtual and augmented reality-based haptics includes determining a position of an object; determining a viewpoint of at least one observer with respect to the object; determining a haptic effect to be output based at least in part on the position and the viewpoint; and outputting the haptic effect.

Abstract: A haptic output device includes a substrate, an array of electrodes disposed on the substrate, and a layer of dielectric material disposed on the array of electrodes. The layer of dielectric material has an exposed outer surface comprising a micro-patterned texture configured to increase adhesion between the exposed outer surface and a contact surface in contact with the exposed outer surface. The haptic output device includes a controller configured to direct a voltage potential across the array of electrodes to generate an electrostatic adhesive force between the exposed outer surface and the contact surface as a haptic effect.

Abstract: A vehicle haptic feedback system includes a haptic actuator, a detection device, and a controller. The haptic actuator is configured to provide haptic feedback to a vehicle driver. The detection device is disposed in an interior of the vehicle and is configured to capture movements of the vehicle driver and output data representing the movements. The controller is coupled to the detection device and is configured to receive a signal from the detection device indicative of the movements. The controller is also coupled to a haptic effect feedback system. Based on the signal, the controller is configured to send a signal to select a haptic effect from an effect table and is configured to send a signal to the haptic actuator to provide the selected haptic effect. The haptic actuator is coupled to a driver's seat, a steering wheel, a driver's seat belt, and/or an object wearable by the driver.

Abstract: Systems and methods for controlling power and/or current consumption for multiple haptic output devices are provided. Various features of the haptic output device may be described within a data structure. In response to a haptic instruction, a power budget for the haptic output device may be determined in accordance with its operational characteristics. A drive signal may then be applied to the haptic output device to produce the haptic effect in accordance with the calculated power budget. The calculated power budget may be configured to limit the current or power drawn by the haptic output device.

Abstract: One illustrative system disclosed herein includes a case configured to mechanically couple with a mobile device and position the mobile device such that the mobile device serves as a display for the case. The system also includes a processor coupled to the case and configured to generate a haptic signal based at least in part on a characteristic of the case. The system also includes a haptic output device in communication with the processor and configured to receive the haptic signal and output a haptic effect in response to the haptic signal.

Abstract: One illustrative system disclosed herein includes a display configured to receive a display signal and output an image, and an image capture device configured to capture an area image and transmit an image signal. The illustrative system also includes a processor in communication with the image capture device and the display, the processor configured to: receive the image signal; determine a virtual object based in part on the image signal; determine the display signal based in part on the image signal, wherein the display signal includes data associated with the virtual object; determine a haptic effect based at least in part on the virtual object; and transmit a haptic signal associated with the haptic effect. The illustrative system further includes a haptic output device configured to receive the haptic signal and output the haptic effect.

Abstract: A system includes a sensor, a processor configured to receive a signal output by the sensor, determine a position and descriptor of the sensor, determine a scene selection of a video, and create a haptic signal based on the selected scene, the signal output by the sensor, and the position and descriptor of the sensor, and a haptic output device configured to receive the haptic signal and generate a haptic effect based on the haptic signal. A system includes a sensor, a processor configured to receive a signal from the sensor, determine a type of event and activity associated with the sensor, and generate a haptic signal based on the signal from the sensor and the type of event and activity associated with the sensor, and a haptic output device configured to generate a haptic effect based on the haptic signal.

Abstract: A haptic output device is configured to generate a deformation-based haptic effect and a vibration-based haptic effect. The haptic output device includes a shape memory material configured to change a shape thereof when heated and generate the deformation-based haptic effect, and a cooling device configured to cool the shape memory material and generate the vibration-based haptic effect.

Abstract: A haptic actuator comprising a base and a haptic transducer at least partially suspended by the base. The haptic transducer comprises a substrate and a smart material operably connected to the substrate. The smart material has resonance in response to an electrical signal having a determined frequency, and the resonance causes the haptic transducer to vibrate and deliver a haptic effect.