Abstract: Systems and methods for generating haptic effects associated with envelopes in audio signals are disclosed. One disclosed system for outputting haptic effects includes a processor configured to: receive an audio signal; determine an envelope associated with the audio signal; determine a haptic effect based in part on the envelope; and output a haptic signal associated with the haptic effect.

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: A system for authoring one or more haptic effects using a haptic effect authoring tool receives a haptification model that is based on a predetermined haptic effect style. The system receives an input that includes at least one of audio and video and a plurality of events. The system then, using the haptification model, recommends a haptic effect to be associated with a corresponding event from the input.

Abstract: Examples of devices, systems, and methods to automatically generate haptics based on visual odometry are disclosed. In one example, a video having a plurality of frames is received and an optical flow estimate between a first frame from the plurality of frames and a second frame from the plurality of frames is created. In this example, the second frame is subsequent to the first frame. An apparent movement of a stationary object between the first frame and the second frame is detected based at least in part on the optical flow estimate in this example and at least one haptic effect corresponding to the apparent movement of the stationary object is generated based at least in part on the optical flow estimate. The generated haptic effect(s) may be output to a haptic file or a haptic output device, or both.

Abstract: Systems and methods for compliance illusions with haptics are disclosed. One illustrative system described herein includes a user interface device including: a sensor configured to detect a gesture; a haptic output device configured to output haptic effects; and a processor coupled to the sensor and the haptic output device, the processor configured to: receive a sensor signal from the sensor; determine a user interaction in mixed reality; determine a haptic effect based in part on the sensor signal and the user interaction; and transmit a haptic signal associated with the haptic effect to the haptic output device.

Abstract: Examples of devices, systems, and methods to automatically generate haptics based on visual color features and motion analysis are disclosed. In one example, a video having a plurality of frames is received and masked frames for the video are generated by applying a color mask to the plurality of frames. An event between two of the masked frames is detected and an optical flow estimate is generated for these masked frames. At least one haptic effect corresponding to the event is generated based on the optical flow. The generated haptic effect(s) may be output to a haptic file or a haptic output device, or both.

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: One illustrative system disclosed herein includes a curved device that includes a curved outer housing. The illustrative system also includes a sensor configured to detect a user interaction with the curved device and transmit a sensor signal associated with the user interaction. The illustrative system additionally includes a processor in communication with the sensor, the processor configured to: receive the sensor signal from the sensor; determine a user interaction based on the sensor signal, determine a first haptic effect based at least in part on the user interaction, and transmit a haptic signal associated with the first haptic effect. The illustrative system also includes a haptic output device configured to receive the haptic signal and output the first haptic effect.

Abstract: A user interface device having a user input component, a mechanical metamaterial region, one or more actuators, and a control unit is presented. The mechanical metamaterial region is located over the user input component. The one or more actuators are coupled to the mechanical metamaterial region, which has an internal structure that is mechanically alterable with the one or more actuators, and has a mechanical property that changes in response to the alteration of the internal structure by the one or more actuators. The control unit is in communication with the one or more actuators, and is configured to determine whether the user input component is to be hidden from tactile perception, and to activate the one or more actuators to mechanically alter the internal structure of the mechanical metamaterial region.

Abstract: A system includes an image capture device configured to capture images, and a processor programmed with one or more computer program modules. When executed, the one or more computer program modules are configured to receive the images captured by the image capture device, generate a control signal for a haptic output device as the images are received, synchronize the images and the control signal, and output a video with the synchronized images and the control signal.

Abstract: Examples of devices, systems, and methods of controlling one or more contact conditions of an insulated static electrostatic force electrode are disclosed. One example device has an insulated static electrostatic force electrode and a flexible suspension attached to insulated the static electrostatic force electrode. In examples, the flexible suspension controls a contact condition of the static electrostatic force electrode to alter the static electrostatic force feedback provided by the insulated static electrostatic force electrode.

Abstract: Systems and methods for visual processing of spectrograms to generate haptic effects are disclosed. In one embodiment, a signal comprising at least an audio signal is received. One or more spectrograms may be generated based at least in part on the received signal. One or more haptic effects may be determined based at least in part on the spectrogram. For example, a generated spectrogram may be a two-dimensional image and this image can be analyzed to determine one or more haptic effects. Once a haptic effect has been determined, one or more haptic output signals can be generated. A generated haptic output signal may be output to one or more haptic output devices.

Abstract: One illustrative system disclosed herein includes an enclosure configured to define a boundary of a chamber, the chamber including a material, and a flexible layer coupled overtop of the chamber and configured to enclose the chamber. The illustrative system also includes a first actuation device configured to receive a first haptic signal and responsively output a first haptic effect by changing a characteristic of the material to deform the flexible layer. The illustrative system also includes a second actuation device configured to receive a second haptic signal and responsively output a second haptic effect by applying an electrical signal to the flexible layer. The illustrative system further includes a processor in communication with the first actuation device and the second actuation device. The processor is configured to transmit the first haptic signal to the first actuation device and the second haptic signal to the second actuation device.

Abstract: A system that generates haptic effects receives input media that includes audio data, video data, or sensory data. The system automatically generates a haptic effect track from the input media. The system then applies at least one filter to the automatically generated haptic effect track to generate a tuned haptic effect track.

Abstract: Systems and methods for generating haptic effects associated with audio signals are disclosed. One disclosed system for outputting haptic effects includes a processor configured to: receive an audio signal; determine a haptic effect based in part on the audio signal by: identifying one or more components in the audio signal; and determining a haptic effect associated with the one or more components; and output a haptic signal associated with the haptic effect.

Abstract: One illustrative system disclosed herein includes a computing device with an electrostatic force (“ESF”) haptic output device coupled to a surface of the computing device. The ESF haptic output device comprises a signal electrode that includes an insulation layer and a conductive layer positioned proximate to the insulation layer and the conductive layer is electrically coupled to a voltage supply to receive an amount of voltage for generating an ESF haptic effect, which can include a dynamic ESF haptic effect or a static ESF haptic effect. The ESF haptic output device can output the ESF haptic effect to the surface of the computing device to which the ESF haptic output device is coupled.

Abstract: An advanced haptic gamepad is provided. A controller having a plurality of surfaces, and a haptic output device located within its housing and coupled to an isolated deformable region disposed at one of the plurality of surfaces is provided. The isolated deformable region expands and contracts in response to the haptic output device. In addition, a controller having a plurality of isolated surface regions, and a plurality of haptic output devices located within its housing and coupled to respective isolated surface regions is provided. Each of the isolated surface regions is configured to provide localized haptic effects.

Abstract: Systems and methods for generating haptic effects associated with envelopes in audio signals are disclosed. One disclosed system for outputting haptic effects includes a processor configured to: receive an audio signal; determine an envelope associated with the audio signal; determine a haptic effect based in part on the envelope; and output a haptic signal associated with the haptic effect.

Abstract: Examples of externally-activated devices and systems are disclosed. One example system includes a first device having an actuation component; and a second device having a haptic output component, wherein: the first device and the second device are configured to be physically separable from each other; the actuation component is configured to transmit an actuation signal to the haptic output component while the first device and the second device are physically separated from each other, and the haptic output component configured to output a haptic effect in response to receiving the actuation signal and while the first device and the second device are physically separated from each other, the haptic effect based on the actuation 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.